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+***The Project Gutenberg Etext of Aeroplanes, by J. S. Zerbe***
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+Aeroplanes
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+by J. S. Zerbe***
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+September, 1998  [Etext #1445]
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+
+
+
+Aeroplanes
+
+by J. S. Zerbe
+
+
+
+
+
+Scanned by Charles Keller with OmniPage Professional OCR software
+
+
+
+
+
+AEROPLANES
+
+
+
+
+This work is not intended to set forth the exploits of aviators
+nor to give a history of the Art. It is a book of instructions
+intended to point out the theories of flying, as given by the
+pioneers, the practical application of power to the various
+flying structures; how they are built, the different methods of
+controlling them; the advantages and disadvantages of the types
+now in use; and suggestions as to the directions in which
+improvements are required.
+
+It distinctly points out wherein mechanical flight differs
+from bird flight, and what are the relations of shape, form, size
+and weight. It treats of kites, gliders and model aeroplanes,
+and has an Interesting chapter on the aeroplane and its uses In
+the great war. All the illustrations have been specially prepared
+for the work.
+
+
+Every Boy's Mechanical Library
+
+AEROPLANES
+
+BY
+J. S. ZERBE, M. E.
+Author of Automobiles--Motors
+
+
+COPYRIGHT, 1915, BY
+CUPPLES & LEON COMPANY
+NY
+
+
+CONTENTS
+
+INTRODUCTORY
+
+CHAPTER I. THEORIES AND FACTS ABOUT FLYING
+
+The "Science" of Aviation. Machine Types. Shape
+or Form not Essential. A Stone as a Flying Machine.
+Power the Great Element. Gravity as Power. Mass
+and Element in Flying. Momentum a Factor. Resistance.
+How Resistance Affects Shape. Mass and Resistance.
+The Early Tendency to Eliminate Momentum.
+Light Machines Unstable. The Application of
+Power. The Supporting Surfaces. Area not the Essential
+Thing. The Law of Gravity. Gravity. Indestructibility
+of Gravitation. Distance Reduces Gravitational
+Pull. How Motion Antagonizes Gravity. A
+Tangent. Tangential Motion Represents Centrifugal
+Pull. Equalizing the Two Motions. Lift and Drift.
+Normal Pressure. Head Resistance. Measuring Lift
+and Drift. Pressure at Different Angles. Difference
+Between Lift and Drift in Motion. Tables of Lift and
+Drift. Why Tables of Lift and Drift are Wrong.
+Langley's Law. Moving Planes vs. Winds. Momentum
+not Considered. The Flight of Birds. The
+Downward Beat. The Concaved Wing. Feather Structure
+Considered. Webbed Wings. The Angle of Movement.
+An Initial Movement or Impulse Necessary. A
+Wedging Motion. No Mystery in the Wave Motion.
+How Birds Poise with Flapping Wings. Narrow-
+winged Birds. Initial Movement of Soaring Birds.
+Soaring Birds Move Swiftly. Muscular Energy
+Exerted by Soaring Birds. Wings not Motionless.
+
+CHAPTER II. PRINCIPLES OF AEROPLANE FLIGHT
+Speed as one of the Elements. Shape and Speed.
+What "Square of the Speed" Means. Action of a
+"Skipper." Angle of Incidence. Speed and Surface.
+Control of the Direction of Flight. Vertical Planes.
+
+CHAPTER III. THE FORM OR SHAPE OF FLYING MACHINES
+The Theory of Copying Nature. Hulls of Vessels.
+Man Does not Copy Nature. Principles Essential, not
+Forms. Nature not the Guide as to Forms. The Propeller
+Type. Why Specially-designed Forms Improve
+Natural Structures. Mechanism Devoid of Intelligence.
+A Machine Must Have a Substitute for Intelligence.
+Study of Bird Flight Useless. Shape of
+Supporting Surface. The Trouble Arising From Outstretched
+Wings. Density of the Atmosphere. Elasticity
+of the Air. "Air Holes." Responsibility for
+Accidents. The Turning Movement. Centrifugal Action:
+The Warping Planes.
+
+CHAPTER IV. FORE AND AFT CONTROL
+The Bird Type of Fore and Aft Control. Angle and
+Direction of Flight. Why Should the Angle of the
+Body Change. Changing Angle of Body not Safe. A
+Non-changing Body. Descending Positions by Power
+Control. Cutting off the Power. The Starting Movement.
+The Suggested Type. The Low Center of Gravity.
+Fore and Aft Oscillations. Application of the
+New Principle. Low Weight not Necessary with Synchronously-
+moving wings.
+
+CHAPTEB V. DIFFERENT MACHINE TYPES AND THEIR CHARACTERISTICS
+The Helicopter. Aeroplanes. The Monoplane. Its
+Advantages. Its Disadvantages. The Bi-plane. Stability
+in Bi-planes. The Orthopter. Nature's Type
+not Uniform. Theories About Flight of Birds. Instinct.
+The Mode of Motion. The Wing Structure.
+The Wing Movement. The Helicopter Motion.
+
+CHAPTER VI. THE LIFTING SURFACES OF AEROPLANES
+Relative Speed and Angle. Narrow Planes Most Effective.
+Stream Lines Along a Plane. The Center of
+Pressure. Air Lines on the Upper Side of a Plane.
+Rarefied Area. Rarefaction Produced by Motion. The
+Concaved Plane. The Center of Pressure. Utilizing
+the Rarefied Area. Changing Center of Pressure.
+Plane Monstrosities. The Bird Wing Structure.
+Torsion. The Bat's Wing. An Abnormal Shape. The
+Tail as a Monitor.
+
+CHAPTER VII. ABNORMAL FLYING STUNTS AND SPEEDS
+Lack of Improvements in Machines. Men Exploited
+and not Machines. Abnormal Flying of no Value.
+The Art of Juggling. Practical Uses the Best Test.
+Concaved and Convex Planes. How Momentum is a
+Factor in Inverted Flying. The Turning Movement.
+When Concaved Planes are Desirable. The Speed
+Mania. Uses of Flying Machines. Perfection in Machines
+Must Come Before Speed. The Range of its
+Uses. Commercial Utility.
+
+CHAPTER VIII. KITES AND GLIDERS
+The Dragon Kite. Its Construction. The Malay
+Kite. Dihedral Angle. The Common Kite. The Bow
+Kite. The Box Kite. The Voison Bi-plane. Lateral
+Stability in Kites, not Conclusive as to Planes. The
+Spear Kite. The Cellular Kite. Tetrahedral Kite.
+The Deltoid. The Dunne Flying Machine. Rotating
+Kite. Kite Principles. Lateral Stability in Kites.
+Similarity of Fore and Aft Control. Gliding Flight
+One of the Uses of Glider Experiments. Hints in
+Gliding.
+
+CHAPTER IX. AEROPLANE CONSTRUCTION
+Lateral and Fore and Aft. Transverse. Stability
+and Stabilization. The Wright System. Controlling
+the Warping Ends. The Curtiss Wings. The Farman
+Ailerons. Features Well Developed. Depressing the
+Rear End. Determining the Size. Rule for Placing
+the Planes. Elevating Plane. Action in Alighting.
+The Monoplane. The Common Fly. Stream Lines.
+The Monoplane Form.
+
+CHAPTER X. POWER AND ITS APPLICATION
+Features in Power Application. Amount of Power
+Necessary. The Pull of the Propeller. Foot Pounds
+Small Amount of Power Available. High Propeller
+Speed Important. Width and Pitch of Blades. Effect
+of Increasing Propeller Pull. Disposition of the
+Planes. Different Speeds with Same Power. Increase
+of Speed Adds to Resistance. How Power Decreases
+with Speed. How to Calculate the Power Applied.
+Pulling Against an Angle. The Horizontal and the
+Vertical Pull. The Power Mounting. Securing the
+Propeller to the Shaft. Vibrations. Weaknesses in
+Mounting. The Gasoline Tank. Where to Locate the
+Tank. The Danger to the Pilot. The Closed-in Body.
+Starting the Machine. Propellers with Varying Pitch.
+
+CHAPTER XI. FLYING MACHINE ACCESSORIES
+The Anemometer. The Anemograph. The Anemometrograph.
+The Speed Indicator. Air Pressure Indicator.
+Determining the Pressure From the Speed.
+Calculating Pressure From Speed. How the Figures
+are Determined. Converting Hours Into Minutes.
+Changing Speed Hours to Seconds. Pressure as the
+Square of the Speed. Gyroscopic:Balance. The Principles
+Involved. The Application of the Gyroscope.
+Fore and Aft Gyroscopic Control. Angle Indicator.
+Pendulum Stabilizer. Steering and Controlling
+Wheel. Automatic Stabilizing Wings. Barometers.
+Aneroid Barometer. Hydroplanes. Sustaining Weight
+of Pontoons. Shape of the Pontoon.
+
+CHAPTER XII. EXPERIMENTAL WORK IN FLYING
+Certain Conditions in Flying. Heat in Air. Motion
+When in Flight. Changing Atmosphere. "Ascending
+Currents." "Aspirate Currents." Outstretched Wings.
+The Starting Point. The Vital Part of the Machine.
+Studying the Action of the Machine. Elevating the
+Machine. How to Practice. The First Stage. Patience
+the Most Difficult Thing. The Second Stage.
+The Third Stage. Observations While in Flight. Flying
+in a Wind. First Trials in a Quiet Atmosphere.
+Making Turns. The Fourth Stage. The Figure 8.
+The Vol Plane. The Landing. Flying Altitudes.
+
+CHAPTER XIII. THE PROPELLER
+Propeller Changes. Propeller Shape. The Diameter.
+Pitch. Laying Out the Pitch. Pitch Rule. Laminated
+Construction. Laying up a Propeller Form.
+Making Wide Blades. Propeller Outline. For High
+Speeds. Increasing Propeller Efficiency.
+
+CHAPTER XIV. EXPERIMENTAL GLIDERS AND MODEL AEROPLANES
+The Relation of Models to Flying Machines. Lessons
+From Models. Flying Model Aeroplanes. An
+Efficient Glider. The Deltoid Formation. Racing
+Models. The Power for Model Aeroplanes. Making
+the Propeller. Material for the Propeller. Rubber.
+Propeller Shape and Size. Supporting Surfaces.
+
+CHAPTER XV. THE AEROPLANE IN THE GREAT WAR
+Balloon Observations. Changed Conditions in Warfare.
+The Effort to Conceal Combatants. Smokeless
+Powder. Inventions to Attack Aerial Craft. Functions
+of the Aeroplane in War. Bomb-throwing Tests.
+Method for Determining the Movement of a Bomb.
+The Great Extent of Modern Battle Lines. The Aeroplane
+Detecting the Movements of Armies. The Effective
+Height for Scouting. Sizes of Objects at Great
+Distances. Some Daring Feats in War. The German
+Taube. How Aeroplanes Report Observations. Signal
+Flags. How Used. Casualties Due to Bombs
+From Aeroplanes.
+
+GLOSSARY
+
+
+
+INTRODUCTORY
+
+In preparing this volume on Flying Machines
+the aim has been to present the subject in such a
+manner as will appeal to boys, or beginners, in
+this field of human activity.
+
+The art of aviation is in a most primitive state.
+So many curious theories have been brought out
+that, while they furnish food for thought, do not,
+in any way, advance or improve the structure of
+the machine itself, nor are they of any service
+in teaching the novice how to fly.
+
+The author considers it of far more importance
+to teach right principles, and correct reasoning
+than to furnish complete diagrams of the details
+of a machine. The former teach the art, whereas
+the latter merely point out the mechanical
+arrangements, independently of the reasons for
+making the structures in that particular way.
+
+Relating the history of an art, while it may be
+interesting reading, does not even lay the foundations
+of a knowledge of the subject, hence that
+field has been left to others.
+
+The boy is naturally inquisitive, and he is interested
+in knowing WHY certain things are
+necessary, and the reasons for making structures in
+particular ways. That is the void into which
+these pages are placed.
+
+The author knows from practical experience,
+while experimenting with and building aeroplanes,
+how eagerly every boy inquires into details.
+They want the reasons for things.
+
+One such instance is related to evidence this
+spirit of inquiry. Some boys were discussing the
+curved plane structure. One of them ventured
+the opinion that birds' wings were concaved on the
+lower side. "But," retorted another, "why are
+birds' wings hollowed?"
+
+This was going back to first principles at one
+leap. It was not satisfying enough to know that
+man was copying nature. It was more important
+to know why nature originated that type of formation,
+because, it is obvious, that if such structures
+are universal in the kingdom of flying creatures,
+there must be some underlying principle
+which accounted for it.
+
+It is not the aim of the book to teach the art
+of flying, but rather to show how and why the
+present machines fly. The making and the using
+are separate and independent functions, and of
+the two the more important is the knowledge how
+to make a correct machine.
+
+Hundreds of workmen may contribute to the
+building of a locomotive, but one man, not a
+builder, knows better how to handle it. To
+manipulate a flying machine is more difficult to
+navigate than such a ponderous machine, because
+it requires peculiar talents, and the building is
+still more important and complicated, and requires
+the exercise of a kind of skill not necessary
+in the locomotive.
+
+The art is still very young; so much is done
+which arises from speculation and theories; too
+much dependence is placed on the aviator; the
+desire in the present condition of the art is to exploit
+the man and not the machine; dare-devil exhibitions
+seem to be more important than perfecting
+the mechanism; and such useless attempts as
+flying upside down, looping the loop, and characteristic
+displays of that kind, are of no value to
+the art.
+                              THE AUTHOR.
+
+
+
+AEROPLANES
+
+CHAPTER I
+
+THEORIES AND FACTS ABOUT FLYING
+
+
+THE "SCIENCE" OF AVIATION.--It may be
+doubted whether there is such a thing as a "science
+of aviation." Since Langley, on May 6,
+1896, flew a motor-propelled tandem monoplane
+for a minute and an half, without a pilot, and the
+Wright Brothers in 1903 succeeded in flying a
+bi-plane with a pilot aboard, the universal opinion
+has been, that flying machines, to be successful,
+must follow the structural form of birds, and
+that shape has everything to do with flying.
+
+We may be able to learn something by carefully
+examining the different views presented by
+those interested in the art, and then see how they
+conform to the facts as brought out by the actual
+experiments.
+
+MACHINE TYPES.--There is really but one type
+of plane machine. While technically two forms
+are known, namely, the monoplane and the
+bi-plane, they are both dependent on outstretched
+wings, longer transversely than fore and aft, so
+far as the supporting surfaces are concerned, and
+with the main weight high in the structure, thus,
+in every particular, conforming to the form
+pointed out by nature as the apparently correct
+type of a flying structure.
+
+SHAPE OR FORM NOT ESSENTIAL.--It may be
+stated with perfect confidence, that shape or form
+has nothing to do with the mere act of flying. It
+is simply a question of power. This is a broad
+assertion, and its meaning may be better understood
+by examining the question of flight in a
+broad sense.
+
+A STONE AS A FLYING MACHINE.--When a stone
+is propelled through space, shape is of no importance.
+If it has rough and jagged sides its speed
+or its distance may be limited, as compared with
+a perfectly rounded form. It may be made in
+such a shape as will offer less resistance to the air
+in flight, but its actual propulsion through space
+does not depend on how it is made, but on the
+power which propelled it, and such a missile is a
+true heavier-than-air machine.
+
+A flying object of this kind may be so constructed
+that it will go a greater distance, or require
+less power, or maintain itself in space at
+less speed; but it is a flying machine, nevertheless,
+in the sense that it moves horizontally through the
+air.
+
+POWER THE GREAT ELEMENT.--Now, let us examine
+the question of this power which is able to
+set gravity at naught. The quality called energy
+resides in material itself. It is something within
+matter, and does not come from without. The
+power derived from the explosion of a charge of
+powder comes from within the substance; and so
+with falling water, or the expansive force of
+steam.
+
+GRAVITY AS POWER.--Indeed, the very act of the
+ball gradually moving toward the earth, by the
+force of gravity, is an illustration of a power
+within the object itself. Long after Galileo
+firmly established the law of falling bodies it began
+to dawn on scientists that weight is force.
+After Newton established the law of gravitation
+the old idea, that power was a property of each
+body, passed away.
+
+In its stead we now have the firmly established
+view, that power is something which must have
+at least two parts, or consist in pairs, or two elements
+acting together. Thus, a stone poised on
+a cliff, while it exerts no power which can be
+utilized, has, nevertheless, what is called potential
+energy. When it is pushed from its lodging place
+kinetic energy is developed. In both cases,
+gravity, acting in conjunction with the mass of
+the stone, produced power.
+
+So in the case of gunpowder. It is the unity of
+two or more substances, that causes the expansion
+called power. The heat of the fuel converting
+water into steam, is another illustration of the
+unity of two or more elements, which are necessary
+to produce energy.
+
+MASS AN ELEMENT IN FLYING.--The boy who
+reads this will smile, as he tells us that the power
+which propelled the ball through the air came
+from the thrower and not from the ball itself.
+Let us examine this claim, which came from a real
+boy, and is another illustration how acute his mind
+is on subjects of this character.
+
+We have two balls the same diameter, one of
+iron weighing a half pound, and the other of cotton
+weighing a half ounce. The weight of one
+is, therefore, sixteen times greater than the other.
+
+Suppose these two balls are thrown with the
+expenditure of the same power. What will be the
+result! The iron ball will go much farther, or,
+if projected against a wall will strike a harder
+blow than the cotton ball.
+
+MOMENTUM A FACTOR.--Each had transferred
+to it a motion. The initial speed was the same,
+and the power set up equal in the two. Why this
+difference, The answer is, that it is in the
+material itself. It was the mass or density which accounted
+for the difference. It was mass multiplied
+by speed which gave it the power, called, in
+this case, momentum.
+
+The iron ball weighing eight ounces, multiplied
+by the assumed speed of 50 feet per second, equals
+400 units of work. The cotton ball, weighing 1/2
+ounce, with the same initial speed, represents 25
+units of work. The term "unit of work" means
+a measurement, or a factor which may be used to
+measure force.
+
+It will thus be seen that it was not the thrower
+which gave the power, but the article itself. A
+feather ball thrown under the same conditions,
+would produce a half unit of work, and the iron
+ball, therefore, produced 800 times more energy.
+
+RESISTANCE.--Now, in the movement of any body
+through space, it meets with an enemy at every
+step, and that is air resistance. This is much
+more effective against the cotton than the iron
+ball: or, it might be expressed in another way:
+The momentum, or the power, residing in the
+metal ball, is so much greater than that within the
+cotton ball that it travels farther, or strikes a
+more effective blow on impact with the wall.
+
+HOW RESISTANCE AFFECTS THE SHAPE.--It is because
+of this counterforce, resistance, that shape
+becomes important in a flying object. The metal
+ball may be flattened out into a thin disk, and now,
+when the same force is applied, to project it forwardly,
+it will go as much farther as the difference
+in the air impact against the two forms.
+
+MASS AND RESISTANCE.--Owing to the fact that
+resistance acts with such a retarding force on an
+object of small mass, and it is difficult to set up a
+rapid motion in an object of great density, lightness
+in flying machine structures has been considered,
+in the past, the principal thing necessary.
+
+THE EARLY TENDENCY TO ELIMINATE MOMENTUM.--
+Builders of flying machines, for several
+years, sought to eliminate the very thing
+which gives energy to a horizontally-movable
+body, namely, momentum.
+
+Instead of momentum, something had to be
+substituted. This was found in so arranging the
+machine that its weight, or a portion of it, would
+be sustained in space by the very element which
+seeks to retard its flight, namely, the atmosphere.
+
+If there should be no material substance, like
+air, then the only way in which a heavier-than-air
+machine could ever fly, would be by propelling it
+through space, like the ball was thrown, or by
+some sort of impulse or reaction mechanism on
+the air-ship itself. It could get no support from
+the atmosphere.
+
+LIGHT MACHINES UNSTABLE.--Gradually the
+question of weight is solving itself. Aviators are
+beginning to realize that momentum is a wonderful
+property, and a most important element in
+flying. The safest machines are those which have
+weight. The light, willowy machines are subject
+to every caprice of the wind. They are notoriously
+unstable in flight, and are dangerous even
+in the hands of experts.
+
+THE APPLICATION OF POWER.--The thing now to
+consider is not form, or shape, or the distribution
+of the supporting surfaces, but HOW to apply
+the power so that it will rapidly transfer a machine
+at rest to one in motion, and thereby get
+the proper support on the atmosphere to hold it
+in flight.
+
+THE SUPPORTING SURFACES.--This brings us to
+the consideration of one of the first great problems
+in flying machines, namely, the supporting
+surfaces,--not its form, shape or arrangement,
+(which will be taken up in their proper places), but
+the area, the dimensions, and the angle necessary
+for flight.
+
+AREA NOT THE ESSENTIAL THING.--The history
+of flying machines, short as it is, furnishes many
+examples of one striking fact: That area has
+but little to do with sustaining an aeroplane when
+once in flight. The first Wright flyer weighed
+741 pounds, had about 400 square feet of plane
+surface, and was maintained in the air with a 12
+horse power engine.
+
+True, that machine was shot into the air by a
+catapult. Motion having once been imparted to it,
+the only thing necessary for the motor was to
+maintain the speed.
+
+There are many instances to show that when
+once in flight, one horse power will sustain over
+100 pounds, and each square foot of supporting
+surface will maintain 90 pounds in flight.
+
+THE LAW OF GRAVITY.--As the effort to fly
+may be considered in the light of a struggle to
+avoid the laws of nature with respect to matter,
+it may be well to consider this great force as a
+fitting prelude to the study of our subject.
+
+Proper understanding, and use of terms is very
+desirable, so that we must not confuse them.
+Thus, weight and mass are not the same. Weight
+varies with the latitude, and it is different at various
+altitudes; but mass is always the same.
+
+If projected through space, a certain mass
+would move so as to produce momentum, which
+would be equal at all places on the earth's surface,
+or at any altitude.
+
+Gravity has been called weight, and weight
+gravity. The real difference is plain if gravity
+is considered as the attraction of mass for mass.
+Gravity is generally known and considered as a
+force which seeks to draw things to the earth.
+This is too narrow.
+
+Gravity acts in all directions. Two balls suspended
+from strings and hung in close proximity
+to each other will mutually attract each other.
+If one has double the mass it will have twice the
+attractive power. If one is doubled and the other
+tripled, the attraction would be increased six
+times. But if the distance should be doubled the
+attraction would be reduced to one-fourth; and
+if the distance should be tripled then the pull
+would be only one-ninth.
+
+The foregoing is the substance of the law,
+namely, that all bodies attract all other bodies
+with a force directly in proportion to their mass,
+and inversely as the square of their distance from
+one another.
+
+To explain this we cite the following illustration:
+Two bodies, each having a mass of 4
+pounds, and one inch apart, are attracted toward
+each other, so they touch. If one has twice the
+mass of the other, the smaller will draw the larger
+only one-quarter of an inch, and the large one
+will draw the other three-quarters of an inch,
+thus confirming the law that two bodies will attract
+each other in proportion to their mass.
+
+Suppose, now, that these balls are placed two
+inches apart,--that is, twice the distance. As
+each is, we shall say, four pounds in weight, the
+square of each would be 16. This does not mean
+that there would be sixteen times the attraction,
+but, as the law says, inversely as the square of
+the distance, so that at two inches there is only
+one-sixteenth the attraction as at one inch.
+
+If the cord of one of the balls should be cut, it
+would fall to the earth, for the reason that the
+attractive force of the great mass of the earth is
+so much greater than the force of attraction in
+its companion ball.
+
+INDESTRUCTIBILITY OF GRAVITATION.--Gravity
+cannot be produced or destroyed. It acts between
+all parts of bodies equally; the force being
+proportioned to their mass. It is not affected by
+any intervening substance; and is transmitted
+instantaneously, whatever the distance may be.
+
+While, therefore, it is impossible to divest matter
+of this property, there are two conditions
+which neutralize its effect. The first of these is
+position. Let us take two balls, one solid and
+the other hollow, but of the same mass, or density.
+If the cavity of the one is large enough to receive
+the other, it is obvious that while gravity is still
+present the lines of attraction being equal at
+all points, and radially, there can be no pull which
+moves them together.
+
+DISTANCE REDUCES GRAVITATIONAL PULL.--Or
+the balls may be such distance apart that the attractive
+force ceases. At the center of the earth
+an object would not weigh anything. A pound
+of iron and an ounce of wood, one sixteen times
+the mass of the other, would be the same,--absolutely
+without weight.
+
+If the object should be far away in space it
+would not be influenced by the earth's gravity;
+so it will be understood that position plays an
+important part in the attraction of mass for mass.
+
+HOW MOTION ANTAGONIZES GRAVITY.--The second
+way to neutralize gravity, is by motion. A
+ball thrown upwardly, antagonizes the force of
+gravity during the period of its ascent. In like
+manner, when an object is projected horizontally,
+while its mass is still the same, its weight is less.
+
+Motion is that which is constantly combating
+the action of gravity. A body moving in a circle
+must be acted upon by two forces, one which tends
+to draw it inwardly, and the other which seeks to
+throw it outwardly.
+
+The former is called centripetal, and the latter
+centrifugal motion. Gravity, therefore, represents
+centripetal, and motion centrifugal force.
+
+If the rotative speed of the earth should be retarded,
+all objects on the earth would be increased
+in weight, and if the motion should be accelerated
+objects would become lighter, and if sufficient
+speed should be attained all matter would fly off
+the surface, just as dirt dies off the rim of a
+wheel at certain speeds.
+
+A TANGENT.--When an object is thrown horizontally
+the line of flight is tangential to the earth,
+or at right angles to the force of gravity. Such
+a course in a flying machine finds less resistance
+than if it should be projected upwardly, or directly
+opposite the centripetal pull.
+
+_Fig 1. Tangential Flight_
+
+TANGENTIAL MOTION REPRESENTS CENTRIFUGAL
+PULL.--A tangential motion, or a horizontal
+movement, seeks to move matter away from the
+center of the earth, and any force which imparts
+a horizontal motion to an object exerts a centrifugal
+pull for that reason.
+
+In Fig. 1, let A represent the surface of the
+earth, B the starting point of the flight of an object,
+and C the line of flight. That represents a
+tangential line. For the purpose of explaining
+the phenomena of tangential flight, we will assume
+that the missile was projected with a sufficient
+force to reach the vertical point D, which
+is 4000 miles from the starting point B.
+
+In such a case it would now be over 5500 miles
+from the center of the earth, and the centrifugal
+pull would be decreased to such an extent that the
+ball would go on and on until it came within the
+sphere of influence from some other celestial
+body.
+
+EQUALIZING THE TWO MOTIONS.--But now let us
+assume that the line of flight is like that shown
+at E, in Fig. 2, where it travels along parallel
+with the surface of the earth. In this case the
+force of the ball equals the centripetal pull,--or,
+to put it differently, the centrifugal equals the
+gravitational pull.
+
+The constant tendency of the ball to fly off at
+a tangent, and the equally powerful pull of
+gravity acting against each other, produce a
+motion which is like that of the earth, revolving
+around the sun once every three hundred and
+sixty-five days.
+
+It is a curious thing that neither Langley, nor
+any of the scientists, in treating of the matter of
+flight, have taken into consideration this quality
+of momentum, in their calculations of the elements
+of flight.
+
+_Fig. 2 Horizontal Flight_
+
+All have treated the subject as though the
+whole problem rested on the angle at which the
+planes were placed. At 45 degrees the lift and
+drift are assumed to be equal.
+
+LIFT AND DRIFT.--The terms should be explained,
+in view of the frequent allusion which
+will be made to the terms hereinafter. Lift
+is the word employed to indicate the amount
+which a plane surface will support while in flight.
+Drift is the term used to indicate the resistance
+which is offered to a plane moving forwardly
+against the atmosphere.
+
+_Fig. 3. Lift and Drift_
+
+In Fig. 3 the plane A is assumed to be moving
+forwardly in the direction of the arrow B. This
+indicates the resistance. The vertical arrow C
+shows the direction of lift, which is the weight
+held up by the plane.
+
+NORMAL PRESSURE.--Now there is another term
+much used which needs explanation, and that is
+normal pressure. A pressure of this kind
+against a plane is where the wind strikes it at
+right angles. This is illustrated in Fig. 4, in
+which the plane is shown with the wind striking
+it squarely.
+
+It is obvious that the wind will exert a greater
+force against a plane when at its normal. On the
+other hand, the least pressure against a plane is
+when it is in a horizontal position, because then
+the wind has no force against the surfaces, and
+the only effect on the drift is that which takes
+place when the wind strikes its forward edge.
+
+_Fig. 4. Normal Air Pressure_
+
+_Fig. 5. Edge Resistance_
+
+
+HEAD RESISTANCE.--Fig. 5 shows such a plane,
+the only resistance being the thickness of the
+plane as at A. This is called head resistance,
+and on this subject there has been much controversy,
+and many theories, which will be considered
+under the proper headings.
+
+If a plane is placed at an angle of 45 degrees
+the lift and the drift are the same, assumedly, because,
+if we were to measure the power required
+to drive it forwardly, it would be found to equal
+the weight necessary to lift it. That is, suppose
+we should hold a plane at that angle with a heavy
+wind blowing against it, and attach two pairs of
+scales to the plane, both would show the same
+pull.
+
+_Fig. 6. Measuring Lift and Drift_
+
+MEASURING LIFT AND DRIFT.--In Fig. 6, A is the
+plane, B the horizontal line which attaches the
+plane to a scale C, and D the line attaching it to
+the scale E. When the wind is of sufficient force
+to hold up the plane, the scales will show the same
+pull, neglecting, of course, the weight of the
+plane itself.
+
+PRESSURE AT DIFFERENT ANGLES.--What every
+one wants to know, and a subject on which a
+great deal of experiment and time have been expended,
+is to determine what the pressures are at
+the different angles between the horizontal, and
+laws have been formulated which enable the pressures
+to be calculated.
+
+DIFFERENCE BETWEEN LIFT AND DRIFT IN MOTION.--The
+first observation is directed to the differences
+that exist between the lift and drift,
+when the plane is placed at an angle of less than
+45 degrees. A machine weighing 1000 pounds
+has always the same lift. Its mass does not
+change. Remember, now, we allude to its mass,
+or density.
+
+We are not now referring to weight, because
+that must be taken into consideration, in the
+problem. As heretofore stated, when an object
+moves horizontally, it has less weight than when
+at rest. If it had the same weight it would not
+move forwardly, but come to rest.
+
+When in motion, therefore, while the lift, so
+far as its mass is concerned, does not change, the
+drift does decrease, or the forward pull is less
+than when at 45 degrees, and the decrease is less
+and less until the plane assumes a horizontal position,
+where it is absolutely nil, if we do not consider
+head resistance.
+
+TABLES OF LIFT AND DRIFT.--All tables of Lift
+and Drift consider only the air pressures. They
+do not take into account the fact that momentum
+takes an important part in the translation of an
+object, like a flying machine.
+
+A mass of material, weighing 1000 pounds while
+at rest, sets up an enormous energy when moving
+through the air at fifty, seventy-five, or one hundred
+miles an hour. At the latter speed the movement
+is about 160 feet per second, a motion which
+is nearly sufficient to maintain it in horizontal
+flight, independently of any plane surface.
+
+Such being the case, why take into account only
+the angle of the plane? It is no wonder that
+aviators have not been able to make the theoretical
+considerations and the practical demonstrations
+agree.
+
+WHY TABLES OF LIFT AND DRIFT ARE WRONG.--
+A little reflection will show why such tables are
+wrong. They were prepared by using a plane
+surface at rest, and forcing a blast of air against
+the plane placed at different angles; and for determining
+air pressures, this is, no doubt, correct.
+But it does not represent actual flying conditions.
+It does not show the conditions existing
+in an aeroplane while in flight.
+
+To determine this, short of actual experiments
+with a machine in horizontal translation, is impossible,
+unless it is done by taking into account
+the factor due to momentum and the element
+attributable to the lift of the plane itself due to its
+impact against the atmosphere.
+
+LANGLEY'S LAW.--The law enunciated by
+Langley is, that the greater the speed the less the
+power required to propel it. Water as a propelling
+medium has over seven hundred times
+more force than air. A vessel having, for instance,
+twenty horse power, and a speed of ten
+miles per hour, would require four times that
+power to drive it through the water at double the
+speed. The power is as the square of the speed.
+
+With air the conditions are entirely different.
+The boat submergence in the water is practically
+the same, whether going ten or twenty miles an
+hour. The head resistance is the same, substantially,
+at all times in the case of the boat; with the
+flying machine the resistance of its sustaining
+surfaces decreases.
+
+Without going into a too technical description
+of the reasoning which led to the discovery of the
+law of air pressures, let us try and understand
+it by examining the diagram, Fig. 7.
+
+A represents a plane at an angle of 45 degrees,
+moving forwardly into the atmosphere in the
+direction of the arrows B. The measurement
+across the plane vertically, along the line B,
+which is called the sine of the angle, represents
+the surface impact of air against the plane.
+
+In Fig. 8 the plane is at an angle of 27 degrees,
+which makes the distance in height across the line
+C just one-half the length of the line B of Fig. 7,
+hence the surface impact of the air is one-half that
+of Fig. 7, and the drift is correspondingly decreased.
+
+_Fig. 7. Equal Lift and Drift in Flight._
+
+_Fig. 8. Unequal Lift and Drift._
+
+
+MOVING PLANES VS. WINDS.--In this way Boisset,
+Duchemin, Langley, and others, determined
+the comparative drift, and those results have been
+largely relied upon by aviators, and assumed to
+be correct when applied to flying machines.
+
+That they are not correct has been proven by
+the Wrights and others, the only explanation being
+that some errors had been made in the calculations,
+or that aviators were liable to commit errors
+in observing the true angle of the planes
+while in flight.
+
+MOMENTUM NOT CONSIDERED.--The great factor
+of momentum has been entirely ignored, and it is
+our desire to press the important point on those
+who begin to study the question of flying machines.
+
+THE FLIGHT OF BIRDS.--Volumes have been
+written concerning observations on the flight of
+birds. The marvel has been why do soaring birds
+maintain themselves in space without flapping
+their wings. In fact, it is a much more remarkable
+thing to contemplate why birds which depend
+on flapping wings can fly.
+
+THE DOWNWARD BEAT.--It is argued that the
+downward beat of the wings is so much more
+rapid than the upward motion, that it gets an action
+on the air so as to force the body upwardly.
+This is disposed of by the wing motion of many
+birds, notoriously the crow, whose lazily-flapping
+wings can be readily followed by the eye, and the
+difference in movement, if any, is not perceptible.
+
+THE CONCAVED WING.--It is also urged that the
+concave on the under side of the wing gives the
+quality of lift. Certain kinds of beetles, and particularly
+the common house fly, disprove that theory,
+as their wings are perfectly flat.
+
+FEATHER STRUCTURE CONSIDERED.--Then the
+feather argument is advanced, which seeks to
+show that as each wing is made up of a plurality
+of feathers, overlapping each other, they form a
+sort of a valved surface, opening so as to permit
+air to pass through them during the period of
+their upward movement, and closing up as the
+wing descends.
+
+It is difficult to perform this experiment with
+wings, so as to show such an individual feather
+movement. It is certain that there is nothing in
+the structure of the wing bone and the feather
+connection which points to any individual feather
+movement, and our observation is, that each
+feather is entirely too rigid to permit of such an
+opening up between them.
+
+It is obvious that the wing is built up in that
+way for an entirely different reason. Soaring
+birds, which do not depend on the flapping motion,
+have the same overlapping feather formation.
+
+WEBBED WINGS.--Furthermore, there are numerous
+flying creatures which do not have
+feathered wings, but web-like structures, or like the
+house fly, in one continuous and unbroken
+plane.
+
+That birds which fly with flapping wings derive
+their support from the air, is undoubtedly true,
+and that the lift produced is due, not to the form,
+or shape, or area of the wing, is also beyond question.
+The records show that every conceivable
+type of outlined structure is used by nature; the
+material and texture of the wings themselves differ
+to such a degree that there is absolutely no
+similarity; some have concaved under surfaces,
+and others have not; some fly with rapidly beating
+wings, and others with slow and measured
+movements; many of them fly with equal facility
+without flapping movements; and the proportions
+of weight to wing surface vary to such an extent
+that it is utterly impossible to use such data as a
+guide in calculating what the proper surface
+should be for a correct flying machine.
+
+THE ANGLE OF MOVEMENT.--How, then, it may
+be asked, do they get their support? There must
+be something, in all this variety and diversity of
+form, of motion, and of characteristics, which
+supplies the true answer. The answer lies in the
+angle of movement of every wing motion, which
+is at the control of the bird, and if this is examined
+it will be found that it supplies the correct
+answer to every type of wing which nature has
+made.
+
+AN INITIAL IMPULSE OR MOVEMENT NECESSARY.--
+Let A, Fig. 9, represent the section of a bird's
+wing. All birds, whether of the soaring or the
+flapping kind, must have an initial forward movement
+in order to attain flight. This impulse is
+acquired either by running along the ground, or
+by a leap, or in dropping from a perch. Soaring
+birds cannot, by any possibility, begin flight,
+unless there is such a movement to change from a
+position of rest to one of motion.
+
+_Fig. 9. Wing Movement in Flight._
+
+In the diagram, therefore, the bird, in moving
+forwardly, while raising the wing upwardly, depresses
+the rear edge of the wing, as in position
+1, and when the wing beats downwardly the rear
+margin is raised, in relation to its front margin,
+as shown in position 2.
+
+A WEDGING MOTION.--Thus the bird, by a
+wedge-like motion, gives a forwardly-propelling
+action, and as the rear margin has more or less
+flexure, its action against the air is less during its
+upward beat, and this also adds to the upward lift
+of the body of the bird.
+
+NO MYSTERY IN THE WAVE MOTION.--There is
+no mystery in the effect of such a wave-like motion,
+and it must be obvious that the humming
+bird, and like flyers, which poise at one spot, are
+able to do so because, instead of moving forwardly,
+or changing the position of its body horizontally,
+in performing the undulatory motion of
+the wing, it causes the body to rock, so that at the
+point where the wing joins the body, an elliptical
+motion is produced.
+
+_Fig. 10. Evolution of Humming-Bird's Wing._
+
+
+HOW BIRDS POISE WITH FLAPPING WINGS.--This
+is shown in Fig. 10, in which eight successive positions
+of the wing are shown, and wherein four
+of the position, namely, 1, 2, 3, and 4, represent
+the downward movement, and 6, 7, 8, and 9, the
+upward beat.
+
+All the wing angles are such that whether the
+suspension point of each wing is moving downwardly,
+or upwardly, a support is found in some
+part of the wing.
+
+NARROW-WINGED BIRDS.--Birds with rapid flapping
+motions have comparatively narrow wings,
+fore and aft. Those which flap slowly, and are
+not swift flyers, have correspondingly broader
+wings. The broad wing is also typical of the
+soaring birds.
+
+But how do the latter overcome gravitation
+without exercising some sort of wing movement?
+
+INITIAL MOVEMENT OF SOARING BIRDS.--Acute
+observations show that during the early stages
+of flight, before speed is acquired, they depend
+on the undulating movement of the wings, and
+some of them acquire the initial motion by flapping.
+When speed is finally attained it is difficult
+for the eye to note the motion of the wings.
+
+SOARING BIRDS MOVE SWIFTLY.--Now, the first
+observation is, that soaring birds are swiftly-
+moving creatures. As they sail overhead
+majestically they seem to be moving slowly. But
+distance is deceptive. The soaring bird travels
+at great speeds, and this in itself should be sufficient
+to enable us to cease wondering, when it is
+remembered that swift translation decreases
+weight, so that this factor does not, under those
+conditions, operate against flight.
+
+MUSCULAR ENERGY EXERTED BY SOARING BIRDS.
+--It is not conceivable that the mere will of the
+bird would impel it forwardly, without it exerted
+some muscular energy to keep up its speed. The
+distance at which the bird performs this wonderful
+evolution is at such heights from the observer
+that the eye cannot detect a movement.
+
+WINGS NOT MOTIONLESS.--While the wings appear
+to be absolutely motionless, it is more reasonable
+to assume that a slight sinuous movement,
+or a rocking motion is constantly kept up, which
+wedges forwardly with sufficient speed to compel
+momentum to maintain it in flight. To do so requires
+but a small amount of energy. The head
+resistance of the bird formation is reduced to a
+minimum, and at such high speeds the angle of
+incidence of the wings is very small, requiring but
+little aid to maintain it in horizontal flight.
+
+
+
+CHAPTER II
+
+PRINCIPLES OF AEROPLANE FLIGHT
+
+
+FROM the foregoing chapter, while it may be
+rightly inferred that power is the true secret of
+aeroplane flight, it is desirable to point out certain
+other things which must be considered.
+
+SPEED AS ONE OF THE ELEMENTS--Every boy,
+probably, has at some time or other thrown small
+flat stones, called "skippers." He has noticed
+that if they are particularly thin, and large in
+diameter, that there is a peculiar sailing motion,
+and that they move through the air in an undulating
+or wave-like path.
+
+Two things contribute to this motion; one is the
+size of the skipper, relative to its weight, and the
+other is its speed. If the speed is slow it will
+quickly wend its way to the earth in a gradual
+curve. This curved line is called its trajectory.
+If it is not very large diametrically, in proportion
+to its weight, it will also make a gradual curve in
+descending, without "skimming" up and down
+in its flight.
+
+SHAPE AND SPEED.--It has been observed, also,
+that a round ball, or an object not flattened out,
+will make a regular curved path, whatever the
+speed may be.
+
+It may be assumed, therefore, that the shape
+alone does not account for this sinuous motion;
+but that speed is the element which accounts for
+it. Such being the case it may be well to inquire
+into the peculiar action which causes a skipper
+to dart up and down, and why the path thus
+formed grows more and more accentuated as the
+speed increases.
+
+As will be more fully described in a later chapter,
+the impact of air against a moving body does
+not increase in proportion to its speed, but in the
+ratio of the square of the speed.
+
+WHAT SQUARE OF THE SPEED MEANS.--In mathematics
+a figure is squared when it is multiplied
+by itself. Thus, 4 X 4= 16; 5 X 5 = 25; and so
+on, so that 16 is the square of 4, and 25 the square
+of 5. It has been found that a wind moving at the
+speed of 20 miles an hour has a striking or pushing
+force of 2 pounds on every square foot of surface.
+
+If the wind travels twice as fast, or 40 miles
+an hour, the pushing force is not 4 pounds, but
+8 pounds. If the speed is 60 miles an hour the
+pushing force increases to 18 pounds.
+
+ACTION OF A SKIPPER.--When the skipper leaves
+the hands of the thrower it goes through the air
+in such a way that its fiat surface is absolutely
+on a line with the direction in which it is projected.
+
+At first it moves through the air solely by force
+of the power which impels it, and does not in any
+way depend on the air to hold it up. See Fig.
+1, in which A represents the line of projection,
+and B the disk in its flight.
+
+_Fig. 11. A Skipper in Flight._
+
+After it has traveled a certain distance, and
+the force decreases, it begins to descend, thus describing
+the line C, Fig. 1, the disk B, in this case
+descending, without changing its position, which
+might be described by saying that it merely settles
+down to the earth without changing its plane.
+
+The skipper still remains horizontal, so that as
+it moves toward the earth its flat surface, which
+is now exposed to the action of the air, meets
+with a resistance, and this changes the angle of
+the disk, so that it will not be horizontal. Instead
+it assumes the position as indicated at D,
+and this impinging effect against the air causes
+the skipper to move upwardly along the line E,
+and having reached a certain limit, as at, say E,
+it automatically again changes its angle and moves
+downwardly along the path F, and thus continues
+to undulate, more or less, dependent on the combined
+action of the power and weight, or momentum,
+until it reaches the earth.
+
+It is, therefore, clear that the atmosphere has
+an action on a plane surface, and that the extent
+of the action, to sustain it in flight, depends on two
+things, surface and speed.
+
+Furthermore, the greater the speed the less the
+necessity for surface, and that for gliding purposes
+speed may be sacrificed, in a large measure,
+where there is a large surface.
+
+This very action of the skipper is utilized by
+the aviator in volplaning,--that is, where the
+power of the engine is cut off, either by accident,
+or designedly, and the machine descends to the
+earth, whether in a long straight glide, or in a
+great circle.
+
+As the machine nears the earth it is caused to
+change the angle of flight by the control mechanism
+so that it will dart upwardly at an angle, or downwardly,
+and thus enable the pilot to sail to another
+point beyond where he may safely land.
+This changing the course of the machine so that
+it will glide upwardly, means that the incidence
+of the planes has been changed to a positive
+angle.
+
+ANGLE OF INCIDENCE.--In aviation this is a term
+given to the position of a plane, relative to the
+air against which it impinges. If, for instance,
+an aeroplane is moving through the air with the
+front margin of the planes higher than their rear
+margins, it is said to have the planes at a positive
+angle of incidence. If the rear margins are
+higher than the front, then the planes have a negative
+angle of incidence.
+
+The word incidence really means, a falling
+upon, or against; and it will be seen, therefore,
+that the angle of incidence means the tilt of the
+planes in relation to the air which strikes it.
+
+Having in view, therefore, that the two qualities,
+namely, speed and surface, bear an intimate
+relation with each other, it may be understood
+wherein mechanical flight is supposed to be analogous
+to bird flight.
+
+SPEED AND SURFACE.--Birds which poise in the
+air, like the humming bird, do so because they
+beat their wings with great rapidity. Those
+which soar, as stated, can do so only by moving
+through the atmosphere rapidly, or by having a
+large wing spread relative to the weight. It will
+thus be seen that speed and surface become the
+controlling factors in flight, and that while the
+latter may be entirely eliminated from the problem,
+speed is absolutely necessary under any and
+all conditions.
+
+By speed in this connection is not meant high
+velocity, but that a movement, produced by power
+expressed in some form, is the sole and most necessary
+requisite to movement through the air with
+all heavier-than-air machines.
+
+If sufficient power can be applied to an aeroplane,
+surface is of no consequence; shape need
+not be considered, and any sort of contrivance
+will move through the air horizontally.
+
+CONTROL OF THE DIRECTION OF FLIGHT.--But the
+control of such a body, when propelled through
+space by force alone, is a different matter. To
+change the machine from a straight path to a
+curved one, means that it must be acted upon by
+some external force.
+
+We have explained that power is something
+which is inherent in the thing itself. Now, in order
+that there may be a change imparted to a
+moving mass, advantage must be taken of the medium
+through which it moves,--the atmosphere.
+
+VERTICAL CONTROL PLANES.--If vertically-arranged
+planes are provided, either fore or aft of
+the machine, or at both ends, the angles of incidence
+may be such as to cause the machine to
+turn from its straight course.
+
+In practice, therefore, since it is difficult to supply
+sufficient power to a machine to keep it in motion
+horizontally, at all times, aeroplanes are provided
+with supporting surfaces, and this aid in
+holding it up grows less and less as its speed increases.
+
+But, however strong the power, or great the
+speed, its control from side to side is not dependent
+on the power of the engine, or the speed
+at which it travels through the air.
+
+Here the size of the vertical planes, and their
+angles, are the only factors to be considered, and
+these questions will be considered in their proper
+places.
+
+
+
+
+CHAPTER III
+
+THE FORM OR SHAPE OF FLYING MACHINES
+
+
+EVERY investigator, experimenter, and scientist,
+who has given the subject of flight study, proceeds
+on the theory that in order to fly man must
+copy nature, and make the machine similar to the
+type so provided.
+
+THE THEORY OF COPYING NATURE.--If such is the
+case then it is pertinent to inquire which bird is
+the proper example to use for mechanical flight.
+We have shown that they differ so radically in
+every essential, that what would be correct in one
+thing would be entirely wrong in another.
+
+The bi-plane is certainly not a true copy. The
+only thing in the Wright machine which in any
+way resembles the bird's wing, is the rounded end
+of the planes, and judging from other machines,
+which have square ends, this slight similarity does
+not contribute to its stability or otherwise help
+the structure.
+
+The monoplane, which is much nearer the bird
+type, has also sounded wing ends, made not so
+much for the purpose of imitating the wing of the
+bird, as for structural reasons.
+
+HULLS OF VESSELS.--If some marine architect
+should come forward and assert that he intended
+to follow nature by making a boat with a hull of
+the shape or outline of a duck, or other swimming
+fowl, he would be laughed at, and justly so, because
+the lines of vessels which are most efficient
+are not made like those of a duck or other swimming
+creatures.
+
+MAN DOES NOT COPY NATURE.--Look about you,
+and see how many mechanical devices follow the
+forms laid down by nature, or in what respect
+man uses the types which nature provides in devising
+the many inventions which ingenuity has
+brought forth.
+
+PRINCIPLES ESSENTIAL, NOT FORMS.--It is essential
+that man shall follow nature's laws. He cannot
+evade the principles on which the operations
+of mechanism depend; but in doing so he has, in
+nearly every instance, departed from the form
+which nature has suggested, and made the machine
+irrespective of nature's type.
+
+Let us consider some of these striking differences
+to illustrate this fact. Originally pins were
+stuck upon a paper web by hand, and placed in
+rows, equidistant from each other. This necessitates
+the cooperative function of the fingers and
+the eye. An expert pin sticker could thus assemble
+from four to five thousand pins a day.
+
+The first mechanical pinsticker placed over
+500,000 pins a day on the web, rejecting every bent
+or headless pin, and did the work with greater
+accuracy than it was possible to do it by hand.
+There was not the suggestion of an eye, or a finger
+in the entire machine, to show that nature furnished
+the type.
+
+NATURE NOT THE GUIDE AS TO FORMS.--Nature
+does not furnish a wheel in any of its mechanical
+expressions. If man followed nature's form
+in the building of the locomotive, it would move
+along on four legs like an elephant. Curiously
+enough, one of the first road wagons had "push
+legs,"--an instance where the mechanic tried to
+copy nature,--and failed.
+
+THE PROPELLER TYPE.--The well known propeller
+is a type of wheel which has no prototype in
+nature. It is maintained that the tail of a fish
+in its movement suggested the propeller, but the
+latter is a long departure from it.
+
+The Venetian rower, who stands at the stern,
+and with a long-bladed oar, fulcrumed to the
+boat's extremity, in making his graceful lateral
+oscillations, simulates the propelling motion of
+the tail in an absolutely perfect manner, but it is
+not a propeller, by any means comparable to the
+kind mounted on a shaft, and revoluble.
+
+How much more efficient are the spirally-formed
+blades of the propeller than any wing or fin movement,
+in air or sea. There is no comparison between
+the two forms in utility or value.
+
+Again, the connecting points of the arms and
+legs with the trunk of a human body afford the
+most perfect types of universal joints which nature
+has produced. The man-made universal
+joint has a wider range of movement, possesses
+greater strength, and is more perfect mechanically.
+A universal joint is a piece of mechanism
+between two elements, which enables them to be
+turned, or moved, at any angle relative to each
+other.
+
+But why multiply these instances. Like samples
+will be found on every hand, and in all directions,
+and man, the greatest of all of nature's
+products, while imperfect in himself, is improving
+and adapting the things he sees about him.
+
+WHY SPECIALLY-DESIGNED FORMS IMPROVE NATURAL
+STRUCTURES.--The reason for this is, primarily,
+that the inventor must design the article
+for its special work, and in doing so makes it better
+adapted to do that particular thing. The
+hands and fingers can do a multiplicity of things,
+but it cannot do any particular work with the facility
+or the degree of perfection that is possible
+with the machine made for that purpose.
+
+The hands and fingers will bind a sheaf of
+wheat, but it cannot compete with the special machine
+made for that purpose. On the other hand
+the binder has no capacity to do anything else than
+what it was specially made for.
+
+In applying the same sort of reasoning to the
+building of flying machines we must be led to the
+conclusion that the inventor can, and will, eventually,
+bring out a form which is as far superior to
+the form which nature has taught us to use as
+the wonderful machines we see all about us are
+superior to carry out the special work they were
+designed to do.
+
+On land, man has shown this superiority over
+matter, and so on the sea. Singularly, the submarines,
+which go beneath the sea, are very far
+from that perfected state which have been attained
+by vessels sailing on the surface; and while
+the means of transportation on land are arriving
+at points where the developments are swift and
+remarkable, the space above the earth has not yet
+been conquered, but is going through that same
+period of development which precedes the production
+of the true form itself.
+
+MECHANISM DEVOID OF INTELLIGENCE.--The great
+error, however, in seeking to copy nature's form
+in a flying machine is, that we cannot invest the
+mechanism with that which the bird has, namely,
+a guiding intelligence to direct it instinctively, as
+the flying creature does.
+
+A MACHINE MUST HAVE A SUBSTITUTE FOR INTELLIGENCE.
+--Such being the case it must be endowed
+with something which is a substitute. A
+bird is a supple, pliant organism; a machine is a
+rigid structure. One is capable of being directed
+by a mind which is a part of the thing itself; while
+the other must depend on an intelligence which is
+separate from it, and not responsive in feeling or
+movement.
+
+For the foregoing reasons success can never
+be attained until some structural form is devised
+which will consider the flying machine independently
+of the prototypes pointed out as the correct
+things to follow. It does not, necessarily, have to
+be unlike the bird form, but we do know that the
+present structures have been made and insisted
+upon blindly, because of this wrong insistence on
+forms.
+
+STUDY OF BIRD FLIGHT USELESS.--The study of
+the flight of birds has never been of any special
+value to the art. Volumes have been written on
+the subject. The Seventh Duke of Argyle, and
+later, Pettigrew, an Englishman, contributed a
+vast amount of written matter on the subject of
+bird flight, in which it was sought to show that
+soaring birds did not exert any power in flying.
+
+Writers and experimenters do not agree on the
+question of the propulsive power, or on the form
+or shape of the wing which is most effective, or
+in the matter of the relation of surface to weight,
+nor do they agree in any particular as to the effect
+and action of matter in the soaring principle.
+
+Only a small percentage of flying creatures use
+motionless wings as in soaring. By far, the
+greater majority use beating wings, a method of
+translation in air which has not met with success
+in any attempts on the part of the inventor.
+
+Nevertheless, experimenting has proceeded on
+lines which seek to recognize nature's form only,
+while avoiding the best known and most persistent
+type.
+
+SHAPE OF SUPPORTING SURFACES.--When we examine
+the prevailing type of supporting surfaces
+we cannot fail to be impressed with one feature,
+namely, the determination to insist on a broad
+spread of plane surface, in imitation of the bird
+with outstretched wings.
+
+THE TROUBLE ARISING FROM OUTSTRETCHED
+WINGS.--This form of construction is what brings
+all the troubles in its train. The literature on
+aviation is full of arguments on this subject, all
+declaring that a wide spread is essential, because,
+--birds fly that way.
+
+These assertions are made notwithstanding the
+fact that only a few years ago, in the great exhibit
+of aeroplanes in Paris, many unique forms of machines
+were shown, all of them capable of flying,
+as proven by numerous experiments, and among
+them were a half dozen types whose length fore
+and aft were much greater than transversely, and
+it was particularly noted that they had most wonderful
+stability.
+
+DENSITY OF THE ATMOSPHERE.--Experts declare
+that the density of the atmosphere varies throughout,
+--that it has spots here and there which are,
+apparently, like holes, so that one side or the
+other of the machine will, unaccountably, tilt, and
+sometimes the entire machine will suddenly drop
+for many feet, while in flight.
+
+ELASTICITY OF THE AIR.--Air is the most elastic
+substance known. The particles constituting it
+are constantly in motion. When heat or cold penetrate
+the mass it does so, in a general way, so as
+to permeate the entire body, but the conductivity
+of the atmospheric gases is such that the heat
+does not reach all parts at the same time.
+
+AIR HOLES.--The result is that varying strata
+of heat and cold seem to be superposed, and also
+distributed along the route taken by a machine,
+causing air currents which vary in direction and
+intensity. When, therefore, a rapidly-moving
+machine passes through an atmosphere so disturbed,
+the surfaces of the planes strike a mass of
+air moving, we may say, first toward the plane,
+and the next instant the current is reversed, and
+the machine drops, because its support is temporarily
+gone, and the aviator experiences the sensation
+of going into a "hole."
+
+RESPONSIBILITY FOR ACCIDENTS.--These so-called
+"holes" are responsible for many accidents. The
+outstretched wings, many of them over forty feet
+from tip to tip, offer opportunities for a tilt at one
+end or the other, which has sent so many machines
+to destruction.
+
+The high center of gravity in all machines makes
+the weight useless to counterbalance the rising
+end or to hold up the depressed wing.
+
+All aviators agree that these unequal areas of
+density extend over small spaces, and it is, therefore,
+obvious that a machine which is of such a
+structure that it moves through the air broadside
+on, will be more liable to meet these inequalities
+than one which is narrow and does not take in such
+a wide path.
+
+Why, therefore, persist in making a form which,
+by its very nature, invites danger? Because birds
+fly that way!
+
+THE TURNING MOVEMENT.--This structural arrangement
+accentuates the difficulty when the machine
+turns. The air pressure against the wing
+surface is dependent on the speed. The broad
+outstretched surfaces compel the wing at the outer
+side of the circle to travel faster than the inner
+one. As a result, the outer end of the aeroplane
+is elevated.
+
+CENTRIFUGAL ACTION.--At the same time the
+running gear, and the frame which carries it and
+supports the machine while at rest, being below
+the planes, a centrifugal force is exerted, when
+turning a circle, which tends to swing the wheels
+and frame outwardly, and thereby still further
+elevating the outer end of the plane.
+
+THE WARPING PLANES.--The only remedy to
+meet this condition is expressed in the mechanism
+which wraps or twists the outer ends of the planes,
+as constructed in the Wright machine, or the
+ailerons, or small wings at the rear margins of the
+planes, as illustrated by the Farman machine.
+The object of this arrangement is to decrease the
+angle of incidence at the rising end, and increase
+the angle at the depressed end, and thus, by manually-
+operated means keep the machine on an even
+keel.
+
+
+
+CHAPTER IV
+
+FORE AND AFT CONTROL
+
+
+THERE is no phase of the art of flying more important
+than the fore and aft control of an airship.
+Lateral stability is secondary to this feature, for
+reasons which will appear as we develop the
+subject.
+
+THE BIRD TYPE OF FORE AND AFT CONTROL.--
+Every aeroplane follows the type set by nature
+in the particular that the body is caused to oscillate
+on a vertical fore and aft plane while in
+flight. The bird has one important advantage,
+however, in structure. Its wing has a flexure at
+the joint, so that its body can so oscillate independently
+of the angle of the wings.
+
+The aeroplane has the wing firmly fixed to the
+body, hence the only way in which it is possible
+to effect a change in the angle of the wing is by
+changing the angle of the body. To be consistent
+the aeroplane should be so constructed that the
+angle of the supporting surfaces should be movable,
+and not controllable by the body.
+
+The bird, in initiating flight from a perch, darts
+downwardly, and changes the angle of the body to
+correspond with the direction of the flying start.
+When it alights the body is thrown so that its
+breast banks against the air, but in ordinary flight
+its wings only are used to change the angle of
+flight.
+
+ANGLE AND DIRECTION OF FLIGHT.--In order to
+become familiar with terms which will be frequently
+used throughout the book, care should be
+taken to distinguish between the terms angle and
+direction of flight. The former has reference to
+the up and down movement of an aeroplane,
+whereas the latter is used to designate a turning
+movement to the right or to the left.
+
+WHY SHOULD THE ANGLE OF THE BODY CHANGE?
+--The first question that presents itself is, why
+should the angle of the aeroplane body change?
+Why should it be made to dart up and down and
+produce a sinuous motion? Why should its nose
+tilt toward the earth, when it is descending, and
+raise the forward part of the structure while ascending?
+
+The ready answer on the part of the bird-form
+advocate is, that nature has so designed a flying
+structure. The argument is not consistent, because
+in this respect, as in every other, it is not
+made to conform to the structure which they seek
+to copy.
+
+CHANGING ANGLE OF BODY NOT SAFE.--Furthermore,
+there is not a single argument which can be
+advanced in behalf of that method of building,
+which proves it to be correct. Contrariwise, an
+analysis of the flying movement will show that it is
+the one feature which has militated against safety,
+and that machines will never be safe so long as
+the angle of the body must be depended upon to
+control the angle of flying.
+
+_Fig. 11a Monoplane in Flight._
+
+In Fig. 11a three positions of a monoplane are
+shown, each in horizontal flight. Let us say that
+the first figure A is going at 40 miles per hour,
+the second, B, at 50, and the third, C, at 60 miles.
+The body in A is nearly horizontal, the angle of
+the plane D being such that, with the tail E also
+horizontal, an even flight is maintained.
+
+When the speed increases to 50 miles an hour,
+the angle of incidence in the plane D must be
+decreased, so that the rear end of the frame must
+be raised, which is done by giving the tail an angle
+of incidence, otherwise, as the upper side of the
+tail should meet the air it would drive the rear
+end of the frame down, and thus defeat the attempt
+to elevate that part.
+
+_Fig. 12. Angles of Flight._
+
+As the speed increases ten miles more, the tail
+is swung down still further and the rear end of
+the frame is now actually above the plane of flight.
+In order, now, to change the angle of flight, without
+altering the speed of the machine, the tail is
+used to effect the control.
+
+Examine the first diagram in Fig. 12. This
+shows the tail E still further depressed, and the
+air striking its lower side, causes an upward movement
+of the frame at that end, which so much decreases
+the angle of incidence that the aeroplane
+darts downwardly.
+
+In order to ascend, the tail, as shown in the second
+diagram, is elevated so as to depress the rear
+end, and now the sustaining surface shoots upwardly.
+
+Suppose that in either of the positions 1 or 2,
+thus described, the aviator should lose control of
+the mechanism, or it should become deranged or
+"stick," conditions which have existed in the history
+of the art, what is there to prevent an accident?
+
+In the first case, if there is room, the machine
+will loop the loop, and in the second case the machine
+will move upwardly until it is vertical, and
+then, in all probability, as its propelling power is
+not sufficient to hold it in that position, like a
+helicopter, and having absolutely no wing supporting
+surface when in that position, it will dart
+down tail foremost.
+
+A NON-CHANGING BODY.--We may contrast the
+foregoing instances of flight with a machine having
+the sustaining planes hinged to the body in
+such a manner as to make the disposition of its
+angles synchronous with the tail. In other words,
+see how a machine acts that has the angle of flight
+controllable by both planes,--that is, the sustaining
+planes, as well as the tail.
+
+_Fig. 13. Planes on Non-changing Body._
+
+In Fig. 13 let the body of the aeroplane be horizontal,
+and the sustaining planes B disposed at
+the same angle, which we will assume to be 15
+degrees, this being the imaginary angle for illustrative
+purposes, with the power of the machine
+to drive it along horizontally, as shown in position
+1.
+
+In position 2 the angles of both planes are now
+at 10 degrees, and the speed 60 miles an hour,
+which still drives the machine forward horizontally.
+
+In position 3 the angle is still less, being now
+only 5 degrees but the speed is increased to 80
+miles per hour, but in each instance the body of
+the machine is horizontal.
+
+Now it is obvious that in order to ascend, in
+either case, the changing of the planes to a greater
+angle would raise the machine, but at the same
+time keep the body on an even keel.
+
+_Fig. 14. Descent with Non-changing Body._
+
+DESCENDING POSITIONS BY POWER CONTROL.--In
+Fig. 14 the planes are the same angles in the three
+positions respectively, as in Fig. 13, but now the
+power has been reduced, and the speeds are 30,
+25, and 20 miles per hour, in positions A, B and C.
+
+Suppose that in either position the power should
+cease, and the control broken, so that it would be
+impossible to move the planes. When the machine
+begins to lose its momentum it will descend on a
+curve shown, for instance, in Fig. 15, where position
+1 of Fig. 14 is taken as the speed and angles
+of the plane when the power ceased.
+
+_Fig. 15. Utilizing Momentum._
+
+CUTTING OFF THE POWER.--This curve, A, may
+reach that point where momentum has ceased as
+a forwardly-propelling factor, and the machine
+now begins to travel rearwardly. (Fig. 16.) It
+has still the entire supporting surfaces of the
+planes. It cannot loop-the-loop, as in the instance
+where the planes are fixed immovably to the body.
+
+Carefully study the foregoing arrangement, and
+it will be seen that it is more nearly in accord with
+the true flying principle as given by nature than
+the vaunted theories and practices now indulged
+in and so persistently adhered to.
+
+The body of a flying machine should not be oscillated
+like a lever. The support of the aeroplane
+should never be taken from it. While it may be
+impossible to prevent a machine from coming
+down, it can be prevented from overturning, and
+this can be done without in the least detracting
+from it structurally.
+
+_Fig. 16. Reversing Motion._
+
+The plan suggested has one great fault, however.
+It will be impossible with such a structure
+to cause it to fly upside down. It does not present
+any means whereby dare-devil stunts can be performed
+to edify the grandstand. In this respect
+it is not in the same class with the present types.
+
+THE STARTING MOVEMENT.--Examine this plan
+from the position of starting, and see the advantages
+it possesses. In these illustrations we
+have used, for convenience only, the monoplane
+type, and it is obvious that the same remarks apply
+to the bi-plane.
+
+Fig. 17 shows the starting position of the stock
+monoplane, in position 1, while it is being initially
+run over the ground, preparatory to launching.
+Position 2 represents the negative angle at which
+the tail is thrown, which movement depresses the
+rear end of the frame and thus gives the supporting
+planes the proper angle to raise the machine,
+through a positive angle of incidence, of the plane.
+
+_Fig. 17. Showing changing angle of body._
+
+THE SUGGESTED TYPE.--In Fig. 18 the suggested
+type is shown with the body normally in a horizontal
+position, and the planes in a neutral position,
+as represented in position 1. When sufficient
+speed had been attained both planes are
+turned to the same angle, as in position 2, and
+flight is initiated without the abnormal oscillating
+motion of the body.
+
+But now let us see what takes place the moment
+the present type is launched. If, by any error on
+the part of the aviator, he should fail to readjust
+the tail to a neutral or to a proper angle of incidence,
+after leaving the ground, the machine would
+try to perform an over-head loop.
+
+The suggested plan does not require this caution.
+The machine may rise too rapidly, or its
+planes may be at too great an angle for the power
+or the speed, or the planes may be at too small an
+angle, but in either case, neglect would not turn
+the machine to a dangerous position.
+
+These suggestions are offered to the novice, because
+they go to the very foundation of a correct
+understanding of the principles involved in the
+building and in the manipulation of flying machines
+and while they are counter to the beliefs of
+aviators, as is shown by the persistency in adhering
+to the old methods, are believed to be mechanically
+correct, and worthy of consideration.
+
+THE LOW CENTER OF GRAVITY.--But we have still
+to examine another feature which shows the wrong
+principle in the fixed planes. The question is
+often asked, why do the builders of aeroplanes
+place most of the weight up close to the planes?
+It must be obvious to the novice that the lower
+the weight the less liability of overturning.
+
+FORE AND AFT OSCILLATIONS.--The answer is,
+that when the weight is placed below the planes it
+acts like a pendulum. When the machine is traveling
+forward, and the propeller ceases its motion,
+as it usually does instantaneously, the weight, being
+below, and having a certain momentum, continues
+to move on, and the plane surface meeting
+the resistance just the same, and having no means
+to push it forward, a greater angle of resistance is
+formed.
+
+In Fig. 19 this action of the two forces is illustrated. The
+plane at the speed of 30 miles is at
+an angle of 15 degrees, the body B of the machine
+being horizontal, and the weight C suspended directly
+below the supporting surfaces.
+
+The moment the power ceases the weight continues
+moving forwardly, and it swings the forward
+end of the frame upwardly, Fig. 20, and we now
+have, as in the second figure, a new angle of incidence,
+which is 30 degrees, instead of 12. It will
+be understood that in order to effect a change in
+the position of the machine, the forward end ascends,
+as shown by the dotted line A.
+
+_Fig. 20. Action when Propeller ceases to pull._
+
+The weight a having now ascended as far as
+possible forward in its swing, and its motion
+checked by the banking action of the plan it will
+again swing back, and again carry with it the
+frame, thus setting up an oscillation, which is extremely
+dangerous.
+
+The tail E, with its unchanged angle, does not,
+in any degree, aid in maintaining the frame on
+an even keel. Being nearly horizontal while in
+flight, if not at a negative angle, it actually assists
+the forward end of the frame to ascend.
+
+APPLICATION OF THE NEW PRINCIPLE.--Extending
+the application of the suggested form, let us see
+wherein it will prevent this pendulous motion at
+the moment the power ceases to exert a forwardly-
+propelling force.
+
+_Fig. 21. Synchronously moving Planes._
+
+In Fig. 21 the body A is shown to be equipped
+with the supporting plane B and the tail a, so
+they are adjustable simultaneously at the same
+angle, and the weight D is placed below, similar to
+the other structure.
+
+At every moment during the forward movement
+of this type of structure, the rear end of
+the machine has a tendency to move upwardly,
+the same as the forward end, hence, when the
+weight seeks, in this case to go on, it acts on the
+rear plane, or tail, and causes that end to raise,
+and thus by mutual action, prevents any pendulous
+swing.
+
+LOW WEIGHT NOT NECESSARY WITH SYNCHRONOUSLY-MOVING WINGS.
+--A little reflection will convince
+any one that if the two wings move in harmony,
+the weight does not have to be placed low,
+and thus still further aid in making a compact
+machine. By increasing the area of the tail, and
+making that a true supporting surface, instead of
+a mere idler, the weight can be moved further
+back, the distance transversely across the planes
+may be shortened, and in that way still further
+increase the lateral stability.
+
+
+
+CHAPTER V
+
+DIFFERENT MACHINE TYPES AND THEIR CHARACTERISTICS
+
+
+THERE are three distinct types of heavier-than-
+air machines, which are widely separated in all
+their characteristics, so that there is scarcely a
+single feature in common.
+
+Two of them, the aeroplane, and the orthopter,
+have prototypes in nature, and are distinguished
+by their respective similarities to the soaring
+birds, and those with flapping wings.
+
+The Helicopter, on the other hand, has no antecedent
+type, but is dependent for its raising
+powers on the pull of a propeller, or a plurality
+of them, constructed, as will be pointed out hereinafter.
+
+AEROPLANES.--The only form which has met
+with any success is the aeroplane, which, in
+practice, is made in two distinct forms, one with
+a single set of supporting planes, in imitation of
+birds, and called a monoplane; and the other having
+two wings, one above the other, and called
+the bi-plane, or two-planes.
+
+All machines now on the market which do not
+depend on wing oscillations come under those
+types.
+
+THE MONOPLANE.--The single plane type has
+some strong claims for support. First of these
+is the comparatively small head resistance, due
+to the entire absence of vertical supporting posts,
+which latter are necessary with the biplane type.
+The bracing supports which hold the outer ends
+of the planes are composed of wires, which offer
+but little resistance, comparatively, in flight.
+
+ITS ADVANTAGES.--Then the vertical height of
+the machine is much less than in the biplane. As
+a result the weight, which is farther below the
+supporting surface than in the biplane, aids in
+maintaining the lateral stability, particularly
+since the supporting frame is higher.
+
+Usually, for the same wing spread, the monoplane
+is narrower, laterally, which is a further
+aid to prevent tilting.
+
+ITS DISADVANTAGES.--But it also has disadvantages
+which must be apparent from its structure.
+As all the supporting surface is concentrated
+in half the number of planes, they must
+be made of greater width fore and aft, and this,
+as we shall see, later on, proves to be a disadvantage.
+
+It is also doubted whether the monoplane can
+be made as strong structurally as the other form,
+owing to the lack of the truss formation which is
+the strong point with the superposed frame. A
+truss is a form of construction where braces can
+be used from one member to the next, so as to
+brace and stiffen the whole.
+
+THE BIPLANE.--Nature does not furnish a type
+of creature which has superposed wings. In this
+particular the inventor surely did not follow nature.
+The reasons which led man to employ this
+type may be summarized as follows:
+
+In experimenting with planes it is found that
+a broad fore and aft surface will not lift as much
+as a narrow plane. This subject is fully explained
+in the chapter on The Lifting Surfaces of
+Planes. In view of that the technical descriptions
+of the operation will not be touched upon
+at this place, except so far as it may be necessary
+to set forth the present subject.
+
+This peculiarity is due to the accumulation of
+a mass of moving air at the rear end of the plane,
+which detracts from its lifting power. As it
+would be a point of structural weakness to make
+the wings narrow and very long, Wenham many
+years ago suggested the idea of placing one plane
+above the other, and later on Chanute, an
+engineer, used that form almost exclusively, in
+experimenting with his gliders.
+
+It was due to his influence that the Wrights
+adopted that form in their gliding experiments,
+and later on constructed their successful flyers
+in that manner. Originally the monoplane was
+the type generally employed by experimenters,
+such as Lilienthal, and others.
+
+STABILITY IN BIPLANES.--Biplanes are not naturally
+as stable laterally as the monoplane.
+The reason is, that a downward tilt has the benefit
+of only a narrow surface, comparable with the
+monoplane, which has broadness of wing.
+
+To illustrate this, let us assume that we have
+a biplane with planes five feet from front to rear,
+and thirty-six feet in length. This would give
+two planes with a sustaining surface of 360 square
+feet. The monoplane would, probably, divide
+this area into one plane eight and a half feet from
+front to rear, and 42 feet in length.
+
+In the monoplane each wing would project out
+about three feet more on each side, but it would
+have eight and a half feet fore and aft spread
+to the biplane's five feet, and thus act as a greater
+support.
+
+THE ORTHOPTER.--The term orthopter, or ornithopter,
+meaning bird wing, is applied to such
+flying machines as depend on wing motion to support
+them in the air.
+
+Unquestionably, a support can be obtained by
+beating on the air but to do so it is necessary to
+adopt the principle employed by nature to secure
+an upward propulsion. As pointed out elsewhere,
+it cannot be the concaved type of wing,
+or its shape, or relative size to the weight it must
+carry.
+
+As nature has furnished such a variety of data
+on these points, all varying to such a remarkable
+degree, we must look elsewhere to find the secret.
+Only one other direction offers any opportunity,
+and that is in the individual wing movement.
+
+NATURE'S TYPE NOT UNIFORM.--When this is
+examined, the same obscurity surrounds the issue.
+Even the speeds vary to such an extent that when
+it is tried to differentiate them, in comparison
+with form, shape, and construction, the experimenter
+finds himself wrapt in doubt and perplexity.
+
+But birds do fly, notwithstanding this wonderful
+array of contradictory exhibitions. Observation
+has not enabled us to learn why these things
+are so. High authorities, and men who are expert
+aviators, tell us that the bird flies because
+it is able to pick out ascending air currents.
+
+THEORIES ABOUT FLIGHT OF BIRDS.--Then we
+are offered the theory that the bird has an instinct
+which tells it just how to balance in the
+air when its wings are once set in motion.
+Frequently, what is taken for instinct, is something
+entirely different.
+
+It has been assumed, for instance, that a cyclist
+making a turn at a rapid speed, and a bird flying
+around a circle will throw the upper part of the
+body inwardly to counteract the centrifugal force
+which tends to throw it outwardly.
+
+Experiments with the monorail car, which is
+equipped with a gyroscope to hold it in a vertical
+position, show that when the car approaches a
+curve the car will lean inwardly, exactly the same
+as a bird, or a cyclist, and when a straight stretch
+is reached, it will again straighten up.
+
+INSTINCT.--Now, either the car, so equipped
+possesses instinct, or there must be a principle
+in the laws of nature which produces the similarity
+of action.
+
+In like manner there must be some principle
+that is entirely independent of the form of matter,
+or its arrangement, which enables the bird
+to perform its evolutions. We are led to believe
+from all the foregoing considerations that it is
+the manner or the form of the motion.
+
+MODE OF MOTION.--In this respect it seems to
+be comparable in every respect to the great and
+universal law of the motions in the universe.
+Thus, light, heat and electricity are the same, the
+manifestations being unlike only because they
+have different modes of motion.
+
+Everything in nature manifests itself by motion.
+It is the only way in which nature acts.
+Every transformation from one thing to another,
+is by way of a movement which is characteristic
+in itself.
+
+Why, then, should this great mystery of nature,
+act unlike the other portions of which it is
+a part?
+
+THE WING STRUCTURE.--The wing structure of
+every flying creature that man has examined, has
+one universal point of similarity, and that is the
+manner of its connection with the body. It is a
+sort of universal joint, which permits the wing
+to swing up and down, perform a gyratory movement
+while doing so, and folds to the rear when
+at rest.
+
+Some have these movements in a greater or
+less degree, or capable of a greater range; but
+the joint is the same, with scarcely an exception.
+When the stroke of the wing is downwardly the
+rear margin is higher than the front edge, so
+that the downward beat not only raises the body
+upwardly, but also propels it forwardly.
+
+THE WING MOVEMENT.--The moment the wing
+starts to swing upwardly the rear end is
+depressed, and now, as the bird is moving forwardly,
+the wing surface has a positive angle of
+incidence, and as the wing rises while the forward
+motion is taking place, there is no resistance
+which is effective enough to counteract the
+momentum which has been set up.
+
+The great problem is to put this motion into a
+mechanical form. The trouble is not ascribable
+to the inability of the mechanic to describe this
+movement. It is an exceedingly simple one.
+The first difficulty is in the material that must
+be used. Lightness and strength for the wing
+itself are the first requirements. Then rigidity
+in the joint and in the main rib of the wing, are
+the next considerations.
+
+In these respects the ability of man is limited.
+The wing ligatures of flying creatures is exceedingly
+strong, and flexible; the hollow bone formation
+and the feathers are extremely light, compared
+with their sustaining powers.
+
+THE HELICOPTER MOTION.--The helicopter, or
+helix-wing, is a form of flying machine which depends
+on revolving screws to maintain it in the
+air. Many propellers are now made, six feet in
+length, which have a pull of from 400 to 500
+pounds. If these are placed on vertically-disposed
+shafts they would exert a like power to
+raise a machine from the earth.
+
+Obviously, it is difficult to equip such a machine
+with planes for sustaining it in flight, after it is
+once in the air, and unless such means are provided
+the propellers themselves must be the
+mechanism to propel it horizontally.
+
+This means a change of direction of the shafts
+which support the propellers, and the construction
+is necessarily more complicated than if they
+were held within non-changeable bearings.
+
+This principle, however, affords a safer means
+of navigating than the orthopter type, because
+the blades of such an instrument can be forced
+through the air with infinitely greater speed than
+beating wings, and it devolves on the inventor to
+devise some form of apparatus which will permit
+the change of pull from a vertical to a horizontal
+direction while in flight.
+
+
+
+CHAPTER VI
+
+THE LIFTING SURFACES OF AEROPLANES
+
+
+THIS subject includes the form, shape and angle
+of planes, used in flight. It is the direction in
+which most of the energy has been expended in
+developing machines, and the true form is still
+involved in doubt and uncertainty.
+
+RELATIVE SPEED AND ANGLE.--The relative
+speed and angle, and the camber, or the curved
+formation of the plane, have been considered in
+all their aspects, so that the art in this respect has
+advanced with rapid strides.
+
+NARROW PLATES MOST EFFECTIVE.--It was
+learned, in the early stages of the development
+by practical experiments, that a narrow plane,
+fore and aft, produces a greater lift than a wide
+one, so that, assuming the plane has 100 square
+feet of sustaining surface, it is far better to make
+the shape five feet by twenty than ten by ten.
+
+However, it must be observed, that to use the
+narrow blade effectively, it must be projected
+through the air with the long margin forwardly.
+Its sustaining power per square foot of surface
+is much less if forced through the air lengthwise.
+
+Experiments have shown why a narrow blade
+has proportionally a greater lift, and this may
+be more clearly understood by examining the
+illustrations which show the movement of planes
+through the air at appropriate angles.
+
+_Fig. 22. Stream lines along a plane._
+
+STREAM LINES ALONG A PLANE.--In Fig. 22, A
+is a flat plane, which we will assume is 10 feet
+from the front to the rear margin. For convenience
+seven stream lines of air are shown,
+which contact with this inclined surface. The first
+line 1, after the contact at the forward end, is
+driven downwardly along the surface, so that it
+forms what we might term a moving film.
+
+The second air stream 2, strikes the first stream,
+followed successively by the other streams, 3, 4,
+and so on, each succeeding stream being compelled
+to ride over, or along on the preceding mass of
+cushioned air, the last lines, near the lower end,
+being, therefore, at such angles, and contacting
+with such a rapidly-moving column, that it produces
+but little lift in comparison with the 1st,
+2d and 3d stream lines. These stream lines are
+taken by imagining that the air approaches and
+contacts with the plane only along the lines indicated
+in the sketch, although they also in practice
+are active against every part of the plane.
+
+THE CENTER OF PRESSURE.--In such a plane the
+center of pressure is near its upper end, probably
+near the line 3, so that the greater portion of the
+lift is exerted by that part of the plane above
+line 3.
+
+AIR LINES ON THE UPPER SIDE OF THE PLANE.--
+Now, another factor must be considered, namely,
+the effect produced on the upper side of the plane,
+over which a rarefied area is formed at certain
+points, and, in practice, this also produces, or
+should be utilized to effect a lift.
+
+RAREFIED AREA.--What is called a rarefied area,
+has reference to a state or condition of the atmosphere
+which has less than the normal pressure or
+quantity of air. Thus, the pressure at sea level,
+is about 14 3/4 per square inch
+
+As we ascend the pressure grows less, and the
+air is thus rarer, or, there is less of it. This is a
+condition which is normally found in the atmosphere.
+Several things tend to make a rarefied
+condition. One is altitude, to which we have just
+referred.
+
+Then heat will expand air, making it less dense,
+or lighter, so that it will move upwardly, to be
+replaced by a colder body of air. In aeronautics
+neither of these conditions is of any importance
+in considering the lifting power of aeroplane surfaces.
+
+RAREFACTION PRODUCED BY MOTION.--The third
+rarefied condition is produced by motion, and generally
+the area is very limited when brought about
+by this means. If, for instance, a plane is held
+horizontally and allowed to fall toward the earth,
+it will be retarded by two forces, namely, compression
+and rarefaction, the former acting on the
+under side of the plane, and the latter on the upper
+side.
+
+Of the two rarefaction is the most effectual,
+and produces a greater effect than compression.
+This may be proven by compressing air in a long
+pipe, and noting the difference in gauge pressure
+between the ends, and then using a suction pump
+on the same pipe.
+
+When a plane is forced through the air at any
+angle, a rarefied area is formed on the side which
+is opposite the one having the positive angle of
+incidence.
+
+If the plane can be so formed as to make a large
+and effective area it will add greatly to the value
+of the sustaining surface.
+
+Unfortunately, the long fiat plane does not lend
+any aid in this particular, as the stream line flows
+down along the top, as shown in Fig. 23, without
+being of any service.
+
+_Fig. 23. Air lines on the upper side of a Plane._
+
+THE CONCAVED PLANE.--These considerations
+led to the adoption of the concaved plane formation,
+and for purposes of comparison the diagram,
+Fig. 24, shows the plane B of the same length and
+angle as the straight planes.
+
+In examining the successive stream lines it will
+be found that while the 1st, 2d and 3d lines have
+a little less angle of impact than the corresponding
+lines in the straight plane, the last lines, 5, 6
+and 7, have much greater angles, so that only line
+4 strikes the plane at the same angle.
+
+Such a plane structure would, therefore, have
+its center of pressure somewhere between the
+lines 3 and 4, and the lift being thus, practically,
+uniform over the surface, would be more effective.
+
+THE CENTER OF PRESSURE.--This is a term used
+to indicate the place on the plane where the air
+acts with the greatest force. It has reference to
+a point between the front and rear margins only
+of the plane.
+
+_Fig. 24. Air lines below a concaved Plane._
+
+UTILIZING THE RAREFIED AREA.--This structure,
+however, has another important advantage, as it
+utilizes the rarefied area which is produced, and
+which may be understood by reference to Fig. 25.
+
+The plane B, with its upward curve, and at the
+same angle as the straight plane, has its lower
+end so curved, with relation to the forward movement,
+that the air, in rushing past the upper end,
+cannot follow the curve rapidly enough to maintain
+the same density along C, hence this exerts
+
+an upward pull, due to the rarefied area, which
+serves as a lifting force, as well as the compressed
+mass beneath the plane.
+
+CHANGING CENTER OF PRESSURE.--The center of
+pressure is not constant. It changes with the
+angle of the plane, but the range is considerably
+less on a concave surface than on a flat plane.
+
+_Fig. 25. Air lines above a convex Plane._
+
+In a plane disposed at a small angle, A, as in
+Fig. 26, the center of pressure is nearer the forward
+end of the plane than with a greater positive
+angle of incidence, as in Fig. 27, and when
+the plane is in a normal flying angle, it is at the
+center, or at a point midway between the margins.
+
+PLANE MONSTROSITIES.--Growing out of the idea
+that the wing in nature must be faithfully copied,
+it is believed by many that a plane with a
+pronounced thickness at its forward margin is one
+of the secrets of bird flight.
+
+Accordingly certain inventors have designed
+types of wings which are shown in Figs. 28 and
+29.
+
+_Fig. 28 Changing centers of Pressures._
+
+_Fig 29. Bird-wing structures._
+
+Both of these types have pronounced bulges,
+designed to "split" the air, forgetting, apparently,
+that in other parts of the machine every effort is
+made to prevent head resistance.
+
+THE BIRD WING STRUCTURE.--The advocates of
+such construction maintain that the forward edge
+of the plane must forcibly drive the air column
+apart, because the bird wing is so made, and that
+while it may not appear exactly logical, still there
+is something about it which seems to do the work,
+and for that reason it is largely adopted.
+
+WHY THE BIRD'S WING HAS A PRONOUNCED
+BULGE.--Let us examine this claim. The bone
+which supports the entire wing surface, called the
+(pectoral), has a heavy duty to perform. It is so
+constructed that it must withstand an extraordinary
+torsional strain, being located at the forward
+portion of the wing surface. Torsion has
+reference to a twisting motion.
+
+In some cases, as in the bat, this primary bone
+has an attachment to the rear of the main joint,
+where the rear margin of the wing is attached to
+the leg of the animal, thus giving it a support
+and the main bone is, therefore, relieved of this
+torsional stress.
+
+THE BAT'S WING.--An examination of the bat's
+wing shows that the pectoral bone is very small
+and thin, thus proving that when the entire wing
+support is thrown upon the primary bone it must
+be large enough to enable it to carry out its functions.
+It is certainly not so made because it is a
+necessary shape which best adapts it for flying.
+
+If such were the case then nature erred in the
+case of the bat, and it made a mistake in the
+housefly's wing which has no such anterior enlargement
+to assist (?) it in flying.
+
+AN ABNORMAL SHAPE.--Another illustration is
+shown in Fig. 30, which has a deep concave directly
+behind the forward margin, as at A, so
+that when the plane is at an angle of about 22
+degrees, a horizontal line, as B, passing back from
+the nose, touches the incurved surface of the plane
+at a point about one-third of its measurement
+back across the plane.
+
+_Fig. 30. One of the Monstrosities_
+
+This form is an exact copy of the wing of an
+actual bird, but it belongs, not to the soaring,
+but to the class which depends on flapping wings,
+and as such it cannot be understood why it should
+be used for soaring machines, as all aeroplanes
+are.
+
+The foregoing instances of construction are
+cited to show how wildly the imagination will
+roam when it follows wrong ideals.
+
+THE TAIL AS A MONITOR.--The tendency of the
+center of pressure to change necessitates a correctional
+means, which is supplied in the tail of
+the machine, just as the tail of a kite serves to
+hold it at a correct angle with respect to the wind
+and the pull of the supporting string.
+
+
+
+
+CHAPTER VII
+
+ABNORMAL FLYING STUNTS AND SPEEDS
+
+
+"PEQUOD, a Frenchman, yesterday repeatedly
+performed the remarkable feat of flying with the
+machine upside down. This exhibition shows
+that the age of perfection has arrived in flying
+machines, and that stability is an accomplished
+fact."--News item.
+
+
+This is quoted to show how little the general
+public knows of the subject of aviation. It correctly
+represents the achievement of the aviator,
+and it probably voiced the sentiment of many
+scientific men, as well as of the great majority of
+aviators.
+
+A few days afterwards, the same newspaper
+published the following:
+
+
+"Lieutenant ----, while experimenting yesterday
+morning, met his death by the overturning
+of his machine at an altitude of 300 meters.
+Death was instantaneous, and the machine was
+completely destroyed."
+
+The machines used by the two men were of the
+same manufacture, as Pequod used a stock machine
+which was strongly braced to support the
+inverted weight, but otherwise it was not unlike
+the well known type of monoplane.
+
+Beachy has since repeated the experiment with
+a bi-plane, and it is a feat which has many imitators,
+and while those remarkable exhibitions
+are going on, one catastrophe follows the other
+with the same regularity as in the past.
+
+Let us consider this phase of flying. Are they
+of any value, and wherein do they teach anything
+that may be utilized,
+
+LACK OF IMPROVEMENTS IN MACHINES.--It is remarkable
+that not one single forward step has
+been taken to improve the type of flying machines
+for the past five years. They possess the same
+shape, their stabilizing qualities and mechanism
+for assuring stability are still the same.
+
+MEN EXPEDITED, AND NOT THE MACHINE.--The
+fact is, that during this period the man has been
+exploited and not the machine. Men have learned,
+some few of them, to perform peculiar stunts,
+such as looping the loop, the side glide, the drop,
+and other features, which look, and are, hazardous,
+all of which pander to the sentiments of the spectators.
+
+ABNORMAL FLYING OF NO VALUE.--It would be
+too broad an assertion to say that it has absolutely
+no value, because everything has its use
+in a certain sense, but if we are to judge from
+the progress of inventions in other directions,
+such exhibitions will not improve the art of building
+the device, or make a fool-proof machine.
+
+Indeed, it is the very thing which serves as a
+deterrent, rather than an incentive. If machines
+can be handled in such a remarkable manner, they
+must be, indeed, perfect! Nothing more is
+needed! They must represent the highest structural
+type of mechanism!
+
+That is the idea sought to be conveyed in the
+first paragraph quoted. It is pernicious, instead
+of praiseworthy, because it gives a false impression,
+and it is remarkable that even certain scientific
+journals have gravely discussed the perfected
+(?) type of flying machine as demonstrated
+by the experiments alluded to.
+
+THE ART OF JUGGLING.--We may, occasionally,
+see a cyclist who understands the art of balancing
+so well that he can, with ease, ride a machine
+which has only a single wheel; or he can, with a
+stock bicycle, ride it in every conceivable attitude,
+and make it perform all sorts of feats.
+
+It merely shows that man has become an
+expert at juggling with a machine, the same as he
+manipulates balls, and wheels, and other artifices,
+by his dexterity.
+
+PRACTICAL USES THE BEST TEST.--The bicycle
+did not require such displays to bring it to perfection.
+It has been the history of every invention
+that improvements were brought about, not
+by abnormal experiments, but by practical uses
+and by normal developments.
+
+The ability of an aviator to fly with the machine
+in an inverted position is no test of the machine's
+stability, nor does it in any manner prove that
+it is correctly built. It is simply and solely a
+juggling feat--something in the capacity of a certain
+man to perform, and attract attention because
+they are out of the ordinary.
+
+CONCAVED AND COXVEX PLANES:--They were performed
+as exhibition features, and intended as
+such, and none of the exponents of that kind of
+flying have the effrontery to claim that they prove
+anything of value in the machine itself, except
+that it incidentally has destroyed the largely
+vaunted claim that concaved wings for supporting
+surfaces are necessary.
+
+HOW MOMENTUM IS A FACTOR IN INVERTED FLYING.--
+When flying "upside down," the convex
+side of the plane takes the pressure of the air,
+and maintains, so it is asserted, the weight of the
+machine. This is true during that period when
+the loop is being made. The evolution is made
+by first darting down, as shown in Fig. 31, from
+the horizontal position, 1, to the position 2, where
+the turn begins.
+
+_Fig. 31. Flying upside down._
+
+TURNING MOVEMENT.--Now note the characteristic
+angles of the tail, which is the controlling
+factor. In position 1 the tail is practically
+horizontal. In fact, in all machines, at
+high flight, the tail is elevated so as to give little
+positive angle of incidence to the supporting
+planes.
+
+In position No. 2, the tail is turned to an angle
+of incidence to make the downward plunge, and
+when the machine has assumed the vertical, as in
+position 3, the tail is again reversed to assume
+the angle, as in 1, when flying horizontally.
+
+At the lower turn, position 4, the tail is turned
+similar to the angle of position 2, which throws
+the rear end of the machine down, and as the
+horizontal line of flight is resumed, in an inverted
+position, as in position 4, the tail has the same
+angle, with relation to the frame, as the supporting
+planes.
+
+During this evolution the engine is running, and
+the downward plunge develops a tremendous
+speed, and the great momentum thus acquired,
+together with the pulling power of the propeller
+while thus in flight, is sufficient to propel it along
+horizontally, whatever the plane surface curve, or
+formation may be.
+
+It is the momentum which sustains it in space,
+not the air pressure beneath the wings, for
+reasons which we have heretofore explained.
+Flights of sufficient duration have thus been made
+to prove that convex, as well as concave surfaces
+are efficient; nevertheless, in its proper place we
+have given an exposition of the reasoning which
+led to the adoption of the concaved supporting
+surfaces.
+
+WHEN CONCAVED PLANES ARE DESIRABLE.--
+Unquestionably, for slow speeds the concaved wing
+is desirable, as will be explained, but for high
+speeds, surface formation has no value. That is
+shown by Pequod's feat.
+
+THE SPEED MANIA.--This is a type of mania
+which pervades every field of activity in the building
+of aeroplanes. Speed contests are of more
+importance to the spectators on exhibition
+grounds than stability or durability. Builders
+pander to this, hence machines are built on lines
+which disregard every consideration of safety
+while at normal flight.
+
+USES OF FLYING MACHINES.--The machine as
+now constructed is of little use commercially.
+Within certain limitations it is valuable for scouting
+purposes, and attempts have been made to
+use it commercially. But the unreliable character
+of its performances, due to the many elements
+which are necessary to its proper working, have
+operated against it.
+
+PERFECTION IN MACHINES MUST COME BEFORE
+SPEED.--Contrary to every precept in the building
+of a new article, the attempt is made to make
+a machine with high speed, which, in the very
+nature of things, operates against its improvement.
+The opposite lack of speed--is of far
+greater utility at this stage of its development.
+
+THE RANGE OF ITS USE.--The subject might be
+illustrated by assuming that we have a line running
+from A to Z, which indicates the range of
+speeds in aeroplanes. The limits of speeds are
+fairly stated as being within thirty and eighty-
+five miles per hour. Less than thirty miles are
+impossible with any type of plane, and while some
+have made higher speeds than eighty-five miles it
+may be safe to assume that such flights took place
+under conditions where the wind contributed to
+the movement.
+
+_Fig. 32. Chart showing Range of Uses_
+
+COMMERCIAL UTILITY.--Before machines can be
+used successfully they must be able to attain
+slower speeds. Alighting is the danger factor.
+Speed machines are dangerous, not in flight or
+at high speeds, but when attempting to land. A
+large plane surface is incompatible with speed,
+which is another illustration that at high velocities
+supporting surfaces are not necessary.
+
+Commercial uses require safety as the first element,
+and reliability as the next essential. For
+passenger service there must be an assurance that
+it will not overturn, or that in landing danger is
+not ever-present. For the carrying of freight interrupted
+service will militate against it.
+
+How few are the attempts to solve the problem
+of decreased speed, and what an eager, restless
+campaign is being waged to go faster and faster,
+and the addition of every mile above the record
+is hailed as another illustration of the perfection
+(?) of the flying machine.
+
+To be able to navigate a machine at ten, or fifteen
+miles an hour, would scarcely be interesting
+enough to merit a paragraph; but such an accomplishment
+would be of far more value than all of
+Pequod's feats, and be more far-reaching in its
+effects than a flight of two hundred miles per hour.
+
+
+
+CHAPTER VIII
+
+KITES AND GLIDERS
+
+
+KITES are of very ancient origin, and in China,
+Japan, and the Malayan Peninsula, they have been
+used for many years as toys, and for the purposes
+of exhibiting forms of men, animals, and particularly
+dragons, in their periodical displays.
+
+THE DRAGON KITE.--The most noted of all are
+the dragon kites, many of them over a hundred
+feet in length, are adapted to sail along majestically,
+their sinuous or snake-like motions lending
+an idea of reality to their gorgeously-colored appearance
+in flight.
+
+ITS CONSTRUCTION.--It is very curiously
+wrought, and as it must be extremely light, bamboo
+and rattan are almost wholly used, together
+with rice paper, in its construction.
+
+Fig. 33 shows one form of the arrangement, in
+which the bamboo rib, A, in which only two sections
+are shown, as B, B, form the backbone, and
+these sections are secured together with pivot
+pins C. Each section has attached thereto a
+hoop, or circularly-formed rib, D, the rib passing
+through the section B, and these ribs are
+connected together loosely by cords E, which run
+from one to the other, as shown.
+
+These circular ribs, D, are designed to carry a
+plurality of light paper disks, F, which are attached
+at intervals, and they are placed at such
+angles that they serve as small wing surfaces or
+aeroplanes to hold the structure in flight.
+
+_Fig. 33. Ribs of Dragon Kite_
+
+THE MALAY KITE.--The Malay kite, of which
+Fig. 34 shows the structure, is merely made up of
+two cross sticks, A, B, the vertical strip, A, being
+bent and rigid, whereas the cross stick, B, is light
+and yielding, so that when in flight it will bend,
+as shown, and as a result it has wonderful stability
+due to the dihedral angles of the two surfaces. This kite
+requires no tail to give it stability.
+
+_Fig. 34. The Malay Kite._
+
+DIHEDRAL ANGLES.--This is a term to designate
+a form of disposing of the wings which has been
+found of great service in the single plane machines.
+A plane which is disposed at a rising
+angle, as A, A, Fig. 35, above the horizontal line,
+is called dihedral, or diedral.
+
+_Fig. 35. Dihedral Angle._
+
+This arrangement in monoplanes does away
+with the necessity of warping the planes, or
+changing them while in flight. If, however, the angle
+is too great, the wind from either quarter is liable
+to raise the side that is exposed.
+
+THE COMMON KITE.--While the Malay kite has
+only two points of cord attachment, both along
+the vertical rib, the common kite, as shown in
+Fig. 36, has a four-point connection, to which the
+flying cord is attached. Since this form has no
+dihedral angle, it is necessary to supply a tail,
+which thus serves to keep it in equilibrium, while
+in flight.
+
+_Fig. 36. Common Kite._
+
+Various modifications have grown out of the
+Malay kite. One of these forms, designed by
+Eddy, is exactly like the Malay structure, but instead
+of having a light flexible cross piece, it is
+bent to resemble a bow, so that it is rigidly held
+in a bent position, instead of permitting the wind
+to give it the dihedral angle.
+
+THE BOW KITE.--Among the different types are
+the bow kite, Fig. 37, and the sexagonal structure,
+Fig. 38, the latter form affording an especially
+large surface.
+
+_Fig. 37. Bow Kite.-
+
+_Fig. 38. Hexagonal Kite._
+
+THE BOX KITE.--The most marked improvement
+in the form of kites was made by Hargreaves,
+in 1885, and called the box kite. It has wonderful
+stability, and its use, with certain modifications,
+in Weather Bureau experiments, have proven its
+value.
+
+It is made in the form of two boxes, A, B, open
+at the ends, which are secured together by means
+of longitudinal bars, C, that extends from one to
+the other, so that they are held apart a distance,
+approximately, equal to the length of one of the
+boxes.
+
+_Fig. 39. Hargreave Kite._
+
+Their fore and aft stability is so perfect that
+the flying cord D is attached at one point only,
+and the sides of the boxes provide lateral stability
+to a marked degree.
+
+THE VOISON BIPLANE.--This kind of kite furnished
+the suggestion for the Voison biplane,
+which was one of the earlier productions in flying
+machines.
+
+Fig. 40 shows a perspective of the Voison plane,
+which has vertical planes A, A, at the ends, and
+also intermediate curtains B, B. This was found
+to be remarkably stable, but during its turning
+movements, or in high winds, was not satisfactory,
+and for that reason was finally abandoned.
+
+LATERAL STABILITY IN KITES NOT CONCLUSIVE AS
+TO PLANES.--This is instanced to show that while
+such a form is admirably adapted for kite purposes,
+where vertical curtains are always in line
+with the wind movement, and the structure is held
+taut by a cord, the lateral effect, when used on a
+machine which does not at all times move in line
+with the moving air current. A condition is thus
+set up which destroys the usefulness of the box
+kite formation.
+
+_Fig. 40. Voison Biplane._
+
+THE SPEAR KITE.--This is a novel kite, with
+remarkable steadiness and is usually made with
+the wings on the rear end larger than those on
+the forward end (Fig. 41), as thereby the cord
+A can be attached to the spear midway between
+the two sets of wings.
+
+_Fig. 41. Spear Kite._
+
+THE CELLULAR KITE.--Following out the suggestion
+of the Hargreaves kite, numerous forms
+embodying the principle of the box structure were
+made and put on the market before the aeroplane
+became a reality.
+
+_Fig. 42. Cellular Kite._
+
+A structure of this form is illustrated in Fig.
+42. Each box, as A, B, has therein a plurality of
+vertical and horizontal partitions, so that a number
+of cells are provided, the two cell-like boxes
+being held apart by a bar C, axially arranged.
+
+This type is remarkably stable, due to the small
+cells, and kites of this kind are largely used for
+making scientific experiments.
+
+THE TETRAHEDRAL KITE.--Prof. Bell, inventor
+of the telephone, gave a great deal of study to
+kites, which resulted in the tetrahedral formation,
+as shown in Fig. 43.
+
+_Fig. 43. Tetrahedral Kite._
+
+The structure, apparently, is somewhat complicated,
+but an examination of a single pair of
+blades, as shown at A, shows that it is built up of
+triangularly-formed pieces, and that the openings
+between the pieces are equal to the latter, thereby
+providing a form of kite which possesses equilibrium
+to a great degree.
+
+It has never been tried with power, and it is
+doubtful whether it would be successful as a sustaining
+surface for flying machines, for the same
+reasons that caused failure with the box-like formation
+of the Voison Machine.
+
+THE DELTOID.--The deltoid is the simplest, and
+the most easily constructed of all the kites. It is
+usually made from stiff cardboard, A-shaped in
+outline, as shown in Figs. 44 and 45, and bent along
+a central line, as at A, forming two wings, each
+of which is a right-angled triangle.
+
+_Fig. 44. and 45. Deltoid Formation._
+
+The peculiarity of this formation is, that it has
+remarkable stability when used as a kite, with
+either end foremost. If a small weight is placed
+at the pointed end, and it is projected through the
+air, it will fly straight, and is but little affected
+by cross currents.
+
+THE DUNNE FLYING MACHINE.--A top view of
+this biplane is shown in Fig. 46. The A-shaped
+disposition of the planes, gives it good lateral
+stability, but it has the disadvantage under which
+all aeroplanes labor, that the entire body of the
+machine must move on a fore and aft vertical
+plan in order to ascend or descend.
+
+_Fig. 46. The Dunne Bi-plane._
+
+This is a true deltoid formation, as the angle of
+incidence of the planes is so disposed that when
+the planes are horizontal from end to end, the inclination
+is such as to make it similar to the deltoid
+kite referred to.
+
+ROTATING KITE.--A type of kite unlike the
+others illustrated is a rotating structure, which
+gives great stability, due to the gyroscopic action
+on the supporting surfaces.
+
+Fig. 47 shows a side view with the top in section.
+The supporting surface is umbrella-shaped.
+In fact, the ordinary umbrella will answer if not
+dished too much. An angularly-bent piece of wire
+A, provided with loops B, B, at the ends, serve as
+bearings for the handle of the umbrella.
+
+At the bend of the wire loop C, the cord D is
+attached. The lower side of the umbrella top has
+cup-shaped pockets E, near the margin, so arranged
+that their open ends project in the same
+direction, and the wind catching them rotates the
+circular plane.
+
+_Fig. 47. Rotable Umbrella Kite._
+
+KITE PRINCIPLES.--A careful study of the examples
+here given, will impress the novice with
+one important fact, which, in its effect has a more
+important bearing on successful flight, than all
+the bird study and speculations concerning its
+mysteries.
+
+This fact, in essence, is, that the angle of the
+kite is the great factor in flight next to the power
+necessary to hold it. Aside from this, the
+comparison between kites and aeroplanes is of no
+practical value.
+
+Disregarding the element of momentum, the
+drift of a machine against a wind, is the same,
+dynamically, as a plane at rest with the wind
+moving past it. But there is this pronounced
+difference: The cord which supports the kite
+holds it so that the power is in one direction only.
+
+When a side gust of wind strikes the kite it
+is moved laterally, in sympathy with the kite,
+hence the problem of lateral displacement is not
+the same as with the aeroplane.
+
+LATERAL STABILITY IN KITES.--In the latter the
+power is definitely fixed with relation to the machine
+itself, and if we should assume that a plane
+with a power on it sufficient to maintain a flight
+of 40 miles an hour, should meet a wind moving
+at the same speed, the machine would be stationary
+in space.
+
+Such a condition would be the same, so far as
+the angles of the planes are concerned, with a
+kite held by a string, but there all similarity in
+action ends.
+
+The stabilizing quality of the kite may be perfect,
+as the wind varies from side to side, but the
+aeroplane, being free, moves to the right or to
+the left, and does not adjust itself by means of a
+fixed point, but by a movable one.
+
+SIMILARITY OF FORE AND AFT CONTROL.--Fore
+and aft, however, the kite and aeroplane act the
+same. Fig. 48 shows a diagram which illustrates
+the forces which act on the kite, and by means
+of which it adjusts its angle automatically.
+
+Let us assume that the kite A is flown from
+a cord B, so that its angle is 22 1/2 degrees, the
+wind being 15 miles per hour to maintain the
+cord B at that angle. When the wind increases
+to 20 miles an hour there is a correspondingly
+greater lift against the kite.
+
+_Fig. 48. Action of Wind forces on Kite._
+
+As its angle is fixed by means of the loop C,
+it cannot change its angle with reference to the
+cord, or independently of it, and its only course
+is to move up higher and assume the position
+shown by the figure at D, and the angle of incidence
+of the kite is therefore changed to 15 degrees,
+or even to 10 degrees.
+
+In the case of the aeroplane the effect is similar
+from the standpoint of power and disposition
+of the planes. If it has sufficient power, and the
+angle of the planes is not changed, it will ascend;
+if the planes are changed to 15 degrees to correspond
+with the kite angle it will remain stationary.
+
+GLIDING FLIGHT.--The earliest attempt to fly
+by gliding is attributed to Oliver, a Monk of
+Malmesbury who, in 1065 prepared artificial
+wings, and with them jumped from a tower, being
+injured in the experiment.
+
+Nearly 700 years later, in 1801, Resnier, a
+Frenchman, conducted experiments with varying
+results, followed by Berblinger, in 1842, and
+LeBris, a French sailor, in 1856.
+
+In 1884, J. J. Montgomery, of California, designed
+a successful glider, and in 1889 Otto and
+Gustav Lilienthal made the most extended tests,
+in Germany, and became experts in handling
+gliders.
+
+Pilcher, in England, was the next to take up the
+subject, and in 1893 made many successful glides,
+all of the foregoing machines being single plane
+surfaces, similar to the monoplane.
+
+Long prior to 1896 Octave Chanute, an
+engineer, gave the subject much study, and in that
+year made many remarkable flights, developing
+the double plane, now known as the biplane.
+
+He was an ardent believer in the ability of man
+to fly by soaring means, and without using power
+for the purpose.
+
+It is doubtful whether gliders contributed much
+to the art in the direction of laterally stabilizing
+aeroplanes. They taught useful lessons with respect
+to area and fore and aft control.
+
+The kite gave the first impulse to seek out a
+means for giving equilibrium to planes, and
+Montgomery made a kite with warping wings as
+early as 1884.
+
+Penaud, a Frenchman, in 1872, made a model
+aeroplane which had the stabilizing means in the
+tail. All these grew out of kite experiments; and
+all gliders followed the kite construction, or the
+principles involved in them, so that, really, there
+is but one intervening step between the kite and
+the flying machine, as we know it, the latter being
+merely kites with power attached, as substitutes
+for the cords.
+
+ONE OF THE USES OF GLIDER EXPERIMENTS.--
+There is one direction in which gliders are valuable
+to the boy and to the novice who are interested
+in aviation. He may spend a lifetime in
+gliding and not advance in the art. It is
+questionable whether in a scientific way it will be of
+any service to him; but experiments of this character
+give confidence, the ability to quickly grasp
+a situation, and it will thus teach self reliance in
+emergencies.
+
+When in a glider quick thinking is necessary.
+The ability to shift from one position to another;
+to apply the weight where required instantaneously;
+to be able during the brief exciting moment
+of flight to know just what to do, requires alertness.
+
+Some are so wedded to the earth that slight
+elevation disturbs them. The sensation in a
+glider while in flight is unlike any other experience.
+It is like riding a lot of tense springs, and the
+exhilaration in gliding down the side of a hill,
+with the feet free and body suspended, is quite
+different from riding in an aeroplane with power
+attached.
+
+HINTS IN GLIDING.--It seems to be a difficult
+matter to give any advice in the art of gliding. It
+is a feat which seems to necessitate experiment
+from first to last. During the hundreds of tests
+personally made, and after witnessing thousands
+of attempts, there seems to be only a few suggestions
+or possible directions in which caution might
+be offered.
+
+First, in respect to the position of the body at
+the moment of launching. The glider is usually
+so made that in carrying it, preparatory to making
+the run and the leap required to glide, it is held
+so that it balances in the hands.
+
+Now the center of air pressure in gliding may
+not be at the same point as its sustaining weight
+when held by the hand, and furthermore, as the
+arm-pits, by which the body of the experimenter
+are held while gliding, are not at the same point,
+but to the rear of the hands, the moment the glider
+is launched too great a weight is brought to the
+rear margin of the planes, hence its forward end
+lifts up.
+
+This condition will soon manifest itself, and be
+corrected by the experimenter; but there is another
+difficulty which is not so easy to discover
+and so quick to remedy, and that is the swing of
+the legs the moment the operator leaves the
+ground.
+
+The experimenter learns, after many attempts,
+that gliding is a matter of a few feet only, and he
+anticipates landing too soon, and the moment he
+leaps from the ground the legs are swung forwardly
+ready to alight.
+
+This is done unconsciously, just as a jumper
+swings his legs forwardly in the act of alighting.
+Such a motion naturally disturbs the fore and aft
+stability of the gliding machine, by tilting up the
+forward margin, and it banks against the air,
+instead of gliding.
+
+The constant fear of all gliders is, that the
+machine will point downwardly, and his motion,
+as well as the position of the body, tend to shoot
+it upwardly, instead.
+
+
+
+CHAPTER IX
+
+AEROPLANE CONSTRUCTION
+
+
+As may be inferred from the foregoing statements,
+there are no definite rules for the construction
+of either type of flying machine, as the
+flying models vary to such an extent that it is
+difficult to take either of them as a model to represent
+the preferred type of construction.
+
+LATERAL, AND FORE AND AFT.--The term lateral
+should be understood, as applied to aeroplanes.
+It is always used to designate the direction at
+right angles to the movement of the machine.
+Fore and aft is a marine term meaning lengthwise,
+or from front to rear, hence is always at right
+angles to the lateral direction.
+
+The term transverse is equivalent to lateral,
+in flying machine parlance, but there is this
+distinction: Transverse has reference to a machine
+or object which, like the main planes of an aeroplane,
+are broader, (that is,--from end to end)
+than their length, (from front to rear).
+
+On the other hand, lateral has reference to side
+branches, as, for instance, the monoplane wings,
+which branch out from the sides of the fore and
+aft body.
+
+STABILITY AND STABILIZATION.--These terms constantly
+appear in describing machines and their
+operations. If the flying structure, whatever it
+may be, has means whereby it is kept from rocking
+from side to side, it has stability, which is usually
+designated as lateral stability. The mechanism
+for doing this is called a stabilizer.
+
+THE WRIGHT SYSTEM.--The Wright machine has
+reference solely to the matter of laterally controlling
+the flying structure, and does not pertain
+to the form or shape of the planes.
+
+In Fig. 49 A designates the upper and lower
+planes of a Wright machine, with the peculiar
+rounded ends. The ends of the planes are so
+arranged that the rear margins may be raised or
+lowered, independently of the other portions of
+the planes, which are rigid. This movement is
+indicated in sketch 1, where the movable part B
+is, as we might say, hinged along the line C.
+
+The dotted line D on the right hand end, shows
+how the section is depressed, while the dotted
+lines E at the left hand end shows the section
+raised. It is obvious that the downturned ends,
+as at D, will give a positive angle at one end of the
+planes, and the upturned wings E at the other end
+will give a negative angle, and thus cause the right
+hand end to raise, and the other end to move
+downwardly, as the machine moves forwardly
+through the air.
+
+CONTROLLING THE WARPING ENDS.--Originally
+the Wrights controlled these warping sections by
+means of a cradle occupied by the aviator, so that
+the cradle would move or rock, dependent on the
+tilt of the machine. This was what was termed
+automatic control. This was found to be unsatisfactory,
+and the control has now been placed so
+that it connects with a lever and is operated by
+the aviator, and is called Manually-operated control.
+
+In all forms of control the wings on one side are
+depressed on one side and correspondingly elevated
+on the other.
+
+THE CURTIS WINGS.--Curtis has small wings,
+or ailerons, intermediate the supporting surfaces,
+and at their extremities, as shown in sketch 2.
+These are controlled by a shoulder rack or swinging
+frame operated by the driver, so that the body
+in swinging laterally will change the two wings
+at the same time, but with angles in different
+directions.
+
+THE FARMAN AILERONS.--Farman's disposition
+is somewhat different, as shown in sketch 3. The
+wings are hinged to the upper planes at their rear
+edges, and near the extremities of the planes.
+Operating wires lead to a lever within reach of the
+aviator, and, by this means, the wings are held at
+any desired angle, or changed at will.
+
+The difficulty of using any particular model, is
+true, also, of the arrangement of the fore and aft
+control, as well as the means for laterally stabilizing
+it. In view of this we shall submit a general
+form, which may be departed from at will.
+
+FEATURES WELL DEVELOPED.--Certain features
+are fairly well developed, however. One is the
+angle of the supporting plane, with reference to
+the frame itself; and the other is the height at
+which the tail and rudder should be placed above
+the surface of the ground when the machine is at
+rest.
+
+DEPRESSING THE REAR END.--This latter is a
+matter which must be taken into consideration,
+because in initiating flight the rear end of the
+frame is depressed in order to give a sufficient
+angle to the supporting planes so as to be able to
+inaugurate flight.
+
+In order to commence building we should have
+some definite idea with respect to the power, as
+this will, in a measure, determine the area of the
+supporting surfaces, as a whole, and from this
+the sizes of the different planes may be determined.
+
+DETERMINING THE SIZE.--Suppose we decide on
+300 square feet of sustaining surface. This may
+require a 30, a 40 or a 50 horse power motor,
+dependent on the speed required, and much higher
+power has been used on that area.
+
+However, let us assume that a forty horse power
+motor is available, our 300 square feet of surface
+may be put into two planes, each having 150 square
+feet of surface, which would make each 5' by 30'
+in size; or, it may be decided to make the planes
+narrower, and proportionally longer. This is immaterial.
+The shorter the planes transversely,
+the greater will be the stability, and the wider the
+planes the less will be the lift, comparatively.
+
+RULE FOR PLACING THE PLANES.--The rule for
+placing the planes is to place them apart a distance
+equal to the width of the planes themselves,
+so that if we decide on making them five feet wide,
+they should be placed at least five feet apart.
+This rule, while it is an admirable one for slow
+movements or when starting flight, is not of any
+advantage while in rapid flight.
+
+If the machine is made with front and rear
+horizontally-disposed rudders, or elevators, they
+also serve as sustaining surfaces, which, for the
+present will be disregarded.
+
+Lay off a square A, Fig. 49a, in which the vertical
+lines B, B, and the horizontal lines C, C, are
+5' long, and draw a cross D within this, the lines
+running diagonally from the corners.
+
+Now step off from the center cross line D, three
+spaces, each five feet long, to a point E, and join
+this point by means of upper and lower bars F,
+G, with the upper and lower planes, so as to form
+the tail frame.
+
+_Fig. 49a. Rule for spacing Planes._
+
+As shown in Fig. 50, the planes should now be
+indicated, and placed at an angle of about 8 degrees
+angle, which are illustrated, H being the
+upper and I the lower plane. Midway between the
+forward edges of the two planes, is a horizontal
+line J, extending forwardly, and by stepping off
+the width of two planes, a point K is made, which
+forms the apex of a frame L, the rear ends of the
+bars being attached to the respective planes H, I,
+at their forward edges.
+
+_Fig. 50. Frame of Control Planes._
+
+_Fig. 51. and Fig. 52._
+
+ELEVATING PLANES.--We must now have the general
+side elevation of the frame, the planes, their
+angles, the tail and the rudder support, and the
+frame for the forward elevator.
+
+To this may be added the forward elevating
+plane L, the rear elevator, or tail M, and the vertical
+steering rudder N.
+
+The frame which supports the structure thus
+described, may be made in a variety of ways, the
+object being to provide a resilient connection for
+the rear wheel O.
+
+Fig. 52 shows a frame which is simple in construction
+and easily attached. The lower fore
+and aft side bars P have the single front wheel
+axle at the forward end, and the aft double wheels
+at the rear end, a flexible bar Q, running from the
+rear wheel axle to the forward end of the lower
+plane.
+
+A compression spring R is also mounted between
+the bar and rear end of the lower plane to
+take the shock of landing. The forward end of
+the bar P has a brace S extending up to the front
+edge of the lower plane, and another brace T connects
+the bars P, S, with the end of the forwardly-
+projecting frame.
+
+_Fig. 53. Plan view._
+
+The full page view, Fig. 53, represents a plan
+view, with one of the wings cut away, showing the
+general arrangement of the frame, and the three
+wheels required for support, together with the
+brace bars referred to.
+
+The necessity of the rear end elevation will
+now be referred to. The tail need not, necessarily,
+be located at a point on a horizontal line
+between the planes. It may be higher, or lower
+than the planes, but it should not be in a position
+to touch the ground when the machine is about
+to ascend.
+
+_Fig. 54. Alighting._
+
+The angle of ascension in the planes need not
+exceed 25 degrees so the frame does not require
+an angle of more than 17 degrees. This is shown
+in Fig. 54, where the machine is in a position
+ready to take the air at that angle, leaving ample
+room for the steering rudder.
+
+ACTION IN ALIGHTING.--Also, in alighting, the
+machine is banked, practically in the same
+position thus shown, so that it alights on the rear
+wheels O.
+
+The motor U is usually mounted so its shaft is
+midway between the planes, the propeller V being
+connected directly with the shaft, and being behind
+the planes, is on a medial line with the
+machine.
+
+The control planes L, M, N, are all connected up
+by means of flexible wires with the aviator at the
+set W, the attachments being of such a character
+that their arrangement will readily suggest themselves
+to the novice.
+
+THE MONOPLANE.--From a spectacular standpoint
+a monoplane is the ideal flying machine. It
+is graceful in outline, and from the fact that it
+closely approaches the form of the natural flyer,
+seems to be best adapted as a type, compared with
+the biplane.
+
+THE COMMON FLY.--So many birds have been
+cited in support of the various flying theories that
+the house fly, as an example has been disregarded.
+We are prone to overlook the small insect, but it
+is, nevertheless, a sample which is just as potent
+to show the efficiency of wing surface as the condor
+or the vulture.
+
+The fly has greater mobility than any other flying
+creature. By the combined action of its legs
+and wings it can spring eighteen inches in the
+tenth of a second; and when in flight can change
+its course instantaneously.
+
+If a sparrow had the same dexterity, proportionally,
+it could make a flight of 800 feet in the
+same time. The posterior legs of the fly are the
+same length as its body, which enable it to spring
+from its perch with amazing facility.
+
+_Fig. 55. Common Fly. Outstretched Wings._
+
+The wing surface, proportioned to its body and
+weight, is no less a matter for wonder and consideration.
+
+In Fig. 55 is shown the outlines of the fly with
+outstretched wings. Fig. 56 represents it with
+the wing folded, and Fig. 57 is a view of a wing
+with the relative size of the top of the body shown
+in dotted lines.
+
+_Fig. 56. Common Fly. Folded Wings._
+
+The first thing that must attract attention, after
+a careful study is the relative size of the body
+and wing surface. Each wing is slightly smaller
+than the upper surface of the body, and the thickness
+of the body is equal to each wing spread.
+
+_Fig. 57. Relative size of wing and body._
+
+The weight, compared with sustaining surface,
+if expressed in understandable terms, would be
+equal to sixty pounds for every square foot of surface.
+
+STREAM LINES.--The next observation is, that
+what are called stream lines do not exist in the fly.
+Its head is as large in cross section as its body,
+with the slightest suggestion only, of a pointed
+end. Its wings are perfectly flat, forming a true
+plane, not dished, or provided with a cambre, even,
+that upward curve, or bulge on the top of the aeroplane
+surface, which seems to possess such a fascination
+for many bird flight advocates.
+
+It will also be observed that the wing connection
+with the body is forward of the line A, which
+represents the point at which the body will balance
+itself, and this line passes through the wings
+so that there is an equal amount of supporting
+surface fore and aft of the line.
+
+Again, the wing attachment is at the upper side
+of the body, and the vertical dimension of the
+body, or its thickness, is equal to four-fifths of the
+length of he wing.
+
+The wing socket permits a motion similar to a
+universal joint, Fig. 55 showing how the inner
+end of the wing has a downward bend where it
+joins the back, as at B.
+
+THE MONOPLANE FORM.--For the purpose of
+making comparisons the illustrations of the monoplane
+show a machine of 300 square feet of surface,
+which necessitates a wing spread of forty
+feet from tip to tip, so that the general dimensions
+of each should be 18 1/2 feet by 8 1/2 feet at its
+widest point.
+
+First draw a square forty feet each way, as in
+Fig. 58, and through this make a horizontal line
+1, and four intermediate vertical lines are then
+drawn, as 2, 3, 4, 5, thus providing five divisions,
+each eight feet wide. In the first division the
+planes A, B, are placed, and the tail, or elevator
+C, is one-half the width of the last division.
+
+_Fig. 58. Plan of Monoplane._
+
+The frame is 3 1/2 feet wide at its forward end,
+and tapers down to a point at its rear end, where
+the vertical control plane D is hinged, and the
+cross struts E, E, are placed at the division lines
+3, 4, 5.
+
+The angles of the planes, with relation to the
+frame, are usually greater than in the biplane,
+for the reason that the long tail plane requires
+a greater angle to be given to the planes when
+arising; or, instead of this, the planes A, B, are
+mounted high enough to permit of sufficient angle
+for initiating flight without injuring the tail D.
+
+Some monoplanes are built so they have a support
+on wheels placed fore and aft. In others
+the tail is supported by curved skids, as shown
+at A, Fig. 59, in which case the forward
+supporting wheels are located directly beneath the planes.
+As the planes are at about eighteen degrees
+angle, relative to the frame, and the tail plane
+B is at a slight negative angle of incidence, as
+shown at the time when the engine is started, the
+air rushing back from the propeller, elevates the
+tail, and as the machine moves forwardly over
+the ground, the tail raises still higher, so as to
+give a less angle of incidence to the planes while
+skimming along the surface of the ground.
+
+_Fig. 59. Side Elevation, Monoplane._
+
+In order to mount, the tail is suddenly turned
+to assume a sharp negative angle, thus swinging
+the tail downwardly, and this increases the angle
+of planes to such an extent that the machine leaves
+the ground, after which the tail is brought to the
+proper angle to assure horizontal flight.
+
+The drawing shows a skid at the forward end,
+attached to the frame which carries the wheels.
+The wheels are mounted beneath springs so that
+when the machine alights the springs yield sufficiently
+to permit the skids to strike the ground,
+and they, therefore, act as brakes, to prevent the
+machine from traveling too far.
+
+
+
+CHAPTER X
+
+POWER AND ITS APPLICATION
+
+
+THIS is a phase of the flying machine which has
+the greatest interest to the boy. He instinctively
+sees the direction in which the machine has its
+life,--its moving principle. Planes have their
+fascination, and propellers their mysterious elements,
+but power is the great and absorbing question
+with him.
+
+We shall try to make its application plain in
+the following pages. We have nothing to do here
+with the construction and operation of the motor
+itself, as, to do that justice, would require pages.
+
+FEATURES IN POWER APPLICATION.--It will be
+more directly to the point to consider the following
+features of the power and its application:
+
+1. The amount of power necessary.
+
+2. How to calculate the power applied.
+
+3. Its mounting.
+
+
+WHAT AMOUNT OF POWER IS NECESSARY.--In the
+consideration of any power plant certain calculations
+must be made to determine what is required.
+A horse power means the lifting of a certain
+weight, a definite distance, within a specified
+time.
+
+If the weight of the vehicle, with its load, are
+known, and its resistance, or the character of the
+roadway is understood, it is a comparatively easy
+matter to calculate just how much power must be
+exerted to overcome that resistance, and move the
+vehicle a certain speed.
+
+In a flying machine the same thing is true, but
+while these problems may be known in a general
+way, the aviator has several unknown elements
+ever present, which make estimates difficult to
+solve.
+
+THE PULL OF THE PROPELLER.--Two such factors
+are ever present. The first is the propeller
+pull. The energy of a motor, when put into a
+propeller, gives a pull of less than eight pounds
+for every horse power exerted.
+
+FOOT POUNDS.--The work produced by a motor
+is calculated in Foot Pounds. If 550 pounds
+should be lifted, or pulled, one foot in one second
+of time, it would be equal to one horse power.
+
+But here we have a case where one horse power
+pulls only eight pounds, a distance of one foot
+within one second of time, and we have utilized
+less than one sixty-fifth of the actual energy produced.
+
+SMALL AMOUNT OF POWER AVAILABLE.--This is
+due to two things: First, the exceeding lightness
+of the air, and its great elasticity; and, second,
+the difficulty of making a surface which, when it
+strikes the air, will get a sufficient grip to effect
+a proper pull.
+
+Now it must be obvious, that where only such
+a small amount of energy can be made available,
+in a medium as elusive as air, the least change, or
+form, of the propeller, must have an important
+bearing in the general results.
+
+HIGH PROPELLER SPEED IMPORTANT.--Furthermore,
+all things considered, high speed is important
+in the rotation of the propeller, up to a certain
+point, beyond which the pull decreases in
+proportion to the speed. High speed makes a
+vacuum behind the blade and thus decreases the
+effective pull of the succeeding blade.
+
+WIDTH AND PITCH OF BLADES.--If the blade is
+too wide the speed of the engine is cut down to a
+point where it cannot exert the proper energy; if
+the pitch is very small then it must turn further to
+get the same thrust, so that the relation of diameter,
+pitch and speed, are three problems far from
+being solved.
+
+It may be a question whether the propeller form,
+as we now know it, is anything like the true or
+ultimate shape, which will some day be discovered.
+
+EFFECT OF INCREASING PROPELLER PULL.--If the
+present pull could be doubled what a wonderful
+revolution would take place in aerial navigation,
+and if it were possible to get only a quarter of
+the effective pull of an engine, the results would
+be so stupendous that the present method of flying
+would seem like child's play in comparison.
+
+It is in this very matter,--the application of
+the power, that the bird, and other flying creatures
+so far excel what man has done. Calculations
+made with birds as samples, show that many
+of them are able to fly with such a small amount
+of power that, if the same energy should be applied
+to a flying machine, it would scarcely drive
+it along the ground.
+
+DISPOSITION OF THE PLANES.--The second factor
+is the disposition or arrangement of the planes
+with relation to the weight. Let us illustrate this
+with a concrete example:
+
+We have an aeroplane with a sustaining surface
+of 300 square feet which weighs 900 pounds,
+or 30 pounds per square foot of surface.
+
+DIFFERENT SPEEDS WITH SAME POWER.--Now, we
+may be able to do two things with an airship under
+those conditions. It may be propelled through
+the air thirty miles an hour, or sixty miles, with
+the expenditure of the same power.
+
+An automobile, if propelled at sixty, instead of
+thirty miles an hour, would require an additional
+power in doing so, but an airship acts differently,
+within certain limitations.
+
+When it is first set in motion its effective pull
+may not be equal to four pounds for each horse
+power, due to the slow speed of the propeller, and
+also owing to the great angle of incidence which
+resists the forward movement of the ship.
+
+INCREASE OF SPEED ADDS TO RESISTANCE.--Finally,
+as speed increases, the angle of the planes
+decrease, resistance is less, and up to a certain
+point the pull of the propeller increases; but beyond
+that the vacuum behind the blades becomes
+so great as to bring down the pull, and there is
+thus a balance,--a sort of mutual governing motion
+which, together, determine the ultimate speed
+of the aeroplane.
+
+HOW POWER DECREASES WITH SPEED.--If now,
+with the same propeller, the speed should be
+doubled, the ship would go no faster, because the
+bite of the propeller on the air would be ineffective,
+hence it will be seen that it is not the amount
+of power in itself, that determines the speed, but
+the shape of the propeller, which must be so made
+that it will be most effective at the speed required
+for the ship.
+
+While that is true when speed is the matter of
+greatest importance, it is not the case where it is
+desired to effect a launching. In that case the
+propeller must be made so that its greatest pull
+will be at a slow speed. This means a wider
+blade, and a greater pitch, and a comparatively
+greater pull at a slow speed.
+
+No such consideration need be given to an automobile.
+The constant accretion of power adds
+to its speed. In flying machines the aviator must
+always consider some companion factor which
+must be consulted.
+
+HOW TO CALCULATE THE POWER APPLIED.--In a
+previous chapter reference was made to a plane
+at an angle of forty-five degrees, to which two
+scales were attached, one to get its horizontal pull,
+or drift, and the other its vertical pull, or lift.
+
+PULLING AGAINST AN ANGLE.--Let us take the
+same example in our aeroplane. Assuming that
+it weighs 900 pounds, and that the angle of the
+planes is forty-five degrees. If we suppose that
+the air beneath the plane is a solid, and frictionless,
+and a pair of scales should draw it up the incline,
+the pull in doing so would be one-half of its
+weight, or 450 pounds.
+
+It must be obvious, therefore, that its force, in
+moving downwardly, along the surface A, Fig. 60,
+would be 450 pounds.
+
+The incline thus shown has thereon a weight B,
+mounted on wheels a, and the forwardly-projecting
+cord represents the power, or propeller pull,
+which must, therefore, exert a force of 450 pounds
+to keep it in a stationary position against the surface
+A.
+
+In such a case the thrust along the diagonal
+line E would be 900 pounds, being the composition
+of the two forces pulling along the lines D, F.
+
+THE HORIZONTAL AND VERTICAL PULL.--Now it
+must be obvious, that if the incline takes half of
+the weight while it is being drawn forwardly, in
+the line of D, if we had a propeller drawing along
+that line, which has a pull of 450 pounds, it would
+maintain the plane in flight, or, at any rate hold
+it in space, assuming that the air should be moving
+past the plane.
+
+_Fig. 60. Horizontal and Vertical pull._
+
+The table of lift and drift gives a fairly accurate
+method of determining this factor, and we refer to
+the chapter on that subject which will show the
+manner of making the calculations.
+
+THE POWER MOUNTING.--More time and labor
+has been wasted, in airship experiments, in poor
+motor mounting, than in any other direction.
+This is especially true where two propellers are
+used, or where the construction is such that the
+propeller is mounted some distance from the motor.
+
+SECURING THE PROPELLER TO THE SHAFT.--But
+even where the propeller is mounted on the engine
+shaft, too little care is exercised to fix it securely.
+The vibratory character of the mounting
+makes this a matter of first importance. If there
+is a solid base a poorly fixed propeller will hold
+much longer, but it is the extreme vibration that
+causes the propeller fastening to give way.
+
+VIBRATIONS.--If experimenters realized that an
+insecure, shaking, or weaving bed would cause a
+loss of from ten to fifteen per cent. in the pull of
+the propeller, more care and attention would be
+given to this part of the structure.
+
+WEAKNESSES IN MOUNTING.--The general weaknesses
+to which attention should be directed are,
+first, the insecure attachment of the propeller to
+the shaft; second, the liability of the base to
+weave; or permit of a torsional movement; third,
+improper bracing of the base to the main body of
+the aeroplane.
+
+If the power is transferred from the cylinder
+to the engine shaft where it could deliver its output
+without the use of a propeller, it would not
+be so important to consider the matter of vibration;
+but the propeller, if permitted to vibrate,
+or dance about, absorbs a vast amount of energy,
+while at the same time cutting down its effective
+pull.
+
+Aside from this it is dangerous to permit the
+slightest displacement while the engine is running.
+Any looseness is sure to grow worse, instead
+of better, and many accidents have been
+registered by bolts which have come loose from
+excessive vibration. It is well, therefore, to have
+each individual nut secured, or properly locked,
+which is a matter easily done, and when so secured
+there is but little trouble in going over the machine
+to notice just how much more the nut must
+be taken up to again make it secure.
+
+THE GASOLINE TANK.--What horrid details have
+been told of the pilots who have been burned to
+death with the escaping gasoline after an accident,
+before help arrived. There is no excuse for
+such dangers. Most of such accidents were due
+to the old practice of making the tanks of exceedingly
+light or thin material, so that the least
+undue jar would tear a hole at the fastening
+points, and thus permit the gasoline to escape.
+
+A thick copper tank is by far the safest, as this
+metal will not readily rupture by the wrench which
+is likely in landing.
+
+WHERE TO LOCATE THE TANK.--There has been
+considerable discussion as to the proper place to
+locate the tank. Those who advocate its placement
+overhead argue that in case of an accident
+the aeroplane is likely to overturn, and the tank
+will, therefore, be below the pilot. Those who
+believe it should be placed below, claim that in
+case of overturning it is safer to have the tank
+afire above than below.
+
+DANGER TO THE PILOT.--The great danger to the
+pilot, in all cases of accidents, lies in the
+overturning of the machine. Many have had accidents
+where the machine landed right side up, even
+where the fall was from a great height, and the
+only damage to the aviator was bruises. Few, if
+any, pilots have escaped where the machine has
+overturned.
+
+It is far better, in case the tank is light, to have
+it detached from its position, when the ship strikes
+the earth, because in doing so, it will not be so
+likely to burn the imprisoned aviator.
+
+In all cases the tank should be kept as far away
+from the engine as possible. There is no reason
+why it cannot be placed toward the tail end of
+the machine, a place of safety for two reasons:
+First, it is out of the reach of any possible
+danger from fire; and, second, the accidents in the
+past show that the tail frame is the least likely to
+be injured.
+
+In looking over the illustrations taken from the
+accidents, notice how few of the tails are even
+disarranged, and in many of them, while the entire
+fore body and planes were crushed to atoms,
+the tail still remained as a relic, to show its
+comparative freedom from the accident.
+
+In all monoplanes the tail really forms part of
+the supporting surface of the machine, and the
+adding of the weight of the gasoline would be
+placing but little additional duty on the tail, and
+it could be readily provided for by a larger tail
+surface, if required.
+
+THE CLOSED-IN BODY.--The closed-in body is a
+vast improvement, which has had the effect of
+giving greater security to the pilot, but even this
+is useless in case of overturning.
+
+STARTING THE MACHINE.--The direction in which
+improvements have been slow is in the starting
+of the machine. The power is usually so mounted
+that the pilot has no control over the starting,
+as he is not in a position to crank it.
+
+The propeller being mounted directly on the
+shaft, without the intervention of a clutch, makes
+it necessary, while on the ground, for the propeller
+to be started by some one outside, while
+others hold the machine until it attains the proper
+speed.
+
+This could be readily remedied by using a
+clutch, but in the past this has been regarded as
+one of the weight luxuries that all have been trying
+to avoid. Self starters are readily provided,
+and this with the provision that the propeller can
+be thrown in or out at will, would be a vast improvement
+in all machines.
+
+PROPELLERS WITH VARYING PITCH.--It is growing
+more apparent each day, that a new type of
+propeller must be devised which will enable the
+pilot to change the pitch, as the speed increases,
+and to give a greater pitch, when alighting, so
+as to make the power output conform to the conditions.
+
+Such propellers, while they may be dangerous,
+and much heavier than the rigid type, will, no
+doubt, appear in time, and the real improvement
+would be in the direction of having the blades
+capable of automatic adjustment, dependent on
+the wind pressure, or the turning speed, and thus
+not impose this additional duty on the pilot.
+
+
+
+CHAPTER XI
+
+FLYING MACHINE ACCESSORIES
+
+
+THE ANEMOMETER.--It requires an expert to
+judge the force or the speed of a wind, and even
+they will go astray in their calculations. It is
+an easy matter to make a little apparatus which
+will accurately indicate the speed. A device of
+this kind is called an Anemometer.
+
+Two other instruments have grown out of this,
+one to indicate the pressure, and the other the
+direction of the moving air current.
+
+THE ANEMOGRAPH.--While these instruments indicate,
+they are also made so they will record the
+speed, the pressure and the direction, and the device
+for recording the speed and pressure is called
+a Anemograph.
+
+All these instruments may be attached to the
+same case, and thus make a handy little device,
+which will give all the information at a glance.
+
+THE ANEMOMETROGRAPH.--This device for recording,
+as well as indicating the speed, pressure
+and direction, is called an Anemometrograph,
+The two important parts of the combined
+apparatus, for the speed and pressure, are illustrated,
+to show the principle involved. While the speed
+will give the pressure, it is necessary to make a
+calculation to get the result while the machine does
+this for you.
+
+_Fig. 61. Speed Indicator._
+
+THE SPEED INDICATOR.--Four hemispherical
+cups A are mounted on four radiating arms B,
+which are secured to a vertical stem C, and
+adapted to rotate in suitable bearings in a
+case, which, for convenience in explaining, is not
+shown.
+
+On the lower end of the stem C, is a small bevel
+pinion, which meshes with a smaller bevel pinion
+within the base. This latter is on a shaft which
+carries a small gear on its other end, to mesh
+with a larger gear on a shaft which carries a
+pointer D that thus turns at a greatly reduced
+speed, so that it can be easily timed.
+
+_Fig. 62. Air Pressure Indicator._
+
+AIR PRESSURE INDICATOR.--This little apparatus
+is readily made of a base A which is provided
+with two uprights B, C, through the upper ends of
+which are holes to receive a horizontally-disposed
+bar D. One end of the bar is a flat plane
+surface E, which is disposed at right angles to the
+bar, and firmly fixed thereto.
+
+The other end of the bar has a lateral pin to
+serve as a pivot for the end of a link F, its other
+end being hinged to the upper end of a lever G,
+which is pivoted to the post C, a short distance
+below the hinged attachment of the link F, so
+that the long end of the pointer which is constituted
+by the lever G is below its pivot, and has,
+therefore, a long range of movement.
+
+A spring I between the upper end of the pointer
+G and the other post B, serves to hold the pointer
+at a zero position. A graduated scale plate J,
+within range of the pointer will show at a glance
+the pressure in pounds of the moving wind, and
+for this purpose it would be convenient to make
+the plane E exactly one foot square.
+
+DETERMINING THE PRESSURE FROM THE SPEED.--
+These two instruments can be made to check each
+other and thus pretty accurately enable you to
+determine the proper places to mark the pressure
+indicator, as well as to make the wheels in the
+anemometer the proper size to turn the pointer
+in seconds when the wind is blowing at a certain
+speed, say ten miles per hour.
+
+Suppose the air pressure indicator has the scale
+divided into quarter pound marks. This will
+make it accurate enough for all purposes.
+
+CALCULATING PRESSURES FROM SPEED.--The following
+table will give the pressures from 5 to 100
+miles per hour:
+
+Velocity of wind in Pressure   Velocity of wind in  Pressure
+miles per hour     per sq. ft.  miles per hour     per sq ft
+     5              .112             55             15.125
+     10             .500             60             18.000
+     15             1.125            65             21.125
+     20             2.000            70             22.500
+     25             3.125            75             28.125
+     30             4.600            80             32.000
+     35             6.126            86             36.126
+     40             8.000            90             40.500
+     45             10.125           95             45.125
+     50             12.5             100            50.000
+
+
+HOW THE FIGURES ARE DETERMINED.--The foregoing
+figures are determined in the following manner:
+As an example let us assume that the velocity
+of the wind is forty-five miles per hour. If
+this is squared, or 45 multiplied by 45, the product
+is 2025. In many calculations the mathematician
+employs what is called a constant, a figure that
+never varies, and which is used to multiply or
+divide certain factors.
+
+In this case the constant is 5/1000, or, as usually
+written, .005. This is the same as one two hundredths
+of the squared figure. That would make
+the problem as follows:
+
+     45 X 45 = 2025 / 200 = 10.125; or,
+     45 X 45 - 2025 X .005 = 10.125.
+
+
+Again, twenty-five miles per hour would be
+25 X 25 = 625; and this multiplied by .005 equals
+2 pounds pressure.
+
+CONVERTING HOURS INTO MINUTES.--It is sometimes
+confusing to think of miles per hour, when
+you wish to express it in minutes or seconds. A
+simple rule, which is not absolutely accurate, but
+is correct within a few feet, in order to express
+the speed in feet per minute, is to multiply the
+figure indicating the miles per hour, by 8 3/4.
+
+To illustrate: If the wind is moving at the
+rate of twenty miles an hour, it will travel in that
+time 105,600 feet (5280 X 20). As there are sixty
+minutes in an hour, 105,600 divided by 60, equals
+1760 feet per minute. Instead of going through
+all this process of calculating the speed per minute,
+remember to multiply the speed in miles per
+hour by 90, which will give 1800 feet.
+
+This is a little more then two per cent. above
+the correct figure. Again; 40 X 90 equals 3600.
+As the correct figure is 3520, a little mental calculation
+will enable you to correct the figures so
+as to get it within a few feet.
+
+CHANGING SPEED HOURS TO SECONDS.--As one-
+sixtieth of the speed per minute will represent the
+rate of movement per second, it is a comparatively
+easy matter to convert the time from speed in
+miles per hour to fraction of a mile traveled in
+a second, by merely taking one-half of the speed
+in miles, and adding it, which will very nearly express
+the true number of feet.
+
+As examples, take the following: If the wind
+is traveling 20 miles an hour, it is easy to take
+one-half of 20, which is 10, and add it to 20, making
+30, as the number of feet per second. If the
+wind travels 50 miles per hour, add 25, making
+75, as the speed per second.
+
+The correct speed per second of a wind traveling
+20 miles an hour is a little over 29 feet. At
+50 miles per hour, the correct figure is 73 1/3 feet,
+which show that the figures under this rule are
+within about one per cent. of being correct.
+
+With the table before you it will be an easy
+matter, by observing the air pressure indicator,
+to determine the proper speed for the anemometer.
+Suppose it shows a pressure of two pounds,
+which will indicate a speed of twenty miles an
+hour. You have thus a fixed point to start from.
+
+PRESSURE AS THE SQUARE OF THE SPEED.--Now
+it must not be assumed that if the pressure at
+twenty miles an hour is two pounds, that forty
+miles an hour it is four pounds. The pressure
+is as the square of the speed. This may be explained
+as follows: As the speed of the wind
+increases, it has a more effective push against an
+object than its rate of speed indicates, and this
+is most simply expressed by saying that each time
+the speed is doubled the pressure is four times
+greater.
+
+As an example of this, let us take a speed of ten
+miles an hour, which means a pressure of one-
+half pound. Double this speed, and we have 20
+miles. Multiplying one-half pound by 4, the result
+is 2 pounds. Again, double 20, which means
+40 miles, and multiplying 2 by 4, the result is 8.
+Doubling forty is eighty miles an hour, and again
+multiplying 8 by 4, we have 32 as the pounds pressure
+at a speed of 80 miles an hour.
+
+The anemometer, however, is constant in its
+speed. If the pointer should turn once a second
+at 10 miles an hour, it would turn twice at 20 miles
+an hour, and four times a second at 40 miles an
+hour.
+
+GYROSCOPIC BALANCE.--Some advance has been
+made in the use of the gyroscope for the purpose
+of giving lateral stability to an aeroplane. While
+the best of such devices is at best a makeshift,
+it is well to understand the principle on which they
+operate, and to get an understanding how they are
+applied.
+
+THE PRINCIPLE INVOLVED.--The only thing
+known about the gyroscope is, that it objects to
+changing the plane of its rotation. This statement
+must be taken with some allowance, however,
+as, when left free to move, it will change in
+one direction.
+
+To explain this without being too technical, examine
+Fig. 63, which shows a gyroscopic top, one
+end of the rim A, which supports the rotating
+wheel B, having a projecting finger C, that is
+mounted on a pin-point on the upper end of the
+pedestal D.
+
+_Fig. 63. The Gyroscope._
+
+When the wheel B is set in rotation it will maintain
+itself so that its axis E is horizontal, or at
+any other angle that the top is placed in when the
+wheel is spun. If it is set so the axis is horizontal
+the wheel B will rotate on a vertical plane,
+and it forcibly objects to any attempt to make it
+turn except in the direction indicated by the
+curved arrows F.
+
+The wheel B will cause the axis E to swing
+around on a horizontal plane, and this turning
+movement is always in a certain direction in relation
+to the turn of the wheel B, and it is obvious,
+therefore, that to make a gyroscope that
+will not move, or swing around an axis, the placing
+of two such wheels side by side, and rotated
+in opposite directions, will maintain them in a
+fixed position; this can also be accomplished by
+so mounting the two that one rotates on a plane
+at right angles to the other.
+
+_Fig. 64. Application of the Gyroscope._
+
+THE APPLICATION OF THE GYROSCOPE.--Without
+in any manner showing the structural details of
+the device, in its application to a flying machine,
+except in so far as it may be necessary to explain
+its operation, we refer to Fig. 64, which
+assumes that A represents the frame of the aeroplane,
+and B a frame for holding the gyroscopic
+wheel C, the latter being mounted so it rotates on
+a horizontal plane, and the frame B being hinged
+fore and aft, so that it is free to swing to the right
+or to the left.
+
+For convenience in explaining the action, the
+planes E are placed at right angles to their regular
+positions, F being the forward margin of the
+plane, and G the rear edge. Wires H connect
+the ends of the frame B with the respective
+planes, or ailerons, E, and another wire I joins
+the downwardly-projecting arms of the two
+ailerons, so that motion is transmitted to both at
+the same time, and by a positive motion in either
+direction.
+
+_Fig. 65. Action of the Gyroscope._
+
+In the second figure, 65, the frame of the aeroplane
+is shown tilted at an angle, so that its right
+side is elevated. As the gyroscopic wheel remains
+level it causes the aileron on the right side to
+change to a negative angle, while at the same
+time giving a positive angle to the aileron on the
+left side, which would, as a result, depress the
+right side, and bring the frame of the machine
+back to a horizontal position.
+
+FORE AND AFT GYROSCOPIC CONTROL.--It is
+obvious that the same application of this force may
+be applied to control the ship fore and aft, although
+it is doubtful whether such a plan would
+have any advantages, since this should be wholly
+within the control of the pilot.
+
+Laterally the ship should not be out of balance;
+fore and aft this is a necessity, and as the great
+trouble with all aeroplanes is to control them
+laterally, it may well be doubted whether it would
+add anything of value to the machine by having
+an automatic fore and aft control, which might,
+in emergencies, counteract the personal control of
+the operator.
+
+ANGLE INDICATOR.--In flight it is an exceedingly
+difficult matter for the pilot to give an accurate
+idea of the angle of the planes. If the air is
+calm and he is moving over a certain course, and
+knows, from experience, what his speed is, he may
+be able to judge of this factor, but he cannot tell
+what changes take place under certain conditions
+during the flight.
+
+For this purpose a simple little indicator may
+be provided, shown in Fig. 66, which is merely a
+vertical board A, with a pendulum B, swinging
+fore and aft from a pin a which projects out
+from the board a short distance above its center.
+
+The upper end of the pendulum has a heart-
+shaped wire structure D, that carries a sliding
+weight E. Normally, when the aeroplane is on
+an even keel, or is even at an angle, the weight
+E rests within the bottom of the loop D, but
+should there be a sudden downward lurch or a
+quick upward inclination, which would cause the
+pendulum below to rapidly swing in either
+direction, the sliding weight E would at once move
+forward in the same direction that the pendulum
+had moved, and thus counteract, for the instant
+only, the swing, when it would again drop back
+into its central position.
+
+_Fig. 66. Angle Indicator._
+
+With such an arrangement, the pendulum would
+hang vertically at all times, and the pointer below,
+being in range of a circle with degrees
+indicated thereon, and the base attached to the
+frame of the machine, can always be observed,
+and the conditions noted at the time the changes
+take place.
+
+PENDULUM STABILIZER.--In many respects the
+use of a pendulum has advantages over the gyroscope.
+The latter requires power to keep it in
+motion. The pendulum is always in condition
+for service. While it may be more difficult to
+adjust the pendulum, so that it does not affect
+the planes by too rapid a swing, or an oscillation
+which is beyond the true angle desired, still, these
+are matters which, in time, will make the pendulum
+a strong factor in lateral stability.
+
+_Fig. 67. Simple Pendulum Stabilizer._
+
+It is an exceedingly simple matter to attach the
+lead wires from an aileron to the pendulum. In
+Fig. 67 one plan is illustrated. The pendulum
+A swings from the frame B of the machine, the
+ailerons a being in this case also shown at right
+angles to their true positions.
+
+The other, Fig. 68, assumes that the machine is
+exactly horizontal, and as the pendulum is in a
+vertical position, the forward edges of both ailerons
+are elevated, but when the pendulum swings
+both ailerons will be swung with their forward
+margins up or down in unison, and thus the proper
+angles are made to right the machine.
+
+STEERING AND CONTROLLING WHEEL.--For the
+purpose of concentrating the control in a single
+wheel, which has not alone a turning motion, but
+is also mounted in such a manner that it will oscillate
+to and fro, is very desirable, and is adapted
+for any kind of machine.
+
+_Fig. 68. Pendulum Stabilizers._
+
+Fig. 69 shows such a structure, in which A
+represents the frame of the machine, and B a
+segment for the stem of the wheel, the segment
+being made of two parts, so as to form a guideway
+for the stem a to travel between, and the segment
+is placed so that the stem will travel in a
+fore and aft direction.
+
+The lower end of the stem is mounted in a
+socket, at D, so that while it may be turned, it
+will also permit this oscillating motion. Near its
+lower end is a cross bar E from which the wires
+run to the vertical control plane, and also to the
+ailerons, if the machine is equipped with them, or
+to the warping ends of the planes.
+
+_Fig. 69. Steering and Control Wheel._
+
+Above the cross arms is a loose collar F to
+which the fore and aft cords are attached that go
+to the elevators, or horizontal planes. The upper
+end of the stem has a wheel G, which may also be
+equipped with the throttle and spark levers.
+
+AUTOMATIC STABILIZING WINGS.--Unquestionably,
+the best stabilizer is one which will act on
+its own initiative. The difficulty with automatic
+devices is, that they act too late, as a general
+thing, to be effective. The device represented in
+Fig. 70 is very simple, and in practice is found to
+be most efficient.
+
+In this Fig. 70 A and B represent the upper
+and the lower planes, respectively. Near the end
+vertical standards a, D, are narrow wings E E,
+F F, hinged on a fore and aft line close below
+each of the planes, the wings being at such distances
+from the standards C D that when they
+swing outwardly they will touch the standards,
+and when in that position will be at an angle of
+about 35 degrees from the planes A B.
+
+_Fig. 70. Automatic Stabilizing Wings._
+
+_Fig. 71. Action of Stabilizing Wings._
+
+Inwardly they are permitted to swing up and
+lie parallel with the planes, as shown in Fig. 71
+where the planes are at an angle. In turning, all
+machines skid,--that is they travel obliquely
+across the field, and this is also true when the
+ship is sailing at right angles to the course of the
+wind.
+
+This will be made clear by reference to Fig.
+72, in which the dart A represents the direction
+of the movement of the aeroplane, and B the
+direction of the wind, the vertical rudder a being
+almost at right angles to the course of the wind.
+
+_Fig. 72. Into the Wind at an Angle._
+
+In turning a circle the same thing takes place
+as shown in Fig. 73, with the tail at a different
+angle, so as to give a turning movement to the
+plane. It will be seen that in the circling movement
+the tendency of the aeroplane is to fly out
+at a tangent, shown by the line D, so that the
+planes of the machine are not radially-disposed
+with reference to the center of the circle, the line
+E showing the true radial line.
+
+Referring now to Fig. 71, it will be seen that
+this skidding motion of the machine swings the
+wings E F inwardly, so that they offer no resistance
+to the oblique movement, but the wings E
+E, at the other end of the planes are swung outwardly,
+to provide an angle, which tends to raise
+up the inner end of the planes, and thereby seek
+to keep the planes horizontal.
+
+_Fig. 73. Turning a Circle._
+
+BAROMETERS.--These instruments are used for
+registering heights. A barometer is a device for
+measuring the weight or pressure of the air.
+The air is supposed to extend to a height of 40
+miles from the surface of the sea. A column of
+air one inch square, and forty miles high, weighs
+the same as a column of mercury one inch square
+and 30 inches high.
+
+Such a column of air, or of mercury, weighs
+14 3/4 pounds. If the air column should be
+weighed at the top of the mountain, that part
+above would weigh less than if measured at the
+sea level, hence, as we ascend or descend the pressure
+becomes less or more, dependent on the altitude.
+
+Mercury is also used to indicate temperature,
+but this is brought about by the expansive quality
+of the mercury, and not by its weight.
+
+_Fig. 74. Aneroid Barometer._
+
+ANEROID BAROMETER.--The term Aneroid barometer
+is frequently used in connection with air-
+ship experiments. The word aneroid means not
+wet, or not a fluid, like mercury, so that, while
+aneroid barometers are being made which do use
+mercury, they are generally made without.
+
+One such form is illustrated in Fig. 74, which
+represents a cylindrical shell A, which has at each
+end a head of concentrically formed corrugations.
+These heads are securely fixed to the ends of the
+shell A. Within, one of the disk heads has a
+short stem C, which is attached to the short end
+of a lever D, this lever being pivoted at E. The
+outer end of this lever is hinged to the short end
+of another lever F, and so by compounding the
+levers, it will be seen that a very slight movement
+of the head B will cause a considerable movement
+in the long end of the lever F.
+
+This end of the lever F connects with one limb
+of a bell-crank lever G, and its other limb has a
+toothed rack connection with a gear H, which
+turns the shaft to which the pointer I is attached.
+
+Air is withdrawn from the interior of the shell,
+so that any change in the pressure, or weight of
+the atmosphere, is at once felt by the disk heads,
+and the finger turns to indicate the amount of
+pressure.
+
+HYDROPLANES.--Hydro means water, hence the
+term hydroplane has been given to machines
+which have suitable pontoons or boats, so they
+may alight or initiate flight from water.
+
+There is no particular form which has been
+adopted to attach to aeroplanes, the object generally
+being to so make them that they will sustain
+the greatest amount of weight with the least
+submergence, and also offer the least resistance
+while the motor is drawing the machine along the
+surface of the water, preparatory to launching it.
+
+SUSTAINING WEIGHT OF PONTOONS.--A pontoon
+having within nothing but air, is merely a measuring
+device which determines the difference between
+the weight of water and the amount placed
+on the pontoon. Water weighs 62 1/2 pounds per
+cubic foot. Ordinary wood, an average of 32
+pounds, and steel 500 pounds.
+
+It is, therefore, an easy matter to determine
+how much of solid matter will be sustained by a
+pontoon of a given size, or what the dimensions
+of a pontoon should be to hold up an aeroplane
+which weighs, with the pilot, say, 1100 pounds.
+
+As we must calculate for a sufficient excess to
+prevent the pontoons from being too much immersed,
+and also allow a sufficient difference in
+weight so that they will keep on the surface when
+the aeroplane strikes the surface in alighting, we
+will take the figure of 1500 pounds to make the
+calculations from.
+
+If this figure is divided by 62 1/2 we shall find
+the cubical contents of the pontoons, not considering,
+of course, the weight of the material of which
+they are composed. This calculation shows that
+we must have 24 cubic feet in the pontoons.
+
+As there should be two main pontoons, and a
+smaller one for the rear, each of the main ones
+might have ten cubic feet, and the smaller one
+four cubic feet.
+
+SHAPES OF THE PONTOONS.--We are now ready
+to design the shapes. Fig. 75 shows three general
+types, A being made rectangular in form,
+with a tapering forward end, so constructed as to
+ride up on the water.
+
+The type B has a rounded under body, the forward
+end being also skiff-shaped to decrease as
+much as possible the resistance of the water impact.
+
+_Fig. 75. Hydroplane Floats._
+
+The third type C is made in the form of a
+closed boat, with both ends pointed, and the bottom
+rounded, or provided with a keel. Or, as in
+some cases the body may be made triangular in
+cross section so that as it is submerged its sustaining
+weight will increase at a greater degree
+as it is pressed down than its vertical measurement
+indicates.
+
+All this, however, is a matter left to the judgment
+of the designer, and is, in a great degree,
+dependent on the character of the craft to which
+it is to be applied.
+
+
+
+
+CHAPTER XII
+
+EXPERIMENTAL WORK IN FLYING
+
+
+THE novice about to take his first trial trip in
+an automobile will soon learn that the great task
+in his mind is to properly start the machine. He
+is conscious of one thing, that it will be an easy
+matter to stop it by cutting off the fuel supply
+and applying the brakes.
+
+CERTAIN CONDITIONS IN FLYING.--In an aeroplane
+conditions are reversed. Shutting off the
+fuel supply and applying the brakes only bring
+on the main difficulty. He must learn to stop the
+machine after all this is done, and this is the
+great test of flying. It is not the launching,--
+the ability to get into the air, but the landing, that
+gives the pupil his first shock.
+
+Man is so accustomed to the little swirls of air
+all about him, that he does not appreciate what
+they mean to a machine which is once free to
+glide along in the little currents which are so unnoticeable
+to him as a pedestrian.
+
+The contour of the earth, the fences, trees, little
+elevations and other natural surroundings, all
+have their effect on a slight moving air current,
+and these inequalities affect the air and disturb
+it to a still greater extent as the wind increases.
+Even in a still air, with the sun shining, there are
+air eddies, caused by the uneven heating of the
+air in space.
+
+HEAT IN AIR.--Heat is transmitted through the
+air by what is called convection, that is, the particles
+of the air transmit it from one point to the
+next. If a room is closed up tight, and a little
+aperture provided so as to let in a streak of sunlight,
+it will give some idea of the unrest of the
+atmosphere. This may be exhibited by smoke
+along the line of the sun's rays, which indicates
+that the particles of air are constantly in motion,
+although there may be absolutely nothing in the
+room to disturb it.
+
+MOTION WHEN IN FLIGHT.--If you can imagine
+a small airship floating in that space, you can
+readily conceive that it will be hurled hither and
+thither by the motion which is thus apparent to
+the eye.
+
+This motion is greatly accentuated by the surface
+of the earth, independently of its uneven contour.
+If a ball is thrown through the air, its
+dynamic force is measured by its impact. So
+with light, and heat. In the space between the
+planets it is very cold. The sunlight, or the rays
+from the sun are there, just the same as on the
+earth.
+
+Unless the rays come into contact with something,
+they produce no effect. When the beams
+from the sun come into contact with the atmosphere
+a dynamic force is exerted, just the same
+as when the ball struck an object. When the rays
+reach the earth, reflection takes place, and these
+reflected beams act on the air under different conditions.
+
+CHANGING ATMOSPHERE.--If the air is full of
+moisture, as it may be at some places, while
+comparatively dry at other points, the reflection
+throughout the moist area is much greater than in
+the dry places, hence evaporation will take place
+and whenever a liquid vaporizes it means heat.
+
+On the other hand, when the vapor is turning
+to a liquid, condensation takes place, and that
+means cooling. If the air should be of the same
+degree of saturation throughout,--that is, have
+the same amount of moisture everywhere, there
+would be few winds. These remarks apply to
+conditions which exist over low altitudes all over
+the earth.
+
+But at high altitudes the conditions are entirely
+different. As we ascend the air becomes rarer.
+It has less moisture, because a wet atmosphere,
+being heavier, lies nearer the surface of the earth.
+Being rarer the action of sunlight on the particles
+is less intense. Reflection and refraction of the
+rays acting on the light atmosphere do not produce
+such a powerful effect as on the air near the
+ground.
+
+All these conditions--the contour of the earth;
+the uneven character of the moisture in the air;
+the inequalities of the convection currents; and
+the unstable, tenuous, elastic nature of the atmosphere,
+make the trials of the aviator a hazardous
+one, and it has brought out numerous theories
+connected with bird flight. One of these assumes
+that the bird, by means of its finely organized
+sense, is able to detect rising air currents, and it
+selects them in its flight, and by that means is enabled
+to continue in flight indefinitely, by soaring,
+or by flapping its wings.
+
+ASCENDING CURRENTS.--It has not been explained
+how it happens that these particular "ascending
+currents" always appear directly in the line of
+the bird flight; or why it is that when, for instance,
+a flock of wild geese which always fly through
+space in an A-shaped formation, are able to get
+ascending air currents over the wide scope of space
+they cover.
+
+ASPIRATE CURRENTS.--Some years ago, in making
+experiments with the outstretched wings of
+one of the large soaring birds, a French sailor
+was surprised to experience a peculiar pulling motion,
+when the bird's wings were held at a certain
+angle, so that the air actually seemed to draw it
+into the teeth of the current.
+
+It is known that if a ball is suspended by a
+string, and a jet of air is directed against it, in
+a particular way, the ball will move toward the
+jet, instead of being driven away from it. A well
+known spraying device, called the "ball nozzle,"
+is simply a ball on the end of a nozzle, and the
+stream of water issuing is not effectual to drive
+the ball away.
+
+From the bird incident alluded to, a new theory
+was propounded, namely, that birds flew because
+of the aspirated action of the air, and the wings
+and body were so made as to cause the moving air
+current to act on it, and draw it forwardly.
+
+OUTSTRETCHED WINGS.--This only added to the
+"bird wing" theory a new argument that all flying
+things must have outstretched wings, in order
+to fly, forgetting that the ball, which has no
+outstretched wings, has also the same "aspirate"
+movement attributed to the wings of the bird.
+
+The foregoing remarks are made in order to impress
+on the novice that theories do not make
+flying machines, and that speculations, or analogies
+of what we see all about us, will not make an
+aviator. A flying machine is a question of
+dynamics, just as surely as the action of the sun on
+the air, and the movements of the currents, and
+the knowledge of applying those forces in the flying
+machine makes the aviator.
+
+THE STARTING POINT.--Before the uninitiated
+should attempt to even mount a machine he should
+know what it is composed of, and how it is made.
+His investigation should take in every part of the
+mechanism; he should understand about the plane
+surface, what the stresses are upon its surface,
+what is the duty of each strut, or brace or wire
+and be able to make the proper repairs.
+
+THE VITAL PART OF THE MACHINE.--The motor,
+the life of the machine itself, should be like a
+book to him. It is not required that he should
+know all the theories which is necessary in the
+building, as to the many features which go to
+make up a scientifically-designed motor; but he
+must know how and why it works. He should understand
+the cam action, whereby the valves are
+lifted at the proper time; what the effect of the
+spark advance means; the throttling of the engine;
+air admission and supply; the regulation
+of the carbureter; its mechanism and construction;
+the propeller should be studied, and its action
+at various speeds.
+
+STUDYING THE ACTION OF THE MACHINE.--Then
+comes the study on the seat of the machine itself.
+It will be a novel sensation. Before him is the
+steering wheel, if it should be so equipped. Turning
+it to the right, swings the vertical tail plane
+so the machine will turn to the right. Certainly,
+he knows that; but how far must he turn the
+wheel to give it a certain angle.
+
+It is not enough to know that a lever or a wheel
+when moved a certain way will move a plane a
+definite direction. He should learn to know
+instinctively, how FAR a movement to make to get
+a certain result in the plane itself, and under running
+conditions, as well.
+
+Suppose we have an automobile, running at the
+rate of ten miles an hour, and the chauffeur turns
+the steering wheel ten degrees. He can do so with
+perfect safety; but let the machine be going forty
+miles an hour, and turn the wheel ten degrees,
+and it may mean an accident. In one case the
+machine is moving 14 1/2 feet a second, and in the
+other instance 58 feet.
+
+If the airship has a lever for controlling the
+angle of flight, he must study its arrangement,
+and note how far it must be moved to assume
+the proper elevating angle. Then come the means
+for controlling the lateral stability of the machine.
+All these features should be considered and studied
+over and over, until you have made them your
+friends.
+
+While thus engaged, you are perfectly sure that
+you can remember and act on a set of complicated
+movements. You imagine that you are skimming
+over the ground, and your sense tells you that you
+have sufficient speed to effect a launching. In
+your mind the critical time has come.
+
+ELEVATING THE MACHINE.--Simply give the elevator
+lever the proper angle, sharp and quick and
+up you go. As the machine responds, and you can
+feel the cushioning motion, which follows, as it begins
+to ride the air, you are aware of a sensation
+as though the machine were about to turn over
+to one side; you think of the lateral control at
+once, but in doing so forget that the elevator must
+be changed, or you will go too high.
+
+You forget about the earth; you are too busy
+thinking about several things which seem to need
+your attention. Yes, there are a variety of matters
+which will crowd upon you, each of which require
+two things; the first being to get the proper
+lever, and the second, to move it just so far.
+
+In the early days of aeroplaning, when accidents
+came thick and fast, the most usual explanation
+which came from the pilot, when he recovered,
+was: "I pushed the lever too far."
+
+Hundreds of trial machines were built, when
+man learned that he could fly, and in every instance,
+it is safe to say, the experimenter made the
+most strenuous exertion to get up in the air the
+first time the machine was put on the trial ground.
+
+It is a wonder that accidents were not recorded
+by the hundreds, instead of by the comparatively
+few that were heard from. It was very discouraging,
+no doubt, that the machines would not fly,
+but that all of them, if they had sufficient power,
+would fly, there can be no doubt.
+
+HOW TO PRACTICE.--Absolute familiarity with
+every part of the machine and conditions is the
+first thing. The machine is brought out, and the
+engine tested, the machine being held in leash
+while this is done. It is then throttled down so
+that the power of the engine will be less than is
+necessary to raise the machine from the ground.
+
+THE FIRST STAGE.--Usually it will require over
+25 miles an hour to raise the machine. The engine
+is set in motion, and now, for the first time a new
+sensation takes possession of you, for the reason
+that you are cut off from communication with
+those around you as absolutely as though they
+were a hundred miles away.
+
+This new dependence on yourself is, in itself,
+one of the best teachers you could have, because
+it begins to instill confidence and control. As the
+machine darts forward, going ten or fifteen miles
+an hour, with the din of the engine behind you,
+and feeling the rumbling motion of the wheels
+over the uneven surface of the earth, you have the
+sensation of going forty miles an hour.
+
+The newness of the first sensation, which is
+always under those conditions very much augmented
+in the mind, wears away as the machine
+goes back and forth. There is only one control
+that requires your care, namely, to keep it on a
+straight course. This is easy work, but you are
+learning to make your control a reflex action,--to
+do it without exercising a distinct will power.
+
+PATIENCE THE MOST DIFFICULT THING.--If you
+have the patience, as you should, to continue this
+running practice, until you absolutely eliminate
+the right and left control, as a matter of thought,
+occasionally, if the air is still turning the machine,
+and eventually, bringing it back, by turning
+it completely around, while skimming the ground,
+you will be ready for the second stage in the
+trials.
+
+THE SECOND STAGE.--The engine is now arranged
+so that it will barely lift, when running
+at its best. After the engine is at full speed, and
+you are sure the machine is going fast enough,
+the elevator control is turned to point the machine
+in the air. It is a tense moment. You are on the
+alert.
+
+The elevator is turned, and the forward end
+changes its relation with the ground before you.
+There was a slight lift, but your caution induces
+you to return the planes to their normal running
+angle. You try it again. You are now certain
+that the machine made a leap and left the ground.
+This is the exhilarating moment.
+
+With a calm air the machine is turned while
+running, by means of the vertical rudders. This
+is an easy matter, because while going at twenty
+miles an hour, the weight of the machine on the
+surface of the ground is less than one-tenth of its
+weight when at rest.
+
+Thus the trial spins, half the time in the air,
+in little glides of fifty to a hundred feet, increasing
+in length, give practice, practice, PRACTICE,
+each turn of the field making the sport less exciting
+and fixing the controls more perfectly in the
+mind.
+
+THE THIRD STAGE.--Thus far you have been
+turning on the ground. You want to turn in the
+air. Only the tail control was required while on
+the ground. Now two things are required after
+you leave the ground in trying to make a turn:
+namely, putting the tail at the proper angle, and
+taking charge of the stabilizers, because in making
+the turn in the air, the first thing which will
+arrest the attention will be the tendency of the
+machine to turn over in the direction that you are
+turning.
+
+After going back and forth in straight-away
+glides, until you have perfect confidence and full
+control, comes the period when the turns should
+be practiced on. These should be long, and tried
+only on that portion of the field where you have
+plenty of room.
+
+OBSERVATIONS WHILE IN FLIGHT.--If there are
+any bad spots, or trees, or dangerous places, they
+should be spotted out, and mentally noted before
+attempting to make any flight. When in the air
+during these trials you will have enough to occupy
+your mind without looking out for the hazardous
+regions at the same time.
+
+Make the first turns in a still air. If you should
+attempt to make the first attempts with a wind
+blowing you will find a compound motion that will
+very likely give you a surprise. In making the
+first turn you will get the sensation of trying to
+fly against a wind. Assuming that you are turning
+to the left, it will have the sensation of a wind
+coming to you from the right.
+
+FLYING IN A WIND.--Suppose you are flying directly
+in the face of a wind, the moment you begin
+to turn the action, or bite of the wind, will cause
+the ends of the planes to the right to be unduly
+elevated, much more so than if the air should be
+calm. This raising action will be liable to startle
+you, because up to this time you have been accustomed
+to flying along in a straight line.
+
+While flying around at the part of the circle
+where the wind strikes you directly on the right
+side the machine has a tendency to climb, and you
+try to depress the forward end, but as soon as you
+reach that part of the circle where the winds begin
+to strike on your back, an entirely new thing
+occurs.
+
+As the machine is now traveling with the wind,
+its grip on the air is less, and since the planes were
+set to lower the machine, at the first part of the
+turn, the descent will be pretty rapid unless the
+angle is corrected.
+
+FIRST TRIALS IN QUIET ATMOSPHERE.--All this
+would be avoided if the first trials were made in
+a quiet atmosphere. Furthermore, you will be
+told that in making a turn the machine should be
+pointed downwardly, as though about to make a
+glide. This can be done with safety, in a still
+air, although you may be flying low, but it would
+be exceedingly dangerous with a wind blowing.
+
+MAKING TURNS.--When making a turn, under no
+circumstances try to make a landing. This
+should never be done except when flying straight,
+and then safety demands that the landing should
+be made against the wind and not with it. There
+are two reasons for this: First, when flying with
+the wind the speed must be greater than when flying
+against it.
+
+By greater speed is meant relative to the earth.
+If the machine has a speed of thirty miles an hour,
+in still air, the speed would be forty miles an hour
+going with the wind, but only twenty miles against
+the wind. Second, the banking of the planes
+against the air is more effective when going into
+the wind than when traveling with it, and, therefore,
+the speed at which you contact with the earth
+is lessened to such an extent that a comparatively
+easy landing is effected.
+
+THE FOURTH STAGE.--After sufficient time has
+been devoted to the long turns shorter turns may
+be made, and these also require the same care,
+and will give an opportunity to use the lateral
+controls to a greater extent. Begin the turns, not
+by an abrupt throw of the turning rudder, but
+bring it around gently, correcting the turning
+movement to a straight course, if you find the
+machine inclined to tilt too much, until you get used
+to the sensation of keeling over. Constant practice
+at this will soon give confidence, and assure
+you that you have full control of the machine.
+
+THE FIGURE 8.--You are now to increase the
+height of flying, and this involves also the ability
+to turn in the opposite direction, so that you may
+be able to experience the sensation of using the
+stabilizers in the opposite direction. You will
+find in this practice that the senses must take in
+the course of the wind from two quarters now, as
+you attempt to describe the figure 8.
+
+This is a test which is required in order to obtain
+a pilot's license. It means that you shall
+be able to show the ability to turn in either direction
+with equal facility. To keep an even flying
+altitude while describing this figure in a wind, is
+the severest test that can be exacted.
+
+THE VOLPLANE.--This is the technical term for
+a glide. Many accidents have been recorded owing
+to the stopping of the motor, which in the
+past might have been avoided if the character of
+the glide had been understood. The only thing
+that now troubles the pilot when the engine "goes
+dead," is to select a landing place.
+
+The proper course in such a case is to urge
+the machine to descend as rapidly as possible, in
+order to get a headway, for the time being. As
+there is now no propelling force the glide is depended
+upon to act as a substitute. The experienced
+pilot will not make a straight-away glide,
+but like the vulture, or the condor, and birds of
+that class, soar in a circle, and thus, by passing
+over and over the same surfaces of the earth, enable
+him to select a proper landing place.
+
+THE LANDING.--The pilot who can make a good
+landing is generally a good flyer. It requires
+nicety of judgment to come down properly. One
+thing which will appear novel after the first altitude
+flights are attempted is the peculiar sensation
+of the apparently increased speed as the earth
+comes close up to the machine.
+
+At a height of one hundred feet, flying thirty
+miles an hour, does not seem fast, because the surface
+of the earth is such a distance away that particular
+objects remain in view for some moments;
+but when within ten feet of the surface the same
+object is in the eye for an instant only.
+
+This lends a sort of terror to the novice. He
+imagines a great many things, but forgets some
+things which are very important to do at this
+time. One is, that the front of the machine must
+be thrown up so as to bank the planes against the
+wind. The next is to shut off the power, which
+is to be done the moment the wheels strike the
+ground, or a little before.
+
+Upon his judgment of the time of first touching
+the earth depends the success of safely alighting.
+He may bank too high, and come down on the tail
+with disastrous results. If there is plenty of field
+room it is better to come down at a less angle, or
+even keep the machine at an even keel, and the
+elevator can then depress the tail while running
+over the ground, and thus bring the machine to
+rest.
+
+Frequently, when about to land the machine
+will rock from side to side. In such a case it is
+far safer to go up into the air than to make the
+land, because, unless the utmost care is exercised,
+one of the wing tips will strike the earth and
+wreck the machine.
+
+Another danger point is losing headway, as the
+earth is neared, due to flying at too flat an angle,
+or against a wind that happens to be blowing particularly
+hard at the landing place. If the motor
+is still going this does not make so much difference,
+but in a volplane it means that the descent
+must be so steep, at the last moment of flight, that
+the chassis is liable to be crushed by the impact.
+
+FLYING ALTITUDE.--It is doubtful whether the
+disturbed condition of the atmosphere, due to
+the contour of the earth's surface, reaches higher
+than 500 feet. Over a level area it is certain that
+it is much less, but in some sections of the country,
+where the hill ranges extend for many miles,
+at altitudes of three and four hundred feet, the
+upper atmosphere may be affected for a thousand
+feet above.
+
+Prof. Lowe, in making a flight with a balloon,
+from Cincinnati to North Carolina, which lasted
+a day and all of one night, found that during the
+early morning the balloon, for some reason, began
+to ascend, and climbed nearly five thousand
+feet in a few hours, and as unaccountably
+began to descend several hours before he landed.
+
+Before it began to ascend, he was on the western
+side of the great mountain range which extends
+south from Pennsylvania and terminates in
+Georgia. He was actually climbing the mountain
+in a drift of air which was moving eastwardly,
+and at no time was he within four thousand feet
+of the earth during that period, which shows that
+air movements are of such a character as to exert
+their influence vertically to great heights.
+
+For cross country flying the safest altitude is
+1000 feet, a distance which gives ample opportunity
+to volplane, if necessary, and it is a height
+which enables the pilot to make observations of the
+surface so as to be able to judge of its character.
+
+But explanations and statements, and the experiences
+of pilots might be detailed in pages, and
+still it would be ineffectual to teach the art of flying.
+The only sure course is to do the work on
+an actual machine.
+
+Many of the experiences are valuable to the
+learner, some are merely in the nature of cautions,
+and it is advisable for the beginner to learn what
+the experiences of others have been, although they
+may never be called upon to duplicate them.
+
+All agree that at great elevations the flying
+conditions are entirely different from those met
+with near the surface of the ground, and the history
+of accidents show that in every case where
+a mishap was had at high altitude it came about
+through defect in the machine, and not from gusts
+or bad air condition.
+
+On the other hand, the uptilting of machines,
+the accidents due to the so-called "Holes in the
+air," which have dotted the historic pages with
+accidents, were brought about at low altitudes.
+
+At from two to five thousand feet the air may be
+moving at speeds of from twenty to forty miles
+an hour,--great masses of winds, like the trade
+stream, which are uniform over vast areas. To
+the aviator flying in such a field, with the earth
+hidden from him, there would be no wind to indicate
+that he was moving in any particular direction.
+
+He would fly in that medium, in any direction,
+without the slightest sense that he was in a gale.
+It would not affect the control of the machine,
+because the air, though moving as a mass, would
+be the same as flying in still air. It is only when
+he sees fixed objects that he is conscious of the
+movement of the wind.
+
+
+
+CHAPTER XIII
+
+THE PROPELLER
+
+
+BY far the most difficult problem connected
+with aviation is the propeller. It is the one great
+vital element in the science and art pertaining to
+this subject which has not advanced in the slightest
+degree since the first machine was launched.
+
+The engine has come in for a far greater share
+of expert experimental work, and has advanced
+most rapidly during the past ten years. But,
+strange to say, the propeller is, essentially, the
+same with the exception of a few small changes.
+
+PROPELLER CHANGES.--The changes which have
+been made pertaining to the form of structure,
+principally, and in the use of new materials. The
+kind of wood most suitable has been discovered,
+but the lines are the same, and nothing has been
+done to fill the requirement which grows out of
+the difference in speed when a machine is in the
+act of launching and when it is in full flight.
+
+PROPELLER SHAPE.--It cannot be possible that
+the present shape of the propeller will be its ultimate
+form. It is inconceivable that the propeller
+is so inefficient that only one sixty-fifth of the
+power of the engine is available. The improvement
+in propeller efficiency is a direction which
+calls for experimental work on the part of inventors
+everywhere.
+
+The making of a propeller, although it appears
+a difficult task, is not as complicated as would appear,
+and with the object in view of making the
+subject readily understood, an explanation will be
+given of the terms "Diameter," and "Pitch," as
+used in the art.
+
+The Diameter has reference to the length of
+the propeller, from end to end. In calculating
+propeller pull, the diameter is that which indicates
+the speed of travel, and for this reason is
+a necessary element.
+
+Thus, for instance, a propeller three feet in
+diameter, rotating 500 times a minute, has a tip
+speed of 1500 feet, whereas a six foot propeller,
+rotating at the same speed, moves 3000 feet at the
+tips.
+
+PITCH.--This is the term which is most confusing,
+and is that which causes the most frequent
+trouble in the mind of the novice. The term will
+be made clear by carefully examining the accompanying
+illustration and the following description:
+
+In Fig. 76 is shown a side view of a propeller
+A, mounted on a shaft B, which is free to move
+longitudinally. Suppose we turn the shaft so the
+tip will move along on the line indicated by the
+arrow C.
+
+Now the pitch of the blade at D is such that it
+will be exactly in line with the spirally-formed
+course E, for one complete turn. As the propeller
+shaft has now advanced, along the line E, and
+stopped after one turn, at F, the measure between
+the points F and G represents the pitch of the propeller.
+Another way to express it would be to
+call the angle of the blade a five, or six, or a seven
+foot pitch, as the pitches are measured in feet.
+
+_Fig. 76. Describing the Pitch Line._
+
+In the illustration thus given the propeller shaft,
+having advanced six feet, we have what is called
+a six foot pitch.
+
+Now, to lay out such a pitch is an easy matter.
+Assume, as in Fig. 77, that A represents the end
+of the blank from which the propeller is to be cut,
+and that the diameter of this blank, or its length
+from end to end is seven feet. The problem now
+is to cut the blades at such an angle that we shall
+have a six foot pitch.
+
+_Fig. 77. Laying out the Pitch._
+
+LAYING OUT THE PITCH.--First, we must get the
+circumference of the propeller, that is, the distance
+the tip of the propeller will travel in making
+one complete turn. This is done by multiplying
+7 by 3.1416. This equals 21.99, or, practically, 22
+feet.
+
+A line B is drawn, extending out horizontally
+along one side of the blank A, this line being made
+on a scale, to represent 22 feet. Secondly, at the
+end of this line drawn a perpendicular line C, 6
+feet long. A perpendicular line is always one
+which is at right angles to a base line. In this
+case B is the base line.
+
+Line C is made 6 feet long, because we are trying
+to find the angle of a 6 foot pitch. If, now, a
+line D is drawn from the ends of the two lines B,
+C, it will represent the pitch which, marked across
+the end of the blank A, will indicate the line to cut
+the blade.
+
+PITCH RULE.--The rule may, therefore, be
+stated as follows: Multiply the diameter (in
+feet) of the propeller by 3.1416, and draw a line
+the length indicated by the product. At one end
+of this line draw a perpendicular line the length
+of the pitch requirement (in feet), and join the
+ends of the two lines by a diagonal line, and this
+line will represent the pitch angle.
+
+Propellers may be made of wood or metal, the
+former being preferred for the reason that this
+material makes a lighter article, and is stronger,
+in some respects, than any metal yet suggested.
+
+LAMINATED CONSTRUCTION.--All propellers
+should be laminated,--that is, built up of layers
+of wood, glued together and thoroughly dried,
+from which the propeller is cut.
+
+A product thus made is much more serviceable
+than if made of one piece, even though the laminated
+parts are of the same wood, because the
+different strips used will have their fibers overlapping
+each other, and thus greatly augment the
+strength of the whole.
+
+Generally the alternate strips are of different
+materials, black walnut, mahogany, birch, spruce,
+and maple being the most largely used, but mahogany
+and birch seem to be mostly favored.
+
+LAYING UP A PROPELLER FORM.--The first step
+necessary is to prepare thin strips, each, say,
+seven feet long, and five inches wide, and three-
+eighths of an inch thick. If seven such pieces are
+put together, as in Fig. 78, it will make an assemblage
+of two and five-eighth inches high.
+
+_Fig. 78. A Laminated Blank._
+
+Bore a hole centrally through the assemblage,
+and place therein a pin B. The contact faces of
+these strips should be previously well painted
+over with hot glue liberally applied. When they
+are then placed in position and the pin is in place,
+the ends of the separate pieces are offset, one beyond
+the other, a half inch, as shown, for instance,
+in Fig. 79.
+
+This will provide ends which are eight and a
+half inches broad, and thus furnish sufficient
+material for the blades. The mass is then subjected
+to heavy pressure, and allowed to dry before the
+blades are pared down.
+
+_Fig. 79. Arranging the Strips._
+
+MAKING WIDE BLADES.--If a wider blade is desired,
+a greater number of steps may be made by
+adding the requisite number of strips; or, the
+strips may be made thicker. In many propellers,
+not to exceed four different strips are thus glued
+together. The number is optional with the
+maker.
+
+An end view of such an assemblage of strips
+is illustrated in Fig. 80. The next step is to lay
+off the pitch, the method of obtaining which has
+been explained.
+
+_Fig. 80. End view of Blank._
+
+Before starting work the sides, as well as the
+ends, should be marked, and care observed to
+place a distinctive mark on the front side of the
+propeller.
+
+Around the pin B, Fig. 81, make S-shaped
+marks C, to indicate where the cuts on the faces
+of the blades are to begin. Then on the ends of
+the block; scribe the pitch angle, which is indicated
+by the diagonal line D, Fig. 80.
+
+_Fig. 81. Marking the Side._
+
+This line is on the rear side of the propeller,
+and is perfectly straight. Along the front of this
+line is a bowline E, which indicates the front surface
+of the propeller blade.
+
+PROPELLER OUTLINE.--While the marks thus
+given show the angles, and are designed to indicate
+the two faces of the blades, there is still another
+important element to be considered, and
+that is the final outline of the blades.
+
+_Fig. 82. Outlining._
+
+It is obvious that the outline may be varied
+so that the entire width at 1, Fig. 82, may be used,
+or it may have an outline, as represented by the
+line 2, in this figure, so that the widest part will
+be at or near the dotted line 3, say two-thirds of
+the distance from the center of the blade.
+
+This is the practice with most of the manufacturers
+at the present time, and some of them
+claim that this form produces the best results.
+
+FOR HIGHER SPEEDS.--Fig. 83 shows a propeller
+cut from a blank, 4" x 6" in cross section, not
+laminated.
+
+_Fig. 83. Cut from a 4" x 6" Single Blank._
+
+It should be borne in mind that for high speeds
+the blades must be narrow. A propeller seven
+feet in diameter with a six foot pitch, turning
+950 revolutions per minute, will produce a pull of
+350 pounds, if properly made.
+
+Such a propeller can be readily handled by a
+forty horse power motor, such as are specially
+constructed for flying machine purposes.
+
+INCREASING PROPELLER EFFICIENCY.--Some experiments
+have been made lately, which, it is
+claimed, largely increase the efficiency of propellers.
+The improvement is directed to the outline
+shape of the blade.
+
+The typical propeller, such as we have illustrated,
+is one with the wide part of the blade at
+the extremity. The new type, as suggested, reverses
+this, and makes the wide part of the blade
+near the hub, so that it gradually tapers down to
+a narrow tip.
+
+Such a form of construction is shown in Fig.
+84. This outline has some advantages from one
+standpoint, namely, that it utilizes that part of
+the blade near the hub, to produce a pull, and
+does not relegate all the duty to the extreme ends
+or tips.
+
+_Fig. 84. A Suggested Form._
+
+To understand this more fully, let us take a
+propeller six feet in diameter, and measure the
+pull or thrust at the tips, and also at a point half
+way between the tip and the hub.
+
+In such a propeller, if the blade is the same
+width and pitch at the two points named, the pull
+at the tips will be four times greater than at the
+intermediate point.
+
+
+
+CHAPTER XIV
+
+EXPERIMENTAL GLIDERS AND MODEL AEROPLANES
+
+
+AN amusing and very instructive pastime is
+afforded by constructing and flying gliding machines,
+and operating model aeroplanes, the latter
+being equipped with their own power.
+
+Abroad this work has been very successful as
+a means of interesting boys, and, indeed, men
+who have taken up the science of aviation are
+giving this sport serious thought and study.
+
+When a machine of small dimensions is made
+the boy wonders why a large machine does not
+bear the same relation in weight as a small machine.
+This is one of the first lessons to learn.
+
+THE RELATION OF MODELS TO FLYING MACHINES.
+--A model aeroplane, say two feet in length, which
+has, we will assume, 50 square inches of supporting
+surface, seems to be a very rigid structure,
+in proportion to its weight. It may be dropped
+from a considerable height without injuring it,
+since the weight is only between two and three
+ounces.
+
+An aeroplane twenty times the length of this
+model, however strongly it may be made, if
+dropped the same distance, would be crushed, and
+probably broken into fragments.
+
+If the large machine is twenty times the dimensions
+of the small one, it would be forty feet in
+length, and, proportionally, would have only
+seven square feet of sustaining surface. But an
+operative machine of that size, to be at all rigid,
+would require more than twenty times the material
+in weight to be equal in strength.
+
+It would weigh about 800 pounds, that is, 4800
+times the weight of the model, and instead of
+having twenty times the plane surface would require
+one thousand times the spread.
+
+It is this peculiarity between models and the
+actual flyers that for years made the question of
+flying a problem which, on the basis of pure calculation
+alone, seemed to offer a negative; and
+many scientific men declared that practical flying
+was an impossibility.
+
+LESSONS FROM MODELS.--Men, and boys, too,
+can learn a useful lesson from the model aeroplanes
+in other directions, however, and the principal
+thing is the one of stability.
+
+When everything is considered the form or
+shape of a flying model will serve to make a large
+flyer. The manner of balancing one will be a
+good criterion for the other in practice, and
+experimenting with these small devices is, therefore,
+most instructive.
+
+The difference between gliders and model aeroplanes
+is, that gliders must be made much lighter
+because they are designed to be projected through
+the air by a kick of some kind.
+
+FLYING MODEL AEROPLANES.--Model aeroplanes
+contain their own power and propellers which,
+while they may run for a few seconds only, serve
+the purpose of indicating how the propeller will
+act, and in what respect the sustaining surfaces
+are efficient and properly arranged.
+
+It is not our purpose to give a treatise on this
+subject but to confine this chapter to an exposition
+of a few of the gliders and model forms which
+are found to be most efficient for experimental
+work.
+
+AN EFFICIENT GLIDER.--Probably the simplest
+and most efficient glider, and one which can be
+made in a few moments, is to make a copy of the
+deltoid kite, previously referred to.
+
+This is merely a triangularly-shaped piece of
+paper, or stiff cardboard A, Fig. 84, creased in
+the middle, along the dotted line B, the side wings
+C, C, being bent up so as to form, what are called
+diedral angles. This may be shot through the
+air by a flick of the finger, with the pointed end
+foremost, when used as a glider.
+
+_Fig. 85. Deltoid Glider._
+
+THE DELTOID FORMATION.--This same form may
+be advantageously used as a model aeroplane, but
+in that case the broad end should be foremost.
+
+_Fig. 86. The Deltoid Racer._
+
+Fig. 86 shows the deltoid glider, or aeroplane,
+with three cross braces, A, B, C, in the two forward
+braces of which are journaled the propeller
+shaft D, so that the propeller E is at the broad
+end of the glider.
+
+A short stem F through the rear brace C, provided
+with a crank, has its inner end connected
+with the rear end of the shaft D by a rubber band
+G, by which the propeller is driven.
+
+A tail may be attached to the rear end, or at
+the apex of the planes, so it can be set for the
+purpose of directing the angle of flight, but it will
+be found that this form has remarkable stability
+in flight, and will move forwardly in a straight
+line, always making a graceful downward movement
+when the power is exhausted.
+
+It seems to be a form which has equal stabilizing
+powers whether at slow or at high speeds,
+thus differing essentially from many forms which
+require a certain speed in order to get the best
+results.
+
+RACING MODELS.--Here and in England many
+racing models have been made, generally of the
+A-shaped type, which will be explained hereinafter.
+Such models are also strong, and able to
+withstand the torsional strain required by the
+rubber which is used for exerting the power.
+
+It is unfortunate that there is not some type of
+cheap motor which is light, and adapted to run
+for several minutes, which would be of great value
+in work of this kind, but in the absence of such
+mechanism rubber bands are found to be most
+serviceable, giving better results than springs or
+bows, since the latter are both too heavy to be
+available, in proportion to the amount of power
+developed.
+
+Unlike the large aeroplanes, the supporting
+surfaces, in the models, are at the rear end of
+the frames, the pointed ends being in front.
+
+_Fig. 87. A-Shaped Racing Glider._
+
+Fig. 87 shows the general design of the A-
+shaped gliding plane or aeroplane. This is composed
+of main frame pieces A, A, running fore
+and aft, joined at their rear ends by a cross bar
+B, the ends of which project out slightly beyond
+their juncture with the side bars A, A. These
+projecting ends have holes drilled therein to receive
+the shafts a, a, of the propeller D, D.
+
+A main plane E is mounted transversely across
+this frame at its rear end, while at its forward
+end is a small plane, called the elevator. The
+pointed end of the frame has on each side a turnbuckle
+G, for the purpose of winding up the shaft,
+and thus twisting the propeller, although this is
+usually dispensed with, and the propeller itself
+is turned to give sufficient twist to the rubber for
+this purpose.
+
+THE POWER FOR MODEL AEROPLANES.--One end
+of the rubber is attached to the hook of the shaft
+C, and the other end to the hook or to the turnbuckle
+G, if it should be so equipped.
+
+The rubbers are twisted in opposite directions,
+to correspond with the twist of the propeller
+blades, and when the propellers are permitted to
+turn, their grip on the air will cause the model to
+shoot forwardly, until the rubbers are untwisted,
+when the machine will gradually glide to the
+ground.
+
+MAKING THE PROPELLER.--These should have
+the pitch uniform on both ends, and a simple
+little device can be made to hold the twisted blade
+after it has been steamed and bent. Birch and
+holly are good woods for the blades. The strips
+should be made thin and then boiled, or, what is
+better still, should be placed in a deep pan, and
+held on a grid above the water, so they will be
+thoroughly steamed.
+
+They are then taken out and bent by hand, or
+secured between a form specially prepared for
+the purpose. The device shown in Fig. 88 shows
+a base board which has in the center a pair of
+parallel pins A, A, slightly separated from each
+other.
+
+_Fig. 88. Making the Propeller._
+
+At each end of the base board is a pair of holes
+C, D, drilled in at an angle, the angles being the
+pitch desired for the ends of the propeller. In
+one of these holes a pin E is placed, so the pins
+at the opposite ends project in different directions,
+and the tips of the propeller are held
+against the ends of these pins, while the middle
+of the propeller is held between the parallel pins
+A, A.
+
+The two holes, at the two angles at the ends of
+the board, are for the purpose of making right
+and left hand propellers, as it is desirable to use
+two propellers with the A-shaped model. Two
+propellers with the deltoid model are not so necessary.
+
+After the twist is made and the blade properly
+secured in position it should be allowed to thoroughly
+dry, and afterwards, if it is coated with
+shellac, will not untwist, as it is the changing
+character of the atmosphere which usually causes
+the twisted strips to change their positions.
+Shellac prevents the moist atmosphere from affecting
+them.
+
+MATERIAL FOR PROPELLERS.--Very light propellers
+can also be made of thin, annealed aluminum
+sheets, and the pins in that case will serve as
+guides to enable you to get the desired pitch.
+Fiber board may also be used, but this is more
+difficult to handle.
+
+Another good material is celluloid sheets,
+which, when cut into proper strips, is dipped in
+hot water, for bending purposes, and it readily
+retains its shape when cooled.
+
+RUBBER--Suitable rubber for the strips are
+readily obtainable in the market. Experiment
+will soon show what size and lengths are best
+adapted for the particular type of propellers
+which you succeed in making.
+
+PROPELLER SHAPE AND SIZE.--A good proportion
+of propeller is shown in Fig. 89. This also
+shows the form and manner of connecting the
+shaft. The latter A has a hook B on one end to
+which the rubber may be attached, and its other
+end is flattened, as at C, and secured to the blade
+by two-pointed brads D, clinched on the other
+side.
+
+_Fig. 89. Shape and Size._
+
+The collar E is soldered on the shaft, and in
+practice the shaft is placed through the bearing
+hole at the end of the frame before the hook is
+bent.
+
+SUPPORTING SURFACES.--The supporting surfaces
+may be made perfectly flat, although in this
+particular it would be well to observe the rules
+with respect to the camber of large machines.
+
+
+
+CHAPTER XV
+
+THE AEROPLANE IN THE GREAT WAR
+
+
+DURING the civil war the Federal forces used
+captive balloons for the purpose of discovering
+the positions of the enemy. They were of great
+service at that time, although they were stationed
+far within the lines to prevent hostile guns from
+reaching them.
+
+BALLOON OBSERVATIONS.--Necessarily, observations
+from balloons were and are imperfect. It
+was found to be very unsatisfactory during the
+Russian-Japanese war, because the angle of vision
+is very low, and, furthermore, at such distances the
+movements, or even the location of troops is not
+observable, except under the most favorable conditions.
+
+Balloon observation during the progress of a
+battle is absolutely useless, because the smoke
+from the firing line is, necessarily, between the
+balloon and the enemy, so that the aerial scout
+has no opportunity to make any observations, even
+in detached portions of the fighting zone, which
+are of any value to the commanders.
+
+CHANGED CONDITIONS OF WARFARE.--Since our
+great war, conditions pertaining to guns have been
+revolutionized. Now the ranges are so great that
+captive balloons would have to be located far in
+the rear, and at such a great distance from the
+firing line that even the best field glasses would
+be useless.
+
+The science of war has also evolved another
+condition. Soldiers are no longer exposed during
+artillery attacks. Uniforms are made to imitate
+natural objects. The khaki suits were designed
+to imitate the yellow veldts of South Africa;
+the gray-green garments of the German
+forces are designed to simulate the green fields
+of the north.
+
+THE EFFORT TO CONCEAL COMBATANTS.--The
+French have discarded the historic red trousers,
+and the elimination of lace, white gloves, and
+other telltale insignias of the officers, have been
+dispensed with by special orders.
+
+In the great European war armies have burrowed
+in the earth along battle lines hundreds of
+miles in length; made covered trenches; prepared
+artificial groves to conceal batteries, and in many
+ingenious ways endeavored to make the battlefield
+an imitation field of nature.
+
+SMOKELESS POWDER.--While smokeless powder
+has been utilized to still further hide a fighting
+force, it has, in a measure, uncovered itself, as
+the battlefield is not now, as in olden times, overspread
+with masses of rolling smoke.
+
+Nevertheless, over every battlefield there is a
+haze which can be penetrated only from above,
+hence the possibilities of utilizing the aeroplane
+in war became the most important study with all
+nations, as soon as flying became an accomplished
+fact.
+
+INVENTIONS TO ATTACK AERIAL CRAFT.--Before
+any nation had the opportunity to make an actual
+test on the battlefield, inventors were at work to
+devise a means whereby an aerial foe could be
+met. In a measure the aerial gun has been successful,
+but months of war has shown that the
+aeroplane is one of the strongest arms of the
+service in actual warfare.
+
+It was assumed prior to the European war that
+the chief function of the aeroplane would be the
+dropping of bombs,--that is for service in attacking
+a foe. Actual practice has not justified
+this theory. In some places the appearance of
+the aeroplane has caused terror, but it has been
+found the great value is its scouting advantages.
+
+FUNCTION OF THE AEROPLANE IN WAR.--While
+bomb throwing may in the future be perfected,
+it is not at all an easy problem for an aviator to
+do work which is commensurate with the risk
+involved. The range is generally too great; the
+necessity of swift movement in the machine too
+speedy to assure accuracy, and to attack a foe at
+haphazard points can never be effectual. Even
+the slowly-moving gas fields, like the Zeppelin,
+cannot deliver bombs with any degree of precision
+or accuracy.
+
+BOMB-THROWING TESTS.--It is interesting, however,
+to understand how an aviator knows where
+or when to drop the bomb from a swiftly-moving
+machine. Several things must be taken into consideration,
+such as the height of the machine from
+the earth; its speed, and the parabolic curve that
+the bomb will take on its flight to the earth.
+
+When an object is released from a moving machine
+it will follow the machine from which it is
+dropped, gradually receding from it, as it descends,
+so that the machine is actually beyond
+the place where the bomb strikes the earth, due
+to the retarding motion of the atmosphere against
+the missile.
+
+The diagram Fig. 90 will aid the boy in grasping
+the situation. A is the airship; B the path
+of its flight; a the course of the bomb after it
+leaves the airship; and D the earth. The question
+is how to determine the proper movement
+when to release the bomb.
+
+METHOD FOR DETERMINING MOVEMENT OF A
+BOMB.--Lieut. Scott, U. S. A., of the Coast Survey
+Artillery, suggested a method for determining
+these questions. It was necessary to ascertain,
+first, the altitude and speed. While the barometer
+is used to determine altitudes, it is
+obvious that speed is a matter much more difficult
+to ascertain, owing to the wind movements,
+which in all cases make it difficult for a flier to
+determine, even with instruments which have
+been devised for the purpose.
+
+_Fig. 90. Course of a Bomb._
+
+Instead, therefore, of relying on the barometer,
+the ship is equipped with a telescope which may
+be instantly set at an angle of 45 degrees, or vertically.
+
+Thus, Fig 91 shows a ship A, on which is
+mounted a telescope B, at an angle of 45 degrees.
+The observer first notes the object along the line
+of 45 degrees, and starts the time of this observation
+by a stop watch.
+
+The telescope is then turned so it is vertical,
+as at C, and the observer watches through the
+telescope until the machine passes directly over
+the object, when the watch is stopped, to indicate
+the time between the two observations.
+
+_Fig. 91. Determining Altitude and Speed._
+
+The height of the machine along the line D is
+thus equal to the line E from B to C, and the time
+of the flight from B to a being thus known, as
+well as the height of the machine, the observer
+consults specially-prepared tables which show
+just what kind of a curve the bomb will make at
+that height and speed.
+
+All that is necessary now is to set the sighter
+of the telescope at the angle given in the tables,
+and when the object to be hit appears at the sight,
+the bomb is dropped.
+
+THE GREAT EXTENT OF MODERN BATTLE LINES.--
+The great war brought into the field such stupendous
+masses of men that the battle lines have
+extended over an unbroken front of over 200
+miles.
+
+In the battle of Waterloo, about 140,000 men
+were engaged on both sides, and the battle front
+was less than six miles. There were, thus massed,
+along the front, over 20,000 men every mile of
+the way, or 10,000 on each side.
+
+In the conflict between the Allies and the Germans
+it is estimated that there were less than
+7500 along each mile. It was predicted in the
+earlier stages of the war that it would be an easy
+matter for either side to suddenly mass such an
+overwhelming force at one point as to enable the
+attacking party to go through the opposing force
+like a wedge.
+
+Such tactics were often employed by Napoleon
+and other great masters of war; but in every effort
+where it has been attempted in the present
+conflict, it was foiled.
+
+The opposing force was ready to meet the attack
+with equal or superior numbers. The eye
+of the army, the aeroplane, detected the movements
+in every instance.
+
+THE AEROPLANE DETECTING THE MOVEMENTS OF
+ARMIES.--In the early stages of the war, when
+the Germans drove the left of the French army
+towards Paris, the world expected an investment
+of that city. Suddenly, and for no apparent
+reason, the German right was forced back and
+commenced to retreat.
+
+It was not known until weeks afterwards that
+the French had assembled a large army to the
+west and northwest of Paris, ready to take the
+Germans in flank the moment an attempt should
+be made to encircle the Paris forts.
+
+The German aviators, flying over Paris, discovered
+the hidden army, and it is well they did
+so, for it is certain if they had surrounded the
+outlying forts, it would have been an easy matter
+for the concealed forces to destroy their communications,
+and probably have forced the surrender
+of a large part of the besiegers.
+
+The aeroplane in warfare, therefore, has constantly
+noted every disposition of troops, located
+the positions and judged the destination of convoys;
+the battery emplacements; and the direction
+in which large forces have been moved from
+one part of the line to the other, thus keeping the
+commanders so well informed that few surprises
+were possible.
+
+THE EFFECTIVE HEIGHT FOR SCOUTING.--It has
+been shown that aeroplane scouting is not effective
+at high altitudes. It is not difficult for aviators
+to reach and maintain altitudes of five thousand
+feet and over, but at that elevation it is impossible
+to distinguish anything but the movement
+of large forces.
+
+SIZES OF OBJECTS AT GREAT DISTANCES.--At a
+distance of one mile an automobile, twenty feet
+in length, is about as large as a piece of pencil
+one inch long, viewed at a distance of thirty-five
+feet. A company of one hundred men, which in
+marching order, say four abreast, occupies a space
+of eight by one hundred feet, looks to the aviator
+about as large as an object one inch in length, four
+and a half feet from the eye.
+
+The march of such a body of men, viewed at
+that distance, is so small as almost to be imperceptible
+to the eye of an observer at rest. How
+much more difficult it is to distinguish a movement
+if the observer is in a rapidly-moving machine.
+
+For these reasons observations must be made
+at altitudes of less than a mile, and the hazard
+of these enterprises is, therefore, very great,
+since the successful scout must bring himself
+within range of specially designed guns, which
+are effective at a range of 3000 yards or more,
+knowing that his only hope of safety lies in the
+chance that the rapidly-moving machine will avoid
+the rain of bullets that try to seek him out.
+
+SOME DARING FEATS IN WAR.--It would be impossible
+to recount the many remarkable aerial
+fights which have taken place in the great war.
+Some of them seem to be unreal, so startling are
+the tales that have been told. We may well imagine
+the bravery that will nerve men to fight
+thousands of feet above the earth.
+
+One of the most thrilling combats took place
+between a Russian aeroplane and a Zeppelin, over
+Russian Poland, at the time of the first German
+invasion. The Zeppelin was soaring over the
+Russian position, at an altitude of about a mile.
+A Russian aviator ascended and after circling
+about, so as to gain a position higher than the
+airship, darted down, and crashed into the great
+gas field.
+
+The aviator knew that it meant death to him,
+but his devotion led him to make the sacrifice.
+The Zeppelin, broken in two, and robbed of its
+gas, slowly moved toward the earth, then gradually
+increased the speed of its descent, as the
+aeroplane clung to its shattered hulk, and by the
+time it neared the earth its velocity was great
+enough to assure the destruction of all on board,
+while the ship itself was crushed to atoms.
+
+One of the most spectacular fights of the war
+occurred outside Paris, when one of the German
+Taubes attempted to make its periodical tour
+of observation. One of the French aeroplanes,
+which had the advantage of greater speed,
+mounted to a greater altitude, and circled about
+the Taube.
+
+The latter with its machine gun made a furious
+attack, during these maneuvers, but the French
+ship did not reply until it was at such an elevation
+that it could deliver the attack from above.
+Then its machine gun was brought into play. As
+was afterwards discovered, the wings and body
+of the Taube were completely riddled, and it was
+a marvel how it was possible for the German aviator
+to remain afloat as long as he did.
+
+Soon the Taube was noticed to lurch from side
+to side, and then dart downwardly. The monoplane,
+in the pursuit, gradually descended, but it
+was not able to follow the destroyed Taube to the
+earth, as the latter finally turned over, and went
+swirling to destruction.
+
+The observer, as well as the aviator, had both
+been killed by the fire from the monoplane.
+
+In the trenches on the Marne, to the northeast
+of Paris, where the most stubborn conflict raged
+for over a week, the air was never clear of aeroplanes.
+They could be seen in all directions, and
+almost all types of machines were represented.
+The principal ones, however, were monoplanes.
+
+THE GERMAN TAUBE.--The German Taube is a
+monoplane, its main supporting surfaces, as well
+as the tail planes, are so constructed that they
+represent a bird. Taube means dove. It would
+have been more appropriate to call it a hawk.
+
+On the other hand, the French monoplane, of
+which the Bleriot is the best known example, has
+wings with well rounded extremities, and flaring
+tail, so that the two can be readily distinguished.
+
+On one occasion, during the lull in the battle,
+two of the Taubes approached the area above the
+French lines, and after ascending to a great
+height, began the volplane toward their own lines.
+Such a maneuver was found to be the most advantageous,
+as it gave the scouting aeroplane the
+advantage of being able to discover the positions
+and movements with greater ease, and at the same
+time, in case of accident to the machine, the impetus
+of the flight would be to their own lines.
+
+Three of the French aeroplanes at once began
+their circling flight, mounting higher and higher,
+but without attempting to go near the Taubes.
+When the French ships had gained the proper
+altitude, they closed in toward the German ships,
+before the latter could reach their own lines in
+their volplaning act.
+
+This meant that they must retreat or fight, and
+the crack of the guns showed that it meant a
+struggle. The monoplanes circled about with
+incredible skill, pouring forth shot after shot.
+Soon one of the Taubes was seen to flutter.
+This was the signal for a more concentrated attack
+on her.
+
+The army in the trenches, and on the fields below,
+witnessed the novel combat. The flying
+ships were now approaching the earth, but the
+gunners below dared not use their guns, because
+in the maneuvers they would be as likely to strike
+friend as foe.
+
+The wounded Taube was now shooting to the
+earth, and the two monoplanes began to give their
+attention to the other ship, which was attempting
+to escape to the north. The flash of the guns of
+all the fliers could be plainly seen, but the sounds
+were drowned by the roar of the great conflict all
+about them.
+
+The Taube could not escape the net around her.
+She, too, was doomed. A shot seemed to strike
+the gasoline tank, and the framework was soon
+enveloped in flames. Then she turned sidewise,
+as the material on one side burned away, and
+skidding to the left she darted to the earth,
+a shapeless mass.
+
+It was found that the aviator was not hurt by
+the shot, but was, undoubtedly, killed by the impact
+with the earth. The observer was riddled
+with bullets, and was likely dead before the ship
+reached the earth.
+
+In the western confines of Belgium, near Ypres,
+the British employed numerous aircraft, many of
+them biplanes, and at all times they were in the
+air, reporting observations. Many of the flying
+fights have been recorded, and the reports when
+published will be most thrilling reading.
+
+HOW AEROPLANES REPORT OBSERVATIONS.--It
+may be of some interest to know how aeroplanes
+are able to report observations to the commanders
+in the field, from the airship itself. Many
+ingenious devices have been devised for this purpose.
+
+SIGNAL FLAGS.--The best known and most universally
+used method is by the use of signaling
+flags. Suppose the commander of a force is desirous
+of getting the range of a hidden battery,
+or a massed force in his front. The observer in
+the aeroplane will sail over the area at an understood
+altitude, say one mile in height.
+
+The officer in charge of the battery, knowing
+the height of the airship, is able, by means of
+the angle thus given him, to get the distance between
+his battery and the concealed point beneath
+the airship. The observer in the airship, of
+course, signals the engineer officer, the exact point
+or time when the airship is directly above, and
+this gives him the correct angle.
+
+The guns of the battery are then directed and
+fired so as to reach the concealed point. It is
+now important to be able to send intelligible signals
+to the officer in charge of the battery. If the
+shot goes beyond the mark, the observer in the
+airship raises the flag above his head, which indicates
+that it was too high.
+
+HOW USED.--If the shot fell short he would
+lower the flag. If the shot landed too far to the
+right, this would be indicated by the flag, and if
+too far to the left, the signal would, in like manner,
+be sufficient to enable the gunners to correct
+the guns.
+
+When the exact range is obtained the observer
+in the ship waves the flag about his head, in
+token of approval. All this work of noting the
+effect of the shots must be taken while the airship
+is under fire, and while circling about within
+visual range of the concealed object below.
+
+The officer in charge of the battery, as well as
+the observer on the flying craft, must be equipped
+with powerful glasses, so the effect of the shots
+may be noted on the one hand, and the signals
+properly read by the officer on the other hand.
+
+It may be said, however, that air battles have
+not been frequent and that they have been merely
+incidents of the conditions under which they were
+operated. The mission of the aeroplane is now
+conceded to be purely one of observation, such as
+we have described.
+
+Both French and German reports are full of
+incidents showing the value of observations, and
+also concerning the effects of bombs. Extracts
+from the diaries of prisoners gave many interesting
+features of the results of aeroplane work.
+
+CASUALTIES DUE TO AEROPLANES.--In the diary
+of one was found the remark: "I was lucky to
+escape the bomb thrown by a French aviator at
+Conrobet, which killed eight of my companions."
+
+Another says: "The Seventh Company of the
+Third Regiment of the Guard had eight killed and
+twenty-two wounded by bomb from a French aeroplane."
+
+Another: "An officer showed us a torn coat
+taken from one of sixty soldiers wounded by a
+bomb from an aeroplane."
+
+A prisoner says: "Near Neuville an aeroplane
+bomb dropped on a supply train, killed four men,
+wounded six, and killed a considerable number of
+horses."
+
+The Belgians, after their defeat and the capture
+of Antwerp, were forced to the west along
+the coast. In some way they learned that the
+Kaiser was about to occupy a chateau near Dixmunde.
+Several aviators flew above the position
+and dropped a number of bombs on the building,
+completely wrecking it, and it was fortunate that
+the Emperor left the building only twenty minutes
+before, as several of his aides and soldiers
+on duty were killed.
+
+On numerous occasions the headquarters of the
+different commanders have been discovered and
+had to be moved to safer places.
+
+During all these wonderful exploits which will
+live in history because men had the opportunity
+during the war to use them for the first time in
+actual conflict, the official reports have not
+mentioned the aviators by name. The deaths of the
+brave men have brought forth the acknowledgments
+of their services. During the first three
+months of the war it is estimated that over sixty
+aviators and aides had lost their lives in the conflict
+on the two great battle lines. This does not
+take into account those who met death on the
+Zeppelins, of which five had been destroyed during
+that time.
+
+THE END
+
+
+GLOSSARY OF WORDS USED IN TEXT OF THIS VOLUME
+
+Where a word has various meanings, that definition is given
+which will express the terms used by the author in explaining
+the mechanism or subject to which it refers.
+
+Aviation. The art of flying.
+
+Altitude. Height; a vertical distance above any point.
+
+Attraction. The art or process of drawing towards.
+
+Allusion. Referring to a certain thing.
+
+Assume. Taking it for granted.
+
+Accentuated. To lay great stress upon a thing.
+
+Angle of Movement. Any direction which is upwardly or downwardly,
+as distinguished from the direction of movement which is either
+to the right or to the left.
+
+Acquire. To obtain; to recover; to procure.
+
+Analogous. Corresponding to or resembling some other thing or
+object.
+
+Air Hole. A term used to express a condition in flying where the
+machine while in horizontal flight takes a sudden drop, due to
+counter currents.
+
+Ailerons. Literally, small planes. Used to designate the small
+planes which are designed to stabilize a machine.
+
+Angle. A figure, or two straight lines which start at the same
+point. The sides of these lines are termed the angle.
+
+Analysis. To separate; to take apart and examine the various
+parts or elements of a thing.
+
+Aeroplane. Any form of machine which has planes, and is heavier
+than air. Usually a flying structure which is propelled by some
+motive power.
+
+Accumulation. Adding to; bringing together the same or unlike
+articles.
+
+Ascribable. A reference to some antecedent source.
+
+Aeronautics. The science of flying.
+
+Anterior. Meaning the front or forward margin or portion of a
+body.
+
+Artifices. Any artificial product, or workmanship.
+
+Axially. Through the central portion. Thus, the shaft which goes
+through a cylinder is axially arranged.
+
+Automatic. A thing which operates by its own mechanism; a
+contrivance which is made in such a manner that it will run
+without manual operation or care.
+
+Alertness. Quick; being active.
+
+Apex. The point at which two lines meet; also the extreme pointed
+end of a conical figure.
+
+Ascension. Moving upwardly.
+
+Accessories. The parts of a machine, or artielee which may ha
+used in connection therewith.
+
+Anemometer. An instrument for measuring the force or the velocity
+of wind.
+
+Anemograph. An instrument that usually traces a curved line OH
+paper to make a record of the force or direction, or velocity of
+the wind.
+
+Anemometrograph. A device which determines the force, velocity
+and direction of the wind.
+
+Accretion. Adding to little by little.
+
+Accelerated. Quiekening; hurrying the process.
+
+Abridged. Partly taken away from; shortened.
+
+Abrogate. To dispense with; to set aside.
+
+Abnormal Not in the usual manner; not in a regular way.
+
+Alternate. First one and then another; going from one side to the
+other.
+
+Ancient Lights. An old English law which prevents a neighbor from
+shutting off sunlight.
+
+Angularly. A line which runs out from another so that the two are
+not parallel.
+
+Aneroid. Not wet. Applied to the type of barometer where the
+medium for determ,ining the pressure is not made of mercury.
+
+Aspirate. A term given by the French to that peculiar action of
+wing, or other body, which, when placed in certain positions,
+relative to a current of air, will cause it to be drawn into the
+current.
+
+Assemblage. The bringing together of the parts or elements of a
+machine.
+
+Augment. To aid; to add to or increase.
+
+Banked. The term used in aviation which indicates that the
+machine is turned up so that its supporting surfaces
+rest against the air, as in alighting.
+
+Barometer. An instrument for determining the air pressure, and
+thereby indicating altitudes.
+
+Bevel Pinion. A toothed wheel driven by a larger wheel.
+
+Bi-Plane. Two planes. In aviation that type which has two planes,
+similar in size, usually, and generally placed one above the
+other so they are separated the same distance from each other, as
+the width of each of the planes.
+
+Bulge. A hump; an enlargement beyond the normal at any point.
+
+Camber, also Cambre. The upward curve in a plane.
+
+Catapult. A piece of mechanism for projecting or throwing a
+missile.
+
+Carbureter. The device which breaks up the fuel oil, and mixes
+the proper quantity of air with it before it is drawn into the
+engine.
+
+Catastrophe. A calamity; a sad ending; loss of life or of
+property.
+
+Cellular. Made up of small hollows, or compartments; filled with
+holes.
+
+Celestial. Pertaining to the heavens.
+
+Centrifugal. That force which throws outwardly from a rotating
+body.
+
+Centripetal. That force, like the attraction of gravity, which
+draws a body to the center.
+
+Characteristic. Striking; that which is peculiar to some thing or
+object.
+
+Commensurate. Sufficient; in proper proportion; sufficient for
+the occasion.
+
+Commercially. Pertaining to the nature of trade; the making of
+money.
+
+Complicated. Not easily explainable; not easy to separate.
+
+Comparatively. Judged by something else; taken with reference to
+another object or thing.
+
+Compression. The drawing together; forcing into a smaller
+compass, or space.
+
+Composition. Made up of different elements, or things.
+
+Conceivable. Made up from the imagination.
+
+Concaved. Hollowed: In aviation it has reference to the underside
+of the plane, which is usually provided, structurally, with a
+hollow or trough formation.
+
+Conforming. To make alike in form; to bring into harmony.
+
+Conjunction. In eonneetion with; joining together.
+
+Convex. A rounded surface; a bulging out.
+
+Conclusion. The end; a finding in law; a reasoning from a certain
+condition.
+
+Conductivity. The property of materials whereby they will
+transmit heat along from one part to another, also electricity.
+
+Concentrated. Brought together; assembled in a smaller space.
+
+Conclusive. A positive ending; decisive of the matter at issue.
+
+Concentrically. A line which is at all points at the same
+distance from one point.
+
+Condensation. The act or process of making denser, or being
+brought together.
+
+Contemplate. To consider; to judge.
+
+Convoys. A protecting force which aeeompanies the transfer of
+property.
+
+Convection. The diffusion of heat through a liquid or gas.
+
+Consistent. A state of harmony; the same at &11 times.
+
+Constant. In mathematics, a figure which never changes; or a
+figure used as a fixed valuation in a problem.
+
+Controllable. Held within bounds; that which can be within the
+power to accomplish.
+
+Correctional. The means whereby a fault may be made right.
+
+Consequence. The result; that which flows from a preceding
+action.
+
+Counterforce. An action contrary or opposite to the main force.
+
+Counter-balance. Any power equally opposing another.
+
+Counteract. A force acting in opposition to another.
+
+Countercurrent. An air current which sets up in an opposite
+direction in the path of a moving aeroplane.
+
+Cushioned. An action which takes place against a moving
+aeroplane, by a sudden gust of air or countercurrent.
+
+Dedicated. To set apart for some special purpose.
+
+Degree. An interval; a grade; a stage; a certain proportion.
+
+Deltoid. Shaped like the Greek letter delta.
+
+Density. Closeness of parts.
+
+Demonstration. Making clear; showing up; an exhibition or
+expression.
+
+Deceptive. The power or tendency to give a false impression.
+
+Deterrent. To hold back; to prevent action.
+
+Detracting. The tendency to take away; to belittle.
+
+Depressed. To move downwardly.
+
+Destination. The place set for the end of the journey.
+
+Despoiling. To take away from; robbing or taking from another
+ by force or by stealth.
+
+Dependant. Hanging below; projecting from the lower side.
+
+Dexterity. Agility; smartness in action.
+
+Deranged. Put out of order; wrongly arranged.
+
+Develop. Brought out; to put into a correct shape or form.
+
+Deferred. Put over to another time.
+
+Designedly. With a direct purpose.
+
+Diagonal. Across an object at an angle to one or more aides.
+
+Diametrically. Across an object through or near the center
+thereof.
+
+Diagram. A mechanical plan or outline of an object.
+
+Dimension. The distance across an object. The measurement, for
+instance, of a propeller from tip to tip.
+
+Dynamically. Pertaining to motion as a result of force.
+
+Dispossessed. A term used to indicate the act which removes a
+person from the possession of property.
+
+Diameter. The measurement across an object.
+
+Divest. Taken away from; removed out of.
+
+Disregard. Deliberate lack of attention.
+
+Diversity. The state wherein one is unlike another;
+dissimilarity.
+
+Drift. The term used to indicate the horizontal motion, or the
+pull of an aeroplane.
+
+Dragon. A fabulous monster, usually in the form of a serpent.
+
+Duplicate. Two; made in exact imitation of an original.
+
+Easement. A legal phrase to designate that right which man
+possesses, irrespective of any law, to gain access to his
+property.
+
+Effrontery. Boldness with insolence; rashness without propriety.
+
+Effective. To be efficient.
+
+Element. One part of a whole.
+
+Elasticity. Material which will go back to its original form
+after being distorted, is said to be elastic.
+
+Eliminate. To take away from; to remove a part, or the whole.
+
+Elliptical. Oblong with rounded ends.
+
+Elusive. Capable of escaping from; hard to hold.
+
+Elevator. The horizontal planes in front or rear, or in both
+front and rear of the supporting surfaces of an aeroplane.
+
+Emergency. A sudden occurrence calling for immediate action.
+
+Emplacement. A spot designed to hold heavy field pieces in
+intrenchments.
+
+Enactment. The formulation of a law; the doing of a special
+thing.
+
+Enunciated. Announced; setting forth of an act or a condition.
+
+Energy. That quality by reason of which anything tends to move or
+act.
+
+Equidistant. Two points or objects at equal distance from a
+common point.
+
+Equilibrinm. A balance produced by the action of two or more
+forces.
+
+Equalizing, One made equal to the other; one side the same as the
+other.
+
+Equipped. Armed; provided with the proper material, or in the
+same condition.
+
+Essential. The important part or element.
+
+Essence The real charaeter or element of the thing itself.
+
+External. The outermost portion.
+
+Evolution. A gradual change or building up; from a lower to a
+higher order.
+
+Evolved. Brought out from a crude condition to a better form.
+
+Expression. The art of explaining or setting forth.
+
+Expansion. Growing larger; to occupy a greater space.
+
+Exerted. To work to the utmost; to put forth in action.
+
+Exhilaratiorn. A lively, pleasing or happy sensation.
+
+Exploited. To fully examine and consider, as well as carry out.
+
+Extremity. The end; as far as ean be considered.
+
+Facility. Ease of management; to do things without difficulty.
+
+Factor. One of the elements in a problem, or in mechanical
+action.
+
+Fascination, Attraetiveness that is pleasing.
+
+Flexure. The capacity to bend and yield, and return to its
+original position.
+
+Flexible, That which will yield; springy.
+
+Fore and Aft. Lengthwise, as from stem to stern of a ship.
+
+Formation. The shape or arrangement of an article or thing.
+
+Formulated. Put into some eonerete form, or so arranged that it
+may be understood.
+
+Frictionless. Being without a grinding or retarding aotion.
+
+Fulcrumed. A resting place for a lever.
+
+Function. The duty or sphere of action in a person, or object.
+
+Glider. An aeroplane, without power, adapted to be operated
+by an aviator.
+
+Governing. An element which is designed to control a machine in a
+regular manner.
+
+Graduated. A marked portion, which is regularly laid off to
+indicate measurements or quantities.
+
+Gravity. The attraction of mass for mass. The tendency of bodies
+to move toward the earth.
+
+Gravitatior The force with which all bodies attract each other.
+
+Gyratory. Having a circular and wheeling as well as a rotary
+motion.
+
+Gyroscope. A wheel, designed to illustrate the laws of motion,
+which freely revolves in gimbals within a ring, and when set into
+motion, objects to change its plane of rotation.
+
+Hemispherical. The half of a sphere. The half of an apple would
+be hemispherical.
+
+Hazardous. That which is doubtful; accompanied by danger.
+
+Helicopter. A type of flying machine which has a large propeller,
+or more than one, revolubly fixed on vertical shafts, by means of
+which the machine is launched and projected through the air.
+
+Horizontal. Level, like water.
+
+Hydroplane. A term used to designate an aeroplane which is
+provided with pontoons, whereby it may alight on the water, and
+be launched from the surface. The term hydroaeroplane is most
+generally used to indicate this type of machine.
+
+Impact. The striking against; the striking force of one body
+against another.
+
+Immersed. Placed under water below the surface.
+
+Impinge. To strike against; usually applied where air strikes
+a plane or a surface at an angle.
+
+Imitation. Similarity; the same in appearance.
+
+Incompatible. Without harmony; incapable of existing together.
+
+Incurved. Applied to a surface formation where there is a
+depression, or hollow.
+
+Inequalities. Not smooth, or regular; uneven.
+
+Infinitely, Boundless; in great number, or quality; without
+measure.
+
+Initial. The first; that which is at the beginning.
+
+Indestructibility. Not capable of being injured or destroyed.
+
+Influenced. Swayed; to be induced to change.
+
+Inherent. That which is in or belongs to itself.
+
+Initiating. To teach; to instill; to give an insight.
+
+Indicator. A term applied to mechanism which shows the results of
+certain operations and enables the user to read the measure,
+quantity, or quality shown.
+
+Inconceivable. Not capable of understanding; that which cannot be
+understood by the human mind.
+
+Institute. To start; to bring into operation.
+
+Insignias. Things which are significant of any particular calling
+or profession.
+
+Instinct. That quality in man or animals which prompts the doing
+of things independently of any direct knowledge or understanding.
+
+Intermediate. Between; that which may be within or inside the
+scope of the mind, or of certain areas.
+
+Intervening. The time between; also applied to the action of a
+person who may take part in an affair between two or more
+persons.
+
+Interval. A time between.
+
+Investigator. One who undertakes to find out certain things.
+
+Incidence. In physics this is a term to indicate the line which
+falls upon or strikes another at an angle.
+
+Inverted. Upside down.
+
+Invest. To give to another thing something that it lacked before.
+
+Kinetic. Consisting in or depending upon motion.
+
+Laminated. Made up of a plurality of parts. When wooden strips,
+of different or of the same kinds are glued and then laid
+together and put under heavy pressure
+until thoroughly dried, the mass makes a far more rigid structure
+than if cut out of a single piece.
+
+Launchiug. The term applied to the raising, or starting of a
+boat, or of a flying object.
+
+Lateral. In mining this is a term to indicate the drifts or
+tunnels which branch out from the main tunnel. Generally it has
+reference to a transverse position or direction,--that is, at
+right angles to a fore and aft direction.
+
+Lift. The vertical motion, or direction in an airship; thus the
+lift may be the load, or the term used to designate
+what the ship is capable of raising up.
+
+Ligament. The exceedingly strong tendons or muscles of birds and
+animals, usually of firm, compact tissues.
+
+Limitations. Within certain bounds; in a prescribed scope.
+
+Longitudinally. Usually that direction across the longest part.
+
+Majestically. Grand; exalted dignity; the quality which inspires
+reverence or fear.
+
+Manipulate. To handle; to conduct so that it will result in a
+certain way.
+
+Maneuver. A methodical movement or change in troops.
+
+Manually. To perform by hand.
+
+Manifestations. The act of making plain to the eye or to the
+understanding.
+
+Manually-operated. With the hands; a term applied to such
+machines as have the control planes operated by hand.
+
+Maintained. Kept up; to provide for; to sustain.
+
+Material. The substance, or the matter from which an article is
+made; also the important thing, or element.
+
+Mass. In physics it is that which in an article is always the
+same. It differs from weight in the particular that the mass of
+an article is the same, however far it may be from the center of
+the earth, whereas weight changes, and becomes less and less as
+it recedes from the center of the earth.
+
+Margin. The edge; the principal differecee between this word and
+edge, is, that margin has reference also to a border, or narrow
+strip along the edge, as, for instance, the blank spaces at the
+edges of a printed page.
+
+Medievral. Belonging to the Middle Ages.
+
+Mercury. A silver-white liquid metal, usually called quicksilver,
+and rather heavy. It dissolves most metals, and this process is
+called amalgamation.
+
+Militate. In determining a question, to have weight, or to
+influence a decision.
+
+Mobility. Being freely movable; capable of quick change.
+
+Modifieation. A change; making a difference.
+
+Monitor. Advising or reproving. Advising or approving by way of
+caution.
+
+Monstrosities. Anything which is huge, or distorted, or wrong in
+structure.
+
+Monorail. A railway with a single track, designed to be used by a
+bicycle form of carriage, with two wheels, fore and aft of each
+other, and depending for its stability upon gyroscopes, mounted
+on the carriage.
+
+Momentum. That which makes a moving body difficult to stop. It is
+the weight of a moving body, multiplied by its speed.
+
+Monoplane. The literal meaning is one plane. As monoplane
+machines are all provided with a fore and aft body, and each has
+a wing or plane projecting out from each side of this body, it is
+obvious that it has two planes instead of one. The term, however,
+has reference to the fact that it has only one supporting surface
+on the same plane. Biplanes have two supporting surfaces, one
+above the other.
+
+Multiplicity. Frequently confounded with plurality. The latter
+means more than one, whereas multiplicity has reference to a
+great number, or to a great variety.
+
+Muscular. Being strong; well developed.
+
+Negative. The opposite of positive; not decisive.
+
+Neutralize. From the word neuter, which means neither, hence the
+term may be defined as one which is not a part of either, or does
+not take up with either side.
+
+Normal Pressure. Normal means the natural or usual, and when
+applied to air it would have reference to the condition of the
+atmosphere at that particular place. If the pressure could change
+from its usual condition, it would be an abnormal pressure.
+
+Notoriously. Generally known, but not favorably so; the subject
+of general remark; or unfavorably known.
+
+Obscurity. Not well known; in the background; without clear
+vision; hidden from view.
+
+Obliquely. That which differs from a right angle; neither
+ obtuse nor acute; deviating from a line by any angle except a
+right angle.
+
+Obvious. That which is readily observed and understood.
+
+Orthopter. That type of flying machine which depends on flapping
+wings to hold it in space, and to transport it, in imitation of
+the motion of the wings of birds in flying.
+
+Oscillate. Moving to and fro; the piston of a steam engine has an
+oscillating motion.
+
+Outline. Describing a marginal line on a drawing; setting forth
+the principal features of an argument, or the details of a story,
+or the like.
+
+Overlapping. One placed over the other.
+
+Parabolic. A form of curve somewhat similar to an ellipse.
+
+Pedestal. A standard or support; an upright to hold machinery.
+
+Pertinent. Appropriate; pertaining to the subject.
+
+Pectoral. The bone which forms the main rib or support at the
+forward edge of a bird's wing.
+
+Persistent. Keeping at it; determination to proceed.
+
+Perpendicular. At right angles to a surface. This term is
+sometimes wrongly applied in referring to an object, particularly
+to an object which is vertical, meaning up and down. The blade of
+a square is perpendieular to the handle at all times, but the
+blade is vertical only when it points to the center of the earth.
+
+Pernicious. Bad; not having good features or possessing wrong
+attributes.
+
+Pendulum. A bar or body suspended at a point and adapted to swing
+to and fro.
+
+Perpetual. For all time; unending or unlimited time.
+
+Phenomena. Some peculiar happening, or event, or object.
+
+Pitch. In aviation this applies to the angle at which the blades
+of a propeller are cut. If a propeller is turned, and it moves
+forwardly in the exact path made by the angle, for one complete
+turn, the distance traveled by the propeller axially indicates
+the pitch in feet.
+
+Placement. When an object is located at any particular point, so
+that it is operative the location is called the placement.
+
+Plane. A flat surface for supporting a flying machine in the air.
+Plane of movement pertains to the imaginary surface described by
+a moving body. A bicycle wheel, for instance, when moving
+forwardly in a straight line, has a plane of movement which is
+vertical; but when the machine turns in a circle the upper end of
+the wheel is turned inwardly, and the plane of rhovement is at an
+angle.
+
+Pliant. Easily yielding; capable of being bent; liable to be
+put out of shape.
+
+Plurality. See multiplicity. More than one.
+
+Poise. Held in suspension; disposed in a particular way.
+
+Pontoon. Applied to a series of boats ranged side by side to
+support a walk laid thereon. In aviation it has reference to a
+float for supporting an aeroplane.
+
+Ponderous. Large; heavy; difficult to handle.
+
+Posterior. The rear end; the opposite of anterior.
+
+Principles. The very nature or essence of a thing; the source or
+cause from which a thing springs.
+
+Proportion. The relation that exists between different parts or
+things.
+
+Propounded. Questioned; stated; to state formally for
+consideration
+
+Proprietary. A right; the ownership of certain property.
+
+Primitive. The beginning or early times; long ago.
+
+Prelude. A statement or action which precedes the main feature
+to be presented.
+
+Proximity. Close to; near at hand.
+
+Prototype. That which is used as the sample from, which something
+is made or judged.
+
+Propeller. The piece of meebanism, with screw shaped blade,
+designed to be rapidly rotated in order to drive a vessel
+forwardly. It is claimed by some that the word Impeller would be
+the more proper term.
+
+Primarily. At the first; the commencement.
+
+Precedes. Goes ahead; forward of all.
+
+Propulsive. The force which gives motion to an object.
+
+Projected. Thrown forward; caused to fly through the air.
+
+Radially. Out from the center; projecting like the spokes of a
+wheel.
+
+Ratio. The relation of degree, number, amount; one with another.
+
+Reaction. A counterforce; acting against.
+
+Recognize. To know; seeing, hearing, or feeling, and having
+knowledge therefrom.
+
+Reflection. Considering; judging one thing by the examination of
+another. A beam of light, or an object, leaving a surface.
+
+Refraction. That peculiarity in a beam of light, which, in
+passing through water at an angle, bends out of its course and
+again assumes a direct line after passing through.
+
+Reflex. Turned back on itself, or in the direction from which it
+came.
+
+Requisite. Enough; suffieient for all purposes.
+
+Relegate. To put back or away.
+
+Rectangular. Having one or more right angles.
+
+Reservations. Land which is held by the Government for various
+purposes.
+
+Resistance. That which holds back; preventing movement.
+
+Retarding. Preventing a free movement.
+
+Revoluble. The turning or swinging motion of a body like the
+earth in its movement around the sun. See Rotative. To cause to
+move as in an orbit or circle.
+
+Resilient. Springy; having the quality of elasticity.
+
+Reversed. Changed about; turned front side to the rear.
+
+Rotative. That which turns, like a shaft. The movement of the
+earth on its axis is rotative.
+
+Saturation. Putting one substance into another until it will hold
+no more. For instance, adding salt to water until the water
+cannot take up any more.
+
+Security. Safety, assuredness that there will be no danger.
+
+Segment. A part eut off from a circle. Distinguished from a
+sector, which might be likened to the form of one of the sections
+of an orange.
+
+Sexagonal. Six-sided.
+
+Sine of the Angle. The line dropped from the highest point of an
+ angle to the line which runs out horizontally.
+
+Sinuous. Wavelike; moving up and down like the waves of the
+ocean.
+
+Simulates. To pattern or copy after; the making of the like.
+
+Skipper. A thin flat stone.
+
+Spirally-formed. Made like an auger; twisted.
+
+Stability. In airships that quality which holds the ship on an
+even and unswerving course, and prevents plunging and side
+motions.
+
+Structural. Belonging to the features of eonstruetion.
+
+Strata. Two or more layers; one over or below the other.
+
+Stream line. In expressing the action of moving air, or an
+aeroplane transported through air, every part is acted upon by
+the air. Stream lines are imaginary lines which act upon the
+planes at all points, and all in the same direction, or angle.
+
+Stupendous. Great; important; above the ordinary.
+
+Substitute. One taken for another; replacing one thing by
+something else.
+
+Supporting. Giving aid; helping another.
+
+Synchronous. Acting at the same time, and to the same extent.
+Thus if two wheels, separated from each other at great distances,
+are so arranged that they turn at exactly the same speed, they
+are said to turn synchronously.
+
+Tactics. The art of handling troops in the presence of an enemy.
+It differs from strategy in the particular that the latter word
+is used to explain the movements or arrangement of forces before
+they arrive at the battle line.
+
+Tandem. One before the other; one after the other.
+
+Tangent. A line drawn from a circle at an angle, instead of
+radially.
+
+Technically. Pertaining to some particular trade, science or art.
+
+Tenuous. Thin, slender, willowy, slight.
+
+Tetrahedral. This has reference to a form which is made up of a
+multiplicity of triangularly shaped thin blades, so as to form
+numerous cells, and thus make a large number of supporting
+surfaces. Used as a kite.
+
+Theories. Views based upon certain consideration.
+
+Theoretical. Where opinions are founded on certain information,
+and expressed, not from the standpoint of actual knowledge, but
+upon conclusions derived from such examinations.
+
+Torsion. A twist; a circular motion around a body.
+
+Transmitted. Sent out; conveyed from one point to another.
+
+Transformed. Changed; entirely made over from one thing to
+another.
+
+Transverse. When a body is shorter from front to rear than from
+side to side its longest dimension is transversely.
+Distinguish from lateral, which has reference only to the
+distance at right angles from the main body.
+
+Translation. The transportation of a body through the air.
+
+Trajectory. The path made by a body projected through the air.
+
+Triangular. A form or body having three sides and three angles.
+
+Typical. In the form of; a likeness to.
+
+Ultimate. The end; the finality; the last that can be said.
+
+Uninitiated. Not having full knowledge; withont information.
+
+Unique. Peculiar; something that on account of its peculiar
+construction or arrangements stands out beyond the others.
+
+Universal. Everywhere; all over the world.
+
+Undulate. To move up and down; a wave-like motion.
+
+Utility. Of use; to take advantageous use of.
+
+Unstable. Not having anything permanent; in a ship in flight one
+that will not ride on an even keel, and is liable to pitch about.
+
+Vacuum. Where air is partly taken away, or rendered rarer.
+
+Valved. A surface which has a multiplicity of openings with
+valves therein, or, through which air can move in one direction.
+
+Vaunted. To boast concerning; to give a high opinion.
+
+Velocity. Speed; the rate at which an object can move from place
+to place.
+
+Vertical. A line running directly to the center of the earth; a
+line at right angles to the surface of water.
+
+Vibratory. Moving from side to side; a regular motion.
+
+Volplane. The glide of a machine without the use of power.
+
+Warping. The twist given to certain portions of planes, so as to
+cause the air to aet against the warped portions.
+
+Weight. The measure of the force which gravity exerts on all
+objects.
+
+
+
+
+
+End of The Project Gutenberg Etext of Aeroplanes, by J. S. Zerbe
+
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+Project Gutenberg (https://www.gutenberg.org) public repository for
+eBook #1445 (https://www.gutenberg.org/ebooks/1445)