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Story of the Aeroplane

C. B. Galbreath, M. A.

PUBLISHED JOINTLY BY

F. A. OWEN PUB. CO., Dansville, N. Y.

and

HALL & McCREARY, Chicago, Ill.

Table of Contents

The Ocean of Air Early Attempts at Aviation Early Flying Machines Nineteenth Century Experiments Claims of Maxim and Ader Langley's Tandem Monoplane Experiments with Gliders Aviation at the Beginning of the Present Century The Kite The "Plane" Defined Essentials of the Aeroplane The Wright Brothers and Their Problem Balancing the Machine At Kitty Hawk The First Flight Machine Balanced by Warping of Planes Newspaper Reports Verified Trial Flights at Fort Meyer Fatal Accident Wilbur Wright Wins Fame in France Wright Brothers Honored United States Government Requirements Successfully Met Recent Improvements Future of the Aeroplane

The Ocean of Air

Around the dry land of the earth are the oceans of water. We may never have seen them, but we have knowledge of them and their navigation, and their names suggest very definite and concrete objects of thought. We sometimes do not realize, however, that we live and move and have our being at the bottom of a vaster and deeper ocean that covers to a depth of many miles the whole earth, and to the surface of which man nor beast nor bird has ever ascended; an ocean with currents and whirlpools and waves of more than mountain height; an ocean in which we are as much at home as are the finny tribes and the monsters of the deep in their watery caverns. This is the ocean of the air. We are about to consider man's efforts to rise from the bottom of this ocean and wing his flight a little way through the atmosphere above him. His excursions upward are limited, for he could not live near the surface heights of this ocean, vast and deep and boundless. The art and science of his flight through the air, because of its relation to the flight of birds, we call aviation.

Early Attempts at Aviation

"The birds can fly and why can't I?"

This query of Darius Green's, in various forms, has suggested itself to man since the dawn of history. Born with an inspiration to look upward and aspire, the navigation of the air has appealed with peculiar force to his imagination and through the centuries has at different times led bold and adventurous spirits to attempt what the world long regarded as impossible. The heavens seemed reserved for winged insects, birds and angels. Audacious man might not venture out upon the impalpable air. Can man fly? After more than four thousand years it was left for man to answer yes, to rise from the earth on wing and thrill the world "with the audacity of his design and the miracle of its execution." Bold enterprise! Fitting achievement to usher in a new century! A seeming miracle at first, but destined soon to excite no more curiosity than the flight of bees and birds. The solution of the problem of human flight was no miracle nor was it the swift work of genius accomplished at a magic master stroke. It was the result of intelligence and industry patiently applied for years till the barriers of difficulty gave way and man ventured out with assurance on the highways of the air.

Just when he first attempted to fly is not known. Ancient Greek mythology abounds in stories of flying gods and mortals. Kites which bear some relation to the aeroplane were toys among the Chinese thousands of years ago. A Greek by the name of Achytes is reported to have made a wooden dove which flew under the propelling power of heated air. Baldad, a tribal king in what is now England, so tradition has it, attempted to fly over a city but fell and broke a leg. A similar accident is said to have happened to a Benedictine monk in the eleventh century and to others attempting like exploits in after years. A fall and a broken leg seem to have been the usual results of these early attempts at aerial flight.

In 1742 the Marquis di Bacqueville at the age of sixty-two attempted to make a gliding flight from the tower of his home in Paris across the river Seine to the gardens of the Tuileries, started successfully in the presence of a great multitude, but suddenly halted over the river and fell into a boat, paying the historic penalty of a broken leg.

At this point it may be well to classify the flying devices thus far considered.

Early Flying Machines

Nineteenth Century Experiments

In the early part of the last century an Englishman, Sir George Cayley, made many experiments with gliders and tabulated with great care the results of his investigations. He concluded, like Swedenborg, that man has not the power to fly by his own strength through any wing-flapping device, or orthopter, but he intimated that with a lighter and more powerful engine than had then been invented a plane like those used in his gliders, if slightly inclined upward, might be made gradually to ascend through the air. The results of his experiments he published in 1810. They clearly foreshadowed the triumph that came almost a century later.

In 1844 two British inventors, Henson and String-fellow, working out the suggestions of Cayley, made an aeroplane model equipped with a steam engine which is said to have made a flight of forty yards--the first real upward flight of a heavier than air machine on record. This model was a monoplane, that is, the lifting surface was a single plane like the outstretched wings of a bird. Twenty-two years later experiments were made with a biplane, that is, an aeroplane with two lifting planes or surfaces, one above the other.

Claims of Maxim and Ader

While others had made flying models, Sir Hiram Maxim in England constructed a multiplane, driven by a powerful steam engine over a track and rising at one time, as he declares, a few inches from the ground. He claims that his was the first machine to "lift man off the ground by its own power." This test was made in 1889.

Clement Ader, a Frenchman, also claims this honor, saying that he was the first to make a machine that would rise and lift a passenger. On October 9, 1890, his friends say he made a short forward flight of 150 feet in a monoplane propelled by a forty horse power steam engine. In 1897 he claims to have made a number of secret flights, but a little later, in a test before officers of the French army who had become interested in the invention, the machine turned over and was wrecked. The support of the army for further experiments was withdrawn and Ader in despair abandoned the problem of aerial navigation which had claimed long years of study and unremitting effort. He stopped just short of the goal "with success almost within his grasp."

Langley's Tandem Monoplane

About this time two Americans, Samuel Pierpont Langley, of the Smithsonian Institution and Octave Chanute were conducting along scientific lines a series of experiments in aviation. On May 6, 1896, a steam-propelled model was started in a flight over the Potomac River. Dr. Alexander Graham Bell, the inventor of the telephone, who was present, declared that after a flight of eighty to one hundred feet the machine "settled down so softly that it touched the water without the least shock and was in fact immediately ready for a second trial." Other experiments were tried with success.

Langley's first machine was a tandem monoplane, that is it had two pairs of wings, one immediately following the other. The engine and the propellers were between the two pairs of wings. In later models he used the biplane construction.

Langley's machine had flown without a pilot. A little later the inventor announced himself ready for the final test. Like his first model, his machine was a tandem monoplane. Its weight with pilot was 830 pounds and its plane or wing surface was 1040 square feet. It was fifty-two feet long and its arched wings measured forty-eight feet from tip to tip. The gasoline motor with which it was equipped developed fifty-two horse power and with all accessories weighed about 250 pounds.

At Widewater, Virginia, September 7, 1903, the machine was tested. On a barge it was carried out into the Potomac River, with Charles M. Manley, Professor Langley's assistant, who was to pilot it in its first flight. The moment for the supreme test arrived. A mechanical device on the barge shot the machine and pilot into the air. To the disappointment and dismay of the spectators, the machine plunged front downward into the water. It was rescued with the young pilot unharmed. Another attempt was made to launch it in the air with a similar result, except that this time it dropped into the water rear end downward. The government gave the project no further encouragement, and the query ascribed to Darius Green remained unanswered. Professor Langley died a few years afterward, his life shortened, it is believed, through the blighting of the hope that he had long entertained to be the first successfully to navigate the air.

Experiments with Gliders

Through the latter part of the last century experiments were carried on with gliders. Among those who achieved much success in this field was the German, Otto Lilienthal, the "flying man," who made remarkable glides in the early nineties. He would run along the crest of a hill, jump from a precipitous declivity and sail on the wings of his glider over the valley below, guiding his course up and down and from side to side with a rudder attached to the machine. It was his idea that the problem of aviation was to be solved by perfecting the glider so that it could be controlled in its downward flight and then adding a propelling power that would sustain it and lift it through the air.

After the death of Lilienthal by accident in 1896, others continued experiments along similar lines with the same purpose in view. Among these were Octave Chanute and A. M. Herring. They tried at first a monoplane glider and afterward one of five planes. This number they reduced to two. The rudder was made of movable horizontal and vertical blades. It was found that the glider with two planes, the biplane, was most satisfactory.

Herring made for this a compressed air engine and claimed that with this he accomplished a flight of seventy-three feet. There is some doubt, however, as to this claim and some question as to whether it was an upward flight or a downward glide.

Aviation at the Beginning of the Present Century

As briefly outlined here, such was the status of aviation at the beginning of the new century. Much progress had been made and substantial vantage ground had been gained, but the problem still awaited practical solution. At this point it may be well to consider some of the features of the problem and the devices thus far evolved by long years of investigation and experiment.

The Kite

One of the simplest forms of the aeroplane is the common kite. This takes various forms. It is usually made of a framework of three light strips of wood crossing a little above the center and secured at the outer ends by similar strips, or strong cord tautly drawn and making when covered with paper a six-sided figure. From the corners of the framework cords are drawn to a common point near the center and there firmly united. At this point of union is attached the twine which is held in the hand of the kite flyer. From the base of the kite is suspended a string with light horizontal paper rolls, each about the size of a lead pencil, tied at intervals of a few inches, and forming the tail which steadies the kite in air. The paper surface of the kite is the plane on which the pressure of the air current and the power applied to the string is to lift the kite upward. As this simple form of the kite has but one plane, it may be considered a monoplane. The box kite presents two such surfaces joined together at the sides by the ends of the "box," and may therefore be called a biplane.

When the boy flies his kite he first determines the direction of the wind and runs in that direction. In other words he flies his kite against the wind. The pressure of the moving current against the under surface keeps the kite aloft. When the boy runs against the wind, moving the kite forward with him, this pressure is increased and the kite tends to rise higher and higher. If instead of the long string and the boy there could be placed with the kite itself a very light motor that would give to it the same forward impulse, the kite would float through the air without boy or string and we would have a small aeroplane flying machine--a monoplane. If there were two kites, with parallel surfaces a few inches apart, united with light framework so that the air would pass between them, we should have a biplane. For many years the great problem in aviation was to get an engine of sufficient lightness and power to propel monoplanes, biplanes and multiplanes at an upward angle through the air.

The "Plane" Defined

It may not be out of place here to consider what Constitutes a plane, as that term is used in aviation. It is that part of the aeroplane, the pressure of the air upon the surface of which, lifts and sustains the aeroplane aloft. The plane may take a variety of forms; it may be curved or its parts may meet in an angle; it may be uniform and unbroken in shape or divided into parts. The two wings of a bird would constitute a monoplane, when they are in a horizontal position for soaring, or when the tips are uplifted and they form an angle like a broad V, called a dihedral angle. If the aeroplane has two such planes, one back of the other, it is still called a monoplane, or, more definitely, a tandem monoplane; but if one of the planes is above the other it is called a biplane. A similar arrangement of three planes, one above the other, could be called a triplane and one of several planes a multiplane.

Essentials of the Aeroplane

The Wright Brothers and Their Problem

The dawn of the twentieth century was to immortalize new names in the annals of aviation. In the city of Dayton, Ohio, two brothers in a modest way were conducting a bicycle repair shop. From youth they had been inseparable in their aims and work. They were the sons of Bishop Milton Wright of the United Brethren Church. They had each a high school education but had not attended college. In 1878, when they were boys of seven and eleven years respectively, their father brought them one evening a little flying toy, a small helicopter, the motive power of which was furnished by a rubber band wound around the shafts of two propellers so as to drive them, when "wound up" and released, in opposite directions. The toy was made of light material to resemble a bird. When the father released it in the presence of the wondering boys, to their astonishment it flew upward in the room, rose to the ceiling and after fluttering there for a little while fell to the floor. They did not concern themselves much about the name of the toy, but properly called it what to their minds it most closely resembled--"the bat." They afterward made other toys like it and discovered that as they were increased in size they flew less successfully. They early developed a fondness for kite flying and in this were regarded as experts. When they grew to manhood, however, they abandoned these boyish sports and devoted themselves industriously to their machine and repair shop. "The bat" and the kite became memories, but the memories of youth have power to shape the thoughts of manhood, and this early observation and experience with aerial toys gave to Wilbur and Orville Wright an interest in the attempts at aviation that were chronicled in the press from time to time through the decade immediately preceding this new century.

In the year 1896 Orville, the younger of the two brothers, was convalescing from a serious attack of typhoid fever. Wilbur, who had been carefully attending him, was one day reading aloud an account of the death of Otto Lilienthal, the German aviator, who was killed while experimenting with his glider. The details of the tragic accident, together with an account of what he had accomplished by years of investigation and experiment, interested the brothers, who resolved as soon as possible to apply themselves to the construction of a glider in which flights could be made with comparative safety. The enthusiasm of Orville over the project ran so high that it almost caused a return of the fever. As soon as he had fully recovered, the two brothers returned to their bicycle shop and applied themselves with increasing zeal to the study of aeronautics, and after a time began the construction of a glider.

The Wright brothers were peculiarly well equipped for the work upon which they had entered. They were men of unflagging industry, abstemious habits, few words and the happy faculty of keeping their own counsel. Wilbur was unusually reticent. It is said of him that he spoke only when he had something to say and then in a manner singularly brief and direct. "He had an unlimited capacity for hard work, nerves of steel and the kind of daring that makes the aviator face death with pleasure every minute of the time he is in the air." Orville, while much like his brother, is more talkative and approachable. Both were modest and unassuming when they began their work and continued so when the world applauded their achievements.

In the study of the problem upon the solution of which they ventured, they had of course the advantage of all that had thus far been achieved by those who had preceded them in this field of investigation and experiment. Professor Langley had already perfected his first monoplane to such an extent that short flights were successfully made with a light steam-propelled model. He was continuing his experiments and the Wright brothers read with avidity the results of his work. Every scrap of information that they could gather from others who had essayed the solution of the problem was now collected and made the subject of critical study. At first taking up aeronautics merely as a sport, they soon afterward with zest began its more serious pursuit. "We reluctantly entered upon the scientific side of it." they said, "but we soon found the work so fascinating that we were drawn into it deeper and deeper."

In their efforts to construct a practical flying machine they adopted the plan of Lilienthal and Chanute. They sought to construct a machine which they could control and in which they could make glides with safety. This they built in the form of a biplane glider and with it they experimented industriously for years. The successful construction of the machine required a high degree of skill. The length and width of the planes, their distance apart, the materials to be used, the shape, size and position of the rudder and numerous other details were to be worked out only by patient study and frequent tests. They were now in the field of original experiment and soon found that they had to reject as useless many theories that had been carefully elaborated by scholarly writers.

The brothers soon learned that a long narrow plane in a position nearly horizontal, moved in a direction at right angles to one of its lateral edges and inclined or "tipped" slightly upward would develop greater lifting power than a square or circular plane. This discovery was not indeed original with them, but their experiments confirmed the conclusions of their predecessors.

The surface shape of the plane is an important consideration. It has been found that a slight upward arch from beneath, making the under surface concave, gives the best results. The concavity should reach its maximum about one-third of the distance from the front or entering edge to the rear edge of the plane and should be the same whether one or more planes are used. In flight the forward or entering edges of the planes are tipped slightly upward to give the machine lifting power for the same reason that the top of a kite is given an angle of elevation so that the air will lift it as it is drawn forward by the string.

Balancing the Machine

The balancing of a machine in mid-air is one of the most difficult problems in aviation. In the balloon this is easily accomplished because the principal weight, the basket with the passenger, is below the gas-filled sphere or compartment, and the balloon tends to right itself after any disturbance by the wind, much like a plummet when swayed out of its position.

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