<h2><span class="pagenum"><SPAN name="Page_9" id="Page_9"></SPAN></span> <SPAN name="how" id="how"></SPAN>How We Made the First Flight</h2>
<p class="center"><em>By Orville Wright</em></p>
<p class="cap">THE flights of the 1902 glider had demonstrated the efficiency of our
system of maintaining equilibrium, and also the accuracy of the
laboratory work upon which the design of the glider was based. We then
felt that we were prepared to calculate in advance the performance of
machines with a degree of accuracy that had never been possible with the
data and tables possessed by our predecessors. Before leaving camp in
1902 we were already at work on the general design of a new machine
which we proposed to propel with a motor.</p>
<p>Immediately upon our return to Dayton, we wrote to a number of
automobile and motor builders, stating the purpose for which we desired
a motor, and asking whether they could furnish one that would develop
eight brake-horsepower, with a weight complete not exceeding 200 pounds.
Most of the companies answered that they were too busy with their
regular business to undertake the building of such a motor for us; but
one company replied that they had motors rated at 8 horse-power,
according to the French system of ratings, which weighed only 135
pounds, and that if we thought this motor would develop enough power for
our purpose they would be glad to sell us one. After an examination of
the particulars of this motor, from which we learned that it had but a
single cylinder of 4-inch bore and 5-inch stroke, we were afraid it was
much over-rated. Unless the motor would develop a full 8
brake-horsepower, it would be useless for our purpose.</p>
<p>Finally we decided to undertake the building of the motor ourselves. We
estimated that we could make one of four cylinders with 4-inch bore and
4-inch stroke, weighing not over two hundred pounds, including all
accessories. Our only experience up to that time in the building of
gasoline motors had been in the construction of an air-cooled motor,
5-inch bore and 7-inch stroke, which was used to run the machinery of
our small workshop. To be certain that four cylinders of the size we had
adopted (4″ × 4″) would develop the necessary 8 horse-power, we first
fitted them in a temporary frame of simple and cheap construction. In
just six weeks from the time the design was started, we had the motor on
the block testing its power. The ability to do this so quickly was
largely due to the enthusiastic and efficient services of Mr. C. E.
Taylor, who did all the machine work in our shop for the first as well
as the succeeding experimental machines. There was no provision for
lubricating either cylinders or bearings while this motor was running.
For that reason it was not possible to run it more than a minute or two
at a time. In these short tests the motor developed about nine
horse-power. We were then satisfied that, with proper lubrication and
better adjustments, a little more power could<span class="pagenum"><SPAN name="Page_10" id="Page_10"></SPAN></span> be expected. The
completion of the motor according to drawing was, therefore, proceeded
with at once.</p>
<div class="figcenter"> <ANTIMG src="images/i009b.png" width-obs="400" height-obs="242" alt="" title="" /></div>
<p>While Mr. Taylor was engaged with this work, Wilbur and I were busy in
completing the design of the machine itself. The preliminary tests of
the motor having convinced us that more than 8 horse-power would be
secured, we felt free to add enough weight to build a more substantial
machine than we had originally contemplated.</p>
<hr class="hr4" />
<p>For two reasons we decided to use two propellers. In the first place we
could, by the use of two propellers, secure a reaction against a greater
quantity of air, and at the same time use a larger pitch angle than was
possible with one propeller; and in the second place by having the
propellers turn in opposite directions, the gyroscopic action of one
would neutralize that of the other. The method we adopted of driving the
propellers in opposite directions by means of chains is now too well
known to need description here. We decided to place the motor to one
side of the man, so that in case of a plunge headfirst, the motor could
not fall upon him. In our gliding experiments we had had a number of
experiences in which we had landed upon one wing, but the crushing of
the wing had absorbed the shock, so that we were not uneasy about the
motor in case of a landing of that kind. To provide against the machine
rolling over forward in landing, we designed skids like sled runners,
extending out in front of the main surfaces. Otherwise the general
construction and operation of the machine was to be similar to that of
the 1902 glider.</p>
<p>When the motor was completed and tested, we found that it would develop
16 horse-power for a few seconds, but that the power rapidly dropped
till, at the end of a minute, it was only 12 horse-power. Ignorant of
what a motor of this size ought to develop, we were greatly pleased with
its performance. More experience showed us that we did not get one-half
of the power we should have had.</p>
<p>With 12 horse-power at our command, we considered that we could permit
the weight of the machine with operator to rise to 750 or 800 pounds,
and still have as much surplus power as we had originally allowed for in
the first estimate of 550 pounds.</p>
<p>Before leaving for our camp at Kitty Hawk we tested the chain drive for
the propellers in our shop at Dayton, and found it satisfactory. We
found, however, that our first propeller shafts, which were constructed
of heavy gauge steel tubing, were not strong enough to stand the shocks
received from a gasoline motor with light fly wheel, although they would
have been able to transmit three or four times the power uniformly
applied. We therefore built a new set of shafts of heavier tubing, which
we tested and thought to be abundantly strong.</p>
<p>We left Dayton, September 23, and arrived at our camp at Kill Devil Hill
on Friday, the 25th. We found there provisions and tools, which had been
shipped by freight several weeks in advance. The building, erected in
1901 and enlarged in 1902, was found to have been blown by a storm from
its foundation posts a few months previously. While we were awaiting the
arrival of the shipment of machinery and parts from Dayton, we were busy
putting the old building in repair, and erecting a new building to serve
as a workshop for assembling and housing the new machine.</p>
<p>Just as the building was being completed, the parts and material for the
machines arrived simultaneously with one of the worst storms that had
visited Kitty Hawk in years. The storm came on suddenly, blowing 30 to
40 miles an hour.<span class="pagenum"><SPAN name="Page_11" id="Page_11"></SPAN></span> It increased during the night, and the next day was
blowing over 75 miles an hour. In order to save the tar-paper roof, we
decided it would be necessary to get out in this wind and nail down more
securely certain parts that were especially exposed. When I ascended the
ladder and reached the edge of the roof, the wind caught under my large
coat, blew it up around my head and bound my arms till I was perfectly
helpless. Wilbur came to my assistance and held down my coat while I
tried to drive the nails. But the wind was so strong I could not guide
the hammer and succeeded in striking my fingers as often as the nails.</p>
<p>The next three weeks were spent in setting the motor-machine together.
On days with more favorable winds we gained additional experience in
handling a flyer by gliding with the 1902 machine, which we had found in
pretty fair condition in the old building, where we had left it the year
before.</p>
<p>Mr. Chanute and Dr. Spratt, who had been guests in our camp in 1901 and
1902, spent some time with us, but neither one was able to remain to see
the test of the motor-machine, on account of the delays caused by
trouble which developed in the propeller shafts.</p>
<p>While Mr. Chanute was with us, a good deal of time was spent in
discussion of the mathematical calculations upon which we had based our
machine. He informed us that, in designing machinery, about 20 per cent.
was usually allowed for the loss in the transmission of power. As we had
allowed only 5 per cent., a figure we had arrived at by some crude
measurements of the friction of one of the chains when carrying only a
very light load, we were much alarmed. More than the whole surplus in
power allowed in our calculations would, according to Mr. Chanute’s
estimate, be consumed in friction in the driving chains. After Mr.
Chanute’s departure, we suspended one of the drive chains over a
sprocket, hanging bags of sand on either side of the sprocket of a
weight approximately equal to the pull that would be exerted on the
chains when driving the propellers. By measuring the extra amount of
weight needed on one side to lift the weight on the other, we calculated
the loss in transmission. This indicated that the loss of power from
this source would be only 5 per cent., as we originally estimated. But
while we could see no serious error in this method of determining the
loss, we were very uneasy until we had a chance to run the propellers
with the motor to see whether we could get the estimated number of
turns.</p>
<p>The first run of the motor on the machine developed a flaw in one of the
propeller shafts which had not been discovered in the test at Dayton.
The shafts were sent at once to Dayton for repair, and were not received
again until November 20, having been gone two weeks. We immediately put
them in the machine and made another test. A new trouble developed. The
sprockets which were screwed on the shafts, and locked with nuts of
opposite thread, persisted in coming loose. After many futile attempts
to get them fast, we had to give it up for that day, and went to bed
much discouraged. However, after a night’s rest, we got up the next
morning in better spirits and resolved to try again.</p>
<p>While in the bicycle business we had become well acquainted with the use
of hard tire cement for fastening tires on the rims. We had once used it
successfully in repairing a stop watch after several watchsmiths had
told us it could not be repaired. If tire cement was good for fastening
the hands on a stop watch, why should it not be good for fastening the<span class="pagenum"><SPAN name="Page_12" id="Page_12"></SPAN></span>
sprockets on the propeller shaft of a flying machine? We decided to try
it. We heated the shafts and sprockets, melted cement into the threads,
and screwed them together again. This trouble was over. The sprockets
stayed fast.</p>
<p>Just as the machine was ready for test bad weather set in. It had been
disagreeably cold for several weeks, so cold that we could scarcely work
on the machine for some days. But now we began to have rain and snow,
and a wind of 25 to 30 miles blew for several days from the north. While
we were being delayed by the weather we arranged a mechanism to measure
automatically the duration of a flight from the time the machine started
to move forward to the time it stopped, the distance traveled through
the air in that time, and the number of revolutions made by the motor
and propeller. A stop watch took the time; an anemometer measured the
air traveled through; and a counter took the number of revolutions made
by the propellers. The watch, anemometer and revolution counter were all
automatically started and stopped simultaneously. From data thus
obtained we expected to prove or disprove the accuracy of our propeller
calculations.</p>
<p>On November 28, while giving the motor a run indoors, we thought we
again saw something wrong with one of the propeller shafts. On stopping
the motor we discovered that one of the tubular shafts had cracked!</p>
<div class="figcenter"> <ANTIMG src="images/i012a.png" width-obs="400" height-obs="191" alt="" title="" /></div>
<p>Immediate preparation was made for returning to Dayton to build another
set of shafts. We decided to abandon the use of tubes, as they did not
afford enough spring to take up the shocks of premature or missed
explosions of the motor. Solid tool-steel shafts of smaller diameter
than the tubes previously used were decided upon. These would allow a
certain amount of spring. The tubular shafts were many times stronger
than would have been necessary to transmit the power of our motor if the
strains upon them had been uniform. But the large hollow shafts had no
spring in them to absorb the unequal strains.</p>
<p>Wilbur remained in camp while I went to get the new shafts. I did not
get back to camp again till Friday, the 11th of December. Saturday
afternoon the machine was again ready for trial, but the wind was so
light a start could not have been made from level ground with the run of
only sixty feet permitted by our monorail track. Nor was there enough
time before dark to take the machine to one of the hills, where, by
placing the track on a steep incline, sufficient speed could be secured
for starting in calm air.</p>
<p>Monday, December 14, was a beautiful day, but there was not enough wind
to enable a start to be made from the level ground about camp. We
therefore decided to attempt a flight from the side of the big Kill
Devil Hill. We had arranged with the members of the Kill Devil Hill Life
Saving Station, which was located a little over a mile from our camp, to
inform them when we were ready to make the first trial of the machine.
We were soon joined by J. T. Daniels, Robert Westcott, Thomas Beachem,
W. S. Dough and Uncle Benny O’Neal, of the station, who helped us get
the machine to the hill, a quarter mile away. We laid the track 150 feet
up the side of the hill on a 9-degree slope. With the slope of the
track, the thrust of the propellers and the machine starting directly
into the wind, we did not anticipate any trouble in getting<span class="pagenum"><SPAN name="Page_13" id="Page_13"></SPAN></span> up flying
speed on the 60-foot monorail track. But we did not feel certain the
operator could keep the machine balanced on the track.</p>
<p>When the machine had been fastened with a wire to the track, so that it
could not start until released by the operator, and the motor had been
run to make sure that it was in condition, we tossed up a coin to decide
who should have the first trial. Wilbur won. I took a position at one of
the wings, intending to help balance the machine as it ran down the
track. But when the restraining wire was slipped, the machine started
off so quickly I could stay with it only a few feet. After a 35 to
40-foot run it lifted from the rail. But it was allowed to turn up too
much. It climbed a few feet, stalled, and then settled to the ground
near the foot of the hill, 105 feet below. My stop watch showed that it
had been in the air just 3<span class="frac"><sup>1</sup>/<sub>2</sub></span> seconds. In landing the left wing touched
first. The machine swung around, dug the skids into the sand and broke
one of them. Several other parts were also broken, but the damage to the
machine was not serious. While the test had shown nothing as to whether
the power of the motor was sufficient to keep the machine up, since the
landing was made many feet below the starting point, the experiment had
demonstrated that the method adopted for launching the machine was a
safe and practical one. On the whole, we were much pleased.</p>
<p>Two days were consumed in making repairs, and the machine was not ready
again till late in the afternoon of the 16th. While we had it out on the
track in front of the building, making the final adjustments, a stranger
came along. After looking at the machine a few seconds he inquired what
it was. When we told him it was a flying machine he asked whether we
intended to fly it. We said we did, as soon as we had a suitable wind.
He looked at it several minutes longer and then, wishing to be
courteous, remarked that it looked as if it would fly, if it had a
“suitable wind.” We were much amused, for, no doubt, he had in mind the
recent 75-mile gale when he repeated our words, “a suitable wind!”</p>
<p>During the night of December 16, 1903, a strong cold wind blew from the
north. When we arose on the morning of the 17th, the puddles of water,
which had been standing about camp since the recent rains, were covered
with ice. The wind had a velocity of 10 to 12 meters per second (22 to
27 miles an hour). We thought it would die down before long, and so
remained indoors the early part of the morning. But when ten o’clock
arrived, and the wind was as brisk as ever, we decided that we had
better get the machine out and attempt a flight. We hung out the signal
for the men of the life saving station. We thought that by facing the
flyer into a strong wind, there ought to be no trouble in launching it
from the level ground about camp. We realized the difficulties of flying
in so high a wind, but estimated that the added dangers in flight would
be partly compensated for by the slower speed in landing.</p>
<p>We laid the track on a smooth stretch of ground about one hundred feet
north of the new building. The biting cold wind made work difficult, and
we had to warm up frequently in our living room, where we had a good
fire in an improvised stove made of a large carbide can. By the time all
was ready, J. T. Daniels, W. S. Dough and A. D. Etheridge, members of
the Kill Devil Life Saving Station; W. C. Brinkley, of Manteo, and
Johnny Moore, a boy from Nag’s Head, had arrived.</p>
<p>We had a “Richards” hand anemometer with which we measured the velocity<span class="pagenum"><SPAN name="Page_14" id="Page_14"></SPAN></span>
of the wind. Measurements made just before starting the first flight
showed velocities of 11 to 12 meters per second, or 24 to 27 miles per
hour. Measurements made just before the last flight gave between 9 and
10 meters per second. One made just after showed a little over 8 meters.
The records of the Government Weather Bureau at Kitty Hawk gave the
velocity of the wind between the hours of 10:30 and 12 o’clock, the time
during which the four flights were made, as averaging 27 miles at the
time of the first flight and 24 miles at the time of the last.</p>
<hr class="hr4" />
<p>Wilbur, having used his turn in the unsuccessful attempt on the 14th,
the right to the first trial now belonged to me. After running the motor
a few minutes to heat it up, I released the wire that held the machine
to the track, and the machine started forward into the wind. Wilbur ran
at the side of the machine, holding the wing to balance it on the track.
Unlike the start on the 14th, made in a calm, the machine, facing a
27-mile wind, started very slowly. Wilbur was able to stay with it till
it lifted from the track after a forty-foot run. One of the life saving
men snapped the camera for us, taking a picture just as the machine had
reached the end of the track and had risen to a height of about two
feet. The slow forward speed of the machine over the ground is clearly
shown in the picture by Wilbur’s attitude. He stayed along beside the
machine without any effort.</p>
<p>The course of the flight up and down was exceedingly erratic, partly due
to the irregularity of the air, and partly to lack of experience in
handling this machine. The control of the front rudder was difficult on
account of its being balanced too near the center. This gave it a
tendency to turn itself when started; so that it turned too far on one
side and then too far on the other. As a result the machine would rise
suddenly to about ten feet, and then as suddenly dart for the ground. A
sudden dart when a little over a hundred feet from the end of the track,
or a little over 120 feet from the point at which it rose into the air,
ended the flight. As the velocity of the wind was over 35 feet per
second and the speed of the machine against this wind ten feet per
second, the speed of the machine relative to the air was over 45 feet
per second, and the length of the flight was equivalent to a flight of
540 feet made in calm air. This flight lasted only 12 seconds, but it
was nevertheless the first in the history of the world in which a
machine carrying a man had raised itself by its own power into the air
in full flight, had sailed forward without reduction of speed, and had
finally landed at a point as high as that from which it started.</p>
<hr class="hr4" />
<p>At twenty minutes after eleven Wilbur started on the second flight. The
course of this flight was much like that of the first, very much up and
down. The speed over the ground was somewhat faster than that of the
first flight, due to the lesser wind. The duration of the flight was
less than a second longer than the first, but the distance covered was
about seventy-five feet greater.</p>
<p>Twenty minutes later the third flight started. This one was steadier
than the first one an hour before. I was proceeding along pretty well
when a sudden gust from the right lifted the machine up twelve to
fifteen feet and turned it up sidewise in an alarming manner. It began
sliding off to the left. I warped the wings to try to recover the
lateral balance and at the same time pointed the machine down to reach
the ground as quickly as possible. The lateral control was more
effective than I had imagined<span class="pagenum"><SPAN name="Page_15" id="Page_15"></SPAN></span> and before I reached the ground the right
wing was lower than the left and struck first. The time of this flight
was fifteen seconds and the distance over the ground a little over 200
feet.</p>
<p>Wilbur started the fourth and last flight at just 12 o’clock. The first
few hundred feet were up and down as before, but by the time three
hundred feet had been covered, the machine was under much better
control. The course for the next four or five hundred feet had but
little undulation. However, when out about eight hundred feet the
machine began pitching again, and, in one of its starts downward, struck
the ground. The distance over the ground was measured and found to be
852 feet; the time of the flight 59 seconds. The frame supporting the
front rudder was badly broken, but the main part of the machine was not
injured at all. We estimated that the machine could be put in condition
for flight again in a day or two.</p>
<p>While we were standing about discussing this last flight, a sudden
strong gust of wind struck the machine and began to turn it over.
Everybody made a rush for it. <SPAN name="tn1" id="tn1"></SPAN><ins class="insert" title="See Transcriber’s Note">
Wilbur, who was at one end, seized it in
front, Mr. Daniels and I, who were behind, tried to stop it by holding
to the rear uprights.</ins> All our efforts were vain. The machine rolled over
and over. Daniels, who had retained his grip, was carried along with it,
and was thrown about head over heels inside of the machine. Fortunately
he was not seriously injured, though badly bruised in falling about
against the motor, chain guides, etc. The ribs in the surfaces of the
machine were broken, the motor injured and the chain guides badly bent,
so that all possibility of further flights with it for that year were at
an end.</p>
<div class="figcenter"> <ANTIMG src="images/i015b.png" width-obs="400" height-obs="228" alt="" title="" /></div>
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