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- J C Coleman
J C Coleman - Octave Chanute experimenting with his gliders on the Michigan sand dunes
Octave Chanute, born in France and reared in America, was one of the first men to make a scientific approach to the problem of flying machines. A thorough scientist, he had followed the progress of all flight experiments the world over. He built gliders with one, two, and even five pairs of wings and tested all of them on the sand dunes of Lake Michigan. His most successful glides were made with a biplane glider. In 1894, he published a book called Progress of Flying Machines, which covered all the efforts of men like himself who had experimented with man-carrying gliders and flying machines. - Wright Brothers' Bicycle shop
Out in Dayton, Ohio, there were two small brothers, who dreamed, as countless other children before them had dreamed, of flying like birds through the air. Their dreams were heightened by a small toy given to them by their father, the pastor of a local church. This toy was to lead to an idea which had a profound effect on the world. You would probably call it a flying propeller. It consisted of a wooden propeller which slipped over a notched stick. By placing a finger against the propeller and rapidly pushing it up the notched stick, the propeller was made to whirl up off the end of the stick and fly into the air. The brothers, young as they were, never quite forgot this little toy as they continued to dream of flying like birds through the air. Though the brothers continued to dream of flying, they were not the kind of lads who spent all their time in dreaming. They made kites which flew a little better and a little higher than those made by the other boys in the neighborhood. They built a press to print their own little newspaper, and they dabbled in woodcuts. To carve out porch posts for their father’s home they built an eight-foot wood-turning lathe. Indeed, they were the sort of boys who caused the neighbors to say, “What will they think of next?” The brothers knew that if they ever wanted to see their dreams come true they must earn their own capital. In the early nineties America was in the midst of the bicycle craze. Everyone who could possibly afford to do so owned a bicycle of some sort and belonged to a cycle club. Being mechanically minded, the brothers did the logical thing. They set themselves up in a small bicycle shop in Dayton, next door to their home. The bicycle shop in Dayton prospered, for the brothers were careful and expert mechanics, and cyclists in need of repairs made their way to the Wright Brothers’ shop. - Wright Brotherrs wind tunnel
The Wright Brothers were not only inspired mechanics (as many people still believe today) but serious scientists, working along the soundest lines. In their keen desire to know what air pressure on wings really was, they cleared a corner of their bicycle shop and built a small wind tunnel with spare lumber and an old electric fan. They built small wing sections of various shapes and experimented with them in their wind tunnel. The electric fan was used to create the moving air around the wing section. By attaching the wing sections to a supporting frame and connecting the frame with a pointer and dial, they were able to keep a record of the effect of moving air on each experimental wing section. Through their wind tunnel research the Wright Brothers discovered the four forces that control all heavier-than-air flight: lift, thrust, weight, and drag. - Wright Brothers' Wind tunnel
They found that a slight curve or camber in the wing section would cause the moving air to travel farther over the top of the wing surface than along the under side. This made the air pressure greater under the wing, gave a suction effect above the wing, and caused it to rise, creating lift. They discovered that a wing section of the proper camber would counteract the weight of gravity. Thus, a wing must be so designed that, with a certain amount of air flowing around it, it would lift a certain weight. They also discovered that air flow against any surface attached to the wing would cause a resistance or drag. Hundreds of experiments in their wind tunnel with various types of wing shapes gave the Wrights a series of tables from which to design a wing that would create the lift for a designed weight. - The Wright Brothers experimental glider
After a year of exhaustive study and experiments with models in their wind tunnel, the Wright Brothers were ready to experiment with a man-carrying glider. With the thoroughness that was typical of every move of the Wrights, the brothers asked the government to let them have information on meteorological conditions all over the country. By studying the weather charts they were able to find a locality where there was a continual flow of wind. This would be nature’s wind tunnel where they could test their glider day after day. Through their study of the charts they found that the wind conditions at Kitty Hawk, on the North Carolina coast, seemed to offer the best possibilities for their glider test. Orville and Wilbur Wright began their experiments with a small man-carrying glider at Kitty Hawk in 1900. From that time until 1903 they made hundreds of successful glider flights and kept accurate records of each flight. They recorded wind velocity, angle of flight, duration of flight, time of day, temperature, humidity, and sky conditions overhead with the typical Wright attention to detail. Each year the Wrights constructed new gliders which embodied principles they had discovered for themselves during their flights at Kitty Hawk. Each glider was larger and had longer and narrower wings than the one before. During the fall of 1902 the brothers recorded nearly a thousand flights in a glider with a wingspan of thirty-two feet. It had a front elevator and a vertical tail which helped to maintain lateral stability. - Wright Brothers first powered airplane
By 1903 the Wright Brothers were ready to build a powered man-carrying flying machine. Their experiments had shown them just how much moving air was necessary to create lift in such a machine. To create the needed thrust, an engine having eight horsepower and weighing not over 200 pounds had to be fitted into the machine. Such an engine was not available, so the Wrights built one in their shop at Dayton, Ohio. They were ready to ship their airplane to Kitty Hawk, N. C., in the fall of 1903. - A One-hand catch
A One-hand catch - A perfect slide
A perfect slide - Another good catch
Another good catch - Another great catch
Another great catch - Caught Out
Caught Out - Climbing the fence to catch the ball
Climbing the fence to catch the ball - Good catch
Good catch - He caught the ball
He caught the ball - He missed the catch
He missed the catch - Trying to steal home
Trying to steal home - Turning an error into an out
Turning an error into an out - Waiting to bat
Waiting to bat - Looks like a home run
Looks like a home run - Misjudged the ball
Misjudged the ball - Signaling from the dugout
Signaling from the dugout - Swing and a miss
Swing and a miss - The Crowd went wild
The Crowd went wild - The Manager of the team
The Manager of the team - The Umpire
The Umpire - Throw to first
Throw to first - The Automobile Fire Engine
The Automobile Fire Engine can go to the fires very swiftly. Many times the saving of a few minutes by the firemen in reaching a fire means stopping the blaze before it becomes too great. - The brave fireman
The brave fireman rescues many people who are caught in burning buildings, in this way risking his life that others may be saved from the smoke and flames. Many people owe their lives to the bravery of the firemen. - The Hoze nozzle
The Hoze nozzle has been taken up to the roof of a building next the one afire and the firemen are sending the water into the upper floors of the burning building. The hose nozzle is very difficult for the firemen to hold. - The Fire Alarm
The Fire Alarm is sounded by a big gong in the station from street alarm boxes near where the fire occurs. The firemen know these alarm stations so well that they seldom look for the address, but dash off quickly to the correct place. - The Fireman's dog
The Fireman's dog goes to every fire, running beside the horses, barking a command to hurry. He gets to the fire hydrant first and sits there panting until the Firemen come up to attach the hose and turn on the water. - The Round House
The Round House is the place where the railroad engines are kept when they are not working. The engines are turned around on a big turn table so each can be run on the different tracks which all lead to the turn-table in the centre. - The water tank
The water tank is seen frequently along the route of the railroads and plenty of water must be taken on and carried in the engine tender to make steam which is the power used to drive the big engines. - An observation train
An observation train is often made up to follow the great college boat races, where the railroad runs along the river bank. Flat cars are used with seats fixed on them for the spectators. - The Train Ferry
The Train Ferry carries entire trains across rivers where there are no bridges. Some of the largest train boats have several tracks and carry a train on each. The boats are tied in slips at the shore so that the tracks meet exactly those on the land. - The Stage coach
The Stage coach is used in the country where towns are few. The stages meet trains at the stations and take on passengers to be carried to their homes away from the railroad. Some of the stage routes are several hundred miles long. - The tunnels
The tunnels are passages for trains under mountains, hills and rivers. The tunnels are dark but the trains are well lighted. Electric motors are often used, this avoids the smoke of steam engines which is very unpleasant in the tunnels. - Fulton’s ‘Clermont’ on The Hudson, 1807
The Clermont made her first voyage from New York to Albany, August 7th, 1807. Her speed was about five miles an hour. During the winter of 1807-8 she was enlarged, her name being then changed to North River. She continued to ply successfully on the Hudson as a passenger boat for a number of years, her owners having acquired the exclusive right to navigate the waters of the State of New York by steam. - Mississippi steamboat ‘J. M. White,’ 1878
The light-draught Mississippi steamers bear little resemblance to the Hudson River and Long Island Sound boats while the American steam ferry-boat is a thing certainly not of beauty, but unique. The J. M. White, of 1878, was deemed “a crowning effort in steamboat architecture in the West.” She was 320 feet long and 91 feet in width, over the guards. Her saloons were magnificently furnished, and all her internal fittings of the most elaborate description. She carried 7,000 bales of cotton and had accommodation for 350 cabinpassengers. Her cost was $300,000. She was totally destroyed by fire in 1886. - Abraham Lincoln
Abraham Lincoln - Albany Run-a-bout, Model 2, 4–6 H. P
Albany Run-a-bout, Model 2, 4–6 H. P. Albany Automobile Co., Albany, Ind. PRICE: $300; with top BODY: Piano box SEATS: 2 persons WEIGHT: 500 pounds WHEEL-BASE: 62 inches TREAD: 52 inches TIRES, FRONT: 30 × 1¼ in., solid TIRES, REAR: 32 × 1¼ in., solid STEERING: Hand lever or tiller BRAKES: Foot brake on transmission SPRINGS: Full elliptic FRAME: Angle steel BORE: 4½ in.; STROKE: 4 in. CYLINDERS: 1, vertical, in front VALVE ARRANGEMENT: 3 port, side valves MOTOR SUSPENSION: From side members of frame COOLING: Water; pump IGNITION: Jump spark CURRENT SUPPLY: Dry battery CARBURETER: Universal; automatic mixture regulation LUBRICATION: Sight feed pressure MOTOR-CONTROL: Spark and throttle TRANSMISSION: Friction CHANGE SPEEDS: Slide of friction disk SPEEDS: 2 to 10 miles and reverse CHANGE-SPEED CONTROL: Side lever DRIVE: Center chain on differential sprocket - Waltham-Orient, Model B R., 4 H.P
Waltham-Orient, Model B R., 4 H.P. Waltham Mfg. Co., Waltham, Mass. PRICE: $400 BODY: Runabout SEATS: 2 persons WEIGHT: 600 pounds WHEEL-BASE: 80 inches TREAD: 42 inches TIRES, FRONT: 26 × 2½ in. TIRES, REAR: 26 × 2½ in. STEERING: Tiller BRAKES: On rear hubs SPRINGS: Elliptical front and rear FRAME: Wood BORE: 3¼ in.; STROKE: 4¼ in. CYLINDERS: One in back VALVE ARRANGEMENT: Automatic inlet; mechanical exhaust MOTOR SUSPENSION: Rear on side members of frame COOLING: Air IGNITION: Jump spark CURRENT SUPPLY: Dry battery CARBURETER: Orient LUBRICATION: Oil pump MOTOR-CONTROL: Throttle and spark CLUTCH: Friction CHANGE GEAR: Friction SPEEDS: 5 forward, 2 reverse CHANGE-GEAR CONTROL: Side lever DRIVE: Friction drive NOTE: Furnished with 2 cylinder motor for $50 extra. - Aurora, Model 'A,' 14–16 H.P
Aurora, Model "A," 14–16 H.P. Aurora Motor Works, North Aurora, Ill. PRICE: $650 BODY: Runabout body SEATS: 2 passengers WEIGHT: 1,000 pounds WHEEL-BASE: 80 inches TREAD: 56 inches TIRES, FRONT: 34 × 2 inches TIRES, REAR: 34 × 2 inches STEERING: Wheel steer; pinion gear BRAKES: Rear hub band brakes and transmission brakes SPRINGS: Half elliptical, front; full elliptical, rear FRAME: Angle steel BORE: 4½ in.; STROKE: 4 in. CYLINDERS: Double opposed horizontal, under hood VALVE ARRANGEMENT: Inlet and exhaust on opposite sides of motor MOTOR SUSPENSION: 3 point suspension COOLING: Water; triangular tube special radiator; thermo-siphon IGNITION: Jump spark CURRENT SUPPLY: Dry batteries CARBURETER: Holly LUBRICATION: Automatic force feed MOTOR-CONTROL: Spark and throttle on steering column CLUTCH: Cone CHANGE GEAR: Planetary transmission SPEEDS: 2 forward and 1 reverse CHANGE-GEAR CONTROL: Side lever DRIVE: Shaft driven - Buggyabout, Model C, 14 H.P
"Buggyabout," Model C, 14 H.P. Hatfield Motor Vehicle Co., Cortland, N. Y. PRICE: $750 BODY: Piano box convertible to commercial wagon SEATS: 4 persons WEIGHT: 900 pounds WHEEL-BASE: 101 inches TREAD: 56 inches TIRES, FRONT: 38 × 1½ inches TIRES, REAR: 42 × 1½ inches STEERING: Chain and sprocket (patented) BRAKES: 2 on differential sprockets, 2 emergency SPRINGS: Full elliptical FRAME: Wood sill, reinforced by angle iron BORE: 4½ in.; STROKE: 4 in. CYLINDERS: 2 opposed VALVE ARRANGEMENT: Automatic intake; mechanical exhaust MOTOR SUSPENSION: From sills COOLING: Air IGNITION: Jump spark CURRENT SUPPLY: Dry cells CARBURETER: Schebler LUBRICATION: Gravity feed MOTOR-CONTROL: Spark and throttle CLUTCH: None SPEEDS: 3 to 25 miles DRIVE: Friction drive (patented) - Wolfe, Model A, 24 H.P
Wolfe, Model A, 24 H.P. H. E. Wilcox Motor Car Company, Minneapolis, Minn. PRICE: $1,800 BODY: Side entrance, rear seat removable SEATS: 5 persons WEIGHT: 1,900 pounds WHEEL-BASE: 108 inches TREAD: 56 inches TIRES, FRONT: 34 × 3½ inches TIRES, REAR: 34 × 3½ inches STEERING: Worm and sector BRAKES: On rear hubs SPRINGS: Full elliptic FRAME: Pressed steel BORE: 4 in.; STROKE: 4 in. CYLINDERS: 4 vertical, tandem MOTOR SUSPENSION: On sub-frame COOLING: Air IGNITION: Jump spark CURRENT SUPPLY: Battery CARBURETER: Float-feed LUBRICATION: Mechanical force feed MOTOR-CONTROL: Spark and throttle CLUTCH: Cone CHANGE GEAR: Sliding type SPEEDS: 3 forward and reverse CHANGE-GEAR CONTROL: Side lever DRIVE: Side chain NOTE: Runabout body fitted to above chassis for a list of $1,700. Light delivery body also furnished on order. - Marion Model 7, 22–24 H.P
Marion Model 7, 22–24 H.P. The Marion Motor Car Co., Indianapolis, Ind. PRICE: $2,000 BODY: Runabout SEATS: 2 persons WEIGHT: 1,750 pounds WHEEL-BASE: 100 inches TREAD: 55 inches TIRES, FRONT: 32 × 3½ inches TIRES, REAR: 32 × 3½ inches STEERING: Worm and sector BRAKES: Hub, internal and external SPRINGS: Semi-elliptic front, and full scroll rear FRAME: Pressed steel BORE: 4 in.; STROKE: 4 in. CYLINDERS: 4 separate VALVE ARRANGEMENT: Opposite sides MOTOR SUSPENSION: From side members of main frame COOLING: Water IGNITION: High-tension CURRENT SUPPLY: Storage battery CARBURETER: Schebler or Holley LUBRICATION: Force feed MOTOR-CONTROL: Spark and throttle CLUTCH: Multiple disc CHANGE GEAR: "Hassler" SPEEDS: 2 forward and reverse CHANGE-GEAR CONTROL: Side lever DRIVE: Shaft - Pennsylvania, 35 H.P. Pennsylvania Auto Motor Co., Phil., Pa.
PRICE: $2,800 BODY: Mercedes SEATS: 5 persons WEIGHT: 2,550 pounds WHEEL-BASE: 111 inches TREAD: 56 inches TIRES, FRONT: 34 × 4 in. TIRES, REAR: 34 × 4 in. STEERING: Worm and nut BRAKES: Double on rear wheels SPRINGS: Front, 40 in. long; Rear, platform type FRAME: Pressed steel BORE: 4½ in.; STROKE: 5 in. CYLINDERS: 4 vertical, cast separate VALVE ARRANGEMENT: Same side MOTOR SUSPENSION: Direct from sub-frame COOLING: Water; cellular radiator IGNITION: Jump spark CURRENT SUPPLY: Storage battery CARBURETER: Schebler LUBRICATION: Force feed MOTOR-CONTROL: Spark and throttle CLUTCH: Cone CHANGE GEAR: Sliding type SPEEDS: 3 forward and reverse CHANGE-GEAR CONTROL: Selective system DRIVE: Shaft - Benjamin Franklin
- The flag Major Anderson carried with him from Fort Sumter
- Cottage Piety
- The Cottage Fire-Side
- Latest Fashions, September 1841
- 1916 Woman
- Orientation of a house to the sun
In the first place, you see three broad, concentric circles, on the outside of which the rising and setting sun is depicted for both midsummer and midwinter day. The figures, 30°–50°, alongside of the sun represent degrees of north latitude, wherever you may happen to live, which, with the exception of most of Florida and southern Texas, cover the United States. The short arrows show the direction of the sun’s rays at sunrise and sunset. The inner circle represents your horizon, and the degrees marked upon it show the points of sunrise and sunset, north or south of the direct east and west line. These angular distances, in terms of degrees, are called amplitudes, north or south, and must not be confused with the degrees of latitude on the earth’s surface, indicated by the numbers along side of the sun, though intimately dependent upon them. The amplitude of the horizon point, where the sun rises and sets from time to time during the year, always depends upon the latitude on the earth’s surface where you happen to live, as may be seen by following with your eye the direction of the arrows of latitude through the amplitude circle. Starting from the number indicating the latitude where you live, trace the arrow until it touches the amplitude circle. You can then read the degree on it which shows how far north or south of the east and west line the sun rises or sets. We are indebted to Professor Philip Fox, of the Dearborn Astronomical Observatory at Evanston, Illinois, for determining these points. The two outer circles are sun-dials for midsummer and midwinter day at the 40th degree of north latitude; and, if you imagined them pivoted on their rising and setting points and tipped up from the south to represent the slanting path of the sun during the day, they show the direction from which the sun is shining during successive hours of the day (or night on the other side of the world). The shaded portions of these circles represent night, which for all northern latitudes is short in summer and long in winter, as the day is short in winter and long in summer. If you examine the hour spaces on the winter dial of your winter night, you will find them exactly like those on the summer dial of your summer day. So also your winter day hours are spaced like your summer night hours. South of the equator, people have precisely the same experiences only in the reverse order. New Zealanders, we fancy, wear straw hats in January and fur caps in July. If you liked summer well enough and cared to move, you could live in a perpetual summer on our little globe. It is probable, however, that, like most people, you rather prefer the change of seasons, in spite of occasional extremes. - View of the Horse-Shoe Fall of Niagara
VIEW of the HORSE-SHOE FALL of NIAGARA I.Weld del. Neele Scupt. Published by J. Stockdale Picadilly. - View of the Lesser Fall of Niagara
VIEW of the Lesser FALL of NIAGARA I.Weld del. J. Scott sculpt. Published Dec. 22, 1798, by J. Stockdale Picadilly. - View of Bethlehem a Moravian settlement
VIEW of BETHLEHEM a Moravian settlement. I. Weld del. J. Dadley sculpt. Published Dec. 12 1798, by I. Stockdale, Picadilly. Bethlehem is the principal settlement, in North America, of the Moravians, or United Brethren. It is most agreeably situated on a rising ground, bounded on one side by the river Leheigh, which falls into the Delaware, and on the other by a creek, which has a very rapid current, and affords excellent seats for a great number of mills. The town is regularly laid out, and contains about eighty strong built stone dwelling houses and a large church. Three of the dwelling houses are very spacious buildings, and are appropriated respectively to the accommodation of the unmarried young men of the society, of the unmarried females, and of the widows. In these houses different manufactures are carried on, and the inmates of each are subject to a discipline approaching somewhat to that of a monastic institution. They eat together in a refectory; they sleep in dormitories; they attend morning and evening prayers in the chapel of the house; they work for a certain number of hours in the day; and they have stated intervals allotted to them for recreation. - An eye sketch of the Falls of Niagara
AN EYE SKETCH of the FALLS of NIAGARA I.Weld del. Neele sculpt. London Published by J. Stockdale Piccadilly 16th. Novr. 1798. - View of the Falls of Niagara
View of the FALLS of Niagara J. Scott Published Dec.14 1798, by J. Stockdale