The Smith–Putnam wind turbine was the world's first megawatt-size

wind turbine A wind turbine is a device that wind power, converts the kinetic energy of wind into electrical energy. , hundreds of thousands of list of most powerful wind turbines, large turbines, in installations known as wind farms, were generating over ...

. In 1941 it was connected to the local electrical distribution system on Grandpa's Knob in

Castleton, Vermont Castleton is a town in Rutland County, Vermont, United States. Castleton is about to the west of Rutland, the county's seat and most populous city, and about east of the New York/Vermont state border. The town had a population of 4,458 at the ...

, US. It was designed by Palmer Cosslett Putnam and manufactured by the S. Morgan Smith Company. The 1.25 MW turbine operated for 1100 hours before a blade failed at a known weak point, which had not been reinforced due to wartime material shortages. It would be the largest wind turbine ever built until 1979.

Description

The turbine had two blades, in diameter, on the down-wind side of a -foot steel lattice tower. Each blade was approximately wide and long, and weighed eight tons. The blades were built on steel spars and covered with a stainless steel skin. The blade spars were hinged at their root attachment to the hub, allowing them to assume a slight cone shape. The generator was a 1250 kva 600 RPM

synchronous generator An alternator (or synchronous generator) is an electrical generator that converts mechanical energy to electrical energy in the form of alternating current. For reasons of cost and simplicity, most alternators use a rotating magnetic field with ...

made by

General Electric General Electric Company (GE) was an American Multinational corporation, multinational Conglomerate (company), conglomerate founded in 1892, incorporated in the New York (state), state of New York and headquartered in Boston. Over the year ...

, producing 2,400 V at 60 cycles. The actual generation of this generator would be something around 1MW, allowing for a

power factor In electrical engineering, the power factor of an AC power system is defined as the ratio of the ''real power'' absorbed by the electrical load, load to the ''apparent power'' flowing in the circuit. Real power is the average of the instantaneou ...

of less than 1. The generator and rotor hub were mounted on a

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beam, which allowed the rotor to capture wind from varying directions. The pitch of the blades was controlled by hydraulic cylinders to maintain constant speed.

Origins

Palmer Putnam became interested in production of electric power from wind after observing high winds at

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. Putnam was aware of the Balaklava 100 kW turbine and desired to improve on its performance. By 1937 he had enlisted General Electric, and

Central Vermont Public Service Central Vermont Public Service Corp. (CVPS) was the largest electricity supplier in Vermont. Its customer base covered 160,000 people in 163 towns, villages and cities in Vermont. The company generated revenue mainly though purchased electricity ...

. General Electric provided a generator, and Central Vermont Public Services Corporation was interested in an energy supply that could displace purchased power for meeting peak loads. A Bold Effort in Vermont: The 1941 Smith–Putnam Wind Turbine, C. Sulzberger, retrieved 2009 Nov 21 Only 23 months elapsed between first discussions and production of power. Palmer concluded that the most promising concept was a two-bladed propeller driving a synchronous AC generator. He developed a preliminary design and cost estimates. Dr.

Vannevar Bush Vannevar Bush ( ; March 11, 1890 – June 28, 1974) was an American engineer, inventor and science administrator, who during World War II, World War II headed the U.S. Office of Scientific Research and Development (OSRD), through which almo ...

, Dean of Engineering at MIT, reacted favorably when shown these calculations in 1937. Bush introduced Putnam to a vice president of General Electric Company, Mr. T. Knight. From this point on Putnam was able to enlist the services of some very talented people which included Theodore von Karman, a world-famous authority on aerodynamics, to assist in the design, parametric studies, cost analyses, site selection, and determination of wind characteristics. In 1939, the Guggenheim Aeronautical Laboratories of the California Institute of Technology (GALCIT) was approached by Palmer C. Putnam, to design the turbine.

Theodore von Kármán Theodore von Kármán ( , May 11, 1881May 6, 1963) was a Hungarian-American mathematician, aerospace engineer, and physicist who worked in aeronautics and astronautics. He was responsible for crucial advances in aerodynamics characterizing ...

had

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and W. Duncan Rannie carry out the aerodynamic design. Unfortunately, Rannie's analytical findings regarding the stability of the giant windmill were not incorporated in the prototype that was built and tested on the mountain. Putnam obtained the financial and technical backing of the S. Morgan Smith Company of York, Pennsylvania. The Smith Company manufactured hydroelectric

hydraulic turbine A water turbine is a rotary machine that converts kinetic energy and potential energy of water into mechanical work. Water turbines were developed in the 19th century and were widely used for industrial power prior to electrical grids. Now, t ...

s. Since the number of feasible sites for hydroelectric development was felt to be declining, the Smith company sought diversification into a new but related product line. The S. Morgan Smith Co. agreed to take on the project as general contractor and financed construction of a pilot turbine.

Construction

The site chosen for the prototype turbine was a previously unnamed elevation, named "Grandpa's Knob"; this mountain was not so high as to have excessive ice build up, but had high wind speeds. Access to the site required construction of a road with 12 to 15% grade. Due to the impending entry of the United States into World War II, some of the fundamental research and testing process was skipped so that major components could be made before wartime material shortages occurred.

Operation and failures

No-load testing of the unit began in August 1941 to verify mechanical operation of the turbine and the blade control system. The generator was first synchronized to the local electrical grid on the evening of October 19, 1941, and tested under load varying from zero to 700 kW. The unit operated for about 1000 hours between startup and February 1943, when a shaft bearing failed. Due to wartime material priorities, the bearing was not replaced until March 3, 1945, when the unit achieved another three weeks of operation. In the early morning of March 26, 1945, the operator on duty in the

nacelle A nacelle ( ) is a streamlined container for aircraft parts such as Aircraft engine, engines, fuel or equipment. When attached entirely outside the airframe, it is sometimes called a pod, in which case it is attached with a Hardpoint#Pylon, pylo ...

of the turbine was thrown down by vibrations. He stopped the turbine. On investigation, it was found one turbine blade had broken off and fallen about away. The blade had failed at a previously repaired weak point in the spar; due to wartime shortages, it had been impractical to complete a full repair and reinforcement of the blade root.

Aftermath

A study completed in 1945 suggested that a block of six turbines similar to the prototype, producing 9 MW, could be installed in Vermont for around US$190 per kilowatt. However, the economic value to the power utility was only $125 per kilowatt, and the wind turbine was not considered economically viable by a factor of 1.5.Erich Hau, ''Wind turbines: fundamentals, technologies, application, economics''Birkhäuser, 2006 , page 36 Although the S. Morgan Smith company had spent more than US$1.25 million on the prototype turbine, entirely private funding, it concluded that there was insufficient prospect for profit on further development. Repairs were never done after the March 1945 failure. The prototype turbine was dismantled in 1946, leaving only concrete footings and a marker plaque at the site today. In the introduction to Putnam's book,

stated that the project achieved proof of the concept of synchronous generation of wind power, and projected future commercial use of wind-generated electricity.

Notes

External links

Smith–Putnam Industrial Photos
, Wind-Works.org {{DEFAULTSORT:Smith-Putnam wind turbine Wind turbines Wind power in Vermont