550, as 1 kV = 1000V
Water behind a dam falls through a turbine, causing the turbine to spin, the turbine spins a large electric alternator (AC generator), the generator produces electricity which is delivered to the power grid.
usually an wind turbine consists of large gears at its shaft point which produces slow speed to high speed to run the generator coupled to it
I do not think that would be possible, as hydroelectric power is produced by large amounts of water spinning a generator to produce electricity. The structure that produces hydroelectric power is called a dam, which are quite large and usually require a lake or at least a large river to produce power.
Hydroelectricity is a method of producing electricity from flowing water. A large area of water - typically held behind a dam - is forced (by it's own weight) through a turbine generator, which makes the generator spin. When the generator spins, magnets attached to the turbine portion move past magnets mounted on the generator walls just outside the turbine. This produces electrical current, which is harnessed as electricity.
Hydroelectricity is a method of producing electricity from flowing water. A large area of water - typically held behind a dam - is forced (by it's own weight) through a turbine generator, which makes the generator spin. When the generator spins, magnets attached to the turbine portion move past magnets mounted on the generator walls just outside the turbine. This produces electrical current, which is harnessed as electricity.
THE ANSWER TO THIS QUESTION IS A VANDAGRAPH GENERATOR
Elephants are an animal that produces large piles of feces. A hippopotamus is another animal that produces large piles of feces.
The price range when purchasing a power generator depends a great deal on the size of a generator. A small generator for the garage can be purchased for $100.00 while a large industrial generator can cost as much as $30,000.00.
The picture above is a dynamo- a large electrical generator.
It is usually a steam turbine that powers a large generator, in which case it is the mechanical force caused by high pressure steam impinging on the turbine blades.
The voltage at which a super grid operates can vary depending on the specific grid and its design. Generally, super grids operate at very high voltages, typically in the range of hundreds of kilovolts (kV) to several hundreds of kilovolts (kV), or even higher. These high voltages are necessary to transmit large amounts of electricity over long distances with minimal losses.
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