How Hydroelectric Power
Works
So just how do we get
electricity from water? Actually,hydroelectric power and coal-fired power
plants produce electricity in a similar way. In both cases a power
source is used to turn a propeller-like piece called a turbine, which then
turns a metal shaft in an electric generator, which is the motor that produces
electricity. A coal-fired power plant uses steam to turn the turbine blades;
whereas a hydroelectric plant uses falling water to turn the turbine. The
results are the same.
Take a look at this diagram (courtesy of the Tennessee Valley
Authority) of a hydroelectric power plant to see the details:
The theory is to build a dam on a large river that has a
large drop in elevation (there are not many hydroelectric plants in Kansas or
Florida). The dam stores lots of water behind it in the reservoir. Near the
bottom of the dam wall there is the water intake. Gravity causes it to fall
through the penstock inside the dam. At the end of the penstock there is a
turbine propeller, which is turned by the moving water. The shaft from the
turbine goes up into the generator, which produces the power. Power lines are
connected to the generator that carry electricity to your home and mine. The
water continues past the propeller through the tailrace into the river past the
dam. By the way, it is not a good idea to be playing in the water right below a
dam when water is released!
This diagram of a hydroelectric generator is
courtesy of U.S. Army Corps of Engineers.
As to how this generator works, the Corps of Engineers
explains it this way:
"A hydraulic turbine converts the energy of flowing
water into mechanical energy. A hydroelectric generator converts
this mechanical energy into electricity. The operation of a generator is based
on the principles discovered by Faraday. He found that when a magnet is moved
past a conductor, it causes electricity to flow. In a large generator,
electromagnets are made by circulating direct current through loops of wire
wound around stacks of magnetic steel laminations. These are called field
poles, and are mounted on the perimeter of the rotor. The rotor is attached to
the turbine shaft, and rotates at a fixed speed. When the rotor turns, it
causes the field poles (the electromagnets) to move past the conductors mounted
in the stator. This, in turn, causes electricity to flow and a voltage to
develop at the generator output terminals."
Pumped storage: Reusing water for peak electricity demand
Demand for electricity is not "flat" and constant.
Demand goes up and down during the day, and overnight there is less need for
electricity in homes, businesses, and other facilities. For example, here in
Atlanta, Georgia at 5:00 PM on a hot August weekend day, you can bet there is a
huge demand for electricity to run millions of air conditioners! But, 12 hours
later at 5:00 AM not so much. Hydroelectric plants are more efficient at
providing for peak power demands during short periods than are fossil-fuel and
nuclear power plants, and one way of doing that is by using "pumped
storage", which reuses the same water more than once.
Pumped storage is a method of keeping water in reserve for
peak period power demands by pumping water that has already flowed through the
turbines back up a storage pool above thepowerplant at a time when
customer demand for energy is low, such as during the middle of the night. The
water is then allowed to flow back through the turbine-generators at times when
demand is high and a heavy load is placed on the system.
The reservoir acts much like a battery, storing power in the
form of water when demands are low and producing maximum power during daily and
seasonal peak periods. An advantage of pumped storage is that hydroelectric
generating units are able to start up quickly and make rapid adjustments in
output. They operate efficiently when used for one hour or several hours.
Because pumped storage reservoirs are relatively small, construction costs are
generally low compared with conventional hydropowerfacilities.