In thermal power stations, mechanical power is produced by a
heat engine that transforms
thermal energy, often from
combustion of a
fuel, into rotational energy. Most thermal power stations produce steam, so they are sometimes called steam power stations. Not all thermal energy can be transformed into mechanical power, according to the
second law of thermodynamics; therefore, there is always heat lost to the environment. If this loss is employed as useful heat, for industrial processes or
district heating, the power plant is referred to as a
cogeneration power plant or CHP (combined heat-and-power) plant. In countries where district heating is common, there are dedicated heat plants called
heat-only boiler stations. An important class of power stations in the Middle East uses by-product heat for the
desalination of water. The efficiency of a thermal power cycle is limited by the maximum working fluid temperature produced. The efficiency is not directly a function of the fuel used. For the same steam conditions, coal-, nuclear- and gas power plants all have the same theoretical efficiency. Overall, if a system is on constantly (base load) it will be more efficient than one that is used intermittently (peak load). Steam turbines generally operate at higher efficiency when operated at full capacity. Besides use of reject heat for process or district heating, one way to improve overall efficiency of a power plant is to combine two different thermodynamic cycles in a
combined cycle plant. Most commonly,
exhaust gases from a gas turbine are used to generate steam for a boiler and a steam turbine. The combination of a "top" cycle and a "bottom" cycle produces higher overall efficiency than either cycle can attain alone. In 2018,
Inter RAO UES and State Grid planned to build an 8-GW thermal power plant, which's the largest
coal-fired power plant construction project in
Russia.
Classification ,
Japan ,
Vantaa, Finland ,
Iceland By heat source •
Fossil-fuel power stations may also use a steam turbine generator or in the case of natural
gas-fired power plants may use a
combustion turbine. A coal-fired power station produces heat by burning coal in a steam boiler. The steam drives a
steam turbine and
generator that then produces
electricity. The waste products of combustion include ash,
sulfur dioxide,
nitrogen oxides, and
carbon dioxide. Some of the gases can be removed from the waste stream to reduce pollution. •
Nuclear power plants use the heat generated in a
nuclear reactor's core (by the
fission process) to create steam which then operates a steam turbine and generator. About 20 percent of electric generation in the US is produced by nuclear power plants. •
Geothermal power plants use steam extracted from hot underground rocks. These rocks are heated by the decay of radioactive material in the Earth's core. •
Biomass-fuelled power plants may be fuelled by
waste from sugar cane,
municipal solid waste, landfill
methane, or other forms of
biomass. • In integrated
steel mills,
blast furnace exhaust gas is a low-cost, although low-energy-density, fuel. •
Waste heat from industrial processes is occasionally concentrated enough to use for power generation, usually in a steam boiler and turbine. •
Solar thermal electric plants use sunlight to boil water and produce steam which turns the generator. •
Hydrogen power plants can use
green hydrogen from
electrolysis to help balance supply and demand from
Variable renewable energy sources.
By prime mover A prime mover is a machine that converts energy of various forms into energy of motion. •
Steam turbine plants use the dynamic pressure generated by expanding steam to turn the blades of a turbine. Almost all large non-hydro plants use this system. About 90 percent of all electric power produced in the world is through use of steam turbines. •
Gas turbine plants use the dynamic pressure from flowing gases (air and combustion products) to directly operate the turbine. Natural-gas fuelled (and oil fueled) combustion turbine plants can start rapidly and so are used to supply "peak" energy during periods of high demand, though at higher cost than base-loaded plants. These may be comparatively small units, and sometimes completely unmanned, being remotely operated. This type was pioneered by the UK,
Princetown being the world's first, commissioned in 1959. •
Combined cycle plants have both a gas turbine fired by natural gas, and a steam boiler and steam turbine which use the hot exhaust gas from the gas turbine to produce electricity. This greatly increases the overall efficiency of the plant, and many new baseload power plants are combined cycle plants fired by natural gas. • Internal combustion
reciprocating engines are used to provide power for isolated communities and are frequently used for small cogeneration plants. Hospitals, office buildings, industrial plants, and other critical facilities also use them to provide backup power in case of a power outage. These are usually fuelled by diesel oil, heavy oil,
natural gas, and
landfill gas. •
Microturbines,
Stirling engine and internal combustion reciprocating engines are low-cost solutions for using opportunity fuels, such as
landfill gas, digester gas from water treatment plants and waste gas from oil production.
By duty Power plants that can be dispatched (scheduled) to provide energy to a system include: •
Base load power plants run nearly continually to provide that component of system load that does not vary during a day or week. Baseload plants can be highly optimized for low fuel cost, but may not start or stop quickly during changes in system load. Examples of base-load plants would include large modern coal-fired and nuclear generating stations, or hydro plants with a predictable supply of water. •
Peaking power plants meet the daily peak load, which may only be for one or two hours each day. While their incremental operating cost is always higher than base load plants, they are required to ensure security of the system during load peaks. Peaking plants include simple cycle gas turbines and reciprocating internal combustion engines, which can be started up rapidly when system peaks are predicted. Hydroelectric plants may also be designed for peaking use. •
Load following power plants can economically follow the variations in the daily and weekly load, at lower cost than peaking plants and with more flexibility than baseload plants. Non-dispatchable plants include such sources as wind and solar energy; while their long-term contribution to system energy supply is predictable, on a short-term (daily or hourly) base their energy must be used as available since generation cannot be deferred. Contractual arrangements ("take or pay") with independent power producers or system interconnections to other networks may be effectively non-dispatchable.
Cooling towers s showing evaporating water at
Ratcliffe-on-Soar Power Station,
United Kingdom " natural draft wet
cooling tower All thermal power plants produce
waste heat energy as a byproduct of the useful electrical energy produced. The amount of waste heat energy equals or exceeds the amount of energy converted into useful electricity. Gas-fired power plants can achieve as much as 65% conversion efficiency, while coal and oil plants achieve around 30–49%. The waste heat produces a temperature rise in the atmosphere, which is small compared to that produced by
greenhouse-gas emissions from the same power plant. Natural draft wet
cooling towers at many nuclear power plants and large fossil-fuel-fired power plants use large
hyperboloid chimney-like structures (as seen in the image at the right) that release the waste heat to the ambient atmosphere by the
evaporation of water. However, the mechanical induced-draft or forced-draft wet cooling towers in many large thermal power plants, nuclear power plants, fossil-fired power plants,
petroleum refineries,
petrochemical plants,
geothermal,
biomass and
waste-to-energy plants use
fans to provide air movement upward through down coming water and are not hyperboloid chimney-like structures. The induced or forced-draft cooling towers are typically rectangular, box-like structures filled with a material that enhances the mixing of the upflowing air and the down-flowing water. In areas with restricted water use, a dry cooling tower or directly air-cooled radiators may be necessary, since the cost or environmental consequences of obtaining make-up water for evaporative cooling would be prohibitive. These coolers have lower efficiency and higher energy consumption to drive fans, compared to a typical wet, evaporative cooling tower.
Air-cooled condenser (ACC) Power plants can use an air-cooled condenser, traditionally in areas with a limited or expensive water supply. Air-cooled condensers serve the same purpose as a cooling tower (heat dissipation) without using water. They consume additional auxiliary power and thus may have a higher carbon footprint compared to a traditional cooling tower.
Once-through cooling systems Electric companies often prefer to use cooling water from the ocean or a lake, river, or cooling pond instead of a cooling tower. This single pass or
once-through cooling system can save the cost of a cooling tower and may have lower energy costs for pumping cooling water through the plant's
heat exchangers. However, the waste heat can cause
thermal pollution as the water is discharged. Power plants using natural bodies of water for cooling are designed with mechanisms such as
fish screens, to limit intake of organisms into the cooling machinery. These screens are only partially effective and as a result billions of fish and other aquatic organisms are killed by power plants each year. For example, the cooling system at the
Indian Point Energy Center in New York kills over a billion fish eggs and larvae annually. A further environmental impact is that aquatic organisms which adapt to the warmer discharge water may be injured if the plant shuts down in cold weather. Water consumption by power stations is a developing issue. In recent years, recycled wastewater, or
grey water, has been used in cooling towers. The Calpine Riverside and the Calpine Fox power stations in
Wisconsin as well as the Calpine Mankato power station in
Minnesota are among these facilities. ==Power from renewable energy==