, a
coal-fired cogeneration power plant in
Helsinki,
Finland Topping cycle plants primarily produce electricity from a steam turbine. Partly expanded steam is then condensed in a heating condensor at a temperature level that is suitable e.g.
district heating or
water desalination.
Bottoming cycle plants produce high temperature heat for industrial processes, then a
waste heat recovery boiler feeds an electrical plant. Bottoming cycle plants are only used in industrial processes that require very high temperatures such as furnaces for glass and metal manufacturing, so they are less common. Large cogeneration systems provide heating water and power for an industrial site or an entire town. Common CHP plant types are: •
Gas turbine CHP plants using the waste heat in the flue gas of gas turbines. The fuel used is typically
natural gas. •
Gas engine CHP plants use a reciprocating gas engine, which is generally more competitive than a gas turbine up to about 5 MW. The gaseous fuel used is normally
natural gas. These plants are generally manufactured as fully packaged units that can be installed within a plantroom or external plant compound with simple connections to the site's gas supply, electrical distribution network and heating systems. Typical outputs and efficiencies see Typical large example see •
Biofuel engine CHP plants use an adapted reciprocating gas engine or
diesel engine, depending upon which biofuel is being used, and are otherwise very similar in design to a Gas engine CHP plant. The advantage of using a biofuel is one of reduced
fossil fuel consumption and thus reduced carbon emissions. These plants are generally manufactured as fully packaged units that can be installed within a plantroom or external plant compound with simple connections to the site's electrical distribution and heating systems. Another variant is the
wood gasifier CHP plant whereby a wood pellet or wood chip biofuel is
gasified in a zero oxygen high temperature environment; the resulting gas is then used to power the gas engine. •
Combined cycle power plants adapted for CHP •
Molten-carbonate fuel cells and
solid oxide fuel cells have a hot exhaust, very suitable for heating. •
Steam turbine CHP plants that use the heating system as the
steam condenser for the steam turbine •
Nuclear power plants, similar to other steam turbine power plants, can be fitted with extractions in the turbines to bleed partially expanded steam to a heating system. With a heating system temperature of 95 °C it is possible to extract about 10 MW heat for every MW electricity lost. With a temperature of 130 °C the gain is slightly smaller, about 7 MW for every MWe lost. A review of cogeneration options is in Czech research team proposed a "Teplator" system where heat from spent fuel rods is recovered for the purpose of residential heating. Smaller cogeneration units may use a
reciprocating engine or
Stirling engine. The heat is removed from the exhaust and radiator. The systems are popular in small sizes because small gas and diesel engines are less expensive than small gas- or oil-fired steam-electric plants. Some cogeneration plants are fired by
biomass, or industrial and
municipal solid waste (see
incineration). Some CHP plants use waste gas as the fuel for electricity and heat generation. Waste gases can be gas from
animal waste,
landfill gas,
gas from coal mines,
sewage gas, and combustible industrial waste gas. Some cogeneration plants combine gas and solar
photovoltaic generation to further improve technical and environmental performance. Such hybrid systems can be scaled down to the building level and even individual homes.
MicroCHP Micro combined heat and power or 'Micro cogeneration" is a so-called
distributed energy resource (DER). The installation is usually less than 5
kWe in a house or small business. Instead of burning fuel to merely heat space or water, some of the energy is converted to electricity in addition to heat. This electricity can be used within the home or business or, if permitted by the grid management, sold back into the electric power grid. Delta-ee consultants stated in 2013 that with 64% of global sales the
fuel cell micro-combined heat and power passed the conventional systems in sales in 2012. 20,000 units were sold in
Japan in 2012 overall within the Ene Farm project. With a
Lifetime of around 60,000 hours. For
PEM fuel cell units, which shut down at night, this equates to an estimated lifetime of between ten and fifteen years. For a price of $22,600 before installation. For 2013 a state subsidy for 50,000 units is in place. A 2013 UK report from Ecuity Consulting stated that MCHP is the most cost-effective method of using gas to generate energy at the domestic level. However, advances in reciprocation engine technology are adding efficiency to CHP plants, particularly in the
biogas field. As both MiniCHP and CHP have been shown to reduce emissions they could play a large role in the field of CO2 reduction from buildings, where more than 14% of emissions can be saved using CHP in buildings. The University of Cambridge reported a cost-effective steam engine MicroCHP prototype in 2017 which has the potential to be commercially competitive in the following decades. Quite recently, in some private homes,
fuel cell micro-CHP plants can now be found, which can operate on hydrogen, or other fuels as natural gas or LPG. When running on natural gas, it relies on
steam reforming of natural gas to convert the natural gas to hydrogen prior to use in the fuel cell. This hence still emits (see reaction) but (temporarily) running on this can be a good solution until the point where the hydrogen is starting to be distributed through the (natural gas) piping system. Another MicroCHP example is a natural gas or propane fueled Electricity Producing Condensing Furnace. It combines the fuel saving technique of cogeneration meaning producing electric power and useful heat from a single source of combustion. The condensing
furnace is a
forced-air gas system with a secondary heat exchanger that allows heat to be extracted from combustion products down to the ambient temperature along with recovering heat from the water vapor. The chimney is replaced by a water drain and vent to the side of the building.
Trigeneration A plant producing electricity, heat and cold is called a trigeneration or polygeneration plant. Cogeneration systems linked to
absorption chillers or
adsorption chillers use waste heat for
refrigeration.
Combined heat and power district heating In the
United States,
Consolidated Edison distributes 66 billion kilograms of steam each year through its seven cogeneration plants to 100,000 buildings in
Manhattan—the biggest steam district in the United States. The peak delivery is 10 million pounds per hour (or approximately 2.5 GW).
Industrial CHP Cogeneration is still common in
pulp and paper mills, refineries and chemical plants. In this "industrial cogeneration/CHP", the heat is typically recovered at higher temperatures (above 100 °C) and used for process steam or drying duties. This is more valuable and flexible than low-grade waste heat, but there is a slight loss of power generation. The increased focus on
sustainability has made industrial CHP more attractive, as it substantially reduces
carbon footprint compared to generating steam or burning fuel on-site and importing electric power from the grid. Smaller industrial co-generation units have an output capacity of 5–25 MW and represent a viable off-grid option for a variety of remote applications to reduce carbon emissions.
Utility pressures versus self generated industrial Industrial cogeneration plants normally operate at much lower boiler pressures than utilities. Among the reasons are: • Cogeneration plants face possible contamination of returned condensate. Because boiler feed water from cogeneration plants has much lower return rates than 100% condensing power plants, industries usually have to treat proportionately more boiler make up water. Boiler feed water must be completely oxygen free and de-mineralized, and the higher the pressure the more critical the level of purity of the feed water. • Utilities are typically larger scale power than industry, which helps offset the higher capital costs of high pressure. • Utilities are less likely to have sharp load swings than industrial operations, which deal with shutting down or starting up units that may represent a significant percent of either steam or power demand.
Heat recovery steam generators A
heat recovery steam generator (HRSG) is a steam boiler that uses hot
exhaust gases from the
gas turbines or
reciprocating engines in a CHP plant to heat up water and generate
steam. The steam, in turn, drives a
steam turbine or is used in industrial processes that require heat. HRSGs used in the CHP industry are distinguished from conventional steam generators by the following main features: • The HRSG is designed based upon the specific features of the gas turbine or reciprocating engine that it will be coupled to. • Since the exhaust gas temperature is relatively low, heat transmission is accomplished mainly through
convection. • The exhaust gas velocity is limited by the need to keep head losses down. Thus, the transmission coefficient is low, which calls for a large heating surface area. • Since the temperature difference between the hot gases and the fluid to be heated (steam or water) is low, and with the heat transmission coefficient being low as well, the evaporator and economizer are designed with plate fin heat exchangers. ==Cogeneration using biomass==