Since conditions from city to city differ, every district heating system is unique. In addition, nations have different access to primary energy carriers and so they have a different approach on how to address heating markets within their borders.
Europe Since 1954, district heating has been promoted in Europe by Euroheat & Power. They have compiled an analysis of district heating and cooling markets in Europe within their
Ecoheatcool project supported by the
European Commission. A separate study, entitled Heat Roadmap Europe, has indicated that district heating can reduce the price of energy in the European Union between now and 2050. The legal framework in the member states of the
European Union is currently influenced by the EU's
CHP Directive.
Cogeneration in Europe The EU has actively incorporated cogeneration into its energy policy via the CHP Directive. In September 2008 at a hearing of the European Parliament's Urban Lodgment Intergroup, Energy Commissioner Andris Piebalgs is quoted as saying, "security of supply really starts with energy efficiency." Energy efficiency and cogeneration are recognized in the opening paragraphs of the European Union's Cogeneration Directive 2004/08/EC. This directive intends to support cogeneration and establish a method for calculating cogeneration abilities per country. The development of cogeneration has been very uneven over the years and has been dominated throughout the last decades by national circumstances. As a whole, the European Union currently generates 11% of its electricity using cogeneration, saving Europe an estimated 35 Mtoe per annum. However, there are large differences between the member states, with energy savings ranging from 2% to 60%. Europe has the three countries with the world's most intensive cogeneration economies: Denmark, the Netherlands and Finland. Other European countries are also making great efforts to increase their efficiency. Germany reports that over 50% of the country's total electricity demand could be provided through cogeneration. Germany set a target to double its electricity cogeneration from 12.5% of the country's electricity to 25% by 2020 and has passed supporting legislation accordingly in "Federal Ministry of Economics and Technology", (BMWi), Germany, August 2007. The UK is also actively supporting district heating. In the light of UK's goal to achieve an 80% reduction in carbon dioxide emissions by 2050, the government had set a target to source at least 15% of government electricity from CHP by 2010. Other UK measures to encourage CHP growth are financial incentives, grant support, a greater regulatory framework, and government leadership and partnership. According to the IEA 2008 modelling of cogeneration expansion for the G8 countries, expansion of cogeneration in France, Germany, Italy and the UK alone would effectively double the existing primary fuel savings by 2030. This would increase Europe's savings from today's 155 TWh to 465 TWh in 2030. It would also result in a 16% to 29% increase in each country's total cogenerated electricity by 2030. Governments are being assisted in their CHP endeavors by organizations like
COGEN Europe who serve as an information hub for the most recent updates within Europe's energy policy. COGEN is Europe's umbrella organization representing the interests of the cogeneration industry, users of the technology and promoting its benefits in the EU and the wider Europe. The association is backed by the key players in the industry including gas and electricity companies, ESCOs, equipment suppliers, consultancies, national promotion organisations, financial and other service companies. A 2016 EU energy strategy suggests increased use of district heating.
Austria , Austria The largest district heating system in Austria is in
Vienna (Fernwärme Wien) – with many smaller systems distributed over the whole country. District heating in Vienna is run by Wien Energie. In the business year of 2004/2005 a total of 5,163 GWh was sold, 1,602 GWh to 251,224 private apartments and houses and 3,561 GWh to 5211 major customers. The three large municipal waste
incinerators provide 22% of the total in producing 116 GWh electric power and 1,220 GWh heat. Waste heat from municipal power plants and large industrial plants account for 72% of the total. The remaining 6% is produced by peak heating boilers from fossil fuel. A biomass-fired power plant has produced heat since 2006. In the rest of Austria the newer district heating plants are constructed as biomass plants or as CHP-biomass plants like the
biomass district heating of Mödling or the
biomass district heating of Baden. Most of the older fossil-fired district heating systems have a
district heating accumulator, so that it is possible to produce the thermal district heating power only at that time where the electric power price is high.
Belgium Belgium has district heating in multiple cities. The largest system is in the Flemish city
Ghent, the piping network of this power plant is 22 km long. The system dates back to 1958.
Bulgaria Bulgaria has district heating in around a dozen towns and cities. The largest system is in the capital
Sofia, where there are four power plants (two CHPs and two
boiler stations) providing heat to the majority of the city. The system dates back to 1949.
Czech Republic The largest district heating system in the
Czech Republic is in Prague owned and operated by Pražská teplárenská, serving 265,000 households and selling c. 13 PJ of heat annually. Most of the heat is actually produced as
waste heat in 30 km distant
thermal power station in
Mělník. There are many smaller central heating systems spread around the country including waste heat usage,
municipal solid waste incineration and .
Denmark In Denmark district heating covers more than 64% of
space heating and
water heating. Heat recovered from waste incineration accounted for 20.4% of the total Danish district heat production. In 2013, Denmark imported 158,000 ton waste for incineration. Most major cities in Denmark have big district heating networks, including transmission networks operating with up to 125 °C and 25 bar pressure and distribution networks operating with up to 95 °C and between 6 and 10 bar pressure. The largest district heating system in Denmark is in the
Copenhagen area operated by CTR I/S and VEKS I/S. In central Copenhagen, the CTR network serves 275,000 households (90–95% of the area's population) through a network of 54 km double district heating distribution pipes providing a peak capacity of 663 MW, some of which is combined with
district cooling. The consumer price of heat from CTR is approximately €49 per MWh plus taxes (2009). Several towns have central solar heating with various types of thermal energy storage. The Danish island of
Samsø has three straw-fueled plants producing district heating.
Finland In Finland district heating accounts for about 50% of the total heating market, 80% of which is produced by combined heat and power plants. Over 90% of apartment blocks, more than half of all terraced houses, and the bulk of public buildings and business premises are connected to a district heating network.
Natural gas is mostly used in the south-east gas pipeline network, imported coal is used in areas close to ports, and
peat is used in northern areas where peat is a local resource. Renewables, such as wood chips and other paper industry combustible by-products, are also used, as is the energy recovered by the incineration of
municipal solid waste. Industrial units which generate heat as an industrial by-product may sell otherwise waste heat to the network rather than release it into the environment. Excess heat and power from
pulp mill recovery boilers is a significant source in mill towns. In some towns waste incineration can contribute as much as 8% of the district heating heat requirement.
Availability is 99.98% and disruptions, when they do occur, usually reduce temperatures by only a few degrees. In Helsinki, an underground
datacenter next to the President's palace releases excess heat into neighboring homes, producing enough heat to heat approximately 500 large houses. A quarter of a million households around
Espoo are scheduled to receive district heating from datacenters.
Germany In Germany district heating has a market share of around 14% in the residential buildings sector. The connected heat load is around 52,729 MW. The heat comes mainly from cogeneration plants (83%). Heat-only boilers supply 16% and 1% is surplus heat from industry. The cogeneration plants use natural gas (42%), coal (39%), lignite (12%) and waste/others (7%) as fuel. The largest district heating network is located in Berlin whereas the highest diffusion of district heating occurs in
Flensburg with around 90% market share. In
Munich about 70% of the electricity produced comes from district heating plants. District heating has rather little legal framework in Germany. There is no law on it as most elements of district heating are regulated in governmental or regional orders. There is no governmental support for district heating networks but a law to support cogeneration plants. As in the European Union the CHP Directive will come effective, this law probably needs some adjustment.
Greece Greece has district heating mainly in the province of
Western Macedonia, Central Macedonia and the
Peloponnese Province. The largest system is the city of
Ptolemaida, where there are five power plants (thermal power stations or TPS in particular) providing heat to the majority of the largest towns and cities of the area and some villages. The first small installation took place in Ptolemaida in 1960, offering heating to
Proastio village of
Eordaea using the TPS of Ptolemaida. Today District heating installations are also available in
Kozani, Ptolemaida,
Amyntaio,
Philotas, Serres and
Megalopolis using nearby power plants. In Serres the power plant is a Hi-Efficiency CHP Plant using natural gas, while coal is the primary fuel for all other district heating networks.
Hungary According to the 2011 census there were 607,578 dwellings (15.5% of all) in Hungary with district heating, mostly
panel flats in urban areas. The largest district heating system located in
Budapest, the municipality-owned
Főtáv Zrt. ("Metropolitan Teleheating Company") provides heat and piped hot water for 238,000 households and 7,000 companies.
Iceland 93% of all housing in Iceland enjoy district heating services – 89.6% from
geothermal energy, Iceland is the country with the highest penetration of district heating. There are 117 local district heating systems supplying towns as well as rural areas with hot water – reaching almost all of the population. The average price is around US$0.027 per kWh of hot water. The
Reykjavík Capital Area district heating system serves around 230,000 residents had a maximum thermal power output of 830 MW. In 2018, the average annual heating demand in the Reykjavik area was 473MW. It is the largest district heating system in Iceland and is operated by
Veitur. Heat is supplied from the Hellisheiði (200MWth) and Nesjavellir (300MWth) CHP plants, as well as a few lower temperature fields inside Reykjavik. Heating demand has increased steadily as the population has grown, necessitating enlargement of thermal water production in the Hellisheiði CHP plant. Iceland's second largest district heating system is on the
Reykjanes peninsula, with the
Svartsengi CHP plant providing heating to 21,000 homes including
Keflavik and
Grindavik, with a thermal power output of 150 MW.
Ireland The
Dublin Waste-to-Energy Facility will provide district heating for up to 50,000 homes in
Poolbeg and surrounding areas. Some existing residential developments in the
North Docklands have been constructed for conversion to district heating – currently using on-site gas boilers – and pipes are in place in the
Liffey Service Tunnel to connect these to the incinerator or other waste heat sources in the area.
Tralee, County Kerry has a 1 MW district heating system providing heat to an apartment complex, sheltered housing for the elderly, a library and over 100 individual houses. The system is fuelled by locally produced wood chip. In
Glenstal Abbey, County Limerick there exists a pond-based 150 kW heating system for a school. A scheme to use waste heat from an
Amazon Web Services datacentre in
Tallaght is intended to heat 1200 units and municipal buildings
Italy (
PV), Italy In Italy, district heating is used in some cities (
Bergamo,
Brescia,
Cremona,
Bolzano,
Verona,
Ferrara,
Imola,
Modena,
Reggio Emilia,
Terlan,
Turin,
Parma,
Lodi, and now
Milan). The district heating of Turin is the biggest of the country and it supplies 550.000 people (62% of the whole city population).
Latvia In Latvia, district heating is used in major cities such as
Riga,
Daugavpils,
Liepāja,
Jelgava. The first district heating system was constructed in Riga in 1952. Each major city has a local company responsible for the generation, administration, and maintenance of the district heating system.
Netherlands District heating is used in
Rotterdam,
Amsterdam,
Utrecht, and
Almere with more expected as the government has mandated a transition away from natural gas for all homes in the country by 2050. The town of Heerlen has developed a grid using water in disused coalmines as a source and storage for heat and cold. This is a good example of a 5th generation heating and cooling grid The three BEG production plants use natural gas as a fuel source. There is also one cogeneration plant TE-TO AD Skopje producing heat delivered to the Skopje district heating system. The share of cogeneration in DH production was 47% in 2017. The distribution and supply of district heating is carried out by companies owned by BEG. Heat is provided primarily by combined heat and power plants, most of which burn hard coal. The largest district heating system is in Warsaw, owned and operated by Veolia Warszawa, distributing approx. 34 PJ annually.
Romania The largest district heating system in
Romania is in
Bucharest. Owned and operated by RADET, it distributes approximately 24 PJ annually, serving 570 000 households. This corresponds to 68% of Bucharest's total domestic heat requirements (RADET fulfills another 4% through single-building boiler systems, for a total of 72%).
Russia , Russia In most Russian cities, district-level combined heat and power plants () produce more than 50% of the nation's electricity and simultaneously provide hot water for neighbouring city blocks. They mostly use coal- and
gas-powered
steam turbines for cogeneration of heat. Now,
combined cycle gas turbines designs are beginning to be widely used as well.
Serbia In
Serbia, district heating is used throughout the main cities, particularly in the capital,
Belgrade. The first district heating plant was built in 1961 as a means to provide effective heating to the newly built suburbs of
Novi Beograd. Since then, numerous plants have been built to heat the ever-growing city. They use natural gas as fuel, because it has less of an effect on the environment. The district heating system of Belgrade possesses 112 heat sources of 2,454 MW capacity, over 500 km of pipeline, and 4,365 connection stations, providing district heating to 240,000 apartments and 7,500 office/commercial buildings of total floor area exceeding 17,000,000 square meters.
Slovenia The first district heating network in Slovenia and Yugoslavia began to be implemented on November 29, 1959, from the newly built network fed from the
Velenje Thermal Power Plant for the needs of the new city center of Velenje. In Slovenia, coverage with district heating systems is 22%, or only 47 out of 210 municipalities have district heating systems. The largest coverage with the district heating system and the lowest price is in Velenje, where all city facilities are connected, so there are no local or individual fireplaces. The prices of MWh of district heat in Slovenia in 2010 ranged between EUR 25 and EUR 93. The largest district heating systems in Slovenia are in Velenje - Šalek Valley and
Ljubljana. The total Slovenian installed production and distribution thermal power of all heating systems amounts to 1.7 GW.
Slovakia Slovakia's centralised heating system covers more than 54% of the overall demand for heat. In 2015 approximately 1.8 million citizens, 35% of the total population of Slovakia, were served by district heating. The infrastructure was built mainly during the 1960s and 1980s. In recent years large investments were made to increase the share of renewable energy sources and energy efficiency in district heating systems. The heat production comes mostly from natural gas and biomass sources, and 54% of the heat in district heating is generated through cogeneration. In terms of the market structure, there were 338 heat suppliers licensed to produce and/or distribute heat in 2016, of which 87% were both producers and distributors. Most are small companies that operate in a single municipality, but some large companies such as Veolia are also present in the market. The state owns and operates large co-generation plants that produce district heat and electricity in six cities (Bratislava, Košice, Žilina, Trnava, Zvolen and Martin). Multiple companies can operate in one city, which is the case in larger cities. A large share of DH is produced by small natural gas heat boilers connected to blocks of buildings. In 2014, nearly 40% of the total DH generation was from natural gas boilers, other than co-generation.
Sweden Sweden has a long tradition for using district heating (fjärrvärme) in urban areas. In 2015, about 60% of Sweden's houses (private and commercial) were heated by district heating, according to the Swedish association of district heating. The city of
Växjö reduced its emissions from fossil fuels by 34% from 1993 to 2009. This was to achieved largely by way of biomass fired district heating. Another example is the plant of
Enköping, combining the use of short rotation plantations both for fuel as well as for phytoremediation. In 2024, 46% of the heat generated in Swedish district heating systems was produced with renewable
bioenergy sources, as well as 22% in
waste-to-energy plants, 7% was provided by heat pumps, 11% by
flue-gas condensation and 8% by industrial
waste heat recovery. 3% was generated from grid electricity. The remaining was produced by fossil fuels (2%) and
peat (0.3%) Because of the law banning traditional
landfills, waste is commonly used as a fuel.
Ukraine district heating is mainly gas-fired and inefficient - there is a national strategy to improve it. Gas heats water which is circulated. There is district heating in
Kyiv. The district heating is vulnerable to winter
Russian strikes which cause
energy crises.
United Kingdom Estate,
Pimlico, London. This plant once used waste heat piped from
Battersea Power Station on the other side of the
River Thames. (January 2006) In the United Kingdom, district heating became popular after World War II, but on a restricted scale, to heat the large residential estates that replaced dwellings destroyed by the
Blitz. In 2013 there were 1,765 district heating schemes, with 920 based in London alone. In total around 210,000 homes and 1,700 businesses are supplied by heat networks in the UK. The
Pimlico District Heating Undertaking (PDHU) in London first became operational in 1950 and continues to expand to this day. The PDHU once relied on waste heat from the now-disused
Battersea Power Station on the south side of the
River Thames. It is still in operation; the water is now heated locally by a new energy centre which incorporates 3.1
MWe / 4.0
MWth of gas fired CHP engines and 3 × 8 MW gas-fired boilers. One of the United Kingdom's largest district heating schemes is EnviroEnergy in
Nottingham. The plant, initially built by
Boots, is now used to heat 4,600 homes, and a wide variety of business premises, including the
Concert Hall, the
Nottingham Arena, the Victoria Baths, the
Broadmarsh Shopping Centre, the
Victoria Centre, and others. The heat source is a
waste-to-energy incinerator.
Sheffield's district heating network was established in 1988 and is still expanding today. It saves an equivalent 21,000 plus tonnes of CO2 each year when compared to conventional sources of energy – electricity from the national grid and heat generated by individual boilers. There are currently over 140 buildings connected to the district heating network. These include city landmarks such as the
Sheffield City Hall, the
Lyceum Theatre, the
University of Sheffield,
Sheffield Hallam University, hospitals, shops, offices and leisure facilities plus 2,800 homes. More than 44 km of underground pipes deliver energy which is generated at
Sheffield Energy Recovery Facility. This converts 225,000 tonnes of waste into energy, producing up to 60 MWe of thermal energy and up to 19 MWe of electrical energy. The
Southampton District Energy Scheme was originally built to use just geothermal energy, but now also uses the heat from a gas-fired CHP generator. It supplies heating and
district cooling to many large premises in the city, including the
Westquay shopping centre, the De Vere Grand Harbour hotel, the
Royal South Hants Hospital, and several housing schemes. In the 1980s
Southampton began to use combined heat and power district heating, taking advantage of geothermal heat "trapped" in the area. The geothermal heat provided by the well works in conjunction with the Combined Heat and Power scheme. Geothermal energy provides 15–20%,
fuel oil 10%, and natural gas 70% of the total heat input for this scheme and the combined heat and power generators use conventional fuels to make electricity. "Waste heat" from this process is recovered for distribution through the 11 km mains network. Scotland has several district heating systems. The first in the UK was installed at
Aviemore, and others followed at
Lochgilphead,
Fort William and Forfar.
Lerwick District Heating Scheme in Shetland is of note because it is one of the few schemes where a completely new system was added to a previously existing small town.
ADE has an online map of district heating installations in the UK. ADE estimates that 54 percent of energy used to produce electricity is being wasted via conventional power production, which relates to £9.5 billion ($US12.5 billion) per year. In the United Kingdom, the Heat Network Technical Assurance Scheme (HNTAS) is a regulatory framework being developed to establish minimum technical standards and an assurance process for heat networks. The scheme, underpinned by powers in the Energy Act 2023, is intended to require compliant heat networks to demonstrate that they meet mandated technical requirements throughout their lifecycle, covering design, installation, operation, and performance monitoring. HNTAS includes a structured assessment and certification system, with draft technical specifications and procedures published by the Department for Energy Security and Net Zero to support implementation. It is designed to improve the reliability, efficiency, and transparency of heat networks, and will apply to networks ranging from small communal systems to larger district heating schemes. DMS can advise.
North America In North America, district heating systems fall into two general categories. Those that are owned by and serve the buildings of a single entity are considered institutional systems. All others fall into the commercial category.
Canada District Heating is becoming a growing industry in Canadian cities, with many new systems being built in the last ten years. Some of the major systems in Canada include: • Calgary:
ENMAX currently operates the Calgary Downtown District Energy Centre which provides heating to up to of new and existing residential and commercial buildings. The District Energy Centre began operations in March 2010 providing heat to its first customer, the City of Calgary Municipal building. •
Edmonton: The community of
Blatchford, which is currently being developed on the grounds of Edmonton's former
City Centre Airport, is launching a District Energy Sharing System (DESS) in phases. A geo-exchange field went online in 2019, and Blatchford's energy utility is in the planning and design phase for a sewage heat exchange system. • Montreal has a district heating and cooling system in the downtown core. •
Toronto: •
Enwave provides district heating and cooling within the downtown core of
Toronto, including deep lake cooling technology, which circulates cold water from Lake Ontario through heat exchangers to provide cooling for many buildings in the city. •
Creative Energy is constructing a combined-heat-and-power district energy system for the
Mirvish Village development. •
Surrey: Surrey City Energy owned by the city, provides district heating to the city's
City Centre district. •
Vancouver: •
Creative Energy's Beatty Street facility has operated since 1968 and provides a central heating plant for the city's downtown core of
Vancouver. In addition to heating 180 buildings, the Central Heat Distribution network also drives a
steam clock. Work is currently underway to move the facility from natural gas to electric equipment. • A large scale district heating system known as the Neighbourhood Energy Utility in the South East False Creek area is in initial operations with natural gas boilers and serves the 2010 Olympic Village. The untreated sewage heat recovery system began operations in January 2010, supplying 70% of annual energy demands, with retrofit work underway to move the facility off its remaining natural gas use. • Windsor, Ontario has a district heating and cooling system in the downtown core. •
Drake Landing Solar Community, AB, is small in size (52 homes) but notable for having the only central solar heating system in North America. • London, Ontario and Charlottetown, PEI have district heating co-generation systems owned and operated by
Veresen. •
Sudbury, Ontario has a district heating cogeneration system in its downtown core, as well as a standalone cogeneration plant for the
Sudbury Regional Hospital. In addition, Naneff Gardens, a new residential subdivision off Donnelly Drive in the city's
Garson neighbourhood, features a geothermal district heating system using technology developed by a local company, Renewable Resource Recovery Corporation. • Ottawa, contains a significant district heating and cooling system serving the large number of federal government buildings in the city. The system loop contains nearly of chilled or heated water at any time. • Cornwall, Ontario operates a district heating system which serves a number of city buildings and schools. •
Markham, Ontario: Markham District Energy operates several district heating sites: • Warden Energy Centre (c. 2000), Clegg Energy Centre and Birchmount Energy Centre serving customers in the Markham Centre area • Bur Oak Energy Centre (c. 2012) serving customers in the Cornell Centre area Many Canadian universities operate central campus heating plants.
United States , approximately 2,500 district heating and cooling systems existed in the United States, in one form or another, with the majority providing heat. •
Consolidated Edison of
New York (Con Ed) operates the New York City steam system, the largest commercial district heating system in the United States. The system has operated continuously since March 3, 1882, and serves
Manhattan Island from the Battery through 96th Street. In addition to providing space- and water-heating, steam from the system is used in numerous restaurants for food preparation, for process heat in laundries and dry cleaners, for steam sterilization, and to power
absorption chillers for
air conditioning. On July 18, 2007, one person was killed and numerous others injured when a
steam pipe exploded on 41st Street at Lexington. On August 19, 1989, three people were killed in an
explosion in Gramercy Park. •
Milwaukee,
Wisconsin, has been using district heating for its
central business district since the
Valley Power Plant commenced operations in 1968. The air quality in the immediate vicinity of the plant, has been measured with significantly reduced ozone levels. The 2012 conversion of the plant, which changed the fuel input from coal to natural gas, is expected to further improve air quality at both the local César Chavez sensor as well as
Antarctic sensors The Wisconsin power plants double as breeding grounds for
peregrine falcons. • Denver's district steam system is the oldest continuously operated commercial district heating system in the world. It began service November 5, 1880, and continues to serve 135 customers. •
Seattle Steam Company, a district system operated by Enwave, in Seattle. Enwave also operates district heat system in
Chicago,
Houston,
Las Vegas,
Los Angeles,
New Orleans, and
Portland along with additional Canadian cities. • Detroit Thermal operates a district system in
Detroit that started operation at the
Willis Avenue Station in 1903, originally operated by Detroit Edison. • Citizens Energy Group in
Indianapolis,
Indiana, operates the
Perry K. Generating Station, a
gas-fired power plant that produces and distributes steam to about 160 downtown Indianapolis customers. •
Lansing Board of Water & Light, a municipal utility system in
Lansing, Michigan operates a steam and chilled water system with the steam coming from the natural gas-fired REO Cogeneration Plant and the chilled water coming from the dedicated Roy E. Peffley Chilled Water Plant. • Cleveland Thermal operates a district steam (since 1894) from the Canal Road plant near The Flats and district cooling system (since 1993) from Hamilton Avenue plant on the bluffs east of downtown. •
Veresen operates district heating/co-generation plants in
Ripon, California, and
San Gabriel, California. • Veolia Energy, a successor of the 1887 Boston Heating Company, operates a district system in
Boston and
Cambridge, Massachusetts, and operates systems in Philadelphia PA, Baltimore MD, Kansas City MO, Tulsa OK, Houston TX and other cities. • District Energy St. Paul operates the largest hot water district heating system in North America and generates the majority of its energy from an adjacent biomass-fueled combined heat and power plant. In March 2011, a 1 MWh thermal solar array was integrated into the system, consisting of 144 20' x 8' solar panels installed on the roof of a customer building, RiverCentre. • The California Department of General Services runs a central plant providing district heating to four million square feet in 23 state-owned buildings, including the State Capitol, using high-pressure steam boilers. • BPU of Jamestown NY operates a second generation water district heating system. It was put into operation in 1984, runs from the BPU electrical plant and provides heat to the business district at Fahrenheit. Historically, district heating was primarily used in urban areas of the US, but by 1985, it was mainly used in institutions. A handful of smaller municipalities in
New England maintained municipal steam into the 21st century, in cities like
Holyoke, Massachusetts and
Concord, New Hampshire, however the former would end service in 2010 and the latter in 2017, attributing aging infrastructure and capital expenses to their closures. In 2019, Concord replaced a number of remaining pipes with more efficient ones for a smaller steam system heating only the
State House and
State Library, mainly due to historic preservation reasons rather than a broader energy plan. Heating Plant District heating is also used on many college campuses, often in combination with district cooling and electricity generation. Colleges using district heating include the
University of Texas at Austin;
Rice University;
Brigham Young University;
Georgetown University;
Cornell University, which also employs
deep water source cooling using the waters of nearby
Cayuga Lake;
Purdue University;
University of Massachusetts Amherst;
University of Maine at Farmington;
University of Notre Dame;
Michigan State University;
Eastern Michigan University;
Case Western Reserve University;
Iowa State University;
University of Delaware;
University of Maryland, College Park ,
University of Wisconsin–Madison,
University of Georgia,
University of Cincinnati,
North Carolina State University, University of North Carolina Chapel Hill, Duke University, and several campuses of the
University of California. MIT installed a cogeneration system in 1995 that provides electricity, heating and cooling to 80% of its campus buildings. The
University of New Hampshire has a cogeneration plant run on
methane from an adjacent landfill, providing the university with 100% of its heat and power needs without burning oil or natural gas. North Dakota State University (NDSU) in Fargo, North Dakota has used district heating for over a century from their coal-fired heating plant.
Asia Japan 87 district heating enterprises are operating in Japan, serving 148 districts. Many companies operate district cogeneration facilities that provide steam and/or hot water to many of the office buildings. Also, most operators in the
Greater Tokyo serve district cooling.
China In southern
China (south of the
Qinling–Huaihe Line), there are nearly no district heating systems. In northern China, district heating systems are common. Most district heating systems are just for heating by burning
hard coal instead of
CHP. Since
air pollution in China has become quite serious, many cities gradually are now using natural gas rather than coal in district heating system. There is also some amount of geothermal heating and sea heat pump systems. In February 2019, China's
State Power Investment Corporation (SPIC) signed a cooperation agreement with the
Baishan municipal government in
Jilin province for the Baishan Nuclear Energy Heating Demonstration Project, which would use a
China National Nuclear Corporation DHR-400 (District Heating Reactor 400 MWt). Building cost is 1.5 billion yuan ($230 million), taking three years to build.
Turkey Geothermal energy in Turkey provides some district heating, and residential district heating and cooling requirements have been mapped. ==Market penetration==