District heating

Animated image showing how district heating works
Biomass fired district heating power plant in Mödling, Austria
Coal heating plant in Wieluń (Poland)
The cancelled Russian Gorky Nuclear Heating Plant in Fedyakovo, Nizhny Novgorod Oblast

District heating (also known as heat networks or teleheating) is a system for distributing heat generated in a centralized location for residential and commercial heating requirements such as space heating and water heating. The heat is often obtained from a cogeneration plant burning fossil fuels but increasingly also biomass, although heat-only boiler stations, geothermal heating, heat pumps and central solar heating are also used, as well as nuclear power. District heating plants can provide higher efficiencies and better pollution control than localized boilers. According to some research, district heating with combined heat and power (CHPDH) is the cheapest method of cutting carbon emissions, and has one of the lowest carbon footprints of all fossil generation plants.[1] CHPDH is being developed in Denmark as a store for renewable energy, particularly wind energy, that exceeds instantaneous grid demand via the use of heat pumps and thermal stores.

Heat generation

Heat sources in use for various district heating systems include: power plants designed for combined heat and power (CHP, also called co-generation), including both combustion and nuclear power plants; and simple combustion of a fossil fuel or biomass; geothermal heat; solar heat; industrial heat pumps which extract heat from seawater, river or lake water, sewage, or waste heat from industrial processes.

District heat from combined heat and power or simple combustion

The core element of many district heating systems is a heat-only boiler station. Additionally a cogeneration plant (also called combined heat and power, CHP) is often added in parallel with the boilers. Both have in common that they are typically based on combustion of primary energy carriers. The difference between the two systems is that, in a cogeneration plant, heat and electricity are generated simultaneously, whereas in heat-only boiler stations – as the name suggests – only heat is generated.

In the case of a fossil fueled cogeneration plant, the heat output is typically sized to meet half of the peak heat load but over the year will provide 90% of the heat supplied. The boiler capacity will be able to meet the entire heat demand unaided and can cover for breakdowns in the cogeneration plant. It is not economic to size the cogeneration plant alone to be able to meet the full heat load. In the New York City steam system, that is around 2.5 GW.[2][3] Germany has the largest amount of CHP in Europe.[4]

The combination of cogeneration and district heating is very energy efficient. A simple thermal power station can be 20–35% efficient,[5] whereas a more advanced facility with the ability to recover waste heat can reach total energy efficiency of nearly 80%.[5] Some may exceed 100% based on the lower heating value by condensing the flue gas as well.[6]

Waste heat from nuclear power plants is sometimes used for district heating. The principles for a conventional combination of cogeneration and district heating applies the same for nuclear as it does for a thermal power station. Russia has several cogeneration nuclear plants which together provided 11.4 PJ of district heat in 2005. Russian nuclear district heating is planned to nearly triple within a decade as new plants are built.[7]

Other nuclear-powered heating from cogeneration plants are in the Ukraine, the Czech Republic, Slovakia, Hungary, Bulgaria, and Switzerland, producing up to about 100 MW per power station. One use of nuclear heat generation was with the Ågesta Nuclear Power Plant in Sweden closed in 1974.

In Switzerland, the Beznau Nuclear Power Plant provides heat to about 20,000 people.[8]

Geothermal-sourced district heat

History

Geothermal district heating was used in Pompeii, and in Chaudes-Aigues since the 14th Century.[9]

United States

Direct use geothermal district heating systems, which tap geothermal reservoirs and distribute the hot water to multiple buildings for a variety of uses, are uncommon in the United States, but have existed in America for over a century.

In 1890, the first wells were drilled to access a hot water resource outside of Boise, Idaho. In 1892, after routing the water to homes and businesses in the area via a wooden pipeline, the first geothermal district heating system was created.

As of a 2007 study,[10] there were 22 geothermal district heating systems (GDHS) in the United States. As of 2010, two of those systems have shut down.[11] The table below describes the 20 GDHS currently operational in America.

System Name City State Startup Year Number of Customers Capacity, MWt Annual Energy Generated, GWh/year System Temperature, °F
Warm Springs Water District Boise ID 1892 275 3.6 8.8 175
Oregon Institute of Technology Klamath Falls OR 1964 1 6.2 13.7 192
Midland Midland SD 1969 12 0.09 0.2 152
College of Southern Idaho Twin Falls ID 1980 1 6.34 14 100
Philip Philip SD 1980 7 2.5 5.2 151
Pagosa Springs Pagosa Springs CO 1982 22 5.1 4.8 146
Idaho Capital Mall Boise ID 1982 1 3.3 18.7 150
Elko Elko NV 1982 18 3.8 6.5 176
Boise City Boise ID 1983 58 31.2 19.4 170
Warren Estates Reno NV 1983 60 1.1 2.3 204
San Bernardino San Bernardino CA 1984 77 12.8 22 128
City of Klamath Falls Klamath Falls OR 1984 20 4.7 10.3 210
Manzanita Estates Reno NV 1986 102 3.6 21.2 204
Elko County School District Elko NV 1986 4 4.3 4.6 190
Gila Hot Springs Glenwood NM 1987 15 0.3 0.9 140
Fort Boise Veteran's Hospital Boise Boise ID 1988 1 1.8 3.5 161
Kanaka Rapids Ranch Buhl ID 1989 42 1.1 2.4 98
In Search Of Truth Community Canby CA 2003 1 0.5 1.2 185
Bluffdale Bluffdale UT 2003 1 1.98 4.3 175
Lakeview Lakeview OR 2005 1 2.44 3.8 206

Solar-sourced district heat

Main article: Central solar heating

Use of solar heat for district heating has been increasing in Denmark and Germany[12] in recent years.[13] The systems usually include interseasonal thermal energy storage for a consistent heat output day to day and between summer and winter. Good examples are in Vojens[14] at 50 MW, Dronninglund at 27 MW and Marstal at 13 MW in Denmark.[15][16] These systems have been incrementally expanded to supply 10% to 40% of their villages' annual space heating needs. The solar-thermal panels are ground-mounted in fields.[17] The heat storage is pit storage, borehole cluster and the traditional water tank. In Alberta, Canada the Drake Landing Solar Community has achieved a world record 97% annual solar fraction for heating needs, using solar-thermal panels on the garage roofs and thermal storage in a borehole cluster.[18][19]

Heat pumps for district heat

Perhaps best illustrated by the Drammen Fjernvarme District Heating project in Norway which produces 14 MW from water at just 8 °C, industrial heat pumps are demonstrated heat sources for district heating networks. Among the ways that industrial heat pumps can be utilized are:

  1. As the primary base load source where water from a low grade source of heat, e.g. a river, fjord, data center, power station outfall, sewage treatment works outfall (all typically between 0 ˚C and 25 ˚C), is boosted up to the network temperature of typically 60 ˚C to 90 ˚C using heat pumps. These devices, although consuming electricity, will transfer a heat output three to six times larger than the amount of electricity consumed. An example of a district system using a heat pump to source heat from raw sewage is in Oslo, Norway that has a heat output of 18 MW(thermal).[20]
  2. As a means of recovering heat from the cooling loop of a power plant to increase either the level of flue gas heat recovery (as the district heating plant return pipe is now cooled by the heat pump) or by cooling the closed steam loop and artificially lowering the condensing pressure and thereby increasing the electricity generation efficiency.
  3. As a means of cooling flue gas scrubbing working fluid (typically water) from 60 ˚C post-injection to 20 ˚C pre-injection temperatures. Heat is recovered using a heat pump and can be sold and injected into the network side of the facility at a much higher temperature (e.g. about 80 ˚C).
  4. Where the network has reached capacity, large individual load users can be decoupled from the hot feed pipe, say 80 ˚C and coupled to the return pipe, at e.g. 40 ˚C. By adding a heat pump locally to this user, the 40 ˚C pipe is cooled further (the heat being delivered into the heat pump evaporator). The output from the heat pump is then a dedicated loop for the user at 40 ˚C to 70 ˚C. Therefore, the overall network capacity has changed as the total temperature difference of the loop has varied from 80–40 ˚C to 80 ˚C–x (x being a value lower than 40 ˚C).

Concerns have existed about the use of hydroflurocarbons as the working fluid (refrigerant) for large heat pumps. Whilst leakage is not usually measured, it is generally reported to be relatively low, such as 1% (compared to 25% for supermarket cooling systems). A 30-megawatt heatpump could therefore leak (annually) around 75 kg of R134a or other working fluid.[21] Given the high global warming potential of some HFCs, this could equate to over 800,000 kilometres (500,000 mi) of car travel per year.

However, recent technical advances allow the use of natural heat pump refrigerants that have very low global warming potential (GWP). CO2 refrigerant (R744, GWP=1) or ammonia (R717, GWP=0) also have the benefit, depending on operating conditions, of resulting in higher heat pump efficiency than conventional refrigerants. An example is a 14 MW(thermal) district heating network in Drammen, Norway which is supplied by seawater-source heatpumps that use R717 refrigerant, and has been operating since 2011. 90 °C water is delivered to the district loop (and returns at 65 °C). Heat is extracted from seawater (from 60-foot (18 m) depth) that is 8 to 9 °C all year round, giving an average coefficient of performance (COP) of about 3.15. In the process the seawater is chilled to 4 °C; however, this resource is not utilized. In a district system where the chilled water could be utilized for air conditioning, the effective COP would be considerably higher.[21]

In the future, industrial heat pumps will be further de-carbonised by using, on one side, excess renewable electrical energy (otherwise spilled due to meeting of grid demand) from wind, solar, etc. and, on the other side, by making more of renewable heat sources (lake and ocean heat, geothermal, etc.). Furthermore, higher efficiency can be expected through operation on the high voltage network.[22]

Excess renewable electrical energy for district heat

With European countries such as Germany and Denmark moving to very high levels (80% and 100% respectively by 2050) of renewable energy for all energy uses there will be increasing periods of excess production of renewable electrical energy. Storage of this energy as potential electrical energy (e.g. pumped hydro) is very costly and reduces total round-trip efficiency. However, storing it as heat in district heating systems, for use in buildings where there is demand, is significantly less costly. Whilst the quality of the electrical energy is degraded, high voltage grid MW sized heat pumps would maximise efficiency whilst not wasting excess renewable electricity.[23]

Heat accumulators and storage

District heating accumulation tower from Theiss near Krems an der Donau in Lower Austria with a thermal capacity of 2 gigawatt-hours (7.2 TJ)

Increasingly large heat stores are being used with district heating networks to maximise efficiency and financial returns. This allows cogeneration units to be run at times of maximum electrical tariff, the electrical production having much higher rates of return than heat production, whilst storing the excess heat production. It also allows solar heat to be collected in summer and redistributed off season in very large but relatively low-cost in-ground insulated reservoirs or borehole systems. The expected heat loss at the 203,000m³ insulated pond in Vojens is about 8%.[14]

Heat distribution

Underground tunnel for heat pipes between Rigshospitalet and Amagerværket in Denmark
Insulated pipes to connect a new building to University of Warwick's campus-wide combined heat and power system
District heating pipe in Tübingen, Germany
District heating substation with a thermal power of 700 kW which insulates the water circuit of the district heating system and the customer's central heating system

After generation, the heat is distributed to the customer via a network of insulated pipes. District heating systems consist of feed and return lines. Usually the pipes are installed underground but there are also systems with overground pipes. Within the system heat storage units may be installed to even out peak load demands.

The common medium used for heat distribution is water or pressurized hot water, but steam is also used. The advantage of steam is that in addition to heating purposes it can be used in industrial processes due to its higher temperature. The disadvantage of steam is a higher heat loss due to the high temperature. Also, the thermal efficiency of cogeneration plants is significantly lower if the cooling medium is high-temperature steam, reducing electric power generation. Heat transfer oils are generally not used for district heating, although they have higher heat capacities than water, as they are expensive, and have environmental issues.

At customer level the heat network is usually connected to the central heating system of the dwellings via heat exchangers (heat substations): the working fluids of both networks (generally water or steam) do not mix. However, direct connection is used in the Odense system.

Typical annual loss of thermal energy through distribution is around 10%, as seen in Norway's district heating network.[24]

Heat metering

The amount of heat provided to customers is often recorded with a heat meter to encourage conservation and maximize the number of customers which can be served, but such meters are expensive. Due to the expense of heat metering, an alternative approach is simply to meter the water – water meters are much cheaper than heat meters, and have the advantage of encouraging consumers to extract as much heat as possible, leading to a very low return temperature, which increases the efficiency of power generation.

Many systems were installed under a socialist economy (such as in the former Eastern Bloc), and these were often not metered. This led to great inefficiencies – users simply opened windows when too hot – wasting energy and minimising the numbers of connectable customers.

Size of systems

District heating systems can vary in size from covering entire cities such as Stockholm or Flensburg with a network of large meter diameter primary pipes linked to secondary pipes – 200 mm diameter perhaps, which in turn link to tertiary pipes of perhaps 25 mm diameter which might connect to 10 to 50 houses.

Some district heating schemes might only be sized to meet the needs of a small village or area of a city in which case only the secondary and tertiary pipes will be needed.

Some schemes may be designed to serve only a limited number of dwellings – 20–50 – in which case only tertiary sized pipes are needed.

Pros and cons

District heating has various advantages compared to individual heating systems. Usually district heating is more energy efficient, due to simultaneous production of heat and electricity in combined heat and power generation plants. This has the added benefit of reducing carbon emissions.[25] The larger combustion units also have a more advanced flue gas cleaning than single boiler systems. In the case of surplus heat from industries, district heating systems do not use additional fuel because they recover heat which would otherwise be dispersed to the environment.

District heating requires a long-term financial commitment that fits poorly with a focus on short-term returns on investment. Benefits to the community include avoided costs of energy through the use of surplus and wasted heat energy, and reduced investment in individual household or building heating equipment. District heating networks, heat-only boiler stations, and cogeneration plants require high initial capital expenditure and financing. Only if considered as long-term investments will these translate into profitable operations for the owners of district heating systems, or combined heat and power plant operators. District heating is less attractive for areas with low population densities, as the investment per household is considerably higher. Also it is less attractive in areas of many small buildings; e.g. detached houses than in areas with a fewer larger buildings; e.g. blocks of flats, because each connection to a single-family house is quite expensive.

Individual heating systems can be completely shutdown intermittently according to local heating demand which is not the case with a district heating system.

Ownership, monopoly issues and charging structures

In many cases large combined heat and power district heating schemes are owned by a single entity. This was typically the case in the old Eastern bloc countries. However, for the majority of schemes, the ownership of the cogeneration plant is separate from the heat using part.

Examples are Warsaw which has such split ownership with PGNiG Termika owning the cogeneration unit, the Dalkia Polska owning 85% of the heat distribution, the rest of the heat distribution is owned by municipality and workers. Similarly all the large CHP/CH schemes in Denmark are of split ownership.

Carbon footprint and cost of reduction

One study shows that district heating with combined heat and power has the potential to be the lowest carbon footprint of any heating system based on combustion, and it rapidly competes with extra insulation. District heating and cooling based on heat sharing networks, seasonal thermal energy storage and electricity from renewable sources powering heat transfer has the potential to be a zero carbon system.[26]

National variation

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.[27] 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."[28] 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.[29] 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.[30]

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.[31] 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.[32]

Austria

The District Heating Power Plant Steyr is a renewable combined heat and power plant in which wood chips are used to generate power [33]

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.

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 Prazska teplarenska, serving 265,000 households and selling c. 13 PJ of heat annually. There are many smaller central heating systems spread around the country.[34]

Denmark

In Denmark district heating covers more than 60% of space heating and water heating.[35] In 2007, 80.5% of this heat was produced by combined heat and power plants. Heat recovered from waste incineration accounted for 20.4% of the total Danish district heat production.[36] In 2013, Denmark imported 158,000 ton waste for incineration.[37] 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.[38] The consumer price of heat from CTR is approximately €49 per MWh plus taxes (2009).[39]

On the island of Samsø, three straw-fueled district heating plants are used (of which one is owned by the Danish energy company NRGi).[40]

Finland

In Finland district heating accounts for about 50% of the total heating market,[41] 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 natural resource. Other 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,[42] producing enough heat to heat approximately 500 large houses.[43]

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.[44]

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.[45]

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.

Geothermal borehole outside the Reykjavik Power Station.

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.[46] 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.[47]

Iceland

With 95% of all housing (mostly in the capital of Reykjavík) enjoying district heating services – mainly from geothermal energy, Iceland is the country with the highest penetration of district heating.

Most of Iceland's district heating comes from three geothermal power plants, producing over 800 MWth:[48]

Ireland

Tralee in Co 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.[49]
In Glenstal Abbey in Co Limerick there exists a pond-based 150 kW heating system for a school.[50]

Italy

A cogeneration thermal power plant in Ferrera Erbognone (PV), Italy

In Italy, district heating is used in some cities (Bergamo, Brescia, Cremona, Bolzano, Ferrara, Imola, Reggio Emilia, Terlan, Turin, Lodi, and now Milan). The district heating of Turin is the biggest of the country and it supplies 550.000 people (55% of the whole city population).

Norway

In Norway district heating only constitutes approximately 2% of energy needs for heating. This is a very low number compared to similar countries. One of the main reasons district heating has a low penetration in Norway is access to cheap hydro-based electricity, and 80% of private electricity consumption goes to heat rooms and water. However, there is district heating in the major cities.

Poland

In 2009, 40% of Polish households used district heating, most of them in urban areas.[51] 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 Dalkia 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

In most Russian cities, district-level combined heat and power plants (ТЭЦ, теплоэлектроцентраль) produce more than 50% of the nation's electricity and simultaneously provide hot water for neighbouring city blocks. They mostly use coal and oil-powered steam turbines for cogeneration of heat. Now, gas turbines and combined cycle designs are beginning to be widely used as well. A Soviet-era approach of using very large central stations to heat large districts of a big city or entire small cities is fading away due to inefficiency, since much heat is lost in the piping network because of leakages and lack of proper thermal insulation.[52]

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 4365 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.

Sweden

Sweden has a long tradition for using teleheating 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.[53] The city of Växjö reduced its fossil fuel consumption by 30% between 1993 and 2006, and aimed for a 50% reduction by 2010. This was to be achieved largely by way of biomass fired teleheating.[54] Another example is the plant of Enköping, combining the use of short rotation plantations both for fuel as well as for phytoremediation.[55]

47% of the heat generated in Swedish teleheating systems are produced with renewable bioenergy sources, as well as 16% in waste-to-energy plants, 7% is provided by heat pumps and 6% by industrial waste heat recovery. The remaining are mostly fossil fuels oil, natural gas, peat, and coal.[56]

Because of the law banning traditional landfills,[57] waste is commonly used as a fuel.

United Kingdom

District heating accumulator tower and workshops on the Churchill Gardens 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 areas devastated by the Blitz. In 2013 there were 1,765 district heating schemes with 920 based in London alone.[58] In total around 210,000 homes and 1,700 businesses are supplied by heat networks in the UK.[59]

The Pimlico District Heating Undertaking (PDHU) 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 now being 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. Scotland has several district heating systems with the first in the UK being installed at Aviemore and others following at Lochgilphead, Fort William and Forfar.

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, Sheffield University, 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's 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.

Lerwick District Heating Scheme is of note because it is one of the few schemes where a completely new system was added to a previously existing small town.

A map of district heating installations can be viewed here.

Spain

The largest district heating system in Spain is located in Soria.[60] It is called "Ciudad del Medio Ambiente" (Environmental Town) and will receive 41 MW from a biomass power plant.

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:

Many Canadian universities operate central campus heating plants.

United States

The Holly Steam Combination Company was the first steam heating company to commercially distribute district heating from a central steam heating system.

The city of Milwaukee, Wisconsin has been using district heating for its central business district since the Valley Power Plant commenced operations in 1968. Amazingly, the air quality in the immediate vicinity of the plant, based on the sensor located on César Chavez Drive, qualifies as the best in Southeastern Wisconsin, at least with regard to ozone concentration. The recent (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 . Interesting to note about Wisconsin power plants is their dual use as breeding grounds for peregrines .

On July 18, 2007, one person was killed and numerous others injured when a steam pipe exploded on 41st Street at Lexington.[68] On August 19, 1989, three people were killed in an explosion in Gramercy Park.[69]

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; Brigham Young University;[76] Georgetown University;[77] Cornell University,[78] which also employs deep water source cooling using the waters of nearby Cayuga Lake;[79] Purdue University;[80] University of Notre Dame; Michigan State University; Case Western Reserve University; Iowa State University; University of Delaware;,[81] University of Maryland, College Park , and several campuses of the University of California.[82] MIT installed a cogeneration system in 1995 that provides electricity, heating and cooling to 80% of its campus buildings.[83] 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.[84] North Dakota State University (NDSU) in Fargo, North Dakota has used district heating for over a century from their coal-fired heating plant.[85]

Asia

Japan

87 district heating enterprises are operating in Japan, serving 148 districts.[86]

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, there are nearly no district heating systems. In northern China, district heating systems are common. most district heating system which are just for heating instead of CHP use hard coal. For 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.

History

District heating traces its roots to the hot water-heated baths and greenhouses of the ancient Roman Empire. District systems gained prominence in Europe during the Middle Ages and Renaissance, with one system in France in continuous operation since the 14th century.[87] The U.S. Naval Academy in Annapolis began steam district heating service in 1853.

Although these and numerous other systems have operated over the centuries, the first commercially successful district heating system was launched in Lockport, New York, in 1877 by American hydraulic engineer Birdsill Holly, considered the founder of modern district heating.

Paris has been using geothermal heating from a 55-70 °C source 1–2 km below the surface since the 1970s for domestic heating.[88]

In the 1980s Southampton began utilising 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.[88][89]

Market penetration

Penetration of district heating (DH) into the heat market varies by country. Penetration is influenced by different factors, including environmental conditions, availability of heat sources, economics, and economic and legal framework.

In the year 2000 the percentage of houses supplied by district heat in some European countries was as follows:

Country Penetration (2000)[90]
Iceland 95%
Denmark 60% (2005)[35]
Estonia 52%
Poland 52%
Sweden 50%
Czech Rep. 49%
Finland 49%
Slovakia 40%
Germany 22% (2014)[91]
Hungary 16%
Austria 12.5%
Netherlands 3%
UK 2%

In Iceland the prevailing positive influence on DH is availability of easily captured geothermal heat. In most Eastern European countries, energy planning included development of cogeneration and district heating. Negative influence in the Netherlands and UK can be attributed partially to milder climate, along with competition from natural gas. The tax on domestic gas prices in the UK is a third of that in France and a fifth of that in Germany.

See also

Footnotes

  1. "Carbon footprints of various sources of heat – CHPDH comes out lowest | Claverton Group". Claverton-energy.com. Retrieved 2011-09-25.
  2. "Newsroom: Steam". ConEdison. Retrieved 2007-07-20.
  3. Bevelhymer, Carl (2003-11-10). "Steam". Gotham Gazette. Retrieved 2007-07-20.
  4. What is cogeneration? COGEN Europe, 2015
  5. 1 2 "DOE – Fossil Energy: How Turbine Power Plants Work". Fossil.energy.gov. Archived from the original on August 12, 2011. Retrieved 2011-09-25.
  6. "Waste-to-Energy CHP Amager Bakke Copenhagen". Retrieved 2015-03-09.
  7. "Nuclear Power in Russia". World-nuclear.org. 2011-09-21. Retrieved 2011-09-25.
  8. SUGIYAMA KEN'ICHIRO (Hokkaido Univ.) et al. /000020060706A0175205.php Nuclear District Heating: The Swiss Experience
  9. Bloomquist, R. Gordon (2001). Geothermal District Energy System Analysis, Design, and Development (PDF). International Summer School. International Geothermal Association. p. 213(1). Retrieved November 28, 2015. Lay summary Stanford University. During Roman times, warm water was circulated through open trenches to provide heating for buildings and baths in Pompeii.
  10. Thorsteinsson, Hildigunnur. "U.S. Geothermal District Heating: Barriers and Enablers" (PDF). Retrieved 25 July 2014.
  11. Lund, John. "The United States of America Country Update 2010" (PDF). Retrieved 25 July 2014.
  12. Schmidt T., Mangold D. (2013). Large-scale thermal energy storage – Status quo and perspectives. First international SDH Conference, Malmö, SE, 9-10th April 2013. Powerpoint.
  13. Wittrup, Sanne (23 October 2015). "Fjernvarmeværker går fra naturgas til sol". Ingeniøren.
  14. 1 2 Wittrup, Sanne (14 June 2015). "Verdens største damvarmelager indviet i Vojens". Ingeniøren.
  15. Holm L. (2012). Long Term Experiences with Solar District Heating in Denmark. European Sustainable Energy Week, Brussels. 18–22 June 2012. Powerpoint.
  16. Current data on Danish solar heat plants (click Vojens in South-West Denmark, then "About the plant")
  17. Dalenbäck, J-O (2012). Large-Scale Solar Heating: State of the Art. Presentation at European Sustainable Energy Week, 18–22 June 2012, Brussels, Belgium.
  18. Wong B., Thornton J. (2013). Integrating Solar & Heat Pumps. Renewable Heat Workshop. (Powerpoint)
  19. Natural Resources Canada, 2012. Canadian Solar Community Sets New World Record for Energy Efficiency and Innovation. 5 Oct. 2012.
  20. Pedersen, S. & Stene, J. (2006). 18 MW heat pump system in Norway utilises untreated sewage as heat source. IEA Heat Pump Centre Newsletter, 24:4, 37–38.
  21. 1 2 Hoffman, & Pearson, D. 2011. Ammonia heat pumps for district heating in Norway 7 – a case study. Presented at Institute of Refrigeration, 7 April, London.
  22. http://setis.ec.europa.eu/system/files/JRCDistrictheatingandcooling.pdf Combined Heat and Power and District Heating report. Joint Research Centre, Petten, under contract to European Commission, DG Energy 2013
  23. DYRELUND Anders,Ramboll,2010. Heat Plan Denmark 2010. .
  24. "Norwegian Water Resources and Energy Directorate" (PDF). Retrieved 2011-09-25.
  25. Dunne, Eimear. "Infographic explaining District Heating Systems". Frontline Energy & Environmental. Retrieved 5 May 2014.
  26. "Balanced Energy Network". Icax.co.uk. Retrieved 2016-03-24.
  27. http://vbn.aau.dk/en/publications/heat-roadmap-europe-2050(306a5052-a882-4af9-a5da-87efa36efeaa).html
  28. "Energy Efficiency Industrial Forum Position Paper: energy efficiency – a vital component of energy security" (PDF).
  29. "COGEN Europe News".
  30. "COGEN Europe: Cogeneration in the European Union's Energy Supply Security" (PDF).
  31. "DEFRA Action in the UK – Combined Heat and Power".
  32. https://ec.europa.eu/transparency/regdoc/rep/1/2016/EN/1-2016-51-EN-F1-1.PDF
  33. http://www.fernwaermesteyr.at/waerme_steyr/page/790213410858496064_790686873558106026~790686753835892434_790686753835892434,de.html
  34. Association for the District Heating of the Czech Republic
  35. 1 2 Kort om elforsyning i Danmark, from the Homepage of Dansk Energi (in Danish). Archived March 2, 2009, at the Wayback Machine.
  36. Danish Energy Statistics 2007 by the Danish Ministry of Energy (in Danish).
  37. Klimaråd: Affaldsimport vil belaste dansk CO2-regnskab 27 November 2015.
  38. Environmentally Friendly District Heating to Greater Copenhagen, publication by CTR I/S (2006)
  39. Prisen på Fjernvarme, price list from the Danish homepage of a Copenhagen district heating provider Københavns Energi
  40. Samsoe heating with straw
  41. District heating in Finland Archived July 22, 2011, at the Wayback Machine.
  42. "In Helsinki". Scientificamerican.com. Retrieved 2011-09-25.
  43. "Underground data center to help heat Helsinki | Green Tech – CNET News". News.cnet.com. 2009-11-29. Retrieved 2011-09-25.
  44. AGFW Branchenreport 2006, by the German Heat and Power Association -AGFW- (in German).
  45. Hungarian census 2011 table 1.2.10 (Hungarian)
  46. About Főtáv (Hungarian)
  47. "History of District Heating in Iceland". Mannvit.com. Retrieved 2011-09-25.
  48. http://www.kerrycoco.ie/en/allservices/environment/energy/thefile,8007,en.pdf
  49. http://www.glenstal.org/monastery/grounds/geothermal-glenstal/
  50. "Zużycie energii w gospodarstwach domowych w 2009 r." [Energy consumption in households in 2009] (PDF) (in Polish). Główny Urząd Statystyczny. 2012-05-28. Retrieved 2013-01-25.
  51. "В Сибири и Якутии ждут подачи тепла". BBC News. January 4, 2008. Retrieved May 1, 2010.
  52. Svensk Fjärrvärme
  53. Municipality of Växjö
  54. Mola-Yudego, B; Pelkonen, P. (2011). "Pulling effects of district heating plants on the adoption and spread of willow plantations for biomass: The power plant In Enköping (Sweden)". Biomass and Bioenergy. 35 (7): 2986–2992. doi:10.1016/j.biombioe.2011.03.040. Retrieved 2012-10-14.
  55. Svensk Fjärrvärme
  56. J.Wawrzynczyk, M. Recktenwald, O. Norrlöw and E. Szwajcer Dey (March 2008). "The role of cation-binding agents and enzymes in solubilisation of sludge" (PDF). Water Research. 42 (6,7): 1555–1562. doi:10.1016/j.watres.2007.11.004. Retrieved 16 April 2013.
  57. "Summary evidence on District Heating Networks in the UK" (PDF). DECC.
  58. "The Future of Heating : Meeting the Challenge" (PDF). DECC.
  59. "NOTICIAS – Bioenergy International España: revista especializada en bioenergía". Bioenergyinternational.es. 2011-01-18. Retrieved 2011-09-25.
  60. "HCE Energy Inc". hamiltonce.com. Retrieved 2015-12-18.
  61. "ENMAX District Energy Centre". ENMAX.com. Retrieved 2015-09-25.
  62. "Neighbourhood Energy Utility". Vancouver.ca. Retrieved 2011-09-25.
  63. "New geothermal technology could cut energy costs". Northern Life, August 12, 2009.
  64. "Con Ed Steam". Energy.rochester.edu. Retrieved 2011-09-25.
  65. "A Brief History of Con Edison". Con Edison. Retrieved 2014-05-04.
  66. "Explosion rocks central New York". BBC News. July 19, 2007. Retrieved May 1, 2010.
  67. Barron, James (July 19, 2007). "Steam Blast Jolts Midtown, Killing One". The New York Times. Retrieved May 1, 2010.
  68. Jan Wagner; Stephen P. Kutska (October 2008). Monica Westerlund, ed. "DENVER'S 128-YEAR-OLD STEAM SYSTEM: "THE BEST IS YET TO COME"". District Energy. 94 (4): 16–20. ISSN 1077-6222.
  69. "TemplatePowerplant". Retrieved 20 July 2010. Plant Description: ... The facility also supplies steam for delivery to Xcel Energy's thermal energy customers in downtown Denver. ... Plant History: Zuni Station was originally built in 1900 and called the LaCombe Plant.
  70. "District energy | combined heat and power plants | NRG Thermal Corporation". Nrgthermal.com. Retrieved 2011-09-25.
  71. Archived August 11, 2010, at the Wayback Machine.
  72. "Theodore Newton Vail and the Boston Heating Company, 1886–1890". Energy.rochester.edu. Retrieved 2010-05-13.
  73. "SACRAMENTO CENTRAL UTILITY PLANT – CASE STUDY" (PDF). Alerton.com. Retrieved 2013-10-25.
  74. http://apmonitor.com/che436/index.php/Main/BYUHeatingPlant
  75. http://sustainability.georgetown.edu/initiatives/carbonfootprint
  76. http://energyandsustainability.fs.cornell.edu/util/heating/production/cep.cfm
  77. http://energyandsustainability.fs.cornell.edu/util/cooling/production/lsc/
  78. https://www.purdue.edu/ees/energy/wade/plantoperation.htm
  79. http://www.facilities.udel.edu/centralplantoperations.aspx
  80. "University of California cogeneration plant gets its power back". Retrieved 2015-12-20.
  81. "MIT students seek to harness waste heat – MIT News Office". Web.mit.edu. 2008-07-24. Retrieved 2011-09-25.
  82. Archived July 4, 2010, at the Wayback Machine.
  83. https://www.ndsu.edu/alphaindex/buildings/Building::371
  84. "平成21年4月現在支部別熱供給事業者: The Japan Heat Service Utilities Associations 2009". Jdhc.or.jp. Retrieved 2011-09-25.
  85. https://pangea.stanford.edu/ERE/pdf/IGAstandard/EGC/szeged/O-8-01.pdf
  86. 1 2 "Structure". 080304 bbm.me.uk
  87. "Geothermie district heating scheme Southampton United Kingdom" (PDF). 080304 energie-cites.org
  88. Sabine Froning (Euroheat & Power): DHC/CHP/RES a smile for the environment, Kiev 2003 Archived February 25, 2009, at the Wayback Machine.
  89. So heizt Deutschland Heute (German)
Wikimedia Commons has media related to District heating.
This article is issued from Wikipedia - version of the 12/3/2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.