Sustainable community energy system

Last updated March 15, 2024

A sustainable community energy system is an integrated approach to supplying a local community with its energy requirements from renewable energy or high-efficiency co-generation energy sources. The approach can be seen as a development of the distributed generation concept.

Such systems are based on a combination of district heating, district cooling, plus 'electricity generation islands' that are interlinked via a private wire electricity system (largely bypassing the normal power grid to cut transmission losses and charges, as well as increasing the robustness of the system). The surplus from one generating island can therefore be used to make up the deficit at another.

Energy communities

Energy communities represent a promising approach designed to encourage localized generation and utilization of energy resources, crucial for achieving the objectives of the ongoing energy transition.^[1] This emerging concept not only facilitates the transition towards sustainable energy but also encourages active engagement from community members. They are recognized as an integral part of creating a sustainable energy system by the European Union, which also included them in the Clean Energy Package and other energy regulations, such as the Renewable Energy Directive.^[2]

Energy communities are any collaboration of citizens and other entities, such as municipalities, companies, energy providers, network operators, NGOs, etc., with the joint aim to contribute to energy system transformation by involving multiple actors in a participatory manner, and by aiming to create benefits for all involved parties (and potentially for society at large).

The benefits of energy communities vary. Most commonly, they are associated with the environmental benefits and benefits for their members, which are often linked to financial savings. Additionally, they also benefit the larger society with the promotion of sustainable energy practices and active citizen participation. Local communities also benefit from energy communities, for example by creation of jobs.^[3]

In 2023, the number of energy community sites in Europe alone reached approximately 3,500. This trend has also gained momentum globally, with similar initiatives emerging in other regions. For instance, the United States has seen the establishment of around 100 sites, while New Zealand has initiated approximately 9 sites.^[1]

United Kingdom

In the United Kingdom, the first sustainable community energy system was pioneered by Woking Borough Council, starting in 1991. The system uses traditional and phosphoric acid fuel cell ^[4] co-generation plants, thermal storage, heat fired absorption cooling and photovoltaics, to supply both residential and non-residential customers, as well as the Council's own facilities.^[5] By end of 2005 there were over 60 generating islands in the borough.^{[ citation needed ]}

Despite the investment in the plant, the system delivers cheaper energy than can be supplied from the traditional brown energy suppliers, helping to tackle fuel poverty. It is part of a plan to cut local carbon dioxide emissions by 80% by 2050. Their initiatives won the Council the Queen's Award for Enterprise in 2001.^[5]

Germany

In 1997, people of Wildpoldsried, in some cases acting as individuals, began a series of projects that produce renewable energy. The first efforts were wind turbines and biomass digesters for cogeneration of heat and power. In the time since, new work has included a number of energy conservation projects, more wind and biomass use, small hydro plants, photovoltaic panels on private houses, and district heating. Tied to this are ecological flood control and wastewater systems.

Today, the effects of this are an unforeseen level of prosperity resulting in construction of nine new community buildings, including a school, gymnasium, and community hall, complete with solar panels. There are three companies operating four biogas digesters with a fifth under construction. There are seven windmills with two more on the way. One hundred and ninety private households are equipped with solar, which pays them dividends. The district heating network has 42 connections. There are three small hydro power plants. Wildpoldsried now produces 321 percent more energy than it needs and is generating 4.0 million Euro in annual revenue. At the same time, there has been a 65% reduction in the town’s carbon footprint.^[6]

Related Research Articles

Distributed generation, also distributed energy, on-site generation (OSG), or district/decentralized energy, is electrical generation and storage performed by a variety of small, grid-connected or distribution system-connected devices referred to as distributed energy resources (DER).

Off-the-grid or off-grid is a characteristic of buildings and a lifestyle designed in an independent manner without reliance on one or more public utilities. The term "off-the-grid" traditionally refers to not being connected to the electrical grid, but can also include other utilities like water, gas, and sewer systems, and can scale from residential homes to small communities. Off-the-grid living allows for buildings and people to be self-sufficient, which is advantageous in isolated locations where normal utilities cannot reach and is attractive to those who want to reduce environmental impact and cost of living. Generally, an off-grid building must be able to supply energy and potable water for itself, as well as manage food, waste and wastewater.

Microgeneration is the small-scale production of heat or electric power from a "low carbon source," as an alternative or supplement to traditional centralized grid-connected power.

<span class="mw-page-title-main">Renewable energy in the European Union</span>

Renewable energy progress in the European Union (EU) is driven by the European Commission's 2023 revision of the Renewable Energy Directive, which raises the EU's binding renewable energy target for 2030 to at least 42.5%, up from the previous target of 32%. Effective since November 20, 2023, across all EU countries, this directive aligns with broader climate objectives, including reducing greenhouse gas emissions by at least 55% by 2030 and achieving climate neutrality by 2050. Additionally, the Energy 2020 strategy exceeded its goals, with the EU achieving a 22.1% share of renewable energy in 2020, surpassing the 20% target.

<span class="mw-page-title-main">Hybrid power</span> Combinations between different technologies to generate electric power

Hybrid power are combinations between different technologies to produce power.

Dispatchable generation refers to sources of electricity that can be programmed on demand at the request of power grid operators, according to market needs. Dispatchable generators may adjust their power output according to an order. Non-dispatchable renewable energy sources such as wind power and solar photovoltaic (PV) power cannot be controlled by operators. Other types of renewable energy that are dispatchable without separate energy storage are hydroelectric, biomass, geothermal and ocean thermal energy conversion.

Renewable energy in Germany is mainly based on wind and biomass, plus solar and hydro. Germany had the world's largest photovoltaic installed capacity until 2014, and as of 2023 it has over 82 GW. It is also the world's third country by installed total wind power capacity, 64 GW in 2021 and second for offshore wind, with over 7 GW. Germany has been called "the world's first major renewable energy economy".

Renewable energy commercialization involves the deployment of three generations of renewable energy technologies dating back more than 100 years. First-generation technologies, which are already mature and economically competitive, include biomass, hydroelectricity, geothermal power and heat. Second-generation technologies are market-ready and are being deployed at the present time; they include solar heating, photovoltaics, wind power, solar thermal power stations, and modern forms of bioenergy. Third-generation technologies require continued R&D efforts in order to make large contributions on a global scale and include advanced biomass gasification, hot-dry-rock geothermal power, and ocean energy. In 2019, nearly 75% of new installed electricity generation capacity used renewable energy and the International Energy Agency (IEA) has predicted that by 2025, renewable capacity will meet 35% of global power generation.

The electricity policy of Ontario refers to plans, legislation, incentives, guidelines, and policy processes put in place by the Government of the Province of Ontario, Canada, to address issues of electricity production, distribution, and consumption. Policymaking in the electricity sector involves economic, social, and environmental considerations. Ontario's electricity supply outlook is projected to deteriorate in the near future due to increasing demand, aging electricity supply infrastructure, and political commitments, particularly the phase-out of coal-fired generation. Policymakers are presented with a range of policy choices in addressing the situation, both in terms of overall system design and structure, and specific electricity generating technologies.

For solar power, South Asia has the ideal combination of both high solar insolation and a high density of potential customers.

According to data from the US Energy Information Administration, renewable energy accounted for 8.4% of total primary energy production and 21% of total utility-scale electricity generation in the United States in 2022.

Renewable energy in the United Kingdom contributes to production for electricity, heat, and transport.

Renewable energy in Finland increased from 34% of the total final energy consumption (TFEC) in 2011 to 48% by the end of 2021, primarily driven by bioenergy (38%), hydroelectric power (6.1%), and wind energy (3.3%). In 2021, renewables covered 53% of heating and cooling, 39% of electricity generation, and 20% of the transport sector. By 2020, this growth positioned Finland as having the third highest share of renewables in TFEC among International Energy Agency (IEA) member countries.

The environmental benefits of renewable energy technologies are widely recognised, but the contribution that they can make to energy security is less well known. Renewable technologies can enhance energy security in electricity generation, heat supply, and transportation. Since renewable energy is more evenly distributed than fossil fuels at the global level, the use of renewable energy technologies can also lead to decentralized and self-sufficient energy systems and reduce energy dependencies among countries.

Renewable energy in Canada represented 17.3% of the Total Energy Supply (TES) in 2020, following natural gas at 39.1% and oil at 32.7% of the TES.

Ethiopia generates most of its electricity from renewable energy, mainly hydropower.

Denmark is a leading country in renewable energy production and usage. Renewable energy sources collectively produced 75% of Denmark's electricity generation in 2022, and are expected to provide 100% of national electric power production from 2030. Including energy use in the heating/cooling and transport sectors, Denmark is expected to reach 100% renewable energy in 2050, up from the 34% recorded in 2021.

Biofuels play a major part in the renewable energy strategy of Denmark. Denmark is using biofuel to achieve its target of using 100% renewable energy for all energy uses by 2050. Biofuels provide a large share of energy sources in Denmark when considering all sectors of energy demand. In conjunction with Denmark's highly developed renewable energy resources in other areas, biofuels are helping Denmark meet its ambitious renewable energy targets.

Renewable energy in South Africa is energy generated in South Africa from renewable resources, those that naturally replenish themselves—such as sunlight, wind, tides, waves, rain, biomass, and geothermal heat. Renewable energy focuses on four core areas: electricity generation, air and water heating/cooling, transportation, and rural energy services. The energy sector in South Africa is an important component of global energy regimes due to the country's innovation and advances in renewable energy. South Africa's greenhouse gas (GHG) emissions is ranked as moderate and its per capita emission rate is higher than the global average. Energy demand within the country is expected to rise steadily and double by 2025.

California produces more renewable energy than any other state in the United States except Texas. In 2018, California ranked first in the nation as a producer of electricity from solar, geothermal, and biomass resources and fourth in the nation in conventional hydroelectric power generation. As of 2017, over half of the electricity (52.7%) produced was from renewable sources.

References

1 2 Barabino, Edoardo; Fioriti, Davide; Guerrazzi, Emanuele; Mariuzzo, Ivan; Poli, Davide; Raugi, Marco; Razaei, Ehsan; Schito, Eva; Thomopulos, Dimitri (2023-12-01). "Energy Communities: A review on trends, energy system modelling, business models, and optimisation objectives". Sustainable Energy, Grids and Networks. 36: 101187. doi:10.1016/j.segan.2023.101187. ISSN 2352-4677.
↑ Mlinarič, Maša; Barnes, Jacob; Kovač, Nina; Bocken, Nancy (2019-12-31). "NEWCOMERS: Typology of new clean energy communities".{{cite journal}}: Cite journal requires |journal= (help)
↑ "Community Energy: A practical guide to reclaiming power". Friends of the Earth Europe. Retrieved 2022-07-04.
↑ "Woking Park Fuel Cell CHP" (PDF). Woking Borough Council. 2004. Archived from the original (PDF) on 11 September 2006 – via Internet Archive.
1 2 "Energetic Council Wins Queen's Award". Woking Borough Council. 23 April 2001. Archived from the original on 2 January 2007 – via Internet Archive.
↑ "German Village Achieves Energy Independence … And Then Some". BioCycle. August 2011.

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[:1-1] 1 2 Barabino, Edoardo; Fioriti, Davide; Guerrazzi, Emanuele; Mariuzzo, Ivan; Poli, Davide; Raugi, Marco; Razaei, Ehsan; Schito, Eva; Thomopulos, Dimitri (2023-12-01). "Energy Communities: A review on trends, energy system modelling, business models, and optimisation objectives". Sustainable Energy, Grids and Networks. 36: 101187. doi:10.1016/j.segan.2023.101187. ISSN 2352-4677.

[2] Mlinarič, Maša; Barnes, Jacob; Kovač, Nina; Bocken, Nancy (2019-12-31). "NEWCOMERS: Typology of new clean energy communities".{{cite journal}}: Cite journal requires |journal= (help)

[3] "Community Energy: A practical guide to reclaiming power". Friends of the Earth Europe. Retrieved 2022-07-04.

[4] "Woking Park Fuel Cell CHP" (PDF). Woking Borough Council. 2004. Archived from the original (PDF) on 11 September 2006 – via Internet Archive.

[:0-5] 1 2 "Energetic Council Wins Queen's Award". Woking Borough Council. 23 April 2001. Archived from the original on 2 January 2007 – via Internet Archive.

[6] "German Village Achieves Energy Independence … And Then Some". BioCycle. August 2011.

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