{{Short description|System to aggregate and deliver power from distributed power sources}} {{More citations needed|date=February 2024}} {{Infobox technology|name=Virtual power plant|abbreviation=VPP|invented=1997|inventor=Shimon Awerbuch|launch_year=2008}}

A '''virtual power plant''' ('''VPP''') is a system for aggregating distributed energy resources (DERs) to function as a single power plant.<ref>{{Cite thesis |last=Landsbergen|first=Patrick|degree=BSc|date=17 June 2009|title=Feasibility, beneficiality, and institutional compatibility of a micro-CHP virtual power plant in the Netherlands|url=https://repository.tudelft.nl/islandora/object/uuid:ee01fc77-2d91-43bb-83d3-847e787494af/|via=repository.tudelft.nl}}</ref> Operators coordinate these resources to balance supply and demand, provide grid services, and participate in energy markets.<ref name="VPP Bilateral 2015">{{Cite journal |author=Shabanzadeh M |last2=Sheikh-El-Eslami |first2=M-K |last3=Haghifam |first3=P |last4=M-R |date=January 2015 |title=Decision Making Tool for Virtual Power Plants Considering Midterm Bilateral Contracts |journal=3rd Iranian Regional CIRED Conference and Exhibition on Electricity Distribution, at Niroo Research Institute (NRI), Tehran, Iran |volume=3 |issue=3 |pages=1–6 |doi=10.13140/2.1.5086.4969}}</ref><ref name="VPP Robust 2015">{{Cite journal |author=Shabanzadeh M |last2=Sheikh-El-Eslami |first2=M-K |last3=Haghifam |first3=P |last4=M-R |date=October 2015 |title=The design of a risk-hedging tool for virtual power plants via robust optimization approach |journal=Applied Energy |volume=155 |pages=766–777 |doi=10.1016/j.apenergy.2015.06.059 |bibcode=2015ApEn..155..766S }}</ref><ref name="VPP FSD 2017">{{Cite journal |author=Shabanzadeh M |last2=Sheikh-El-Eslami |first2=M-K |last3=Haghifam |first3=P |last4=M-R |date=January 2017 |title=Risk-based medium-term trading strategy for a virtual power plant with first-order stochastic dominance constraints |journal=IET Generation, Transmission & Distribution |volume=11 |issue=2 |pages=520–529 |doi=10.1049/iet-gtd.2016.1072 |s2cid=114478127}}</ref> A VPP typically sells its output to an electric utility.<ref>{{Cite web |last=Zurborg|first=Aaron|date=2010|title=Unlocking Customer Value: the Virtual Power Plant|url=https://www.energy.gov/sites/default/files/oeprod/DocumentsandMedia/ABB_Attachment.pdf|access-date=15 January 2023|website=Energy.gov}}</ref><ref name="VPP Bilateral 2015" /><ref name="VPP Robust 2015" /><ref name="VPP Coalition Forming 2016" /><ref name="VPP FSD 2017" /><ref name="VPP SSD 2016" /> VPPs allow energy resources that are individually too small to be of interest to a utility to aggregate and market their power.<ref name="VPP FSD 2017" />

VPPs typically access dispatchable and non-dispatchable resources, including microCHPs, natural gas-fired reciprocating engines, wind power plants, photovoltaics (PV), run-of-river hydroelectricity, biomass, backup generators, battery energy storage systems (BESS) such as home or vehicle batteries. VPPs can manage demand as well as supply; e.g., heat pumps and other devices can be turned on or off based on available energy supply.<ref>{{cite journal |last1=Lee|first1=Zachary E.|last2=Sun|first2=Qingxuan|last3=Ma|first3=Zhao|last4=Wang|first4=Jiangfeng|last5=MacDonald|first5=Jason S.|last6=Zhang|first6=K. Max|date=Feb 2020|title=Providing Grid Services With Heat Pumps: A Review|journal=Journal of Engineering for Sustainable Buildings and Cities|volume=1|issue=1|article-number=011007|doi=10.1115/1.4045819|s2cid=213898377|doi-access=free}}</ref>

Heterogeneity and numbers reduce dependence on any single resource, improving system stability.<ref>{{Cite thesis |last=Landsbergen |first=Patrick |degree=BSc |date=17 June 2009 |title=Feasibility, beneficiality, and institutional compatibility of a micro-CHP virtual power plant in the Netherlands |url=https://repository.tudelft.nl/islandora/object/uuid:ee01fc77-2d91-43bb-83d3-847e787494af/ |via=repository.tudelft.nl}}</ref>

Vehicle-to-grid allows grid-connected electric vehicles to participate.

Storage-based VPPs ramp faster than thermal generators, e.g., helping grids with high ramp needs avoid the duck curve.

A management system securely controls operations, billing, and payments to power suppliers and consumers.<ref>{{Cite journal |last1=Fang |first1=Xi |last2=Misra |first2=Satyajayant |last3=Xue |first3=Guoliang |last4=Yang |first4=Dejun |date=2012 |title=Smart Grid — The New and Improved Power Grid: A Survey |journal=IEEE Communications Surveys & Tutorials |volume=14 |issue=4 |pages=944–980 |doi=10.1109/SURV.2011.101911.00087 |issn=1553-877X}}</ref>

VPPs provide peak shaving by delivering power during high demand, avoiding expensive peaker plants (saving 40–60%).<ref name=":0">{{Cite web |last=Kim|first=June|date=February 7, 2024|title=How virtual power plants are shaping tomorrow's energy system|url=https://www.technologyreview.com/2024/02/07/1087836/how-virtual-power-plants-are-shaping-tomorrows-energy-system/|access-date=2024-02-28|website=MIT Technology Review|language=en}}</ref><ref name="VPPs">{{cite news |last1=Silverstein|first1=Ken|title=Electricity Users and Virtual Power Plants|url=https://www.forbes.com/sites/kensilverstein/2024/12/16/electricity-users-may-warm-to-the-next-big-thing-virtual-power-plants/|access-date=December 16, 2024|work=Forbes}}</ref> They offer load following and ancillary services such as frequency regulation and operating reserves, responding in seconds to minutes.

VPPs can trade energy in wholesale markets, acting as dispatchable plants. Strategies hedge risks in markets:

* Info-gap decision theory (IGDT)<ref name="VPP Bilateral 2015" /> * Robust optimization (RO)<ref name="VPP Robust 2015" /> * Conditional value at risk (CVaR)<ref name="VPP Coalition Forming 2016">{{Cite journal |author=Shabanzadeh M |last2=Sheikh-El-Eslami |first2=M-K |last3=Haghifam |first3=P |last4=M-R |date=May 2016 |title=A medium-term coalition-forming model of heterogeneous DERs for a commercial virtual power plant |journal=Applied Energy |volume=169 |pages=663–681 |doi=10.1016/j.apenergy.2016.02.058 |bibcode=2016ApEn..169..663S }}</ref> * First-order Stochastic Dominance (FSD)<ref name="VPP FSD 2017" /> * Second-order Stochastic Dominance (SSD)<ref name="VPP SSD 2016">{{Cite book |author=Shabanzadeh M |title=2016 Iranian Conference on Renewable Energy & Distributed Generation (ICREDG) |last2=Sheikh-El-Eslami |first2=M-K |last3=Haghifam |first3=P |last4=M-R |date=April 2016 |isbn=978-1-5090-0857-5 |volume=11 |pages=520–529 |chapter=Modeling the cooperation between neighboring VPPS: Cross-regional bilateral transactions |doi=10.1109/ICREDG.2016.7875909 |s2cid=16453458}}</ref>

== History == Shimon Awerbuch proposed the VPP concept in 1997.<ref name=":1">{{Cite journal|title=Evolution and role of virtual power plants: Market strategy with integration of renewable based microgrids|url=https://www.sciencedirect.com/science/article/pii/S2211467X2400097X|journal=Energy Strategy Reviews|date=2024-05-01|issn=2211-467X|article-number=101390|volume=53|doi=10.1016/j.esr.2024.101390|first=Ahmad Faiz|last=Minai|first2=Akhlaque Ahmad|last2=Khan|last3=Kitmo|first4=Mouhamadou Falilou|last4=Ndiaye|first5=Tabish|last5=Alam|first6=Rohit|last6=Khargotra|first7=Tej|last7=Singh}}</ref> Early work remained theoretical due to technology and regulatory limits. Papers in the early 2000s examined renewable aggregation. Challenges included communication costs and risks.

RWE launched the first VPP in 2008, aggregating nine hydroelectric plants for 8.6 MW. The University of Kassel piloted one linking solar, wind, biogas, and hydroelectricity for load following. Kraftwerke started in 2011, expanding across seven countries, aggregating biogas, solar, and wind.<ref name=":1" />

In the United States, VPPs built on demand response programs. The 2009 American Recovery and Reinvestment Act supported smart grids. Federal Energy Regulatory Commission Order 745 (2011) treated demand reductions as generation in wholesale markets. Order 2222 (2020) enabled direct DER bidding.<ref name=":1" />

AGL Energy started a 5 MW VPP in Adelaide in 2016 with batteries and PV for 1,000 homes. Tesla opened a VPP in South Australia in 2018, reaching 50,000 homes by 2022; AGL acquired the program in 2025, reaching 25 MW solar and 37 MW storage.<ref name="slezak-2016">{{cite news |first=Michael |last=Slezak |title=Adelaide charges ahead with world's largest 'virtual power plant' |date=5 August 2016 |newspaper=The Guardian |url=https://www.theguardian.com/environment/2016/aug/05/adelaide-charges-ahead-with-worlds-largest-virtual-power-plant |access-date=2016-08-05}}</ref>

UK Power Networks and Powervault launched London's first VPP in 2018 (0.32 MWh); Tesla partnered with Octopus Energy there in 2020.<ref name=":1" />created London's first VPP in 2018, installing BESS at 40+ homes across Barnet, with capacity of 0.32&nbsp;MWh,<ref name=":2" /> expanding it in 2020.<ref>{{cite web |url=https://www.gov.uk/government/news/london-pioneers-first-virtual-power-station|title=London pioneers first 'virtual power station' |date=6 March 2020 |website=GOV.UK |access-date=1 July 2021}}</ref> In 2019, SMS plc launched a VPP following the acquisition of Irish firm, Solo Energy.<ref name=":3" /> In 2020, Tesla launched its Tesla Energy Plan in the UK in partnership with Octopus Energy. Participant homes are powered with renewable energy either from solar panels or from Octopus Energy.<ref name=":4" />

By 2023, U.S. capacity reached 30–60 GW (4–8% of peak demand). Tesla operated VPPs in Texas and California.

In 2024, Enpal and Entrix (via Flexa) planned Europe's largest VPP, targeting 1 GW by 2026 with solar, batteries, and EVs; launch occurred later that year.<ref>{{cite web |url=https://www.pv-magazine.com/2024/06/14/enpal-entrix-reveal-plans-for-europes-biggest-vpp/ |title=Enpal, Entrix reveal plans for Europe's biggest VPP |date=14 June 2024 |website=PV Magazine |access-date=25 September 2024}}</ref>

Virginia mandated a Dominion Energy VPP pilot (up to 450 MW) in 2025; the utility proposed it by December.<ref>{{Cite web|url=https://blog.advancedenergyunited.org/articles/virginia-governor-greenlights-virtual-power-plant-pilot|title=Smart Grid, Smart Move: Virginia Governor Greenlights Virtual Power Plant Pilot|first=Savannah|last=Gribbins|website=blog.advancedenergyunited.org}}</ref> Vermont VPPs saved $3 million during 2025 heat waves.<ref name=":0" /> North American capacity reached 37.5 GW in 2025.<ref>{{Cite web|url=https://www.woodmac.com/press-releases/virtual-power-plant-capacity-expands-13.7-year-over-year-to-reach-37.5-gw|title=Virtual power plant capacity expands 13.7% year-over-year to reach 37.5 GW, according to Wood Mackenzie|website=Wood Mackenzie}}</ref>

== Distributed energy resources == VPPs typically aggregate large numbers of distributed energy resources (DER). Resources can be dispatchable or non-dispatchable, controllable or flexible load (CL or FL). Resources can include micro-CHPs, natural gas-fired reciprocating engines, wind power (WPP), photovoltaics (PV), run-of-river hydroelectricity, small hydro, biomass, backup generators, and BESS, as well as devices whose consumption is adjustable (such as water heaters and appliances). The numbers and heterogeneity mean that system output is not dependent on any single resource, offering the potential for stable output even if the output of any single resource is not.

Vehicle-to-grid (V2G) technology allows grid-connected EVs to participate in VPPs. The VPP controls the rate at which each vehicle charges/discharges (accepts/delivers power).

The same principle applies to consuming systems, such as heat pumps or air conditioners that can lower their power demands to reduce demand.<ref>{{cite journal |last1=Lee |first1=Zachary E. |last2=Sun |first2=Qingxuan |last3=Ma |first3=Zhao |last4=Wang |first4=Jiangfeng |last5=MacDonald |first5=Jason S. |last6=Zhang |first6=K. Max |date=Feb 2020 |title=Providing Grid Services With Heat Pumps: A Review |journal=Journal of Engineering for Sustainable Buildings and Cities |volume=1 |issue=1 |article-number=011007 |doi=10.1115/1.4045819 |s2cid=213898377 |doi-access=free}}</ref>

VPPs based on storage can ramp at higher rates than thermal generators (such as fossil fuel plants), which is especially valuable in grids that experience a duck curve and must satisfy high ramping requirements in the morning and evening.

VPPs can be as dependable as conventional plants, while costing 40–60 percent less. One study forecasted that decentralized generation would comprise 500,000 megawatts of capacity compared to centralized generation of 280,000 megawatts.<ref name="VPPs">{{cite news |last1=Silverstein |first1=Ken |title=Electricity Users and Virtual Power Plants |url=https://www.forbes.com/sites/kensilverstein/2024/12/16/electricity-users-may-warm-to-the-next-big-thing-virtual-power-plants/ |access-date=December 16, 2024 |work=Forbes}}</ref>

==Operation== Power delivery is controlled by a management system. The distributed nature of VPPs requires software to respond appropriately and securely to power requests, utility billing, payments to resource owners, etc.<ref>{{Cite journal |last1=Fang |first1=Xi |last2=Misra |first2=Satyajayant |last3=Xue |first3=Guoliang |last4=Yang |first4=Dejun |date=2012 |title=Smart Grid — The New and Improved Power Grid: A Survey |journal=IEEE Communications Surveys & Tutorials |volume=14 |issue=4 |pages=944–980 |doi=10.1109/SURV.2011.101911.00087 |issn=1553-877X}}</ref><ref>{{cite web |title=Manage the Virtual Power and prevent a blackout! |url=https://www.next-kraftwerke.com/virtual-power-plant-vpp-simulation/?lang=en |access-date=2 December 2019 |website=Next Kraftwerke}}</ref>

== Services == Typically, the VPP provides power (only) when requested by the utility.

=== Peak shaving === With the appropriate resources, a VPP can deliver incremental power on short notice, helping utilities to manage peak loads that would otherwise require purchasing expensive power from a peaker plant (typically powered by natural gas).

=== Load following === Given sufficient scale, a VPP can operate as a load-following generator, supplying output dynamically as demand changes throughout the day/night cycle.

=== Ancillary services === Virtual power plants can provide ancillary services that help maintain grid stability such as frequency regulation and providing operating reserve. These services are primarily used to maintain the instantaneous balance of electrical supply and demand. These services must respond to signals to increase or decrease load on the order of seconds to minutes.

== Energy trading == Electrical energy markets are wholesale, international markets that trade electrical energy.<ref>{{Cite web |author=JEAN-PHILIPPE TAILLON, CFA |date=2021-10-14 |title=Introduction to the World of Electricity Trading |url=https://www.investopedia.com/articles/investing/042115/understanding-world-electricity-trading.asp |access-date=2022-01-04 |publisher=Investopedia}}</ref><ref name="VPP FSD 2017" /> Market prices fluctuate with demand and supply (e.g., when the wind subsides). The VPP behaves as a conventional dispatchable power plant from the point of view of other market participants. A VPP arbitrages between diverse energy markets (e.g., bilateral and purchase power agreements (PPA), forward and futures markets, and the pool).<ref name="VPP Bilateral 2015" /><ref name="VPP Robust 2015" /><ref name="VPP Coalition Forming 2016" /><ref name="VPP SSD 2016" />

Five risk-hedging strategies have been applied to VPP decision-making to measure the degree of conservatism of VPPs' decisions in energy trading (e.g., day-ahead electricity market, derivatives exchange market, and bilateral contracts):

* IGDT: Information Gap Decision Theory<ref name="VPP Bilateral 2015" /> * RO: Robust optimization<ref name="VPP Robust 2015" /> * CVaR: Conditional value at risk<ref name="VPP Coalition Forming 2016" /> * FSD: First-order Stochastic Dominance<ref name="VPP FSD 2017" /> * SSD: Second-order Stochastic Dominance<ref name="VPP SSD 2016" /><ref>{{Cite journal|last1=Shabanzadeh|first1=Morteza|last2=Sheikh-El-Eslami|first2=Mohammad-Kazem|last3=Haghifam|first3=Mahmoud-Reza|title=An interactive cooperation model for neighboring virtual power plants|journal=Applied Energy|volume=200|pages=273–289|doi=10.1016/j.apenergy.2017.05.066|year=2017|bibcode=2017ApEn..200..273S |s2cid=157309706 }}</ref>

== Markets ==

=== United States === In 2023 the Department of Energy estimated VPP capacity at around 30 to 60&nbsp;GW, some 4–8% of peak electricity demand.<ref name=":0" />

Texas has two Tesla-operated VPPs. Eligible Tesla Electric members automatically join the Virtual Power Plant, consisting of Tesla Powerwall batteries. Tesla pays the owner a monthly fee in addition to payment per unit of energy delivered.<ref>{{Cite web |title=Tesla Electric Virtual Power Plant Beta with ERCOT |url=https://www.tesla.com/support/energy/virtual-power-plant/tesla-electric |access-date=February 29, 2024 |website=tesla.com}}</ref>

California has two electric markets: retail and wholesale. As of 2022 PG&E paid VPP providers $2/kWh during peak demand.<ref>{{cite web |title=PG&E, Tesla virtual power plant delivers 16.5 MW to California grid amid calls for energy conservation |url=https://www.utilitydive.com/news/pge-tesla-virtual-power-plant/630310/ |website=Utility Dive |date=23 August 2022}}</ref> As of August/September 2022, SunRun VPP often delivered 80&nbsp;MW at peak times,<ref>{{cite web |last1=Colthorpe |first1=Andy |title=California's fleet of battery storage working to avert energy crisis |url=https://www.energy-storage.news/californias-fleet-of-battery-storage-working-to-avert-energy-crisis/ |website=Energy Storage News |date=8 September 2022}}</ref> while Tesla VPP supplied 68 MW.<ref>{{Cite web |last=Lambert |first=Fred |date=2022-09-02 |title=Tesla virtual power plant is rocketing up, reaches 50 MW |url=https://electrek.co/2022/09/02/tesla-virtual-power-plant-growing/ |access-date=2022-09-08 |website=Electrek |language=en-US}}</ref><ref>{{Cite web |title=Tesla's Virtual Power Plant Tracker |url=https://www.lastbulb.com/virtual-power-plant |access-date=2022-09-08 |website=Lastbulb |language=en-US}}</ref> By 2025, California was testing 100,000 residential batteries at a combined 535&nbsp;MW.<ref>{{cite web |last1=Driscoll |first1=William |title=100,000 residential batteries in California tested as one distributed power plant |url=https://www.ess-news.com/2025/08/06/100000-residential-batteries-in-california-tested-as-one-distributed-power-plant/ |website=Energy Storage |date=6 August 2025}}</ref>

Virginia's Virtual Power Plant (VPP) pilot program is a state-mandated initiative requiring Dominion Energy Virginia (a Phase II Utility) to implement a pilot VPP.<ref name="law">{{cite web |title=§ 56-585.1:16. Virtual power plant pilot program |url=https://law.lis.virginia.gov/vacode/title56/chapter23/section56-585.1:16 |access-date=February 6, 2026 |website=Virginia Law}}</ref> The pilot is capped at 450 MW.<ref name="utilitydive">{{cite news |date=May 12, 2025 |title=Virginia utility-scale VPP pilot mandate is first amid national push |url=https://www.utilitydive.com/news/virginia-leads-with-utility-scale-vpp-pilot-amid-national-push/747770 |access-date=February 6, 2026 |work=Utility Dive}}</ref> It is to include incentives for 15 MW+ of distributed BESS, including residential, commercial, and industrial customers.<ref name="vcn">{{cite web |date=July 25, 2025 |title=New Laws: Sharing and Distributing Clean Energy Through Virtual Power Plants |url=https://vcnva.org/new-laws-sharing-and-distributing-clean-energy-through-virtual-power-plants |access-date=February 6, 2026 |website=Virginia Conservation Network}}</ref> As of early 2026, the program represented one of the US' largest VPP pilots.<ref name="vcn" /> A program for electrification of school buses must be filed by December 31, 2027.<ref> No later than December 1, 2025, each Phase II Utility shall petition the State_Corporation_Commission (the Commission) for approval to conduct a pilot program to evaluate methods to optimize demand through various technology applications including the establishment of virtual power plants. Such pilot program shall evaluate electric grid capacity needs and the ability of such virtual power plants to provide grid services, including Peak-shaving, during times of peak electric demand. Such pilot program shall consist of aggregations of distributed energy resources totaling up to 450 megawatts for a Phase II Utility and shall include Distributed_energy_resources located in multiple geographic regions of the Commonwealth. An electric utility may utilize any existing or proposed distributed energy programs as part of the pilot program and to further the development of virtual power plants in the Commonwealth. An electric utility that petitions the Commission for such pilot program shall demonstrate that the utility has evaluated funding opportunities from the U.S. Department of Energy. In furthering the goals of such pilot program, the electric utility shall (i) propose programs of at least 15 megawatts incentivizing residential customers to purchase battery storage devices and (ii) notwithstanding the provisions of § 56-585.1:13 of the Code of Virginia, propose a broader electric school bus program as part of a grid transformation filing no later than December 31, 2027, and the Commission may require competitive solicitation open to utility-owned and non-utility-owned resources. The electric utility shall not own the electric school buses as a part of its proposed program, but such electric utility may own the related storage batteries. The electric utility shall only use the bus storage batteries to access the stored electricity at times when the participating school system determines that the electric school buses are not needed to transport students. https://law.lis.virginia.gov/vacode/title56/chapter23/section56-585.1:16/ </ref>

Vermont's Green Mountain Power works with Tesla to offer a Powerwall to participating customers at a discounted rate.<ref name=":0" />

Three Massachusetts utilities, National Grid, Eversource, and Cape Light Compact, operate a VPP.<ref name=":0" /> The Massachusetts Clean Energy Center (MassCEC) is implementing a vehicle‑to‑everything (V2X) demonstration program as part of its VPP that installs free, bi‑directional EV chargers at school districts, municipalities, and residents.<ref>{{Cite web |last=Lewis |first=Michelle |date=2026-02-03 |title=Free V2X chargers will let Massachusetts EVs power the grid |url=https://electrek.co/2026/02/03/free-v2x-chargers-will-let-massachusetts-evs-power-the-grid/ |access-date=2026-02-06 |website=Electrek |language=en-US}}</ref>

=== Europe === The Institute for Solar Energy Supply Technology of Germany's University of Kassel pilot-tested a VPP that linked solar, wind, biogas, and pumped-storage hydroelectricity to provide load-following power from renewable sources.<ref name="combined_power_plant">{{Cite web |url=http://www.solarserver.de/solarmagazin/anlagejanuar2008_e.html |title=The Combined Power Plant: the first stage in providing 100% power from renewable energy |date=January 2008 |access-date=2008-10-10 |publisher=SolarServer |archive-date=2008-10-14 |archive-url=https://web.archive.org/web/20081014054221/http://www.solarserver.de/solarmagazin/anlagejanuar2008_e.html}}</ref>

A VPP operated on the Scottish Inner Hebrides island of Eigg.<ref>{{Cite web |last=Gardiner |first=Karen |title=The small Scottish isle leading the world in electricity |url=https://www.bbc.com/future/article/20170329-the-extraordinary-electricity-of-the-scottish-island-of-eigg |access-date=2023-07-17 |website=www.bbc.com |date=30 March 2017 |language=en}}</ref><ref>BBC Radio 4. Costing the Earth- Electric Island</ref>

Kraftwerke operates a VPP in seven European countries that provides peak-load resources, power trading and grid balancing. The company aggregates energy from biogas, solar and wind as well as large-scale power consumers.<ref name="Next_Kraftwerke">{{Cite web |url=https://cleantechnica.com/2016/10/20/next-kraftwerk-reimagines-redefines-electrical-grid-virtual-power-plant/ |title=Next Kraftwerk Reimagines & Redefines The Electrical Grid With Virtual Power Plants |date=October 2016 |access-date=2019-03-13 |publisher=Clean Technica}}</ref>

A London VPP is supported by UK Power Networks, and Powervault.<ref name=":2">{{cite web |url=https://www.ukpowernetworks.co.uk/internet/en/news-and-press/first-virtual-power-station.html/|title=Electricity network plan to launch London's first virtual power station |date=22 June 2018 |website=UK Power Networks |access-date=15 October 2021}}</ref> SMS plc operates a UK VPP.<ref name=":3">{{cite web |url=https://www.current-news.co.uk/news/smart-metering-systems-reveals-solo-energy-acquisition-as-it-enters-vpp-market |last=Grundy |first=Alice |title=Smart Metering Systems reveals Solo Energy acquisition as it enters VPP market |date=27 March 2020 |website=Current News |access-date=1 July 2021}}</ref>

Tesla operates in the UK in partnership with Octopus Energy. Participant homes are powered with renewable energy from solar panels or from Octopus Energy.<ref name=":4">{{cite web |url=https://www.current-news.co.uk/news/tesla-energy-plan-launched-inviting-homes-to-become-part-of-virtual-power-plant | last=Lempriere |first=Molly |title=Tesla Energy Plan launched inviting homes to become part of Virtual Power Plant |date=27 October 2020 |website=Current News|access-date=1 July 2021}}</ref>

German companies Enpal and Entrix operate Europe's largest VPP that integrates PV, BESS, and electric vehicles. Enpal is a solar installer with more than 70,000 installed systems, connects thousands of solar/BESS households to the VPP.<ref>{{cite web |url=https://www.pv-magazine.com/2024/06/14/enpal-entrix-reveal-plans-for-europes-biggest-vpp/ |title=Enpal, Entrix reveal plans for Europe's biggest VPP |date=14 June 2024 |website=PV Magazine |access-date=25 September 2024}}</ref><ref>{{cite web |url=https://www.faz.net/aktuell/wirtschaft/unternehmen/so-baut-solar-installateur-enpal-das-groesste-virtuelle-kraftwerk-in-europa-19781418.html |title=So baut Solar-Installateur Enpal das größte virtuelle Kraftwerk in Europa |date=14 June 2024 |website=Frankfurter Allgemeine Zeitung |access-date=25 September 2024}}</ref>

=== Australia === AGL Energy operates a 25{{nbsp}}MW virtual-power-plant scheme in Adelaide. The company supplies BESS and photovoltaic systems, to >8,000 customers. The systems cost consumers A$3500 with a 7{{nbsp}}year payout. As of 2025, the program provided 25&nbsp;MW solar and 37&nbsp;MW storage.<ref>{{cite web |title=Tesla's South Australian virtual power plant sold to utility AGL |url=https://www.ess-news.com/2025/07/04/teslas-south-australian-virtual-power-plant-sold-to-utility-agl/ |website=Energy Storage |date=4 July 2025}}</ref><ref>{{Cite web |last=Heynes |first=George |date=2025-07-07 |title=AGL Energy buys the South Australia Virtual Power Plant from Tesla |url=https://www.energy-storage.news/agl-energy-buys-the-south-australia-virtual-power-plant-from-tesla/ |access-date=2026-02-06 |website=Energy-Storage.News |language=en-US}}</ref>

==See also== {{Portal|Energy|Renewable energy}} {{div col}} * Automatic meter reading * Distributed generation * Electricity meter * Energy demand management * Engine power plant * Feed-in tariff * Grid energy storage * Net metering * Peaking power plant * Power system automation * Power-to-X * Smart meter * Smart grid * Utility submeter {{div col end}}

==References== {{reflist|30em}}

==External links== {{commons category}} * [https://arena.gov.au/projects/agl-virtual-power-plant AGL Virtual Power Plant VPP project]

{{Electricity generation}}

Category:Distributed generation