词条 | Wide area synchronous grid | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
释义 |
|direction = vertical |align = right |width = 300 |image1=ElectricityUCTE.svg |image2=NERC-map-en.svg |caption1=The synchronous grids of Europe |caption2=The two major and three minor interconnections of North America |image3=Wide area synchronous grid (Eurasia, Mediterranean).png |caption3=Major WASGs in Eurasia and northern Africa }} A wide area synchronous grid (also called an "interconnection" in North America) is a three-phase electric power grid that has regional scale or greater that operates at a synchronized frequency and is electrically tied together during normal system conditions. Also known as synchronous zones, the most powerful is the synchronous grid of Continental Europe (ENTSO-E) with 667 gigawatts (GW) of generation, while the widest region served being that of the IPS/UPS system serving countries of the former Soviet Union. Synchronous grids with ample capacity facilitate electricity market trading across wide areas. In the ENTSO-E in 2008, over 350,000 megawatt hours were sold per day on the European Energy Exchange (EEX).[1] All of the interconnects in North America are synchronized at a nominal 60 Hz, while those of Europe run at 50 Hz. Interconnections can be tied to each other via high-voltage direct current power transmission lines (DC ties), or with variable-frequency transformers (VFTs), which permit a controlled flow of energy while also functionally isolating the independent AC frequencies of each side. The benefits of synchronous zones include pooling of generation, resulting in lower generation costs; pooling of load, resulting in significant equalizing effects; common provisioning of reserves, resulting in cheaper primary and secondary reserve power costs; opening of the market, resulting in possibility of long term contracts and short term power exchanges; and mutual assistance in the event of disturbances.[2] One disadvantage of a wide-area synchronous grid is that problems in one part can have repercussions across the whole grid. For example, in 2018 Kosovo used more power than it generated due to a row with Serbia, leading to the phase in the whole Synchronous grid of Continental Europe lagging behind what it should have been. The frequency dropped to 49.996 Hz. This caused certain kinds of clocks to become six minutes slow.[3] PropertiesWide area synchronous networks improve reliability and permit the pooling of resources. Also, they can level out the load, which reduces the required generating capacity, allow more environmentally-friendly power to be employed; and allow more diverse power generation schemes and permit economies of scale.[4] Wide area synchronous networks cannot be formed if the two networks to be linked are running at different frequencies or have significantly different standards. For example, in Japan, for historical reasons, the northern part of the country operates on 50 Hz, but the southern part uses 60 Hz. That makes it impossible to form a single synchronous network, which was problematic when the Fukushima Daiichi plant melted down. Also, even when the networks have compatible standards, failure modes can be problematic. Phase and current limitations can be reached, which can cause widespread outages. The issues are sometimes solved by adding HVDC links within the network to permit greater control during off-nominal events. As was discovered in the California electricity crisis, there can be strong incentives among some market traders to create deliberate congestion and poor management of generation capacity on an interconnection network to inflate prices. Increasing transmission capacity and expanding the market by uniting with neighboring synchronous networks make such manipulations more difficult. FrequencyAn entire synchronous grid runs at the same frequency. Where interconnection to a neighboring grid, operating at a different frequency, is required, a frequency converter is required. High voltage direct current links can connect two grids that operate at different frequencies or that are not maintaining synchronism. In a synchronous grid all the generators must run at the same frequency, and must stay very nearly in phase with each other and the grid. For rotating generators, a local governor regulates the driving torque, maintaining constant speed as loading changes. Droop speed control ensures that multiple parallel generators share load changes in proportion to their rating. Generation and consumption must be balanced across the entire grid, because energy is consumed as it is produced. Energy is stored in the immediate short term by the rotational kinetic energy of the generators. Small deviations from the nominal system frequency are very important in regulating individual generators and assessing the equilibrium of the grid as a whole. When the grid is heavily loaded, the frequency slows, and governors adjust their generators so that more power is output (droop speed control). When the grid is lightly loaded the grid frequency runs above the nominal frequency, and this is taken as an indication by Automatic Generation Control systems across the network that generators should reduce their output. In addition, there's often central control, which can change the parameters of the AGC systems over timescales of a minute or longer to further adjust the regional network flows and the operating frequency of the grid. For timekeeping purposes, over the course of a day the nominal frequency will be allowed to vary so as to balance out momentary deviations and to prevent line-operated clocks from gaining or losing significant time. High-voltage direct current lines or variable-frequency transformers can be used to connect two alternating current interconnection networks which are not necessarily synchronized with each other. This provides the benefit of interconnection without the need to synchronize an even wider area. For example, compare the wide area synchronous grid map of Europe (above left) with the map of HVDC lines (below right). Deployed networks
A partial table of some of the larger interconnections. Planned
Planned non synchronous connectionsThe Tres Amigas SuperStation aims to enable energy transfers and trading between the Eastern Interconnection and Western Interconnection using 30GW HVDC connections. See also{{Portal|Energy}}
References1. ^{{cite journal | url=http://www.eex.com/de/document/39600/20081027_EEX_Market_Monitor_Q3_2008_English.pdf | title=EEX Market Monitor Q3/2008 | format=pdf | publisher= Market Surveillance (HÜSt) group of the European Energy Exchange | date=2008-10-30 | location=Leipzig | accessdate=2008-12-06 | page=4}} 2. ^{{cite book | title=Operation of Interconnected Power Systems | chapter=Characteristics of interconnected operation | chapterurl=http://www.iaew.rwth-aachen.de/cms/upload/PDF/Vorlesungen/Denzel/chapter_1.1.pdf | page=3 | format=pdf | publisher= Institute for Electrical Equipment and Power Plants (IAEW) at RWTH Aachen University | last=Haubrich | first= Hans-Jürgen |author2=Dieter Denzel | date=2008-10-23 | location=Aachen | accessdate=2008-12-06 | url=http://www.iaew.rwth-aachen.de/cms/upload/PDF/Vorlesungen/Denzel/chapter_0.1.pdf}} (See "Operation of Power Systems" link for title page and table of contents.) 3. ^{{cite news |title=Serbia, Kosovo power grid row delays European clocks |url=https://www.reuters.com/article/serbia-kosovo-energy/serbia-kosovo-power-grid-row-delays-european-clocks-idUSL5N1QP2FF |agency=Reuters |date=Mar 7, 2018}} 4. ^https://www.un.org/esa/sustdev/publications/energy/chapter2.pdf 5. ^{{cite web |title=ENTSO-E Statistical Factsheet 2017 |url=https://www.entsoe.eu/Documents/Publications/Statistics/Factsheet/entsoe_sfs_2017.pdf |website=www.entsoe.eu |accessdate=2 January 2019}} 6. ^{{cite journal | url= | title=Feasibility Study: Synchronous Interconnection of the IPS/UPS with the UCTE | author=UCTE-IPSUPS Study Group | format=pdf | publisher= TEN-Energy programme of the European Commission | date=2008-12-07 | page=2}} 7. ^{{cite journal | url=http://www.ucte-ipsups.org/Pdf/Download/englisch/IPSUPS_Overview_Lebed.pdf | title=IPS/UPS Overview | author=Sergei Lebed RAO UES | format=pdf | publisher= UCTE-IPSUPS Study presentation | date=2005-04-20 | location=Brussels | accessdate=2008-12-07 | page=4}} 8. ^Electricity sector in India 9. ^[https://www.wecc.biz/Reliability/2016%20SOTI%20Final.pdf 2016 State of the Interconnection] page 10-14 + 18-23. WECC, 2016. [https://web.archive.org/web/20160809221758/https://www.wecc.biz/Reliability/2016%20SOTI%20Final.pdf Archive] 10. ^https://www.gov.uk/government/statistics/electricity-chapter-5-digest-of-united-kingdom-energy-statistics-dukes 11. ^http://www.ercot.com/content/wcm/lists/89476/ERCOT2016D_E.xlsx 12. ^{{cite web|url=http://www.ercot.com/content/wcm/lists/144926/ERCOT_Quick_Facts_8818.pdf|title=Quick facts |date=818 |website=www.ercot.com |format=PDF}} 13. ^https://www.aer.gov.au/wholesale-markets/wholesale-statistics/electricity-supply-to-regions-of-the-national-electricity-market 14. ^{{cite journal | url=http://www.sgcc.com.cn/ywlm/gsyw-e/45953.shtml | title=Address at the 2006 International Conference of UHV Transmission Technology | author=Liu Zhengya President of SGCC | publisher= UCTE-IPSUPS Study presentation | date=2006-11-29 | location=Beijing | accessdate=20068-12-06}} 15. ^{{cite journal | url=http://www.bsecenergy.ro/prezentari/Energy%20Policies%20and%20Strategies/Sergey%20Kouzmin/IPSUPS-UCTE.pdf | title=Synchronous Interconnection of IPS/UPS with UCTE - Study Overview | author=Sergey Kouzmin UES of Russia | format=pdf | publisher= Black Sea Energy Conference | date=2006-04-05 | location=Bucharest, Romania | accessdate=2008-12-07 | page=2}} External links
2 : Wide area synchronous grids|Electric power transmission systems |
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