Primary energy congestion of power systems

详细信息    查看全文

• 作者：Yusheng Xue (1)
  Bin Cai (1) (2)
  Geoffrey James (4)
  Zhaoyang Dong (3)
  Fushuan Wen (5)
  Feng Xue (1)
  
• 关键词：Power system reliability ; Energy security ; Electric power security ; Primary energy congestion ; Blackout defence
• 刊名：Journal of Modern Power Systems and Clean Energy
• 出版年：2014
• 出版时间：March 2014
• 年：2014
• 卷：2
• 期：1
• 页码：39-49
• 全文大小：852 KB
• 参考文献：1. BP statistical review of world energy June 2012. British Petroleum (BP), London (2012)
  2. Kundur P, Paserba J, Ajjarapu V et al (2004) Definition and classification of power system stability. IEEE Trans Power Syst 19(2):1387-401
  3. Eto JH (2004) Blackout 2003: final report on the August 14, 2003 blackout in the United States and Canada: causes and recommendations. Electricity Markets and Policy Group, Energy Analysis and Environmental Impacts Department, US Department of Energy, Washington, DC
  4. Alhajji AF (2007) What is energy security? Definitions and concepts. Middle East Econ Surv 50(45):5
  5. Kruyt B, van Vuuren DP, de Vries HJM (2009) Indicators for energy security. Energy Policy 37:2166-181 CrossRef
  6. Energy security. International Energy Agency (IEA), Paris (2012)
  7. Sharan I, Balasubramanian R (2012) Integrated generation and transmission expansion planning including power and fuel transportation constraints. Energy Policy 43:275-84 CrossRef
  8. Annual report on electricity regulation 2011. State Electricity Regulatory Commission of China (SERC), Beijing (in Chinese)
  9. Xue YS (2007) Towards space–time cooperative defence framework against blackouts in China. In: Proceedings of the IEEE Power Engineering Society general meeting, Tampa, FL, USA, 24-8 June 2007, p 6
  10. Xue YS (2008) Progresses of blackout defense systems in China. In: Proceedings of the IEEE Power and Energy Society general meeting, Pittsburgh, PA, USA, 20-4 July 2008, p 6
  11. Ackermann T, Kuwahata R (2011) Lessons learned from international wind integration studies. Energynautics GmbH, Langen
  12. Liu ZY (2012) Electric power and energy in China. China Electric Power Press, Beijing (in Chinese)
  13. Xue YS, Li TR, Yin X et al (2010) A research framework for generalized congestions and market power. Autom Electr Power Syst 34(21):1-0 (in Chinese)
  14. Holttinen H, Meibom P, Orths A et al (2011) Impacts of large amounts of wind power on design and operation of power systems, results of IEA collaboration. Wind Energy 14(2):179-92 CrossRef
  15. Soitoa J, Freitasa M (2011) Amazon and the expansion of hydropower in Brazil: vulnerability, impacts and possibilities for adaptation to global climate change. Renew Sustain Energy Rev 15(6):3165-177 CrossRef
  16. Wind power and wind farms in South Australia. http://ramblingsdc.net/Australia/WindSA.html. Accessed 19 Nov 2012
  17. Challenges facing the natural gas and electric power interface in New England—and opportunities to improve mutual reliability. Northeast Gas Association, Needham Heights (2012)
  18. Shahidehpour M, Fu Y, Wiedman T (2005) Impact of natural gas infrastructure on electric power systems. Proc IEEE 93(5):1042-059 CrossRef
  19. Li T, Eremia M, Shahidehpour M (2008) Interdependency of natural gas network and power system security. IEEE Trans Power Syst 23(4):1817-824 CrossRef
  20. Unsihuay-Vila C, Marangon-Lima JW, de Souza ACZ et al (2010) A model to long-term, multiarea, multistage, and integrated expansion planning of electricity and natural gas systems. IEEE Trans Power Syst 25(2):1154-168 CrossRef
  21. Xue YS, Fei SY, Bu FQ (2008) Upgrading the blackout defense scheme against extreme disasters: Part I New challenges and reflection. Autom Electr Power Syst 32(9):1- (in Chinese)
  22. Xue YS, Fei SY, Bu FQ (2008) Upgrading the blackout defense scheme against extreme disasters: Part II tasks and prospects. Autom Electr Power Syst 32(10):1- (in Chinese)
  23. Review of on-line dynamic security assessment tools and techniques. CIGRE WG C4.601. International Council on Large Electric Systems, Paris (2007)
  24. Makarov YV, Reshetov VI, Stroev VA (2005) Blackout prevention in the United States, Europe and Russia. Proc IEEE 93(11):1942-955 CrossRef
  25. Mukhopadhyay S, Soonee SK, Narasimhan SR, et al (2008) An Indian experience of defense against blackouts and restoration mechanism followed. In: Proceedings of the IEEE Power and Energy Society general meeting—conversion and delivery of electrical energy in the 21st century, Pittsburgh, PA, USA, 20-4 Jul 2008, p 7
  26. Trudel G, Bernard S, Scott G (1999) Hydro-Quebec’s defence plan against extreme contingencies. IEEE Trans Power Syst 14(3):958-66 CrossRef
  27. Filho XV, Pilottto LAS, Martins N, et al (2001) Brazilian defense plan against extreme contingencies. In: Proceedings of the Power Engineering Society summer meeting. Vancover, Canada, 15-9 July 2007,vol 2, pp 834-39
  28. Lachs WR (2005) Area-wide system protection scheme against extreme contingencies. Proc IEEE 93(5):1004-027 CrossRef
  29. Li H, Rosenwald GW, Jung JH et al (2005) Strategic power infrastructure defense. Proc IEEE 93(5):918-33 CrossRef
  30. DL 755-001 Guide and standard of power system security and stability control, 2001 (in Chinese)
  31. Giri J, Parashar M, Trehern J, et al (2012) The situation room: control center analytics for enhanced situational awareness. IEEE Power Energy Mag 10(5):24-9 CrossRef
  32. Xue YS (1999) Quantitative study of general motion stability and an example on power system stability. Jiangsu Science and Technology Press, Nanjing (in Chinese)
  33. Olivier JGJ, Janssens-Maenhout G, Peters JAHW, et al (2011) Long-term trend in global CO₂ emissions: 2011 report. PBL Netherlands Environmental Assessment Agency, Institute for Environment and Sustainability (IES) of the European Commission’s JRC Joint Research Centre, Hague
  34. Key world energy statistics. International Energy Agency (IEA), Paris (2011)
  35. BP energy outlook 2030. British Petroleum (BP), London (2012)
  36. Electricity shortage in California: issues for petroleum and natural gas supply. US Energy Information Administration (EIA), Washington, DC (2001)
  37. Gowaid IA, El-Zawawi A, El-Gammal M (2011) Improved inertia and frequency support from grid-connected DFIG wind farms. In: Proceedings of the power systems conference and exposition (PSCE-1), Phoenix, AZ, USA, 20-3 March 2011, p 6
  38. National Bureau of Statistics of China (NBS) (2011) China energy statistical yearbook 2011. China Statistics Press, Beijing (in Chinese)
  39. Communique on land and resources of China (2001-010). Ministry of Land and Resources of China (MLR), Beijing (2001-010) (in Chinese)
  40. China overtakes Japan as world’s top coal importer. China Briefing, 26 Jan 2012
  41. Lin B, Liu J (2010) Estimating coal production peak and trends of coal imports in China. Energy Policy 38:512-19 CrossRef
  42. China’s 12th Five Year Plan for coal. National Development and Reform Commission (NDRC), Beijing, 2012 (in Chinese)
  43. China coal transport capacity to reach 2 billion tonnes in 2011. http://www.ecoalchina.com/english/news/gnmtxw/967846.shtml. Accessed 9 Nov 2011 (in Chinese)
  44. Wang B (2007) An imbalanced development of coal and electricity industries in China. Energy Policy 35:4959-968 CrossRef
  45. Peng WY (2011) Coal sector reform and its implications for the power sector in China. Resour Policy 36(1):60-1 CrossRef
  46. Contract negotiation between coal and electric companies will be held, stabilizing the coal price should be the focal point. http://energy.people.com.cn/GB/16290605.html. Accessed 11 Nov 2011 (in Chinese)
  47. Foreign power firm sheds assets. http://english.people.com.cn/90778/7811553.html . Accessed 9 May 2011
  48. General Office of the State Council of P. R. China. Guidance on deepening the reform of marketization of power coal. http://www.gov.cn/zwgk/2012-12/25/content_2298187.html. Accessed 25 Dec 2012 (in Chinese)
  49. An outlook for power industry development strategy in -2th Five Year Plan- http://www.china5e.com/show.php?contentid=135468. Accessed 9 Oct 2010 (in Chinese)
  
• 作者单位：Yusheng Xue (1)
  Bin Cai (1) (2)
  Geoffrey James (4)
  Zhaoyang Dong (3)
  Fushuan Wen (5)
  Feng Xue (1)
  
  1. State Grid Electric Power Research Institute (SGEPRI), Nanjing, 210003, China
  2. Nanjing University of Science and Technology (NJUST), Nanjing, 210094, China
  4. Commonwealth Scientific and Industrial Research Organisation (CSIRO), North Ryde, NSW, 2113, Australia
  3. The University of Sydney, Sydney, NSW, 2006, Australia
  5. Zhejiang University, Hangzhou, 310027, China
  
• ISSN：2196-5420

文摘

Primary energy has the potential to bring challenges to the reliability, economic, and eco-friendliness of global electric power systems. The concept of electric power security are proposed, including many factors that are not considered in power system reliability analysis, such as coal supply for power system, fuel price for electricity power market, carbon emissions of power generation, and so on. It is broader than power system reliability and security, which means that providing energy in the form of reliable, economical, and eco-friendly electric power. Following an account of existing blackout defence methods and systems, the processes of transforming various kinds of primary energy into electric power and the interactions between them are described, particularly with regard to flows of energy, capital, and information. Factors that limit the liquidity of these flows are defined as “generalized congestion- and the challenges presented by primary energy are named “primary energy congestion- China’s dilemma on coal supply for power generation is presented in some detail as an example of primary energy congestion. To cope with impacts of the primary energy on electric power systems, an idea is introduced to extend the scope of existing coordinated blackout defence systems to account for primary energy, which would lead to an integrated tool to provide decision support to power system operators accounting for primary energy congestion.