台山核电机组接入电网的相互影响研究
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摘要
当今世界环境日益恶化的趋势导致清洁能源的迫切需求,核能发电作为一种无污染能源已经在全世界大力发展起来。随着能源危机的来临以及人们环保意识的提高,核电机组大量的接入电网,核电在电网中所占的比重日益增加。由于台山核电机组是目前世界上单机容量最大的核电机组,其单机容量达1755MW,因此核电站运行特性的研究对电网的安全稳定运行具有至关重要的意义。
电网故障或扰动会导致核电机端电压、频率的变化,从而引起核电机组内部参数的波动。核电机组的退出将会导致系统失去大量有功功率,使故障情况进一步恶化。而核电机组对电网的影响主要考虑核电机组的切机、失磁对电网的稳定性和电压、频率的扰动。
为了对大扰动下核电机组接入电网后的相互影响进行研究,本文以台山核电机组为研究对象,研究核电机组的数学模型及仿真模型,在此基础上针对不同的故障模式对大型压水堆核电机组的特性进行了仿真研究。研究的结果表明:对于一般形态的故障在快速而正确切除的情况下,核电机组本身不需要采取特殊的措施。但是如果某些保护不正确动作,故障长期存在,则可能导致系统内机组失去同步,必须在机组内采取一些特殊的措施。
Today's trend of deteriorating world environment led to the urgent needs of clean energy, nuclear power generation as a pollution-free energy has been developed vigorously in the world. With the advent of the energy crisis and increasing awareness of environmental protection,a large number of nuclear power units connected to the power grid, the proportion of nuclear power in the grid increases,however the capacity of Taishan nuclear power units is the largest in the world, its capacity is 1755 MW, Which makes the studies on nuclear power plant operating characteristics of critical importance in safe and stable operation of power grid.
The Power grid malfunction or disturbance may lead to instability of the terminal voltage of nuclear power units and grid frequency,which may cause the fluctuations in intrinsic parameters of nuclear power generating sets. Also the withdrawal of nuclear Power units will cause the system to lose substantive active Power making the malfunction even worse.
In order to investigate the interaction between nuclear power units and power grid under serious disturbance, the paper study the mathematical model and simulation model of Taishan nuclear power units.The characteristics of pressurized water reactor plant are simulated in fault modes.Simulative results show that.it is not necessary to take special measures for normal faults which are removed rapidly and correctly:special measures have to be taken if the fault stays because of the incorrect protection operations,which may cause unit synchronization loss.
电网故障或扰动会导致核电机端电压、频率的变化,从而引起核电机组内部参数的波动。核电机组的退出将会导致系统失去大量有功功率,使故障情况进一步恶化。而核电机组对电网的影响主要考虑核电机组的切机、失磁对电网的稳定性和电压、频率的扰动。
为了对大扰动下核电机组接入电网后的相互影响进行研究,本文以台山核电机组为研究对象,研究核电机组的数学模型及仿真模型,在此基础上针对不同的故障模式对大型压水堆核电机组的特性进行了仿真研究。研究的结果表明:对于一般形态的故障在快速而正确切除的情况下,核电机组本身不需要采取特殊的措施。但是如果某些保护不正确动作,故障长期存在,则可能导致系统内机组失去同步,必须在机组内采取一些特殊的措施。
Today's trend of deteriorating world environment led to the urgent needs of clean energy, nuclear power generation as a pollution-free energy has been developed vigorously in the world. With the advent of the energy crisis and increasing awareness of environmental protection,a large number of nuclear power units connected to the power grid, the proportion of nuclear power in the grid increases,however the capacity of Taishan nuclear power units is the largest in the world, its capacity is 1755 MW, Which makes the studies on nuclear power plant operating characteristics of critical importance in safe and stable operation of power grid.
The Power grid malfunction or disturbance may lead to instability of the terminal voltage of nuclear power units and grid frequency,which may cause the fluctuations in intrinsic parameters of nuclear power generating sets. Also the withdrawal of nuclear Power units will cause the system to lose substantive active Power making the malfunction even worse.
In order to investigate the interaction between nuclear power units and power grid under serious disturbance, the paper study the mathematical model and simulation model of Taishan nuclear power units.The characteristics of pressurized water reactor plant are simulated in fault modes.Simulative results show that.it is not necessary to take special measures for normal faults which are removed rapidly and correctly:special measures have to be taken if the fault stays because of the incorrect protection operations,which may cause unit synchronization loss.
引文
[1]刑运民,陶永红.能源与发电技术[M].西安:西安电子科技大学出版社2007.
[2]王大中.21世纪中国能源科技发展展望[M].北京:清华大学出版社,2007.
[3]刘映尚,张伯明,谢昌渝.具有大型核电站的电力系统的安全策略和措施[J].中国电力,2003,36(5):20-23.
[4]阎昌琪.核反应堆工程[M].哈尔滨:哈尔滨工程大学出版社,2007.
[5]臧希年,申世飞.核电厂系统及设备[M].北京:清华大学出版社,2003.
[6]周修铭,干福麟,衷文华.适用于分析大扰动下机网相互影响的压水堆核电站数学模型研究[LIl_核动力工程,1996,17(1):6-11.
[7]段新会.压水堆堆芯系统建模及其控制系统仿真研究[D].华北电力大学,2001.
[8]赵洁,刘涤尘,吴耀文.压水堆核电厂接入电力系统建模[J].中国电机工程学报,2009,29(31):8-13.
[9]施希.大型压水堆核电站接入电网的理论和技术研究[D].武汉大学,2009.
[10]张学成,胡学浩,周修铭,等.具有核电模型的中期动态模拟程序开发及大型核电站与电力系统相互影响的研究[J].电网技术,1995,19(2):5-10.
[11]熊莉,刘涤尘,赵洁,等.大型核电站的建模及接入电网的相互影响[J1.电力自动化设备,2011,31(5):10-14.
[12]高慧敏,孙蓉,徐政.田湾核电机组动态模型研究及其对江苏电网系统扰动的响应分析[LIl_华东电力,2006,34(5):6-9.
[13]Hu Xuehao,Zheng Xuecheng,et a1.Pressurized water reactor nuclear powerplant(NPP)modeling and the midterm dynamic simulation after NPP has beenintroducedinto power system[C].//TEEETENCON’93,Beijing,China:1993:367.370.
[14]DustinRO,JiaHou,GaryG,et a1.Development ofamodempressurizedwaterreactor simulator:instrumentation,design mad data acquisition[C].NuclearScience Symposium Conference,Honolulu,USA,2007.
[15]王正风,王厚文.同步发电机暂态分析中模型的合理选择[J].华东电力,2003,8:4.8.
[16]倪以信,陈寿孙,张宝霖.动态电力系统的理论和分析[M].北京:清华大学出版社,2002.
[17]杨靖萍.大规模互联电力系统动态等值方法研究[D].浙江大学.2007,7.
[18]鄂志君.基于PSCAD/EMTDc的电力系统机电暂态与电磁暂态混合仿真[D].天津大学,2005.
[19]龙云.同步发电机励磁调节参数优化[D].浙江大学,2003.
[20]姚玉斌,吴志良,王丹,等.电力系统变压器模型分析J].继电器,2007,35(24):16-20.
[21]何仰赞,温增银,汪馥瑛,等.电力系统分析[M].武汉:华中理工大学出版社,1996.
[22]王锡凡,方万良,杜正春.现代电力系统分析[M].北京:科学出版社,2003.
[23]Smith J M.Mathematical Modeling&Digital Simul~ion for Engineers&Scientists[M].Wiley&Sons Inc,1997:75-98.
[24]Li Xiong,Liu Dichen,Wang Bo,et a1.Dynamic characteristics analyse ofpressurized water reactor nuclear power plant based on PSASP[C]//4th IEEEConference on Industrial Electronics and Applications.Xi’an,China:IEEE,2009:3629.3634.
[25]Brendan K,John K,Harvey L,et a1.Nuclear Generating Stations andTransmission Grid Reliability[J].2007 39“North American Power System(NAPS2007).2007IEEE.279-287.
[26]韩祯祥.电力系统稳定[M].北京:中国电力出版社,1995.
[27]Interaction of Grid Characteristics With Design and Performance of NuclearPower Plants-A Guide book[R].IAEA Technical Report,Series No 224,1983.
[28]Sang-Seung Lee,Jong-Keun Park,Seung-II Moon,et a1.Small nuclear powergeneration units,and electric power system interconnection[J].PowerEngineering Society General Meeting,2006IEEE,Montreal,Que.2006:1-6.
[29]Prabha Kundur Power System Stability and Control[M].北京:中国电力出版社,2002.
[30]林金东,胡永泰.浅述大型核电机组接入福建电网出现的问题及其对策[J1.福建电力与电工,1997,17(4):23-24.
[31]沈如刚,许慧中.核电站与电网的相互影响[J1.广东电力,1996,3:20-23.
[32]张森如.先进压水堆核电站关键技术研究开发综述[J].核动力工程,2002,23(2):1-6.
[33]中国南方电网电力调度通信中心.中国南方电网2009年运行方式[z].2008,12.
[34]中华人民共和国电力行业标准.《电力系统安全稳定导则DL755-2001》[S].
[35]王葵.核电机组投产后山东电网调峰情况分析[J].山东电力技术,1996,(2):13.16.
[36]周秋森.核电站的调峰运行[J].华东电力,1991,(4):53-54.
[37]郑秀波,刘云,孙景强.广东电网核电机组调峰分析[s1.电力技术,2010,19(13-14):82-85.
[38]Trehan N K,Saran R.Nuclear power revival[C].Nuclear Science Symposium Conference,Portlmad,USA,2003.
[39]Maldonado G I.The performance ofNorth American nuclear power plants duringthe electric power blackout of August 14,2003[C].Nuclear Science SymposiumConference,Rome,Italy,2004.
[2]王大中.21世纪中国能源科技发展展望[M].北京:清华大学出版社,2007.
[3]刘映尚,张伯明,谢昌渝.具有大型核电站的电力系统的安全策略和措施[J].中国电力,2003,36(5):20-23.
[4]阎昌琪.核反应堆工程[M].哈尔滨:哈尔滨工程大学出版社,2007.
[5]臧希年,申世飞.核电厂系统及设备[M].北京:清华大学出版社,2003.
[6]周修铭,干福麟,衷文华.适用于分析大扰动下机网相互影响的压水堆核电站数学模型研究[LIl_核动力工程,1996,17(1):6-11.
[7]段新会.压水堆堆芯系统建模及其控制系统仿真研究[D].华北电力大学,2001.
[8]赵洁,刘涤尘,吴耀文.压水堆核电厂接入电力系统建模[J].中国电机工程学报,2009,29(31):8-13.
[9]施希.大型压水堆核电站接入电网的理论和技术研究[D].武汉大学,2009.
[10]张学成,胡学浩,周修铭,等.具有核电模型的中期动态模拟程序开发及大型核电站与电力系统相互影响的研究[J].电网技术,1995,19(2):5-10.
[11]熊莉,刘涤尘,赵洁,等.大型核电站的建模及接入电网的相互影响[J1.电力自动化设备,2011,31(5):10-14.
[12]高慧敏,孙蓉,徐政.田湾核电机组动态模型研究及其对江苏电网系统扰动的响应分析[LIl_华东电力,2006,34(5):6-9.
[13]Hu Xuehao,Zheng Xuecheng,et a1.Pressurized water reactor nuclear powerplant(NPP)modeling and the midterm dynamic simulation after NPP has beenintroducedinto power system[C].//TEEETENCON’93,Beijing,China:1993:367.370.
[14]DustinRO,JiaHou,GaryG,et a1.Development ofamodempressurizedwaterreactor simulator:instrumentation,design mad data acquisition[C].NuclearScience Symposium Conference,Honolulu,USA,2007.
[15]王正风,王厚文.同步发电机暂态分析中模型的合理选择[J].华东电力,2003,8:4.8.
[16]倪以信,陈寿孙,张宝霖.动态电力系统的理论和分析[M].北京:清华大学出版社,2002.
[17]杨靖萍.大规模互联电力系统动态等值方法研究[D].浙江大学.2007,7.
[18]鄂志君.基于PSCAD/EMTDc的电力系统机电暂态与电磁暂态混合仿真[D].天津大学,2005.
[19]龙云.同步发电机励磁调节参数优化[D].浙江大学,2003.
[20]姚玉斌,吴志良,王丹,等.电力系统变压器模型分析J].继电器,2007,35(24):16-20.
[21]何仰赞,温增银,汪馥瑛,等.电力系统分析[M].武汉:华中理工大学出版社,1996.
[22]王锡凡,方万良,杜正春.现代电力系统分析[M].北京:科学出版社,2003.
[23]Smith J M.Mathematical Modeling&Digital Simul~ion for Engineers&Scientists[M].Wiley&Sons Inc,1997:75-98.
[24]Li Xiong,Liu Dichen,Wang Bo,et a1.Dynamic characteristics analyse ofpressurized water reactor nuclear power plant based on PSASP[C]//4th IEEEConference on Industrial Electronics and Applications.Xi’an,China:IEEE,2009:3629.3634.
[25]Brendan K,John K,Harvey L,et a1.Nuclear Generating Stations andTransmission Grid Reliability[J].2007 39“North American Power System(NAPS2007).2007IEEE.279-287.
[26]韩祯祥.电力系统稳定[M].北京:中国电力出版社,1995.
[27]Interaction of Grid Characteristics With Design and Performance of NuclearPower Plants-A Guide book[R].IAEA Technical Report,Series No 224,1983.
[28]Sang-Seung Lee,Jong-Keun Park,Seung-II Moon,et a1.Small nuclear powergeneration units,and electric power system interconnection[J].PowerEngineering Society General Meeting,2006IEEE,Montreal,Que.2006:1-6.
[29]Prabha Kundur Power System Stability and Control[M].北京:中国电力出版社,2002.
[30]林金东,胡永泰.浅述大型核电机组接入福建电网出现的问题及其对策[J1.福建电力与电工,1997,17(4):23-24.
[31]沈如刚,许慧中.核电站与电网的相互影响[J1.广东电力,1996,3:20-23.
[32]张森如.先进压水堆核电站关键技术研究开发综述[J].核动力工程,2002,23(2):1-6.
[33]中国南方电网电力调度通信中心.中国南方电网2009年运行方式[z].2008,12.
[34]中华人民共和国电力行业标准.《电力系统安全稳定导则DL755-2001》[S].
[35]王葵.核电机组投产后山东电网调峰情况分析[J].山东电力技术,1996,(2):13.16.
[36]周秋森.核电站的调峰运行[J].华东电力,1991,(4):53-54.
[37]郑秀波,刘云,孙景强.广东电网核电机组调峰分析[s1.电力技术,2010,19(13-14):82-85.
[38]Trehan N K,Saran R.Nuclear power revival[C].Nuclear Science Symposium Conference,Portlmad,USA,2003.
[39]Maldonado G I.The performance ofNorth American nuclear power plants duringthe electric power blackout of August 14,2003[C].Nuclear Science SymposiumConference,Rome,Italy,2004.
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