引文
[1]刘振亚.特高压直流电气设备[M].北京:中国电力出版社,2009.LIU Zhen-ya.HVDC equipment[M].Beijing:China Electric Power Press,2009.
[2]袁清云.特高压直流输电技术现状及在我国的应用前景[J].电网技术,2005,29(14):1-3.YUAN Qing-yun.Present state and application prospect of ultra HVDC transmission in China[J].Power System Technology,2005,29(14):1-3.
[3]杨万开,印永华,王明新,等.灵宝背靠背直流工程换流站和系统调试总结[J].电网技术,2006,30(19):36-41.YANG Wan-kai,YIN Yong-hua,WANG Ming-xin,et al.Summary of converter station commissioning and system commissioning for lingbao back to back HVDC project[J].Power System Technology,2006,30(19):36-41.
[4]杨万开,王明新,曾南超,等.灵宝背靠背直流工程系统调试中的关键技术分析[J].电网技术,2007,31(10):32-37.YANG Wan-kai,WANG Ming-xin,ZENG Nan-chao,et al.Analysis on several key technologies applied in system commissioning of Lingbao back-to-back HVDC project[J].Power System Technology,2007,31(10):32-37.
[5]赵军.“云-广”特高压直流输电滤波电容器装置的设计与调试[J].电力电容器与无功补偿,2010,31(1):48-50.ZHAO Jun.Design and debugging on the capacitor bank for Yun-Guang HVDC poject[J].Power Capacitor&Reactive Power Compensation,2010,31(1):48-50.
[6]赵畹君.高压直流输电工程技术[M].第2版.北京:中国电力出版社,2011.ZHAO Wan-jun.High voltage direct current engineering technology[M].The Second Edition.Beijing:China ElectricPower Press,2011.
[7]刘小刚,王茂忠,种芝艺,等.宝鸡换流站阀厅电气连接及金具设计特点[J].电力建设,2011,32(9):24-29.LIU Xiao-gang,WANG Mao-zhong,CHONG Zhi-yi,et al.Electric connections and fittings design in vall hall of±500 kV Baoji converter station[J].Electric Power Construction,2011,32(9):24-29.
[8]刘水平,饶娣.±500 kV超高压直流输电直流滤波电容器及装置的开发[J].电力电容器与无功补偿,2009,30(1):1-3.LIU Shui-ping,RAO Di.Development of DC filtering capacitors and installations for±500 kV extra HVDC transmission[J].Power Capacitor&Reactive Power Compensation,2009,30(1):1-3.
[9]国家电网公司直流建设分公司.高压直流输电系统成套标准化设计[M].北京:中国电力出版社,2012.State Grid Corporation of DC Construction Branch.Complete sets of standardized design of the HVDC system[M].Beijing:China Electric Power Press,2012.
[10]张凌,杨金根,曾静.特高压阀厅电气设计研究[J].电力建设,2007,28(5):12-16.ZHANG Ling,YANG Jin-gen,ZENG Jing.Study on electric design of UHV valve hall[J].Electric Power Construction,2007,28(5):12-16.
[11]吴轶,杨春,蔡健,等.阀厅结构悬吊设备地震作用的简化计算方法[J].广西大学学报:自然科学版,2012,37(1):41-48.WU Yi,YANG Chun,CAI Jian,et al.A simplified method for earthquake actions on suspended equipments in valvehall structures[J].Journal of Guangxi University:Natural Science Edition,2012,37(1):41-48.
[12]王丽杰,杨金根.高岭背靠背换流站阀厅金具设计[J].电力建设,2009,30(9):31-35.WANG Li-jie,YANG Jin-gen.Hardware design of Gaoling back-to-back conversion station valve hall[J].Electric Power Construction,2009,30(9):31-35.
[13]张广洲,万保权,路遥,等.特高压交流试验基地电晕噪声抑制[J].高电压技术,2008,34(11):2300-2304.ZHANG Guang-zhou,WAN Bao-quan,LU Yao,et al.Restraint of corona noise in UHV AC test base[J].High Voltage Engineering,2008,34(11):2300-2304.
[14]王栋,阮江军,杜志叶,等.±660 kV直流换流站阀厅内金具表面场强数值求解[J].高电压技术,2011,37(10):2594-2600.WANG Dong,RUAN Jiang-jun,DU Zhi-ye,et al.Numerical,mlution of electric power fittings about surface electric field in±660 kV DC collverter station valve hall[J].Hish Voltage Engineering,2011,37(10):2594-2600.
[15]董吉谔.电力金具手册[M].第2版.北京:中国电力出版社,2001.DONG Ji-e.Electrical fittings manual[M].The Second Edition.Beijing:China Electric Power Press,2001.
[16]黄玲,曾静,张先伟.±660 kV阀厅金具采购技术规范研究[J].中国电力,2012,45(6):26-29.HUANG Ling,ZENG Jing,ZHANG Xian-wei.Study on technical specification of±660 kV valve hall fittings[J].Electric Power,2012,45(6):26-29.
[17]GB/T 2314—2008.电力金具通用技术条件[S].GB/T 2314—2008.General technical requirements for electric power fittings[S].
[18]DL/T 758—2009.接续金具[S].DL/T 758—2009.Splicing fittings[S].
[19]张文亮,于永清,李光范,等.特高压直流技术研究[J].中国电机工程学报,2007,27(22):1-7.ZHANG Wen-liang,YU Yong-qing,LI Guang-fan,et al.Researches on UHVDC technology[J].Proceedings of the Chinese Society for Electrical Engineering,2007,27(22):1-7.
[20]刘振亚,舒印彪,张文亮,等.直流输电系统电压等级序列研究[J].中国电机工程学报,2008,28(10):1-8.LIU Zhen-ya,SHU Yin-biao,ZHANG Wen-liang,et al.Study on voltage class series for HVDC transmission system[J].Proceedings of the CSEE,2008,28(10):1-8.
[21]舒印彪,刘泽洪,高理迎,等.±800 kV 6 400 MW特高压直流输电工程设计[J].电网技术,2006,30(1):1-8.SHU Yin-biao,LIU Ze-hong,GAO Li-ying,et al.A preliminary exploration for design of±800 kV UHVDC project with transmission capacity of 6 400 MW[J].Power System Technology,2006,30(1):1-8.