电力勘测设计
電力勘測設計
전력감측설계
ELECTRIC POWER SURVEY
2015年
z1期
99-104,135
,共7页
严文根%高倚山%张建龙%胡钧
嚴文根%高倚山%張建龍%鬍鈞
엄문근%고의산%장건룡%호균
特高压%直流输电%接地极%大地电阻率%物探
特高壓%直流輸電%接地極%大地電阻率%物探
특고압%직류수전%접지겁%대지전조솔%물탐
UHV%HVDC transmission%earth electrode%soil resistivity%geophysics methods
在特高压直流线路的送、受端,与换流站配套的接地极承担着单极运行时形成大地回路的电极作用,其选址、设计对整个线路的安全运行极其重要。接地极的设计包括接地电阻、跨步电压等计算均需要准确可信的地层电阻率资料。特别是在锦屏-苏南线路同里换流站庙泾接地极及溪洛渡-浙西金华换流站金丝接地极单极运行引起附近变电站偏磁报警事件之后,对接地极深部(地下50 km)地层电阻率的测试尤显重要。针对设计方的要求,根据几种物探方法的应用条件及其主要的优势、劣势,提出了一套测试方法的组合,即用常规对称四极了解极环埋深处(地下3~4 m)和300 m以浅地层的电阻率分层,用可控源声频大地电磁(CSAMT)了解300 m~3 km地层电阻率,用大地电磁(MT)了解3~50 km地层电阻率。实践证明该方法组合既很好满足了设计需求,也具有较好经济性和可操作性,可以在一定范围内推广。
在特高壓直流線路的送、受耑,與換流站配套的接地極承擔著單極運行時形成大地迴路的電極作用,其選阯、設計對整箇線路的安全運行極其重要。接地極的設計包括接地電阻、跨步電壓等計算均需要準確可信的地層電阻率資料。特彆是在錦屏-囌南線路同裏換流站廟涇接地極及溪洛渡-浙西金華換流站金絲接地極單極運行引起附近變電站偏磁報警事件之後,對接地極深部(地下50 km)地層電阻率的測試尤顯重要。針對設計方的要求,根據幾種物探方法的應用條件及其主要的優勢、劣勢,提齣瞭一套測試方法的組閤,即用常規對稱四極瞭解極環埋深處(地下3~4 m)和300 m以淺地層的電阻率分層,用可控源聲頻大地電磁(CSAMT)瞭解300 m~3 km地層電阻率,用大地電磁(MT)瞭解3~50 km地層電阻率。實踐證明該方法組閤既很好滿足瞭設計需求,也具有較好經濟性和可操作性,可以在一定範圍內推廣。
재특고압직류선로적송、수단,여환류참배투적접지겁승담착단겁운행시형성대지회로적전겁작용,기선지、설계대정개선로적안전운행겁기중요。접지겁적설계포괄접지전조、과보전압등계산균수요준학가신적지층전조솔자료。특별시재금병-소남선로동리환류참묘경접지겁급계락도-절서금화환류참금사접지겁단겁운행인기부근변전참편자보경사건지후,대접지겁심부(지하50 km)지층전조솔적측시우현중요。침대설계방적요구,근거궤충물탐방법적응용조건급기주요적우세、열세,제출료일투측시방법적조합,즉용상규대칭사겁료해겁배매심처(지하3~4 m)화300 m이천지층적전조솔분층,용가공원성빈대지전자(CSAMT)료해300 m~3 km지층전조솔,용대지전자(MT)료해3~50 km지층전조솔。실천증명해방법조합기흔호만족료설계수구,야구유교호경제성화가조작성,가이재일정범위내추엄。
An earth electrode helps to make up the current circuit in the earth when the transmission line works with single phase, so it plays an important role in the safe operation of the transmission line. The accurate and reliable data on soil resistivity data is required for design and calculation of an earth electrode. Especially, after the magnetic biasing alarm events of Xiluodu-Zhexi ±800kV UHVDC project and Jinping-Sunan±800kV UHVDC project, dependable data of soil resistivitybecomes more and more important. To provide parameter values for designer, we put forward a combination of geophysics methods based on the analysis of the advantages and disadvantages of those methods. The main idea of the combination is using symmetric quadrupole sounding method for prospecting the electrical distribution of 300m deep rock and soil mass, using CSAMT for 3000m depth prospecting, and using MT for 3km ~ 50km depth prospecting. We applied the combination to several UHVDC projects. The combination’s operability and effectiveness are tested in practice, meanwhile it is relatively economic.
