CSAMT法在昆玉线宝峰深埋隧道勘察中的应用
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摘要
宝峰深埋隧道洞深附近地质情况复杂,需对岩体完整性进行评价。依据可控源音频大地电磁法(CSAMT)的带地形二维非线性共轭梯度(NLCG)反演结果,把电阻率异常分为Ⅴ类、Ⅳ类、Ⅲ类及Ⅱ类,分别对应极破碎岩体(Ⅴ级围岩)、破碎岩体(Ⅳ级围岩)、较破碎岩体(Ⅲ级围岩)和完整岩体(Ⅱ级围岩)。结合围岩分级结果,查明了宝峰深埋隧道洞深附近岩性、断层破碎带及岩溶位置,对岩体完整性进行了评估。经钻孔及地质资料验证,CSAMT勘探达到了预期效果。
Based on the NLCG inversion results of CSAMT,resistivity anomaly of CSAMT data were divided into four types(type Ⅴ,type Ⅳ,type Ⅲ and type Ⅱ),four tunnels(route) in the lines were compared and one of them was recommended in the light of engineering geological condition-based extent of anomaly and hard rock.Ac-cording to the rock classification results,we identified the distribution of fault fracture zone and karst area,and we also assessed the integrity of the rock.Verified by drilling and geological data,CSAMT exploration reached the desired results.
Based on the NLCG inversion results of CSAMT,resistivity anomaly of CSAMT data were divided into four types(type Ⅴ,type Ⅳ,type Ⅲ and type Ⅱ),four tunnels(route) in the lines were compared and one of them was recommended in the light of engineering geological condition-based extent of anomaly and hard rock.Ac-cording to the rock classification results,we identified the distribution of fault fracture zone and karst area,and we also assessed the integrity of the rock.Verified by drilling and geological data,CSAMT exploration reached the desired results.
引文
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[9]孙英勋.CSAMT法在高速公路长大深埋隧道勘察中的应用研究[J].地球物理学进展,2005,20(4):1184-1189.
[2]汤井田,何继善.可控源音频大地电磁法及其应用[M].长沙:中南大学出版社,2005:250-285.
[3]李坚,邓红科,张家德,等.可控源音频大地电磁勘探在大瑞铁路高黎贡山隧道地质选线中的应用[J].水文地质工程地质,2009(2):72-76.
[4]汤井田,周聪,邓晓红.CSAMT视电阻率曲线对水平层状大地的识别与分辨[J].地质与勘探,2010,46(6):1079-1086.
[5]黄力军,孟银生,陆桂福.可控源音频大地电磁测深在深部地热资源勘查中的应用[J].物探化探计算技术,2007,29(增刊):60-63.
[6]安志国,底青云.CSAMT法对低阻薄层结构分辨能力的探讨[J].地震地磁观测与研究,2006,27(2):32-37.
[7]何继善.可控源音频大地电磁法[M].长沙:中南大学出版社,1990:91-114.
[8]王艳,林君,周逢道,等.CSAMT法深部低阻分辨能力及方法研究[J].中国矿业大学学报,2009,38(1):86-90.
[9]孙英勋.CSAMT法在高速公路长大深埋隧道勘察中的应用研究[J].地球物理学进展,2005,20(4):1184-1189.
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