深切河谷区水电站厂址初始应力场规律研究及对地下厂房布置的思考

doi:10.13722/j.cnki.jrme.2014.11.006

Abstract
Figure/Table
References
Related Citation (15)

Download: PDF (20017 KB) HTML (1 KB)
Export: BibTeX | EndNote (RIS)

Abstract In order to understand the spatial distribution of stress tensors of initial geostress field and to identify its relationship with the cavern group arrangement for hydropower plant site in high geostress region of deep valley，a new method and an operation procedure for obtaining a quantitative and fine numerical initial geostress field based on the coupling of 3D initial geostress calculation model and the structural calculation model containing excavation details were proposed considering the evolution process of river valley，using the space analysis method of stress tensor and the multi-core parallel computing technique. Then，the initial geostress field distribution at Jinping I hydropower station was identified with the method and verified against the field phenomenon of deformation and failure. The underground cavern groups of Jinping I hydropower station were found to be in the stress transitional region near the deep valley with the high geostress levels and the large stress variations and the high initial geostress environment was thus formed. The average principal stress ratio is about 1.9–2.5 and the rock strength-stress ratio is about 1.5–3.0 in this transitional region. Under the high initial 3D geostress，the low strength-stress ratio and the high principal stress ratio，the deformation and the failure and the depth of unloading relaxation of the surrounding rock during the construction of the underground powerhouse cavern groups were found to be larger than the ones of the cavern groups of the same size in other projects. The locations and distributions of the stress induced deformation and failure confirm the reasonability of the initial 3D geostress field obtained and also verify that the above proposed quantitative model of geostress field is correct and feasible. On this basis，a method of layout design for the underground powerhouse cavern groups located in high geostress area was proposed，considering the three-dimensional geostress，the strength to stress ratio and the structure characteristic，etc. The proposed design method reflects the load characteristics of caverns，the structure characteristics and the bearing capacity of surrounding rock. Using the above design method，some principles and procedures are put forward from a qualitative point of view，which includs how to determine the location of the main cavern，the longitudinal axis，the cavern spacing and type，etc.

Key words： rock mechanics Jinping I hydropower station underground caverns geostress field quantitative model high geostress

Received: 17 June 2014

	Service

	E-mail this article
	Add to my bookshelf
	Add to citation manager
	E-mail Alert
	RSS
	Articles by authors

Cite this article:

URL:

https://rockmech.whrsm.ac.cn/EN/10.13722/j.cnki.jrme.2014.11.006 OR https://rockmech.whrsm.ac.cn/EN/Y2014/V33/I11/2210

[1] 冯夏庭，江权，苏国韶. 高应力下硬岩地下工程的稳定性智能分析与动态优化[J]. 岩石力学与工程学报，2008，27(7)：1 341–1 352. (FENG Xiating，JIANG Quan，SU Guoshao. Integrated intelligent stability analysis and dynamic optimization of underground engineering in hard rock with high geostress[J]. Chinese Journal of Rock Mechanics and Engineering，2008，27(7)：1 341–1 352.(in Chinese)) [2] 刘允芳，罗超文，刘元坤. 岩体地应力与工程建设[M]. 武汉：湖北科学技术出版社，2000：5–10.(LIU Yunfang，LUO Chaowen，LIU Yuankun. Geostress in rock mass and engineering construction[M]. Wuhan：Hubei Science and Technology Press，2000：5–10.(in Chinese)) [3] 朱焕春，赵海斌. 河谷地应力场的数值模拟[J]. 水利学报，1996，(5)：29–36.(ZHU Huanchun，ZHAO Haibin. Numerical simulation for rock stress field in a valley[J]. Journal of Hydraulic Engineering，1996，(5)：29–36.(in Chinese)) [4] 王涛，周先前，田树斌，等. 基于正交设计的河谷地应力场数值模拟方法及应用[J]. 岩土力学，2004，25(5)：831–835.(WANG Tao，ZHOU Xianqian，TIAN Shubin，et a1. Numerical simulation method for rock natural stress field of a valley and its application based on orthogonal experiments[J]. Rock and Soil Mechanics，2004，25(5)：831–835.(in Chinese)) [5] 袁风波，刘建，李蒲健，等. 拉西瓦工程河谷区高地应力场反演与形成机理[J]. 岩土力学，2007，28(4)：836–842.(YUAN Fengbo，LIU Jian，LI Pujian，et a1. Back analysis and multiple-factor influencing mechanism of high geostress field for river valley region of Laxiwa hydropower engineering[J]. Rock and Soil Mechanics，2007，28(4)：836–842.(in Chinese)) [6] 江权，冯夏庭，黄书岭，等. 锦屏二级水电站厂址区域三维地应力场非线性反演[J]. 岩土力学，2008，29(11)：3 003–3 010.(JIANG Quan，FENG Xiating，HUANG Shuling，et al. Nonlinear inversion of 3D initial geostress field in Jinping II hydropower station region[J]. Rock and Soil Mechanics，2008，29(11)：3 003–3 010.(in Chinese)) [7] 裴启涛，李海波，刘亚群，等. 复杂地质条件下坝区初始地应力场二次反演分析[J]. 岩石力学与工程学报，2014，33(增1)：2 779–2 785.(PEI Qitao，LI Haibo，LIU Yaqun，et al. Two-stage back analysis of initial geostress field of dam areas under complex geological conditions[J]. Chinese Journal of Rock Mechanics and Engineering，2014，33(Supp.1)：2 779–2 785.(in Chinese)) [8] 丁秀丽，卢波，黄书岭，等. 雅砻江锦屏一级水电站技施阶段——高应力低强度应力比条件大型地下洞室群围岩开裂变形机制及稳定性研究[R]. 武汉：长江科学院，2010.(DING Xiuli，LU Bo，HUANG Shuling，et al. Technical construction stage of Jinping I hydropower station on Yalong river—research on stability and fracturing mechanism of surrounding rock mass for large underground powerhouse under conditions of high in-situ stress and low strength stress ratio[R]. Wuhan：Yangtze River Scientific Research Institute，2010.(in Chinese)) [9] 黄书岭，张勇，丁秀丽，等. 大型地下厂房区域地应力场多源信息融合分析方法及工程应用[J]. 岩土力学，2011，32(7)：2 057–2 065. (HUANG Shuling，ZHANG Yong，DING Xiuli，et al. Analytical methods of multi-source information fusion for in-situ stress field of large underground powerhouse region and its application[J]. Rock and Soil Mechanics，2011，32(7)：2 057–2 065.(in Chinese)) [10] 景锋，盛谦，张勇慧，等. 不同地质成因岩石地应力分布规律的统计分析[J]. 岩土力学，2008，29(7)：1 877–1 883.(JING Feng，SHENG Qian，ZHANG Yonghui，et al. Statistical analysis of geostress distribution laws for different rocks[J]. Rock and Soil Mechanics，2008，29(7)：1 877–1 883.(in Chinese)) [11] 郑汉淮，杨静熙，邓卫东，等. 雅砻江锦屏一级水电站可行性研究报告(工程地质)[R]. 成都：中国水电工程顾问集团成都勘测设计研究院，2003.(ZHENG Hanhuai，YANG Jingxi，DENG Weidong，et al. Feasibility study report of Jinping I hydropower project located on Yalong river(engineering geology)[R]. Chengdu：HydroChina Chengdu Engineering Corporation，2003.(in Chinese)) [12] 王士天，黄润秋，李渝生. 雅砻江锦屏水电站重大工程地质问题研究[M]. 成都：成都科技大学出版社，1995：68–99.(WANG Shitian，HUANG Runqiu，LI Yusheng. Research on the major engineering geology issues of Jinping hydropower station on the Yalongjiang river[M]. Chengdu：Chengdu Technology University Press，1995：68–99.(in Chinese)) [13] 周钟，巩满福，侯东奇，等. 四川省雅砻江锦屏一级水电站地下厂房洞室群施工期围岩稳定与支护设计报告(4)[R]. 成都：中国水电工程顾问集团成都勘测设计研究院，2008.(ZHOU Zhong，GONG Manfu，HOU Dongqi，et al. Report on surrounding rock mass stability and support design for underground powerhouse caverns group construction of Jinping I hydropower project located on Yalong river(4)[R]. Chengdu：HydroChina Chengdu Engineering Corporation，2008.(in Chinese)) [14] 黄书岭，徐劲松，丁秀丽，等. 考虑结构面特性的层状岩体复合材料模型与应用研究[J]. 岩石力学与工程学报，2010，29(4)：743–756.(HUANG Shuling，XU Jinsong，DING Xiuli，et al. Study on layered rockmass composite model based on characteristics of structural plane and its application[J]. Chinese Journal of Rock Mechanics and Engineering，2010，29(4)：743–756.(in Chinese)) [15] 黄书岭，王继敏，丁秀丽，等. 基于层状岩体卸荷演化的锦屏I级地下厂房洞室群稳定性与调控[J]. 岩石力学与工程学报，2011，30(11)：2 203–2 216.(HUANG Shuling，WANG Jimin，DING Xiuli，et al. Stability and control for underground caverns of Jinping I hydropower station based on unloading evolution of layered rockmass[J]. Chinese Journal of Rock Mechanics and Engineering，2011，30(11)：2 203–2 216.(in Chinese)) [16] 张勇，肖平西，丁秀丽，等. 高地应力条件下地下厂房洞室群围岩的变形破坏特征及对策研究[J]. 岩石力学与工程学报，2012，31(2)：228–243.(ZHANG Yong，XIAO Pingxi，DING Xiuli，et al. Study of deformation and failure characteristics for surrounding rocks of underground powerhouse caverns under high geostress condition and countermeasures[J]. Chinese Journal of Rock Mechanics and Engineering，2012，31(2)：228–243.(in Chinese)) [17] 中华人民共和国行业标准编写组. SD335—1989水电站厂房设计规范[S]. 北京：水利电力出版社，2003.(The Professional Standards Compilation Group of People?s Republic of China. SD335—1989 Design code for powerhouses of hydropower stations[S]. Beijing：Water Resources and Electric Power Press，2003.(in Chinese)) [18] 中华人民共和国行业标准编写组. SL266—2001水电站厂房设计规范[S]. 北京：中国水利水电出版社，2001.(The Professional Standards Compilation Group of People?s Republic of China. SL266—2001 Design code for hydropower house[S]. Beijing：China Water Power Press，2001.(in Chinese)) [19] 丁秀丽，盛谦，邬爱清，等. 水布垭枢纽地下厂房施工开挖与加固的数值模拟[J]. 岩石力学与工程学报，2002，21(增)：2 162–2 167. (DING Xiuli，SHENG Qian，WU Aiqing，et al. Numerical modeling on the excavation and reinforcement for the underground powerhouse in the Shuibuya project[J]. Chinese Journal of Rock Mechanics and Engineering，2002，21(Supp.)：2 162–2 167.(in Chinese))