Engineering rock mechanics practices in the underground powerhouse at Jinping I hydropower station

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• 作者：Aiqing Wu^a ; ^{wuaiqing@vip.sina.com" class="auth_mail" title="E-mail the corresponding author}Author Vitae ; Jimin Wang^b ; Zhong Zhou^c ; Shuling Huang^a ; Xiuli Ding^a ; Zhihong Dong^a ; Yuting Zhang^a
• 关键词：Underground powerhouse ; High geo-stress ; Rock mechanics ; Rock mass stability ; Engineering practice
• 刊名：Journal of Rock Mechanics and Geotechnical Engineering
• 出版年：2016
• 出版时间：October 2016
• 年：2016
• 卷：8
• 期：5
• 页码：640-650
• 全文大小：4751 K

文摘

Based on the analyses of data obtained from the underground powerhouse at Jinping I hydropower station, a comprehensive review of engineering rock mechanics practice in the underground powerhouse is first conducted. The distribution of strata, lithology, and initial geo-stress, the excavation process and corresponding rock mass support measures, the deformation and failure characteristics of the surrounding rock mass, the stress characteristics of anchorage structures in the cavern complex, and numerical simulations of surrounding rock mass stability and anchor support performance are presented. The results indicate that the underground powerhouse of Jinping I hydropower station is characterized by high to extremely high geo-stresses during rock excavation. Excessive surrounding rock mass deformation and high stress of anchorage structures, surrounding rock mass unloading damage, and local cracking failure of surrounding rock masses, etc., are mainly caused by rock mass excavation. Deformations of surrounding rock masses and stresses in anchorage structures here are larger than those found elsewhere: 20% of extensometers in the main powerhouse record more than 50 mm with the maximum at around 250 mm observed in the downstream sidewall of the transformer hall. There are about 25% of the anchor bolts having recorded stresses of more than 200 MPa. Jinping I hydropower plant is the first to have an underground powerhouse construction conducted in host rocks under extremely high geo-stress conditions, with the ratio of rock mass strength to geo-stress of less than 2.0. The results can provide a reference to underground powerhouse construction in similar geological conditions.