富水断层破碎带井筒围岩控制

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摘要针对云南某新建煤矿富水断层破碎带垮塌井筒的修复难题，通过现场调研及数值模拟研究，分析富水断层破碎带井筒围岩垮塌灾变机制，提出此类地质及工程条件下围岩控制基本原则和“顺序–联合”控制方法。研究认为：(1) 断层破碎围岩受水致弱化作用后泥化严重，松散体自承能力低，塑性流动显著，是造成围岩失稳及滑移的根本原因；多次低强度无效巷修并开挖造成冒落高度增加，活化断层裂隙，导通局部含水层，是造成破碎区段大面积垮塌及涌水的直接原因；(2) 破碎围岩失稳滑移过程中存在“应力快速卸压区”、“应力过渡区”及“应力集中区”，控制重点在于针对“应力卸压导水区”进行治水封堵及岩体加固，提高其自身承载能力，降低后期支护载荷；(3) 采用滞后变形区一定距离的变角伞状超前注浆预处理，可实现堵水和加固围岩双重目的。临时支护可为后期一次、二次支护提供空间和时间；(4) 适时采用衬砌预埋注浆管方式对破碎围岩内可能存在的空洞进行壁后二次注浆回填和加固，可以提高“围岩–支护体”整体承载能力。

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关键词 ：采矿工程；主斜井；断层破碎带；灾变机制；顺序&ndash, 联合控制；变角伞状超前注浆

Abstract：In order to repair the collapsed shaft at the watery zone with fault fractures in a new mine in Yunnan province，the basic principles and the“sequence-combined”control method were put forward based on the callapsing mechanism of shaft rocks obtained through on-site research and numerical simulation. The fundamental reasons of the instability and slippage of shaft rocks were found to be the serious degradation of the surrounding rock by water，the low capability of self-supporting and the distinct plastic fluidity of loose rocks in the watery zone with fault fractures. Previous multiple unsuccessful repairing led to the increase of the caving height，the activation of the fault fractures and the unblocking of the local aquifers and caused large area collapses and water gushing in the broken section. The broken surrounding rock during the process of instability and slipping had a zone of quickly release of stress，a zone of transition of stress and a zone of stress concentration. The key measure of controlling the surrounding rock is to block water flow and to reinforce the rock in the zone of stress relieved and containing groundwater flows for improving support ability of the surrounding rock and decreasing the support loading in the following stage. Variation angle umbrella-like ahead grouting are proposed to carry out from a distance behind the deformed area. The temporary support can provide the space and the time for the first and/or the secondary support later. The integral supporting capacity of the surrounding rock can be improved by embedding grouting pipes so that the secondary grouting can be applied to backfill the cavities which may exist in fractured surrounding rock.

Key words： mining engineering main inclined shaft fault fracture zone disaster mechanism sequence-combined control variation angle umbrella-like ahead grouting

收稿日期: 2013-06-28

引用本文:

曹树刚1，洛锋1，2，程崇胜3，李国栋1，郭平4. 富水断层破碎带井筒围岩控制[J]. 岩石力学与工程学报, 2014, 33(8): 1536-1545.
CAO Shugang1，LUO Feng1，2，CHENG Chongsheng3，LI Guodong1，GUO Ping4. SURROUNDING ROCK CONTROL OF SHAFT IN WATER ENRICHED FAULT FRACTURE ZONE. , 2014, 33(8): 1536-1545.

链接本文:

https://rockmech.whrsm.ac.cn/CN/Y2014/V33/I8/1536

[1] 王锦山，王力，曹志刚，等. 厦门海底隧道综合超前地质预报实践[J]. 岩石力学与工程学报，2007，26(11)：2 309–2 317. (WANG Jinshan，WANG Li，CAO Zhigang，et al. Practice on synthetic geological prediction ahead of construction of Xiamen subsea tunnel[J]. Chinese Journal of Rock Mechanics and Engineering，2007，26(11)：2 309–2 317.(in Chinese)) [2] 张志龙，王兰生，王跃飞，等. 雪峰山高速公路隧道F_2断层带的综合超前地质预报[J]. 岩石力学与工程学报，2007，26(增1)：3 311–3 315.(ZHANG Zhilong，WANG Lansheng，WANG Yuefei，et al. Comprehensive advanced geological prediction of fault F_2 in xuefeng mountain highway tunnel[J]. Chinese Journal of Rock Mechanics and Engineering，2007，26(Supp.1)：3 311–3 315.(in Chinese)) [3] 张学文. 金子山隧道穿越F2富水断层带的帷幕注浆综合施工技术探讨[J]. 水利与建筑工程学报，2008，6(4)：63–66.(ZHANG Xuewen. Research on comprehensive construction technique of curtain grouting for F2 of Jinzishan tunnel[J]. Journal of Water Resources and Architectural Engineering，2008，6(4)：63–66.(in Chinese)) [4] 覃卫民，李祺，任伟中，等. 复杂结构形式隧道的围岩位移监测分析[J]. 岩石力学与工程学报，2010，29(3)：549–557.(QIN Weimin，LI Qi，REN Weizhong，et al. Monitoring analysis of surrounding rock displacement of complex structure tunnel[J]. Chinese Journal of Rock Mechanics and Engineering，2010，29(3)：549–557.(in Chinese)) [5] 雷军，白明洲，许兆义，等. 地铁隧道施工期冻结法穿越断层破碎带施工效果现场试验研究[J]. 岩石力学与工程学报，2008，27(7)：1 492–1 498.(LEI Jun，BAI Mingzhou，XU Zhaoyi，et al. In-situ test on construction effect with freezing method for fault-crossing fragmentation zone in metro tunnel[J]. Chinese Journal of Rock Mechanics and Engineering，2008，27(7)：1 492–1 498.(in Chinese)) [6] 顾义磊，李晓红，赵瑜，等. 通渝隧道涌突泥成因分析[J]. 岩土力学，2005，26(6)：920–923.(GU Yilei，LI Xiaohong，ZHAO Yu，et al. Analysis of forming reason of mud breakout in Tong-Yu tunnel[J]. Rock and Soil Mechanics，2005，26(6)：920–923.(in Chinese)) [7] 李利平，李术才，石少帅，等. 基于应力–渗流–损伤耦合效应的断层活化突水机制研究[J]. 岩石力学与工程学报，2011，30(增1)： 3 295–3 304.(LI Liping，LI Shucai，SHI Shaoshuai，et al. Water inrush mechanism study of fault activation induced by coupling effect of stress-seepage-damage[J]. Chinese Journal of Rock Mechanics and Engineering，2011，30(Supp.1)：3 295–3 304.(in Chinese)) [8] 刘恺德，刘泉声，刘滨，等. 地质异常带巷道稳定控制对策及效果研究[J]. 岩石力学与工程学报，2011，30(12)：2 486–2 497.(LIU Kaide，LIU Quansheng，LIU Bin，et al. Research on control measures and effects for roadway stability in geological anomaly zone[J]. Chinese Journal of Rock Mechanics and Engineering，2011，30(12)：2 486–2 497.(in Chinese)) [9] 薛翊国，李术才，苏茂鑫，等. 青岛胶州湾海底隧道涌水断层注浆效果综合检验方法研究[J]. 岩石力学与工程学报，2011，30(7)： 1 382–1 388.(XUE Yiguo，LI Shucai，SU Maoxin，et al. Study of comprehensive test method for grouting effect of water filling fault in Qingdao Kiaochow bay subsea tunnel[J]. Chinese Journal of Rock Mechanics and Engineering，2011，30(7)：1 382–1 388.(in Chinese)) [10] 王金安，魏现昊，陈绍杰. 承压水体上开采底板岩层破断及渗流特征[J]. 中国矿业大学学报，2012，41(4)：536–542.(WANG Jinan，WEI Xianhao，CHEN Shaojie. Fracture and seepage characteristics in the floor strata when above a confined aquifer[J]. Journal of China University of Mining and Technology，2012，41(4)：536–542.(in Chinese)) [11] 郭建伟. 深井节理化围岩巷道破坏机制及控制技术[J]. 煤炭学报，2012，37(9)：1 559–1 563.(GUO Jianwei. Roadway fracture mechanism and control technology of joint fissured surrounding rock in deep mines[J]. Journal of China Coal Society，2012，37(9)：1 559– 1 563.(in Chinese)) [12] 李学华，杨宏敏，刘汉喜，等. 动压软岩巷道锚注加固机制与应用研究[J]. 采矿与安全工程学报，2006，23(2)：159–163.(LI Xuehua，YANG Hongmin，LIU Hanxi，et al. Research on bolt-grouting reinforcement technology in dynamic pressure and soft rock roadway[J]. Journal of Mining and Safety Engineering，2006，23(2)：159–163.(in Chinese)) [13] 王连国，缪协兴，董建涛. 动压巷道锚注支护数值模拟研究[J]. 采矿与安全工程学报，2006，23(1)：39–42.(WANG Lianguo，MIAO Xiexing，DONG Jiantao. Numerical simulation of bolt-grouting support in soft roadway affected by mining[J]. Journal of Mining and Safety Engineering，2006，23(1)：39–42.(in Chinese)) [14] 李桂臣，马振乾，张农，等. 淮北矿区多次跨采巷道破坏特征及控制对策研究[J]. 采矿与安全工程学报，2013，30(2)：181–187.(LI Guichen，MA Zhanqian，ZHANG Nong，et al. Research on failure characteristics and control measures of roadways affected by multiple overhead mining in Huaibei mining area[J]. Journal of Mining and Safety Engineering，2013，30(2)：181–187.(in Chinese)) [15] 张民庆，彭峰. 地下工程注浆技术[M]. 北京：地质出版社，2008：67–120.(ZHANG Minqing，PENG Feng. Grouting technology of underground engineering[M]. Beijing：Geological Publishing House，2008：67–120.(in Chinese))