相邻巷道断面形状选择及联合支护技术研究

doi:10.19286/j.cnki.cci.2024.03.004

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Abstract In order to solve the problems of large deformation and difficult support of roadway surrounding rock under the condition of high stress soft rock, No. 2 coal of Shuguang Mine takeng as an example, the outside-type layout of roadway excavation was adopted. The section shapes of adjacent roadways were selected as “rectangular-rectangular”, “rectangular- special-shaped” and “special-shaped-special-shaped” respectively. Numerical simulation was used to study the deformation characteristics of surrounding rock, the distribution of lateral supporting pressure of surrounding rock and the distribution law of surrounding rock plastic zone after the excavation of the lower roadway. The results showed that the " special-shaped-special-shaped " roadway was smaller than the "rectangular-special-shaped" roadway and the "rectangular-rectangular" roadway, and the surrounding rock displacement, lateral support stress and plastic zone of the surrounding rock were the smallest. The shape-shaped roadway was used as the cross-section shape of the roadway along the roadway. Three-dimensional combined support technology was adopted between adjacent roadways, and through on-site monitoring, the maximum roof subsidence was 144mm, the maximum floor heave was 91mm, and the maximum displacement of two sides was 315mm, which reduced the deformation of surrounding rock in the lower roadway.

Key words： roadway excavation along goaf cross-section shapes numerical simulation joint support

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	Articles by authors
	Pei Yanfei
	Li Yongjun

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Pei Yanfei,Li Yongjun. Study on cross-section shape selection and combined support technology[J]. CCI, 2024, 47(3): 17-21.

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http://www.mtyhg.com.cn/EN/10.19286/j.cnki.cci.2024.03.004 OR http://www.mtyhg.com.cn/EN/Y2024/V47/I3/17

[ 1 ] 周宏伟，谢和平，左建平.深部高地应力下岩石力学行为研究进展[ J ]. 力学进展，2005， 35（ 1 ）：191 - 199. [ 2 ] 王连国，张健，李海亮. 软岩巷道锚注支护结构蠕变分析[ J ]. 中国矿业大学学报，2009，38（ 5 ）：607 - 612 . [ 3 ] 何满潮，谢和平，彭苏萍，等. 深部开采岩体力学研究[ J ]. 岩土力学与工程学报，2005，24（ 16 ）：2 804 - 2 812. [ 4 ] 路沙沙，麻凤海，路艳艳. 冲击载荷作用下不同断面形状巷道稳定性数值仿真分析[ J ]. 安全与环境学报，2017，17（ 1 ）：76 - 80. [ 5 ] 付强，赵玉成，何东旭，等. 巷道形状对高应力软岩巷道变形的影响[ J ]. 煤矿安全，2014，45（ 9 ）：197 - 199. [ 6 ] 孟庆彬，韩立军，乔卫国，等. 深部高应力软岩巷道断面形状优化设计数值模拟研究[ J ]. 采矿与安全工程学报，2012，29（ 5 ）：650 - 656. [ 7 ] 李桂臣，张农，王成，等. 高地应力巷道断面形状优化数值模拟研究[ J ]. 中国矿业大学学报，2010，39（ 5 ）：652 - 658. [ 8 ] 戴永浩，陈卫忠，刘泉声，等. 深部高地应力巷道断面优化研究[ J ]. 岩石力学与工程学报，2004，23（ s2 ）：4 960 - 4 965. [ 9 ] 冯伟，韩立军. 基于ABAQUS数值模拟的采区巷道断面形状优化研究[ J ]. 煤炭工程，2013（ 2 ）：83 - 86. [ 10 ] 王文，朱维申. 采用非连续变形分析方法分析巷道的稳定性[ J ]. 地下空间与工程学报，2014，10（ 3 ）：705 - 710，715. [ 11 ] 赵宣宣. 厚松软煤层巷道掘进断面形状优化数值研究[ J ]. 山东煤炭科技，2018（ 3 ）：43 - 45. [ 12 ] 马德鹏，杨永杰，曹吉胜，等. 基于能量释放的深井巷道断面形状优化[ J ]. 中南大学学报（自然科学版），2015，46（ 9 ）：3 354 - 3 360. [ 13 ] 曹树刚，王帅，王寿全，等. 大倾角煤层回采巷道断面适应性[ J ]. 东北大学学报（自然科学版），2017，38（ 3 ）：436 - 441. [ 14 ] 李浩春，苏学贵，杨永康. 大倾角特厚复合顶板巷道支护稳定性分析[ J ]. 金属矿山，2013（ 12 ）：5 - 8，12. [ 15 ] 王志强，石磊，苏越，等. 特厚煤层错层位外错巷道围岩控制技术研究[ J ]. 矿业科学学报，2018，3（ 5 ）：470 - 476. [ 16 ] 王志强，苏越，石磊，等. 错层位外错式沿空掘巷机理及相邻巷道的立体化联合支护技术[ J ]. 煤炭学报，2018，43（ S1 ）：12 - 20．