采煤突水安全敏感性的AHP-熵权法分析

金属矿山 ›› 2016, Vol. 45 ›› Issue (11): 162-166.

采煤突水安全敏感性的AHP-熵权法分析

胡涛^1,2，夏洪春^1,2，赵德深^1,2

1.大连大学建筑工程学院，辽宁大连 116622；2.辽宁省复杂结构体系灾害预测与防治重点实验室，辽宁大连 116622

出版日期:2016-11-15 发布日期:2017-02-15
基金资助:
基金项目：国家自然科学基金项目（编号：51274051,51574055）。

AHP-Entropy Weight Analysis on Safety Sensitivity of Water Inrush during Mining

Hu Tao^1,2 ，Xia Hongchun^1,2 ，Zhao Deshen^1,2

1.College of Architecture and Engineering,Dalian University,Dalian 116622,China；2.Liaoning Provincial Key Laboratory of Complex Structure System Disaster Prediction and Prevention,Dalian 116622,China

Online:2016-11-15 Published:2017-02-15

摘要/Abstract

摘要： 以不同矿区综采导水裂隙带高度的实例数据作为分析样本，利用Mathmatica软件对影响采煤突水安全的地质构造条件、岩石力学强度和开挖扰动等因素进行概化分析建立评估模型，运用AHP-熵权理论对导水裂隙带发育敏感性因素进行综合评估，从而对采煤突水安全性进行评价并提出相应的安全措施。研究表明：地下水位和开采厚度是影响导水裂隙带发育的各因素中所占权重最大的2个因素，其次是硬岩系数。地下水位与裂隙带高度大致呈指数增长关系，采厚与裂隙带高度大致呈二次函数的关系。由此可知，控制采厚和留设防水煤岩柱能大大降低导水裂隙带的高度，且优化采煤工作面有利于进一步减少突水灾害。该研究丰富了矿井顶板水害防范的方法，对水体下深部矿井的安全生产具有实际的指导意义。

关键词: AHP, 熵权法, 导水裂隙带, 突水, 敏感性分析

Abstract: Taking instance data of height of water flowing fractured zone from different mining area as analysis samples,the influential factors about geological structure conditions,mechanical strength of rock and excavation disturbance have been analyzed briefly,and the evaluation model has been established by Mathmatica.The sensitivity factors for development of water flowing fractured zone were evaluated comprehensively based on AHP-entropy weight theory so as to evaluate the safety of water inrush during mining and put forward the corresponding security measures.This research indicated that groundwater and mining thickness are the uppermost factors which affect the height of the water flowing fractured zone,and next is the coefficient of hard rock.There is an exponential increase relationship between groundwater level and the height of fractured zone,the quadric relationship between mining thickness and the height of fracture zone is approximately apparent.Therefore,controlling mining thickness and leaving waterproof coal pillar can significantly reduce the height of water flowing fractured zone,optimization of working face will be beneficial to further reduce the water inrush disaster.The method of mine roof flood prevention is enriched by this research.It has practical guiding significance for the safety production of deep mine under water body.

Key words: AHP, Entropy weight method, Water flowing fractured zone, Water inrush, Sensitivity analysis

胡涛, 夏洪春, 赵德深. 采煤突水安全敏感性的AHP-熵权法分析[J]. 金属矿山, 2016, 45(11): 162-166.

HU Tao, XIA Hong-Chun, ZHAO De-Shen. AHP-Entropy Weight Analysis on Safety Sensitivity of Water Inrush during Mining[J]. Metal Mine, 2016, 45(11): 162-166.

[1]	尹会永, 赵涵, 徐琳, 赵翠月, 马登贤, 丛顺明. 岩体质量分级的改进模糊综合评价法[J]. 金属矿山, 2020, 49(07): 53-58.
[2]	余晨, 唐明杰, 王大国, 李莎莎. 露天采场土地复垦适宜性评价的FAHP-Entropy赋权法[J]. 金属矿山, 2018, 47(11): 138-143.
[3]	薛森, 李文平, 郭启琛, 刘士亮, 孙梦雅, 范宝江. 基于FAHP-GRA评价方法的顶板承压含水层富水性预测研究[J]. 金属矿山, 2018, 47(04): 168-172.
[4]	郭进平, 张星, 李世伦. 非煤矿山安全管理的生态系统理论研究[J]. 金属矿山, 2018, 47(03): 168-172.
[5]	杨斌, 杨天鸿, 师文豪, 杨鑫. 基于非达西流模型的煤矿突水渗流机制数值模拟[J]. 金属矿山, 2017, 46(06): 180-185.
[6]	尹彬, 陆卫东, 贾宝山, 刘闯. 岩爆危险性评价的变权物元可拓模型[J]. 金属矿山, 2017, 46(05): 54-59.
[7]	冯伟, 毛燕军, 耿克普. 极软弱围岩巷道反演参数敏感性分析[J]. 金属矿山, 2016, 45(10): 59-64.
[8]	黄东旭, 李仲学, 李翠平, 赵怡晴, 张聪. 矿井突水仿真构模及系统实现[J]. 金属矿山, 2016, 45(08): 155-160.
[9]	魏晓明, 李长洪. 胶结充填体强度敏感性分析及灰砂比优化[J]. 金属矿山, 2016, 45(06): 37-42.
[10]	夏冬, 袁雪涛, 常宏. 中关铁矿堵水帷幕内外水位变化规律[J]. 金属矿山, 2016, 45(05): 31-35.
[11]	任海芝, 洪曼绮. 台阶爆破效果的熵权物元可拓法综合评价[J]. 金属矿山, 2016, 45(01): 1-7.
[12]	王文才, 赵婧雯, 付鹏, 张培, 王鑫宙, 张根源. 露天矿生态环境的AHP与模糊数学评价法[J]. 金属矿山, 2016, 45(01): 146-150.
[13]	熊立新, 罗周全, 吴超, 石东平, 贾楠. 深井受限空间职业危害程度辨析方法[J]. 金属矿山, 2014, 43(11): 132-137.
[14]	李文光, 冀东, 孙英安. 千米深盲竖井下行前进式注浆堵水施工技术[J]. 金属矿山, 2014, 43(09): 30-34.
[15]	阮竹恩, 李翠平, 李仲学. 地下突水隐患识别与风险预测的改进D-S算法[J]. 金属矿山, 2014, 43(09): 142-146.