基于灰色关联分析的断层突水阶段化感知方法

doi:10.16265/j.cnki.issn1003-3033.2024.07.2086

中国安全科学学报 ›› 2024, Vol. 34 ›› Issue (7): 63-70.doi: 10.16265/j.cnki.issn1003-3033.2024.07.2086

基于灰色关联分析的断层突水阶段化感知方法

孙文斌¹(), 张纪扬¹, 王晓¹, 杨辉¹, 樊建聪², ABDUMALIK Olimov³

¹ 山东科技大学能源与矿业工程学院,山东青岛 266590
² 山东科技大学计算机科学与工程学院,山东青岛 266590
³ 塔吉克斯坦冶金学院地质与油气工程系,塔吉克斯坦苦盏 735730

收稿日期:2024-01-12 修回日期:2024-04-15 出版日期:2024-07-28
作者简介:
孙文斌 (1981—),男,山东郓城人,博士,教授,博士生导师,泰山学者青年专家,主要从事矿山灾变演化智能识别等方面的研究。E-mail: swb@sdust.edu.cn。
樊建聪教授；
ABDUMALIK Olimov 教授
基金资助:
国家自然科学基金面上项目资助(52274131); 泰山学者工程专项经费项目(tsqn202211152); 陕西省煤矿水害防治技术重点实验室开放基金资助(2021SKZD02); 煤炭资源高效开采与洁净利用国家重点实验室开放基金资助(2021-CMCU-KF017)

Staged sensing method of fault sudden water based on gray correlation analysis

SUN Wenbin¹(), ZHANG Jiyang¹, WANG Xiao¹, YANG Hui¹, FAN Jiancong², ABDUMALIK Olimov³

¹ College of Energy and Mining Engineering, Shandong University of Science and Technology, Qingdao Shandong 266590, China
² College of Computer Science and Engineering, Shandong University of Science and Technology, Qingdao Shandong 266590, China
³ Department of Geology and Oil and Gas Works, Mining-metallurgy Institute of Tajikistan, Sugd 735730,Tajikistan

Received:2024-01-12 Revised:2024-04-15 Published:2024-07-28

摘要/Abstract

摘要：

为提升煤矿断层水害感知水平,提出一种以断层活化演变机制和关键控制因素识别的断层突水阶段化感知方法,通过断层突水演化过程相似模拟试验研究工作面底板与断层破坏的演化特征,以底板破坏带应力、断层裂隙带应力、导水通道内水压等为阶段监测参数,揭示各监测参数与涌水量变化的阶段特征;结合灰色关联性分析法,判定断层突水阶段转化的关键控制因素,进而根据断层突水分析与研究过程,提出断层突水阶段化感知方法。结果表明:底板破坏带、断层裂隙带的应力,导水通道内的水压等监测参数的数值变化特征在断层活化突水过程中呈现出明显的阶段特征,控制因素与涌水量的灰色关联度排序为:底板破坏带应力>断层裂隙带应力>导水通道水压,通过对关键控制因素的识别,可实现断层突水阶段的感知,揭示基于灰色关联分析的感知方法在原理上具备可行性。

关键词: 灰色关联性分析, 断层突水, 阶段化感知, 关键控制因素, 相似模拟试验

Abstract:

In order to improve the perception level of fault water damage in coal mine, a fault water inrush stage sensing method based on fault activation evolution mechanism and key control factors was proposed. The evolution characteristics of working face floor and fault failure were studied through similar simulation tests of fault water inrush evolution process. The stage characteristics of monitoring parameters and the change of water inflow were revealed by taking the stress in the failure zone of floor, the stress in the fracture zone of fault and the water pressure in the water channel as the stage monitoring parameters. The key controlling factors of water inrush phase transformation were determined by grey correlation analysis method. Then, according to the fault water inrush analysis and research process, the fault water inrush stage perception method was proposed. The study determines that the numerical variation characteristics of monitoring parameters such as stress of floor failure zone, fault fracture zone and water pressure in water channel show obvious stage characteristics during fault activation water inrush. The order of grey correlation degree between control factors and water inflow is as follows: stress in floor failure zone > stress in fault fracture zone > water pressure in water channel, through identification of key control factors. Through the identification of key control factors, the perception of fault water inrush stage can be realized, and the perception method based on grey correlation analysis is feasible in principle.

Key words: grey correlation degree analysis method, fault water inrush, staged perception, key controlling factors, similar simulation tests

中图分类号:

X936

孙文斌, 张纪扬, 王晓, 杨辉, 樊建聪, ABDUMALIK Olimov. 基于灰色关联分析的断层突水阶段化感知方法[J]. 中国安全科学学报, 2024, 34(7): 63-70.

SUN Wenbin, ZHANG Jiyang, WANG Xiao, YANG Hui, FAN Jiancong, ABDUMALIK Olimov. Staged sensing method of fault sudden water based on gray correlation analysis[J]. China Safety Science Journal, 2024, 34(7): 63-70.

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断层名称	性质	走向	倾向	倾角/ (°)	落差/ m	延展长度/m
F1	正	近SN	W	60~70	0~30	1 900
F2	正	近SN	W	60~70	0~20	880
F3	正	近SN	E	60~70	0~40	2 900
F4	正	近SN	W	60~70	25~90	700

位置	岩性	实际厚度/m	模型厚度/cm	抗压强度/MPa		模拟材料配比
位置	岩性	实际厚度/m	模型厚度/cm	实际强度	模拟强度	模拟材料配比
顶板	砂质泥岩	6.4	4	32.6	0.15	8∶8∶2	石英砂∶碳酸钙∶ 石膏
	细砂岩	20.8	14	42.0	0.19	6∶5∶5
	砾岩	12.6	8	80.6	0.36	8∶6∶4
	砂质泥岩	15.3	10	32.7	0.15	8∶8∶2
	粉砂岩	11.8	8	20.9	0.10	7∶5∶5
煤层	煤层	6	4	15.3	0.07	30∶1∶0.8∶1∶1	石英砂∶ 石蜡∶液压油∶ 碳酸钙∶凡士林
底板	泥岩	14.6	10	93.8	0.42	12∶1.8∶0.7∶1.2∶0.6
	砂质泥岩	10.7	7	75.1	0.33	14∶1.6∶0.7∶1.2∶0.7
	中砂岩	13.2	8	39.7	0.18	18∶0.8∶0.6∶1.2∶0.8
	粉砂岩	11.1	7	28.6	0.13	18∶1∶0.7∶1.2∶0.9
断层	充填物	5.6	4	—		1∶1.2∶0.3	碎石∶河沙∶黏土

基于灰色关联分析的断层突水阶段化感知方法

Staged sensing method of fault sudden water based on gray correlation analysis

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