分层开采煤矿的矿震能量释放模型与能量释放谱
|
摘要
以下行分层开采的我国东北某大型煤矿为工程背景,通过现场微震观测和工程数据分析,探索矿震能量释放的时空分布规律及其工程应用价值.发现在没有显著的外部长周期调制动力流入的矿区,各相同地应力强度环境持续开采引发的矿震能量累积释放的时域分布均符合3参数的S形Logistic阻滞增长模型;不同地应力强度环境间,该模型的3个参数是地应力强度的自相似函数.通过最大主应力建立起不同地应力强度环境开采进程的典型矿震能量释放谱,定量揭示了开采活动与矿震能量释放间的内在联系及力学机理.
Presented a model to quantitatively investigate the spatial and temporal distribution of rockburst energy release and its engineering application at a large-scale coalmine in layered ground in the Northeast region,by adopting approaches of field microseismic monitoring and data analysis.It is found that,in mining areas where there are no obvious long-term external force disturbances,the accumulated total energy release in the time domain at a specific mining level can be described by a three-parameter,S-shaped Logistic model.These three parameters in the model are functions of in-situ stress intensity.Using the maximum principal stress component,a series of energy release curves at different mining depths were calculated to obtain a typical energy release spectrum which quantitatively demonstrates the relationship between mining activity and rockburst energy release.The mechanism of this interrelationship was also investigated.
Presented a model to quantitatively investigate the spatial and temporal distribution of rockburst energy release and its engineering application at a large-scale coalmine in layered ground in the Northeast region,by adopting approaches of field microseismic monitoring and data analysis.It is found that,in mining areas where there are no obvious long-term external force disturbances,the accumulated total energy release in the time domain at a specific mining level can be described by a three-parameter,S-shaped Logistic model.These three parameters in the model are functions of in-situ stress intensity.Using the maximum principal stress component,a series of energy release curves at different mining depths were calculated to obtain a typical energy release spectrum which quantitatively demonstrates the relationship between mining activity and rockburst energy release.The mechanism of this interrelationship was also investigated.
引文
[1]Cook N G W.Seismicity associated with mining[J].Engineering Geology,1976(10):99~122.
[2]修济刚,徐平,杨心平.矿山地震学引论[M].北京:地震出版社,1998.347.
[3]李铁.采矿诱发地震机理及其安全对策的研究[D].北京:北京科技大学,2007.35~94.
[4]Cai M F,Ji HG,Wang J A.Study on the time-space-strength relation for mining seismicity at Laohutai coal mine and its pre-diction[J].International Journal of Rock Mechanics&Mining Sciences,2005(42):145~151.
[5]国家地震局震害防御司.地震工作手册[M].北京:地震出版社,1990.129~130.
[6]钱鸣高,石平五.矿山压力与岩层控制[M].北京:中国矿业大学出版社,2003.297.
[7]李玉寿,李世平.石灰岩三轴压缩全应力应变过程的声发射特性[J].中国矿业大学学报,1993(增):1~7.
[8]贾德义,李新元.唐山矿深部开采冲击地压发生的综合治理[J].中国煤炭,2000,26(7):18~20.
[9]阿维尔申СГ.冲击地压[M].朱敏,汪伯煜,韩金祥,译.北京:煤炭工业出版社,1959.200~202.
[2]修济刚,徐平,杨心平.矿山地震学引论[M].北京:地震出版社,1998.347.
[3]李铁.采矿诱发地震机理及其安全对策的研究[D].北京:北京科技大学,2007.35~94.
[4]Cai M F,Ji HG,Wang J A.Study on the time-space-strength relation for mining seismicity at Laohutai coal mine and its pre-diction[J].International Journal of Rock Mechanics&Mining Sciences,2005(42):145~151.
[5]国家地震局震害防御司.地震工作手册[M].北京:地震出版社,1990.129~130.
[6]钱鸣高,石平五.矿山压力与岩层控制[M].北京:中国矿业大学出版社,2003.297.
[7]李玉寿,李世平.石灰岩三轴压缩全应力应变过程的声发射特性[J].中国矿业大学学报,1993(增):1~7.
[8]贾德义,李新元.唐山矿深部开采冲击地压发生的综合治理[J].中国煤炭,2000,26(7):18~20.
[9]阿维尔申СГ.冲击地压[M].朱敏,汪伯煜,韩金祥,译.北京:煤炭工业出版社,1959.200~202.
版权所有:© 2023 中国地质图书馆 中国地质调查局地学文献中心