煤岩体破坏过程中电磁辐射与能量耗散耦合分析
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摘要
为了完善电磁辐射方法预测预报煤岩体动力灾害理论,利用物理实验、理论分析的方法研究受载煤岩体变形破裂过程中产生电磁辐射信号特征及其与煤岩体能量耗散的耦合关系。结果表明:电磁辐射是煤岩体塑性变形引起的,受载煤岩体电磁辐射脉冲数与塑性能变化率成正比,比例系数为5.962,电磁辐射总脉冲数与煤岩体的塑性能成正比,电磁辐射不仅仅与损伤速率有关,而且还与受载煤样的弹性模量成正比,这与受载煤岩体电磁辐射试验现象相符合。
To consummate the forecast theory of coal-rock mass dynamic disaster based on electromagnetic emission (EME) method, the coupling relations between EME Signal and energy dissipation of coal-rock mass during the deformation of coal-rock mass are investigated using physical experiments and theoretical analysis. The results show that EME is caused by the plastic deformation of coal-rock mass. The pulse number of EME is proportional to the rate of plastic energy change, and the ratio is 5.962. In addition, the total pulse number of EME is proportional to plastic energy. EME is not only related with damage rate, but also proportional to plastic module of coal samples, which is corresponding to experimental phenomena.
To consummate the forecast theory of coal-rock mass dynamic disaster based on electromagnetic emission (EME) method, the coupling relations between EME Signal and energy dissipation of coal-rock mass during the deformation of coal-rock mass are investigated using physical experiments and theoretical analysis. The results show that EME is caused by the plastic deformation of coal-rock mass. The pulse number of EME is proportional to the rate of plastic energy change, and the ratio is 5.962. In addition, the total pulse number of EME is proportional to plastic energy. EME is not only related with damage rate, but also proportional to plastic module of coal samples, which is corresponding to experimental phenomena.
引文
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[11]谢和平,彭瑞东,鞠杨.岩石变形破坏过程中的能量耗散分析[J].岩石力学与工程学报,2004,23(21):3565-3570.
[12]B.R劳恩,T.R.威尔肖.脆性固体断裂力学[M].陈颙,尹祥础译.北京:地震出版社,1985.
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[14]杨圣奇,徐卫亚,韦立德.单轴压缩下岩石损伤统计本构模型与试验研究[J].河海大学学报,2004,32(2):200-203.
[2]Brady B T,Rowell G A,Laboratory investigation of the electrodynamics of rock fracture[J].Nature,1986,321:488-492.
[3]何学秋,王恩元,聂百胜等.煤岩流变电磁动力学[J].北京:科学出版社,2003.
[4]窦林名,何学秋,,王恩元,等.由煤岩变形冲击破坏所产生的电磁辐射.清华大学学报:自然科学版,2001,41(12):86-88.
[5]王恩元,赵恩来.岩土单轴压缩过程的电磁辐射特性实验研究.辽宁工程技术大学学报,2007,26(1):56-58.
[6]肖红飞,何学秋,冯涛,等.单轴压缩煤岩变形破裂电磁辐射与应力耦合规律的研究[J].岩石力学与工程学报,2004,23(23):3948-3953.
[7]窦林名,何学秋.冲击矿压防治理论与技术[M].徐州:中国矿业大学出版社,
[8]王恩元,何学秋,刘贞堂.煤岩变形及破裂电磁辐射信号的R/S统计规律.中国矿业大学学报,1998,27(4):349-351.
[9]王恩元,何学秋,刘贞堂.煤岩变形及破裂电磁辐射信号的分形规律[J].辽宁工程技术大学学报,1998,17(4):343-347.
[10]窦林名,何学秋,王恩元.冲击矿压预测的电磁辐射技术及应用[J].煤炭学报,2004,29(4):396-399.
[11]谢和平,彭瑞东,鞠杨.岩石变形破坏过程中的能量耗散分析[J].岩石力学与工程学报,2004,23(21):3565-3570.
[12]B.R劳恩,T.R.威尔肖.脆性固体断裂力学[M].陈颙,尹祥础译.北京:地震出版社,1985.
[13]唐春安.岩石破裂过程中的灾变.北京:煤炭工业出版社,1993.
[14]杨圣奇,徐卫亚,韦立德.单轴压缩下岩石损伤统计本构模型与试验研究[J].河海大学学报,2004,32(2):200-203.
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