Study on Synchronous Response Law of Acoustic and Electrical Signals of Outburst Coal Rock under Load and Fracture

A multisignal nanosecond synchronous acquisition system to measure acoustic emission (AE) and electromagnetic radiation (EMR) generated during the process of loading and failure of coal and rock samples is established. The correlation between the energy of the AE and EMR signals and the loading stress of outburst coal-rock samples was studied, and the characteristics of the AE and EMR signals during the process of loading and fracturing the outburst coal and rock samples were analyzed. The results show that (1) before the failure of the outburst coal and rock samples, the fluctuation of the AE and EMR signals is the largest, with the same rising and falling trend, and the intensity is not strictly positively correlated, with the phenomenon of low EMR when the AE intensity is high; (2) the EMR and AE deviation degree and frequency exhibit a good response to coal and rock fracturing. The correlation between EMR and stress drop is stronger than that of AE, and the AE signal is richer than the EMR signal. The results show that it is feasible to develop combined AE and EMR early warning technology to improve the early forecasting accuracy of coal and gas outbursts.

Automated summary

A multisignal nanosecond synchronous acquisition system was established to measure the acoustic emission (AE) and electromagnetic radiation (EMR) generated during the loading and failure of coal and rock samples. The correlation between the energy of AE and EMR signals and the loading stress of outburst coal-rock samples was studied, and the characteristics of these signals during the loading and fracturing process were analyzed. The results show the feasibility of developing a combined AE and EMR early warning technology to improve the accuracy of early forecasting for coal and gas outbursts.