Relationship between EMR and dissipated energy of coal rock mass during cyclic loading process

Dynamic collapses of deeply mined coal rocks are severe threats to miners. In order to predict the collapses more accurately using electromagnetic radiation (EMR), this paper researched the energy conversion mechanism in the damage process of coal rock mass, analysed its EMR and dissipated energy, and a relationship between which was established using the voltage amplitude of EMR signal and hysteresis loop generated in the loading and unloading cycles as a bridge; then a series of cyclic loading experiments using coal samples of Junde and Xinlu coal mines from Heilongjiang province were carried out, and EMR signal released during these cycles were collected. Results show that during a whole damage process of a sample, the cumulative values of EMR energy and corresponding dissipated energy (hysteresis loop area) well subject to the form of y=aln(x)+by=aln(x)+b, whose correlation coefficients are above 0.90, and EMR signals received by different frequency antenna seldom impacted on this relationship; the total EMR energy released from the whole failure process of the samples obtained from adjacent sampling point in same mining area are different to some extent, so are the dissipated energy; compared with cyclic loading for coal rock mass orderly with the peak loads of 5 kN and 10 kN previously, the dissipated energy of direct using that of 15 kN increase 17.8%, and EMR signal is more abundant; EMR energy received in each cycle increase steadily with the improvement of load level, and in a single loading and unloading cycle, sometimes it is very rich in the unloading phase, even more than the loading one.

► We research the energy conversion mechanism in the damage process of coal rock mass. ► We establish a relationship between EMR and dissipated energy. ► The cumulative values of the two well subject to the form of y = a ln(x) + b. ► The total EMR energy released from the whole process of same samples are different. ► In cyclic loading process, EMR energy sometimes is very rich in the unloading phase.