Abstract
To reveal the dynamic mechanical response and energy dissipation behavior of rockburst-prone coal samples under impact loading, the compressive experiments on Xinzhouyao coals (prone) and Machang coals (nonprone) under different impact loadings were carried out using the Split Hopkinson Pressure Bar (SHPB). The dynamic mechanical properties were studied, including dynamic elastic modulus, strain rate, peak stress, peak strain, dynamic increment factor, and energy dissipation. The results show that the dynamic elastic modulus, peak stress, and peak strain of both prone and nonprone coals perform an obvious correlation with the increase of strain rate. The strain rate strengthening effect on the dynamic elastic modulus and compressive strength of rockburst-prone coal samples are more significant, reflected by the greater increment with the increase of strain rate, while the dynamic increment factors of both prone and nonprone coals show apparent strain rate strengthening. The incident, reflected, and transmitted energy of both two coals linearly increases with the impact velocity, although the increased rate may be different. The dissipated energy of rockburst-prone coal samples increases faster, while the rate of the increase of the dissipated energy is more stable with strain rate. The results may provide an important reference for revealing the failure law of engineering-scaled coal mass suffered by rockburst.
Highlights
Coal and rock mass buried in deep is subjected to a complex geological environment with the depletion of shallow resources and the increase of coal mining depth [1, 2]
Coal mass with great stored elastic energy may be subjected to strong impact loading when it is disturbed by mining operations, such as uncovering coal seam from rock mass, engineering blasting, roadway excavation, nearby coal seam mining, resulting in serious mine dynamic disasters such as rockburst, coal and gas outburst accompanyed with a large amount of released energy [3,4,5,6,7,8,9]. ese disasters may lead to great property losses and casualties. erefore, it is much significant to reveal the dynamic mechanical response of coal and rock mass under different impact loadings and the law of energy dissipation in the process of dynamic failure, which may provide a reliable theoretical basis for further understanding of the trigger mechanism of dynamic disasters [10]
Zhao et al studied on energy dissipation characteristics of coal samples under impact loading [22]
Summary
Coal and rock mass buried in deep is subjected to a complex geological environment with the depletion of shallow resources and the increase of coal mining depth [1, 2]. Most of these experiments only obtained the dynamic stress-strain curve We supplement this dearth of observations by recovering a full suite of dynamic failure characteristics and energy dissipation laws to contrast the response of rockburst-prone coals (Xinzhouyao coals) against a control sample of rockburst resistant coals (Machang coals) by using the Split Hopkinson Pressure Bar (SHPB) experimental system to reveal the mechanism of coal mine dynamic disasters induced by impact load. Where σs(t), εs(t), ε_s(t) are the dynamic stress, strain, and strain rate of coal samples respectively; A and As represent the cross-sectional area of the elastic bar and coal sample, respectively; E represents the elastic modulus of the elastic bar; C0 and L represent the longitudinal wave velocity of the elastic bar and the length of the specimen, respectively; εi(t), εr(t), εt(t) represent the strain value of incident wave, reflected wave, and transmitted wave, respectively.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
