Experimental study on the damage and fracture mechanism of deep coal beds impacted by water jets at different temperatures.

• Coal-breaking using water jets at different reservoir temperatures was studied. • When temperatures exceed 75.0 °C, the depth of pit increases by 81.0 %, the specific energy consumption decreases by 52.4 %. • The threshold fracturing pressure presenting an exponential trend as coal temperature increases. • Coal-breaking shifts from a "water wedge" dominated mode to a "water wedge-thermal fracture" as temperature increases. The development of abundant deep coalbed methane (CBM) resources has attracted significant attention due to their commercial development potential. However, developing such resources presents many challenges due to their generation in complex geological environments governed by high temperatures and stresses. Thus, this work investigated coal fragmentation using water jets at different reservoir temperatures. The results show that compared with room temperature conditions, under water jet impact, the threshold fracturing pressure of high-temperature coal is lower, the rock-breaking volume is larger, and thermal stress leads to intensified dynamic damage. Indeed, when the temperature exceeds 75.0 °C, the coal undergoes volume fragmentation, and the depth of water jet-breaking coal increases by 81.0 %, while the specific energy consumption decreases by 52.4 %. The threshold fracturing pressure rapidly decreases as temperature increases and stabilizes, presenting an exponential trend. When the temperature exceeds 75.0 °C, the threshold fracturing pressure is maintained at around 10.0 MPa and no longer decreases with the temperature increase. In addition, three-dimensional (3D) damage field analysis highlights that the coal breaking mode shifts from a "water wedge" dominated mode to a "water wedge-thermal fracture" mode as temperature increases. Finally, the dynamic fracturing mechanism of coal under high-temperature conditions of water jet impact has been revealed. The research results of this paper provide a theoretical basis for the hydraulic permeability enhancement design of deep coal seams. [ABSTRACT FROM AUTHOR]