Infrared Precursor Experiment to Predict Water Inrushes in Underground Spaces Using a Multiparameter Normalization

Abstract: Rock failure is the root cause of geological disasters such as slope failure, civil tunnel collapse, and water inrush in roadways and mines. Accurate and effective monitoring of the loaded rock failure process can provide reliable precursor information for water inrushes in underground engineering structures such as in mines, civil tunnels, and subways. The water inrush may affect the safe and efficient execution of these engineering structures. Therefore, it is essential to predict the water inrush effectivel… Show more

“…With the exhaustion of shallow energy resources and sustainable utilization of underground space, human endeavors have inevitably extended into deeper regions of the Earth. − The rock masses in deep underground engineering are characterized by inherent heterogeneity, often containing an abundance of structural planes such as joints, fissures, and faults. , Meanwhile, the intricate geological structures typically subject the fractured rock underground to true three-dimensional stress with high geostress and elevated pore pressure . The presence of pore pressure in the cracked causes a decrease in the strength of the rock masses, reducing its stability and increasing its susceptibility to failure under stress perturbations. , During the rock failure process, the water diffusion volume change (i.e., Δ V ) can potentially lead to water inrush disaster, significantly jeopardizing the safe construction of underground engineering. Therefore, it is crucial to investigate the mechanical and Δ V characteristics in the failure process of cracked rocks under the influence of true triaxial stress and pore pressure.…”

“… 2 The presence of pore pressure in the cracked causes a decrease in the strength of the rock masses, reducing its stability and increasing its susceptibility to failure under stress perturbations. 6 , 7 During the rock failure process, the water diffusion volume change (i.e., Δ V ) can potentially lead to water inrush disaster, significantly jeopardizing the safe construction of underground engineering. Therefore, it is crucial to investigate the mechanical and Δ V characteristics in the failure process of cracked rocks under the influence of true triaxial stress and pore pressure.…”

Experimental Study on the Response of Cracked Sandstone to the Intermediate Principal Stress Coupled with Pore Pressure

“…With the exhaustion of shallow energy resources and sustainable utilization of underground space, human endeavors have inevitably extended into deeper regions of the Earth. − The rock masses in deep underground engineering are characterized by inherent heterogeneity, often containing an abundance of structural planes such as joints, fissures, and faults. , Meanwhile, the intricate geological structures typically subject the fractured rock underground to true three-dimensional stress with high geostress and elevated pore pressure . The presence of pore pressure in the cracked causes a decrease in the strength of the rock masses, reducing its stability and increasing its susceptibility to failure under stress perturbations. , During the rock failure process, the water diffusion volume change (i.e., Δ V ) can potentially lead to water inrush disaster, significantly jeopardizing the safe construction of underground engineering. Therefore, it is crucial to investigate the mechanical and Δ V characteristics in the failure process of cracked rocks under the influence of true triaxial stress and pore pressure.…”

“… 2 The presence of pore pressure in the cracked causes a decrease in the strength of the rock masses, reducing its stability and increasing its susceptibility to failure under stress perturbations. 6 , 7 During the rock failure process, the water diffusion volume change (i.e., Δ V ) can potentially lead to water inrush disaster, significantly jeopardizing the safe construction of underground engineering. Therefore, it is crucial to investigate the mechanical and Δ V characteristics in the failure process of cracked rocks under the influence of true triaxial stress and pore pressure.…”

Experimental Study on the Response of Cracked Sandstone to the Intermediate Principal Stress Coupled with Pore Pressure

Infrared radiation precursor and energy dissipation properties of water-containing concrete under impact load

Investigating average infrared radiation temperature characteristics during shear and tensile cracks in sandstone under different water contents