TY - GEN
T1 - Eancing Rock Mass Stability Through the Efficient Utilization of Backfill
AU - Yu, Xin
AU - Qi, Shengwen
AU - Tan, Yuye
AU - Song, Weidong
AU - Kemeny, John
N1 - Publisher Copyright:
© The Author(s), under exclusive license to Springer Nature Singapore Pte Ltd. 2024.
PY - 2024
Y1 - 2024
N2 - Backfills have gained significant attention as sustainable materials for recycling waste generated in underground mining processes. However, a comprehensive understanding of the efficient mechanisms and their effects on underground rock mass stability under varying conditions is still necessary. This paper investigates the failure process of two different rock-backfill structures through triaxial compressive experiments, employing acoustic emission (AE) and computed tomography (CT) technology. The study reveals the cooperative behavior of the bi-material system and identifies four key reactions of the backfills on the rock mass: stress redistribution, energy absorption, intact force, and intact friction. The specific reactions and their sensitivities depend on the structure and external confinement applied to the system. Considering the volume fraction of the materials and the external loading, the study presents technical recommendations for utilizing backfills in diverse mining conditions. These findings provide insights for more efficient and flexible design considerations when implementing the backfilling mining method, contributing to a greener and sustainable future.
AB - Backfills have gained significant attention as sustainable materials for recycling waste generated in underground mining processes. However, a comprehensive understanding of the efficient mechanisms and their effects on underground rock mass stability under varying conditions is still necessary. This paper investigates the failure process of two different rock-backfill structures through triaxial compressive experiments, employing acoustic emission (AE) and computed tomography (CT) technology. The study reveals the cooperative behavior of the bi-material system and identifies four key reactions of the backfills on the rock mass: stress redistribution, energy absorption, intact force, and intact friction. The specific reactions and their sensitivities depend on the structure and external confinement applied to the system. Considering the volume fraction of the materials and the external loading, the study presents technical recommendations for utilizing backfills in diverse mining conditions. These findings provide insights for more efficient and flexible design considerations when implementing the backfilling mining method, contributing to a greener and sustainable future.
KW - Backfill
KW - Response characteristic
KW - Rock mass stability
KW - Underground mining
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U2 - 10.1007/978-981-99-9057-3_21
DO - 10.1007/978-981-99-9057-3_21
M3 - Conference contribution
AN - SCOPUS:85205365995
SN - 9789819990566
T3 - Environmental Science and Engineering
SP - 271
EP - 284
BT - Engineering Geology for a Habitable Earth
A2 - Wang, Sijing
A2 - Huang, Runqiu
A2 - Azzam, Rafig
A2 - Marinos, Vassilis P.
PB - Springer Science and Business Media Deutschland GmbH
T2 - 14th International Association for Engineering Geology and the Environment, IAEG 2023
Y2 - 21 September 2023 through 27 September 2023
ER -