Application of the Cohesion Softening–Friction Softening and the Cohesion Softening–Friction Hardening Models of Rock Mass Behavior to Estimate the Specific Energy of TBM, Case Study: Amir–Kabir Water Conveyance Tunnel in Iran

Abstract

The specific energy (SE) of an excavation is an important factor to consider in economic and technological investigations of mechanical excavation projects using a tunnel-boring machine (TBM). SE is defined as the energy consumed during excavation of per unit volume of rock mass, and it can be determined in real time from the data recording the performance of a TBM. Several experimental, empirical, and analytical methods have been developed to predict SE based on rock mass and machine parameters. In this study, a new empirical method is proposed to predict SE based on the strain energy ratio of rock mass (Ψ). This is defined as the ratio of the residual post peak strain energy to the stored pre peak strain energy of the rock mass. It depends on three important parameters, namely rock mass properties, intact rock parameters, and rock mass behavior models. In this study, to estimate the strain energy ratio of rock mass, two post peak rock mass behavior models—cohesion softening–friction softening (CSFS) and cohesion softening–friction hardening (CSFH)—were used. Based on actual data from the Amir–Kabir water conveyance tunnel project, the relationships between the SE of TBM and the strain energy ratio were investigated. Due to different rock mass qualities in the tunnel route, classification of rock mass according to Hoek and Brown’s proposal was carried out, and the correlation between the mentioned parameters in each class was studied. The results showed a direct relationship between the parameters, and the best relationships in poor and moderate rock mass (geological strength index [GSI] 70) because of its ability to modify the brittle behavior of brittle rock mass.