Study on mechanical properties and acoustic emission characteristics of deep diorite under uniaxial compression

Kai-De Liu; Yu Zhou; Xiao-Ping Zhang; Shao-Jun Fu; Quan-Sheng Liu; Peng Dong; Kai-Wen Yao; Ding-Bo Wang

doi:10.1016/j.heliyon.2024.e24482

Study on mechanical properties and acoustic emission characteristics of deep diorite under uniaxial compression

Heliyon. 2024 Jan 11;10(2):e24482. doi: 10.1016/j.heliyon.2024.e24482. eCollection 2024 Jan 30.

Authors

Kai-De Liu¹, Yu Zhou¹, Xiao-Ping Zhang^{1

2}, Shao-Jun Fu^{1

2}, Quan-Sheng Liu², Peng Dong³, Kai-Wen Yao¹, Ding-Bo Wang¹

Affiliations

¹ Xijing University, Shaanxi Key Laboratory of Safety and Durability of Concrete Structures, Xi'an, 710123, China.
² The Key Laboratory of Safety for Geotechnical and Structural Engineering of Hubei Provine, School of Civil Engineering, Wuhan University, Wuhan, 430072, China.
³ Hanjiang -to -Weihe River Valley Water Diversion Project Construction Co., Let., Xi' an, 710024, China.

Abstract

The research object is diorite in the Lingbei TBM section of the Hanjiang-To-Weihe River Qinling tunnel, with a buried depth of over 1 km. Using MTS-2000 microcomputer-controlled electro-hydraulic servo universal testing machine and DS5-16b acoustic emission (AE) monitoring system, uniaxial compression and acoustic emission monitoring tests were carried out on rock samples, to study the uniaxial compression mechanical properties and acoustic emission characteristics of the deep diorite. The results of the study indicate that: (1) During uniaxial compression, diorite undergoes four stages: initial compaction, elasticity, yield and failure, in which the curve of the initial compaction stage is significantly smoother. The uniaxial compressive strength is 41.95 MPã102.42 MPa, with an average of 74.07 Mpa; The axial peak strain ranges from 1 % to 1.4 %, and the failure mode belongs to brittle ductile splitting failure. (2) The cumulative ringing count and energy showed a very slow increase trend during the calm period; After entering a surge period (with the appearance of Kaiser points), both show a significant transition state; During the slow increase period, the overall growth rate of the two slowed down and remained almost silent. (3) On the basis of the analysis of RA-AF values during the deformation and rupture process of diorite, it can be seen that the damage type of diorite is tensile damage by the significant low RA value and high AF value characteristics, which coincides with the actual damage fracture characteristics of the rocks in the sample. (4) During the compaction stage, there are few acoustic emission location points, which correspond to low energy and are mainly distributed at the higher and lower ends of the sample; After entering the elasticity stage, the number of positioning points significantly increases and gradually expands towards the middle; Near Kaiser point, the number of location points and corresponding energy are both in a sharp increase state, and this trend is in good agreement with the changes in the ringing count-time and energy-time curves. (5) The damage time mainly starts at the end of the calm period, and the pattern of change in the damage curve coincides with the localization point and energy evolution. The results of the research can be used as a referential basis for the development of the excavation, protection and other construction plans for the Lingbei TBM section of the Hanjiang-To-Weihe River Qinling tunnel or similar surrounding rock tunnels, as well as for further conducting triaxial unloading tests on diorite.

Keywords: Acoustic emission characteristics; Anchor point; Damage mechanism; Energy; Mechanical properties of uniaxial compression; RA-AF; Ringing count.