Abstract
At present, theoretical analysis, numerical simulation, and other methods cannot be used to properly solve the problems associated with the stability and bearing capacity of the surrounding rock and its supporting system, the interaction between the supporting structure and surrounding rock, and the sharing role of each supporting structure, all of which commonly occur in deep tunnels. The model test method represented by the photoelastic test is still an important approach to study this kind of problem. In view of the deficiency of the current loading system of the photoelastic model test, we developed a geo-stress loading system for the photoelastic model test, which can simulate the in situ geo-stress environment of unidirectional loading, bidirectional equal pressure, bidirectional unequal pressure, and tridirectional unequal pressure. The universal retaining force loading rod can realize the stability and effective compensation of loading, which is an original design. According to the principle of umbrella-shaped expansion and contraction mechanism, an excavation unloading device for the photoelastic model test is developed, which can realize the simulation of various degrees of displacement release in the excavation process of deep tunnels and other underground projects. The loading simulation test and excavation unloading simulation test show that the geo-stress loading system and excavation unloading device developed in this paper are flexible, exhibit good performance, and can fully achieve their respective test functions. The combination of two devices can compensate for the insufficiency of the current photoelastic model test and will promote the application of photoelastic model tests in underground engineering applications such as deep tunnel projects.
Highlights
Deep tunnels are mechanical bodies with complex properties, stress states, and boundary conditions
Researchers at home and abroad have conducted many in-depth studies on the distribution of the stress field and displacement field of tunnel surrounding rock and the supporting structure under different construction methods and supporting types based on theoretical analyses, numerical calculations, and model tests [1,2,3,4,5].based on the theoretical analysis method of mathematical mechanics, only the analytical solutions for the stress and displacement field of the tunnel surrounding rock mass with a simple section and under simple support conditions can be obtained [6,7,8]. e numerical analysis method [9,10,11] based on the finite element, finite difference, and discrete element methods provides a powerful tool for the stress analysis of tunnel engineering with complex crosssections and composite supports
As a result of the lack of an excavation unloading device to simulate the tunnel excavation effect, the photoelastic model test is unable to capture the stress characteristics and transmission mechanism of the surrounding rock mass and supporting structure in the process of displacement adjustment after tunnel excavation. erefore, to meet actual requirements, we developed a geo-stress loading system for the photoelastic model test based on the principle of lead screw loading, which can realize unidirectional loading, bidirectional equal loading, and bidirectional unequal pressure loading
Summary
Deep tunnels are mechanical bodies with complex properties, stress states, and boundary conditions. As a result of the lack of an excavation unloading device to simulate the tunnel excavation effect, the photoelastic model test is unable to capture the stress characteristics and transmission mechanism of the surrounding rock mass and supporting structure in the process of displacement adjustment after tunnel excavation. E geo-stress loading and excavation unloading devices of the photoelastic test developed in this paper can improve the research method of the photoelastic model test and are of great significance to study the stress characteristics, force transmission process, and sharing mechanism of the surrounding rock mass and supporting structure considering the excavation effect in a real stress state. To improve the convenience of manufacturing, the rotating part of the loading rod is realized by the crosspin
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