Your search keyword '"Bingxiong Tu"' showing total 4 results

1. Influence of Grout’s Poisson Effect on Interfacial Shear Stress for Compression Anchor in Rock Mass

Author

Chao Liu, Zhang Lihua, Bingxiong Tu, and Haitao Wang

Subjects

Materials science, Grout, Soil Science, Geology, Mechanics, engineering.material, Geotechnical Engineering and Engineering Geology, Poisson distribution, Poisson's ratio, Condensed Matter::Soft Condensed Matter, Stress (mechanics), symbols.namesake, Architecture, symbols, Shear stress, engineering, Compression (geology), Rock mass classification, Elastic modulus

Abstract

The distribution and magnitude of the shear stress at the interface between the grout of a compression anchor rod and rock are strongly affected by the Poisson effect. A new analytical equation of the influence coefficient of the Poisson effect is proposed to quantitatively evaluate the influence of the Poisson effect on the interfacial shear stress. When the Poisson effect is considered, the interfacial shear stress from the neutral point to the bearing plate increases, and the distribution curve becomes steep. However, the interfacial shear stress far from the neutral point is low, and the distribution curve becomes smooth. Overall, the Poisson effect leads to a more nonuniform distribution of the shear stress at the interface of the compression anchor rod. A larger Poisson's ratio, smaller elastic modulus, and smaller diameter of the grout lead to a greater influence of the Poisson effect. Furthermore, a larger elastic modulus of rock leads to a greater influence of the Poisson effect. The Poisson's ratio of rock and that of grout both affect the Poisson effect greatly, but the influence of the variation in the Poisson’s ratio of rock on the Poisson effect is negligible. A larger interface friction angle leads to a greater influence of the Poisson effect.

Published

2021

2. Time-Dependent Deformation Mechanism for Swelling Soft-Rock Tunnels in Coal Mines and Its Mathematical Deduction

Author

Yanyan Cai, Zhou Jianfeng, Jin Yu, Bingxiong Tu, Gengyun Liu, and Shiyu Liu

Subjects

business.industry, 010102 general mathematics, 0211 other engineering and technologies, Coal mining, Soil Science, Excavation, 02 engineering and technology, 01 natural sciences, Deformation mechanism, medicine, Geotechnical engineering, 0101 mathematics, Swelling, medicine.symptom, business, Geology, 021101 geological & geomatics engineering

Abstract

The floor heave and the inward movement of sidewalls are often encountered in the excavation of tunnels with swelling rock properties. However, the deformation mechanism for swelling soft-r...

Published

2020

3. Numerical Simulation Study on Lateral Displacement of Pile Foundation and Construction Process under Stacking Loads

Author

Bingxiong Tu, Jin Yu, Yanyan Cai, Yaoliang Zhu, and Zhou Jianfeng

Subjects

geography, Multidisciplinary, geography.geographical_feature_category, Article Subject, General Computer Science, Computer simulation, 0211 other engineering and technologies, Stacking, Process (computing), Foundation (engineering), 02 engineering and technology, Compression (physics), lcsh:QA75.5-76.95, 021105 building & construction, Coupling (piping), Geotechnical engineering, lcsh:Electronic computers. Computer science, Levee, Pile, Geology, 021101 geological & geomatics engineering

Abstract

Lateral displacement of pile foundation is crucial to the safety of an overall structure. In this study, a numerical simulation on the lateral displacement of pile foundation under stacking loads was conducted to determine its relation with different influencing factors. Simulation results demonstrated that stacking loads at the pile side mostly influence the lateral displacement of pile foundation. The lateral displacement of pile foundation increases by one order of magnitude when the stacking loads increase from 100 kPa to 300 kPa. Other influencing factors are less important than stacking loads. Lateral displacements of the pile body and at the pile top can be reduced effectively by increasing the deformation modulus of surface soil mass, reducing the thickness of soft soil, and expanding pile diameter. Our analysis indicates that a nonlinear relationship exists between the lateral displacement at the pile top and the pile diameter. The lateral resistance of the pile body can be enhanced by coupling the stacking load along piles and the axial force at the pile top. An actual large-scale engineering project was chosen to simulate the effects of postconstructed embankment on lateral displacement and axial force of bridge pile foundation under different construction conditions and to obtain the lateral displacement of the pile body and the negative frictional resistance caused by soft soil compression under stacking loads. On the basis of the calculated results, engineering safety and stability were evaluated, and a guide for the design and construction was proposed.

Published

2018

4. Analytical Analysis and Field Test Investigation of Consolidation for CCSG Pile Composite Foundation in Soft Clay

Author

Zhibo Qi, Bingxiong Tu, Jin Yu, Yunfei Guan, Shiyu Liu, and Yanyan Cai

Subjects

geography, geography.geographical_feature_category, Consolidation (soil), Article Subject, Applied Mathematics, lcsh:Mathematics, Composite number, lcsh:QA1-939, Permeability (earth sciences), Pore water pressure, Geotechnical engineering, Bearing capacity, Pile, Levee, Terzaghi's principle, Geology

Abstract

Low-grade concrete-cored sand-gravel (CCSG) pile composite foundation is a new kind of composite foundation for thick and soft clay ground treatment. An analytical solution was derived for calculating the consolidation process of this composite foundation by considering coefficients of horizontal permeability in smear zone, the radial flow within the sand-gravel shell, and the impervious property of concrete-cored pile. The results show that Terzaghi’s one-dimensional consolidation solution and the consolidation analytical solution of ordinary composite foundation were special cases of this solution. Curves of the average consolidation degree of the composite foundation under various nondimensional parameters were observed using the program based on the theoretical formula. Meanwhile, a series of in situ measurements including the settlement of pile and soil, the pore water pressure, and the total stress under embankment load were obtained on the CCSG pile composite foundation on a section of Zhenjiang-Liyang highway. The analyzed results show that the new style composite foundation patent technology has many advantages such as small differential postconstruction settlement (differential is not good, small is), reliable quality, high bearing capacity, and stability. And the consolidation of composite foundation is largely affected by the nondimensional parameters. The analytical solution is finally verified with the actual measurement data.

Published

2013