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1. A new peak dilation angle model for rock joints considering different contribution proportions of actual contact joint asperities to shear strength

Author

Liren BAN, Yuhang HOU, Weisheng DU, Jin YU, Chengzhi QI, and Renliang SHAN

Subjects
shear strength, rock joints, asperities, surface morphology, actual contact, Geology, QE1-996.5, Mining engineering. Metallurgy, TN1-997
Abstract

The shear properties of rock joints have always been the focus of rock engineering, and the peak dilation angle is a key physical quantity describing the shear behavior of joints. A reasonable peak dilation angle model should fully reflect the peak shear strength of rock joints. To predict the peak dilation angle of rock joints and clarify the intrinsic relationship between the peak dilation angle and the morphology of rock joints, the distribution range of asperities on the joint surface that contribute to the shear strength is defined at first, and then the contribution ratio of asperities to the strength in actual contact joints is determined. The resistance to shear on the joint surface is generated by the touched asperities facing the shear direction. \begin{document}$ {\theta }_{\text{cr1}}^{*} $\end{document} and \begin{document}$ {\theta }_{\text{cr2}}^{*} $\end{document} are proposed to define whether asperities participate in the shear process and the failure mode of asperities, respectively. For the asperities of \begin{document}${\theta }^{*} $\end{document} at (\begin{document}$ {\theta }_{\text{cr1}}^{*} $\end{document}, \begin{document}$ {\theta }_{\text{cr2}}^{*} $\end{document}), the failure mode is shear dilation failure, and the contribution to shear strength is proportional to \begin{document}${\theta }^{*} $\end{document}. For the asperities of \begin{document}${\theta }^{*} $\end{document} at (\begin{document}$ {\theta }_{\text{cr2}}^{*} $\end{document}, \begin{document}$ {\theta }_{\text{max}}^{*} $\end{document}), the failure mode is shear off failure, and the contribution to shear strength is proportional to \begin{document}$ {\theta }_{\text{cr2}}^{*} $\end{document}. Furthermore, the equivalent average angle of joints in contact is deduced considering the different contribution ratios of asperities in contact to shear strength and the area ratio of asperities. Equating the equivalent average angle of joints in contact with the peak dilation angle, a new model of peak dilation angle of joints is proposed. The physical meaning of the new model is clear, and the existing parameter of peak dilation angle is only a special case of equivalent average angle of actual contact joints. The calculation accuracy of six peak dilation angle models is compared through 89 sets of experimental results, which show that the prediction results of the new model are the best (the average error is 10%). It is critical to determine \begin{document}$ {\theta }_{\text{cr2}}^{*} $\end{document} in the new peak dilation angle model. The angles \begin{document}$ {\theta }_{\text{cr2}}^{*} $\end{document} corresponding to the joints of different rock materials are different in the new model. Considering the simplification of the model form, \begin{document}$ {\theta }_{\text{cr2}}^{*} $\end{document} = 32° fitted by tests is used to determine the new peak dilation angle model. The relative average error of the new simplified peak dilation angle model is 11%, and the prediction accuracy is higher than that of other models listed in this study. The influence of \begin{document}$ {\theta }_{\text{cr2}}^{*} $\end{document} on the rock joints with different morphologies, and the value basis of \begin{document}$ {\theta }_{\text{cr2}}^{*} $\end{document} are discussed. The findings reveal that in cases of pronounced joint roughness, the new model outperforms other models in terms of accuracy. Additionally, the derived value of \begin{document}${\theta }_{\text{cr2}}^{*} $\end{document}, obtained by fitting 89 sets of experimental data, appears to be a reasonable estimate.

Published
2023
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2. A consecutive joint shear strength model considering the 3D roughness of real contact joint surface

Author

Liren Ban, Zhigang Tao, Weisheng Du, and Yuhang Hou

Subjects
Shear strength, Actual contact area, 3D roughness, Shear test, Mining engineering. Metallurgy, TN1-997
Abstract

A consecutive joint shear strength model for soft rock joints is proposed in this paper, which takes into account the degradation law of the actual contact three-dimensional (3D) roughness. The essence of the degradation of the maximum possible dilation angle is the degradation of the 3D average equivalent dip angle of the actual contact joint asperities. Firstly, models for calculating the maximum possible dilation angle at the initial and residual shear stress stages are proposed by analyzing the 3D joint morphology characteristics of the corresponding shear stages. Secondly, the variation law of the maximum possible dilation angle is quantified by studying the degradation law of the joint micro convex body. Based on the variation law of the maximum possible dilation angle, the maximum possible shear strength model is proposed. Furthermore, a method to calculate the shear stiffness degradation in the plastic stage is proposed. According to the maximum possible shear strength of rock joints, the shear stress-shear displacement prediction model of rock joints is obtained. The new model reveals that there is a close relationship between joint shear strength and actual contact joint roughness, and the degradation of shear strength after the peak is due to the degradation of actual contact joint roughness.

Published
2023
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3. Investigation on the physical mechanism of cavity percentage dependent shear strength for rock joints considering the real contact joint surface

Author

Liren Ban, Zefan Wang, Weisheng Du, Yuhang Hou, Chengzhi Qi, and Jin Yu

Subjects
Roughness, Joint peak shear strength, Joint shear test, Surface morphology, Cavity percentage, Mining engineering. Metallurgy, TN1-997, Hydraulic engineering, TC1-978
Abstract

To explain the effect of joint roughness on joint peak shear strength (JPSS) and investigate the effect of different contact states of joint surface on JPSS, we try to clarify the physical mechanism of the effect of joint cavity percentage (JCP) on JPSS from the perspective of the three-dimensional (3D) distribution characteristics of the actual contact joint surface, and propose a JPSS model considering the JCP. Shear tests for red sandstone joints with three different surface morphologies and three different JCPs were performed under constant normal load condition. Based on test fitting results, the reduction effect of the JCP on JPSS is investigated, and a JPSS model for cavity-containing joints is obtained. However, the above model only considers the influence of JCP by fitting test data, and does not reveal the physical mechanism of JCP affecting the JPSS. Based on the peak dilation angle model for consideration of the actual contact joint morphology, and the influence of JCP on the roughness of the actual contact joint surface, a theoretical model of the JPSS considering the JCP is proposed. The derivation process does not depend on the test fitting, but is entirely based on the joint mechanical law, and its physical significance is clear. It is proposed that the essence of the influence of the JCP on JPSS is that the JCP first affects the normal stress of the actual contact joints, further affects the roughness of actual contact joints, and then affects the shear strength.

Published
2023
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4. A roughness parameter considering joint material properties and peak shear strength model for rock joints

Author

Liren Ban, Weisheng Du, Tianwei Jin, Chengzhi Qi, and Xiaozhao Li

Subjects
Roughness, Joint material properties, Rock joints, Peak shear strength, Asperities, Mining engineering. Metallurgy, TN1-997
Abstract

This study aims at proposing a reasonable roughness parameter that can reflect the peak shear strength (PSS) of rock joints. Firstly, the contribution of the asperities with different apparent dip angles to shear strength is studied. Then the shear strength of the entire joint asperities is derived. The results showed that the PSS of the entire joint asperities is proportional to a key parameter θτ, which is related to the geometric character of the joint surface and the joint material properties. The parameter θτ is taken as the new roughness parameter, and it is reasonable to associate the PSS with the geometric characteristics of the joint surface. Based on the new roughness parameter and shear test results of 20 sets of joint specimens, a new PSS model for rock joints is proposed. The new model is validated with the artificial joints in this paper and real rock joints in published studies. Results showed that it is suitable for different types of rock joints except for gneiss joints. The new model has the form of the Mohr-Coulomb model, which can directly reflect the relationship between the 3D roughness parameters and the peak dilation angle.

Published
2021
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8. A roughness parameter considering joint material properties and peak shear strength model for rock joints

Author

Chengzhi Qi, Liren Ban, Weisheng Du, Xiaozhao Li, and Tianwei Jin

Subjects
Rock joints, Mining engineering. Metallurgy, Materials science, TN1-997, 0211 other engineering and technologies, Peak shear strength, Energy Engineering and Power Technology, 02 engineering and technology, Surface finish, Mechanics, Entire joint, Geotechnical Engineering and Engineering Geology, Roughness, Joint material properties, 020401 chemical engineering, Asperities, Geochemistry and Petrology, Dilation (morphology), Direct shear test, 0204 chemical engineering, Material properties, Shear strength (discontinuity), Joint (geology), 021101 geological & geomatics engineering, Gneiss
Abstract

This study aims at proposing a reasonable roughness parameter that can reflect the peak shear strength (PSS) of rock joints. Firstly, the contribution of the asperities with different apparent dip angles to shear strength is studied. Then the shear strength of the entire joint asperities is derived. The results showed that the PSS of the entire joint asperities is proportional to a key parameter θτ, which is related to the geometric character of the joint surface and the joint material properties. The parameter θτ is taken as the new roughness parameter, and it is reasonable to associate the PSS with the geometric characteristics of the joint surface. Based on the new roughness parameter and shear test results of 20 sets of joint specimens, a new PSS model for rock joints is proposed. The new model is validated with the artificial joints in this paper and real rock joints in published studies. Results showed that it is suitable for different types of rock joints except for gneiss joints. The new model has the form of the Mohr-Coulomb model, which can directly reflect the relationship between the 3D roughness parameters and the peak dilation angle.

Published
2021

9. A Peak Dilation Angle Model Considering the Real Contact Area for Rock Joints

Author

Chengzhi Qi, Weisheng Du, and Liren Ban

Subjects
Materials science, 0211 other engineering and technologies, Magnetic dip, Geology, Geometry, 02 engineering and technology, 010502 geochemistry & geophysics, Geotechnical Engineering and Engineering Geology, 01 natural sciences, Distribution function, Shear (geology), Triangle mesh, Area ratio, Contact area, Joint (geology), 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, Civil and Structural Engineering, Test data
Abstract

The area ratio content of the asperities with different apparent dip angles is studied based on Grasselli’s apparent dip angle distribution function. An approximate expression of the minimum dip angle of the asperities in contact is further obtained according to the contact theory. For regular joints, the peak dilation angle is the average dip angle of all asperities on the contact part. Extending the above idea to the peak dilation angle of rough joints, the peak dilation angle model is derived based on the apparent dip angle distribution of the real contact asperities. In the derivation process, the peak dilation angle of an arbitrary stress state is directly obtained, instead of obtaining the initial dilation angle first and then defining the relation between the peak dilation angle and the initial dilation angle. The more important innovation is that all the parameters in the new model are of physical significance and easy to obtain; furthermore, they are not obtained by fitting test results. Based on 89 sets of test data, the predicted values of the new model are compared with those of the other 4 existing models. The results show that the prediction accuracy of the new model is the best. Besides, the mesh scales of rock joint are discussed, and the size range of the triangle mesh is obtained. It is proposed to remove the isolated points with a large apparent dip angle when processing test data. The shear mechanism of rough joints is further clarified in this study: the dilation is regarded as the average apparent dip angle of the asperities in contact at a certain stress level. This view is easy to understand and follow. It is as simple and beautiful as many natural principles.

Published
2020

10. A modified model for estimating peak shear displacement of artificial joints

Author

Ansen Gao, Chengzhi Qi, Liren Ban, Chenmeng Ji, and Fayuan Yan

Subjects
Materials science, Computer simulation, 0211 other engineering and technologies, Geology, 02 engineering and technology, 010502 geochemistry & geophysics, Geotechnical Engineering and Engineering Geology, medicine.disease_cause, 01 natural sciences, Shear (geology), Mold, Empirical formula, medicine, Surface roughness, Artificial joints, Direct shear test, Composite material, Joint (geology), 021101 geological & geomatics engineering, 0105 earth and related environmental sciences
Abstract

The peak shear displacement (PSD) of artificial joints was studied by the shear test of cement mortar duplicate joints under constant normal load. First, the splitting rock joints were produced by the Brazilian splitting method, and the high-precision point cloud of joint surface morphology was acquired by three-dimensional (3D) scanning method. The polylactic acid (PLA) base mold was produced by 3D printing technology. The duplicate joints with the same joint surface as the splitting rock joints were obtained by pouring cement mortar on the PLA base mold. Then, shear tests of 20 cement mortar specimens with 5 groups of joint surface morphologies under 4 different normal loads were carried out, and the joint shear stress-displacement curves were obtained. The influencing factors of the PSD were studied. The results indicate that the PSD is inversely related to the joint roughness and positively related to the normal stress (NS). The limitation of Barton’s empirical formula is that it cannot predict (fit) the PSD of the joints with JRC = 0 and reflect the effect of NS on the PSD. To quantitatively study the PSD of joints, an empirical formula that can comprehensively consider the influence of surface roughness and NS is introduced based on the test results. The modified model overcomes the limitation of Barton’s empirical formula which ignored the NS and can well reflect the sensitivity of joint roughness coefficient (JRC) to PSD. The acquisition of PSD can provide a basis for the numerical simulation of rock engineering and provide quantitative research methods for the analysis of stick-slip events.

Published
2020

11. The shear stiffness criterion for rock joints considering rock wear behaviour

Author

Zhigang Tao, Chengzhi Qi, Chun Zhu, Liren Ban, Kuan Jiang, and Jingtao Li

Subjects
Shearing (physics), Materials science, Normal force, Shear stiffness, 0211 other engineering and technologies, Joint surface, Geology, 02 engineering and technology, Mechanics, Surface finish, 010502 geochemistry & geophysics, Geotechnical Engineering and Engineering Geology, Curvature, 01 natural sciences, Physics::Geophysics, Earth and Planetary Sciences (miscellaneous), Joint (geology), 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, Asperity (materials science)
Abstract

Rock is a material that is affected by wear, and the curvature of the asperities on a rock joint surface increases with the degree of wear after shearing. Based on the Greenwood and Williamson (GW) model, a new model considering the change of asperity curvature is proposed to explain the wear behaviour of rock joints. First, the shear stiffness formula for a joint surface is derived when the asperity curvature is constant, which shows that the shear stiffness increases with increase of asperity curvature. According to the Mohr–Coulomb criterion, the yield position of a single asperity under normal force and tangential friction force is discussed. Then, the critical normal force for a single asperity at a specific friction coefficient is obtained, which shows that the normal force corresponds to the curvature radius of the asperity. A rough surface model with multi-level curvature radius is proposed. With increase of normal force, the higher-order asperities gradually fail and the curvature radius become larger. A specific pressure value excites a specific radius of curvature, and the larger the pressure, the larger the radius of curvature. The relation between the normal force and the curvature radius is proposed and a shear stiffness formula considering the change of curvature radius of the asperity is derived. The proposed model is verified on the basis of the published experimental results. The calculation results of the proposed model can reflect the test results well: for a given joint surface, with increase in normal force the joint surface gradually becomes smooth; for different joint surfaces, with increase in roughness, the joint surface is more easily smoothed.

Published
2020

12. A New Criterion for Peak Shear Strength of Rock Joints with a 3D Roughness Parameter

Author

Chengzhi Qi, Liren Ban, Chenmeng Ji, Haoxiang Chen, and Fayuan Yan

Subjects
Shearing (physics), Materials science, Laser scanning, 0211 other engineering and technologies, Geology, 02 engineering and technology, Surface finish, 010502 geochemistry & geophysics, Geotechnical Engineering and Engineering Geology, Engraving, 01 natural sciences, Shear (geology), visual_art, visual_art.visual_art_medium, Composite material, Anisotropy, Joint (geology), Cement mortar, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, Civil and Structural Engineering
Abstract

With the help of 3D printing and 3D laser scanning techniques, cement mortar joint samples with a certain surface morphology were prepared. Shear tests of 20 sets of matching joint samples and 8 sets of joint samples with different percentages of cavity area were performed under constant normal load and uniform shear displacement. The results show that the distribution characteristics of the equivalent height difference based on the new roughness description were in accordance with the distribution of the wearing area after shearing, and the effect of cavities on the peak shear strength is essentially due to the influence of the cavities on the roughness of the joint surface. The relationships between the peak shear strength and the two roughness parameters were discussed, and a new criterion for predicting the peak shear strength of rock joints was proposed. It was noted that the roughness parameter system adopted in this paper, which can describe the peak shear strength, was reasonable. The roughness anisotropy of the five joint surfaces was discussed, and a corresponding quantification parameter AAHD accounting for the roughness anisotropy was proposed. The roughness of the joint surface has a positive size effect, a negative size effect and no size effect in a certain direction. However, no matter the direction, the roughness parameters will gradually stabilize as the research scale increases. A similar relationship between the roughness anisotropy parameters and research scales was also observed. To check the applicability of the proposed criterion for estimating the peak shear strength of natural rock joints, 12 sets of rock joints with the same surface morphology were produced based on a numerically controlled engraving technique. Under the same loading conditions as those in the shear tests of the cement mortar replication joints, the peak shear strengths of the rock joints were tested, and the results indicated that the new criterion was also applicable to predict the peak shear strength of natural rock joints.

Published
2019

13. Research on the anisotropy, size effect, and sampling interval effect of joint surface roughness

Author

Liren Ban, Chengzhi Qi, Hong-hu Yuan, Renliang Shan, and Fayuan Yan

Subjects
Surface (mathematics), Materials science, 010504 meteorology & atmospheric sciences, Laser scanning, Joint surface, Sampling (statistics), Geometry, Surface finish, 010502 geochemistry & geophysics, 01 natural sciences, Shear (sheet metal), Sample size determination, General Earth and Planetary Sciences, Anisotropy, 0105 earth and related environmental sciences, General Environmental Science
Abstract

In order to explore the factors impacting on the roughness of natural rock joints, a new roughness parameter AHD (the average equivalent height difference) is proposed based on study of joint surface by using the 3D laser scanning technology. The new parameter AHD cannot only reflect the roughness anisotropy of joint surface, but the sampling interval effect and the size effect on roughness. To quantitatively characterize the roughness anisotropy of joint surface, a new anisotropy parameter AAHD is established based on the new roughness parameter AHD. The new parameter AAHD is more comprehensive and reasonable than the anisotropy parameter Ka obtained by Belem because of its consideration on surface morphology in all shear directions, while Ka only considers the largest and the smallest values of roughness parameter. Based on the new parameter AAHD, the sampling interval effect and the size effect on the roughness anisotropy are further studied. The obtained results show that the roughness of joint surface is determined by shear directions, sampling intervals, and research sizes (which refers to window sampling size). It is found that the size effect on roughness depends on shear directions and stabilizes when research size increases to a certain value, while the roughness anisotropy is determined by sampling intervals and research size as well.

Published
2020

14. Stability analysis of anchored slopes based on a peak shear-strength criterion of rock joints

Author

Chengzhi Qi, Liren Ban, and Weisheng Du

Subjects
Global and Planetary Change, Materials science, 0208 environmental biotechnology, Soil Science, Tangent, Anchoring, Geology, 02 engineering and technology, Surface finish, 010501 environmental sciences, 01 natural sciences, Pollution, Physics::Geophysics, 020801 environmental engineering, Shear rate, Slope stability, Environmental Chemistry, Geotechnical engineering, Sensitivity (control systems), Joint (geology), Shear strength (discontinuity), 0105 earth and related environmental sciences, Earth-Surface Processes, Water Science and Technology
Abstract

A new three-dimensional shear-strength criterion (3DSSC) considering the three-dimensional (3D) roughness of rock joints and the internal friction angle of rock masses is discussed. Two methods for transforming the parameters of the 3DSSC into the linear Mohr–Coulomb failure criterion parameters are proposed. The calculation method of the anti-sliding safety coefficient of a rock slope controlled by a single anchored rock joint is derived, and anchoring parameter analysis is carried out. Compared with the equivalent linear fitting method and tangent equivalent method for obtaining the Mohr–Coulomb shear-strength parameters, the 3DSSC can be directly applied to calculate the rock slope stability controlled by a single rock joint. The change in the characteristics of the anti-sliding safety coefficient of the slope with the changes in the 3D roughness parameters, shear rate, and internal friction angle are discussed. The sensitivity of these factors to the slope stability is analyzed. It is suggested that for rock slopes with high roughness and a small internal friction angle, the weakening effect of the anchoring force angle on the anti-sliding stability of the slope should be taken into account.

Published
2020

15. Study on fracture process zone near mode II and mode III dynamic crack tip

Author

Chengzhi Qi, Liren Ban, and Chenmeng Ji

Subjects
Materials science, 010504 meteorology & atmospheric sciences, Mode (statistics), Fracture mechanics, Mechanics, Stress functions, 010502 geochemistry & geophysics, Poisson distribution, 01 natural sciences, Physics::Geophysics, symbols.namesake, symbols, General Earth and Planetary Sciences, von Mises yield criterion, In plane strain, Fracture process, Rayleigh wave, 0105 earth and related environmental sciences, General Environmental Science
Abstract

Determination of the configuration and size of fracture process zone (FPZ) at dynamic crack tip is still a problem unsolved completely at present. In this paper, based on elastic dynamic theory and stress functions, a method for evaluating the configuration and the size of FPZ is proposed and the feasibility of the method is demonstrated. The configuration and size of the FPZ near the crack tip in dependence on crack propagation velocity are determined by using the Von Mises and Tresca criteria, respectively. Numerical results show that FPZ at mode II and mode III dynamic crack tip is distributed symmetrically with respect to crack plane and increases with the crack propagation velocity. FPZ changes more rapidly when the Rayleigh wave velocity is approached. The effects of Poisson’s ratio on FPZ are discussed. Analysis reveals an intricate dependence on Poisson’s ratio in plane strain condition.

Published
2020

16. New roughness parameters for 3D roughness of rock joints

Author

Liren Ban, Chun Zhu, Zhigang Tao, and Chengzhi Qi

Subjects
Materials science, 0211 other engineering and technologies, Geology, Geometry, 02 engineering and technology, Surface finish, 010502 geochemistry & geophysics, Geotechnical Engineering and Engineering Geology, 01 natural sciences, Fractal dimension, Power law, Directivity, Fractal, Shear (geology), Anisotropy, Joint (geology), 021101 geological & geomatics engineering, 0105 earth and related environmental sciences
Abstract

To clearly portray the mechanical behavior of the shear process and to relate three-dimensional surface morphology to the shear strength of rock joints, we propose a new method, the equivalent height difference system, which can reflect that different geometric parameters of the asperities contribute differently to shear strength. A roughness parameter, the average equivalent height difference (AHD), is obtained by averaging the equivalent height difference in the shear direction, which can reflect the fluctuation and directivity of the joint surface morphology. The values of AHD at different sampling intervals were studied. The relationship between AHD values and sampling intervals is power law. Another roughness parameter, fractal dimension (DAHD), was proposed based on the fractal component, which characterizes the relationship of roughness at different scales and describes the roughness comprehensively from the point of view of scale. We used these two newly proposed roughness parameters to characterize the roughness of five joint surfaces. The results show that the new method can well reflect the three-dimensional morphology of the joint and describe the anisotropy of roughness, and it can also overcome the influence of the sampling interval.

Published
2018

18. Modified 2D roughness parameters for rock joints at two different scales and their correlation with JRC

Author

Chengzhi Qi, Weisheng Du, Chun Zhu, and Liren Ban

Subjects
Correlation, Joint roughness, Waviness, Mathematical analysis, 0211 other engineering and technologies, 02 engineering and technology, Surface finish, Geotechnical Engineering and Engineering Geology, Joint (geology), 021101 geological & geomatics engineering, 021102 mining & metallurgy, Mathematics
Abstract

To overcome the drawbacks of the existing two-dimensional (2D) roughness parameters, this paper proposes two parameters to characterise the roughness of rock joints. One is used to represent the local features of the joint profiles, and the other is used to characterise the overall features. The proposed local 2D parameter θ2d can provide an alternative approach and facilitate the characterisation of the roughness of the joint rock surface when a three-dimensional measuring apparatus is unavailable. This parameter is calculated using 10 standard joint roughness coefficient (JRC) profiles, and the value of θ2d does not increase monotonically with an increase in the JRC. The results suggest that θ2d can reflect the local waviness but fails to describe the overall features of the profiles. Another parameter, h1, is introduced to consider the overall features of the profiles. A new equation for the JRC is derived by combining the small- and large-scale roughness parameters. Predictions based on the new equation are compared with the experimental data, and the results indicate the applicability of the new equation.

Published
2021

19. A modified roughness index based on the root mean square of the first derivative and its relationship with peak shear strength of rock joints

Author

Weisheng Du, Chengzhi Qi, and Liren Ban

Subjects
Shearing (physics), Materials science, Engineering geology, 0211 other engineering and technologies, Geology, 02 engineering and technology, Surface finish, 010502 geochemistry & geophysics, Geotechnical Engineering and Engineering Geology, 01 natural sciences, Root mean square, Shear (geology), Surface roughness, Direct shear test, Composite material, Joint (geology), 021101 geological & geomatics engineering, 0105 earth and related environmental sciences
Abstract

Based on the index, the root mean square of the first derivative of the profile (Z2), the contribution of the asperities with different geometric characteristics to the peak shear strength (PSS) is considered, and an improved roughness index (Z2)ds is proposed. (Z2)ds is reasonably related to the PSS and can reflect the directionality of the PSS. The direct shear tests of 60 joints under different normal stress are carried out. Test results show that the PSS is related to normal stress, surface morphology and shear direction. The joint equivalent dip angles and the abrasion zone of joints after shearing share a similar distribution. There is a clear linear relationship between (Z2)ds and the joint PSS. Accordingly, a new relationship between the roughness index (Z2)ds and PSS is proposed. The new relationship can eliminate the influence of sampling intervals. The proposed index (Z2)ds establishes a reasonable relationship between the surface roughness and shear mechanical properties of rock joints. This is helpful to study the shear behavior of rock masses in a specific direction in engineering geology.

Published
2020

20. A direction-dependent shear strength criterion for rock joints with two new roughness parameters

Author

Chunsheng Lu, Chengzhi Qi, and Liren Ban

Subjects
Slope angle, Materials science, 0211 other engineering and technologies, 02 engineering and technology, Mechanics, Surface finish, 010502 geochemistry & geophysics, 01 natural sciences, Joint roughness, Shear (geology), General Earth and Planetary Sciences, Contact area, Joint (geology), 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, General Environmental Science
Abstract

The surface morphology of a rock joint is closely related to its mechanical properties. To reasonably characterize a rock surface, two new roughness parameters were proposed in this paper. One is related to the average slope angle of asperities that contribute to the shear strength, and the other reflects the frictional behavior of asperities that is defined as the maximum possible contact area in the shear direction. Taking the standard joint roughness coefficient profiles as example, these two roughness parameters can be applied to describe the directional characteristics of shear strength. Based on their relationships with initial dilation angles, the proposed roughness parameters were incorporated into a peak shear strength criterion. It is shown that the predicted peak shear strength is consistent with experimental data, and there is a power–law relationship. The application range of new roughness parameters was determined, which may facilitate a measurement process.

Published
2018

21. Numerical analysis of the axial strength of CHS T-joints reinforced with external stiffeners

Author

Yuxing Huang, Liren Ban, Shuwen Li, Lei Zhu, and Yan Zhao

Subjects
Engineering, business.industry, Mechanical Engineering, Numerical analysis, Building and Construction, Structural engineering, Finite element method, Fe model, Composite material, business, Reinforcement, Joint (geology), Civil and Structural Engineering, Parametric statistics
Abstract

This study reinforced circular hollow section (CHS) T-joints with external stiffeners and analyzed the axial strength of both the unreinforced and reinforced T-joints. The SHELL181 element in ANSYS was used to establish FE models of the T-joints. A comparison between the experimental results indicated that the numerical method could be used to compute the strength for the unreinforced and reinforced CHS T-joints. To further investigate the reinforcement effect of the external stiffeners, a numerical parametric study was conducted. The study then evaluated the variations in strength of differently sized stiffeners. It was found that the joint strength increased significantly as the size of the stiffener increased. The reinforcement effect is more dependent on the stiffener length than on the stiffener height, but it is reasonable to adopt stiffeners with equal lengths and heights since this shape is commonly-used in engineering projects.

Published
2014

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