Suggested New Statistical Parameter for Estimating Joint Roughness Coefficient considering the Shear Direction

Zhang, Zhiqiang; Huan, Jiuyang; Li, Ning; He, Mingming

doi:10.1155/2021/8872873

Cited by 3 publications

(3 citation statements)

References 35 publications

(61 reference statements)

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“…Obviously, this procedure ignored the effect of the protrusion size on overall roughness. The distribution law of the external force borne by the joint protrusion was rarely mentioned in the existing literature, and there was no quantitative result for reference [34][35][36]. Moreover, the size of joint protrusion in rough joints is difficult to be clearly simulated, which leads to poor correlation of corresponding analysis results [37].…”

Section: Introductionmentioning

confidence: 99%

An Investigation on Local Shearing Mechanisms of Irregular Dentate Rock Joints Using the PFC

Huan

Zhang

et al. 2022

Geofluids

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Joint surfaces are widely distributed in natural rock mass, and their shear mechanical properties play an important role in determining the safety and stability of rock mass. Previous studies rarely discussed the contribution degree of different joint protrusions to resisting shear stress. In this study, seven irregular dentate joint profiles were proposed to represent the geometric morphology of natural joints. Joint samples were subjected to direct shear tests under constant normal stress using the particle flow code (PFC). First, the reliability of the research scheme was verified by routine test results. Secondly, based on the microcrack tracking module and the force chain analysis, the local failure modes of the joint sample after and during the shearing process are discussed in detail. The relationship between the shear stress and the number of microcracks was studied. Finally, based on the measuring circle function, the variation law of the mean stress at different joint protrusions during the shearing process was tracked. The maximum stress of each protrusion before the shear stress peak was introduced to quantitatively describe the contribution of local protrusions to shear stress. There was an important link between the size of the protrusion and the stress it can withstand. During the shearing process, the local shearing mechanism of the joint surface is controlled by the distribution of joint protrusions. The research results of this paper can provide a good idea for the follow-up joint surface research.

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Section: Introductionmentioning

confidence: 99%

An Investigation on Local Shearing Mechanisms of Irregular Dentate Rock Joints Using the PFC

Huan

Zhang

et al. 2022

Geofluids

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“…Formula Ref. JRC = 411(R P − 1) JRC = 65.9(R P − 1) 0.302 − 9.65 [21] [22] [23] [25] [27] [28] [29] JRC = −106.67(θ p + ) −0.363 + 55.34 [30] Z…”

Section: Parametermentioning

confidence: 99%

“…(max(0, y i+1 − y i )) 2 1/2 [31] JRC = −9.43(Z 2 ) −0.687 + 35.11 [30] tan θ * = − tan θ cos α [33] JRC = 14.602 ln(WPA) − 12.536 [33] With the development of scanning technology, three-dimensional (3D) statistical parameters were proposed. Based on the "local apparent inclination asperity dip", a 3D roughness parameter was proposed [32,[34][35][36].…”

Section: Parametermentioning

confidence: 99%

A New Characterization Method for Rock Joint Roughness Considering the Mechanical Contribution of Each Asperity Order

Yuan

Luo

et al. 2021

Applied Sciences

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The morphology of the joint surface is multi-scale, and it can be divided into first-order asperity (waviness) and second-order asperity (unevenness). At present, the joint roughness characterization formula considers only the morphology contribution of waviness and unevenness components and does not fully consider their mechanical contribution. At same time, the relationship between the mechanical contribution and the morphology contribution is still unclear. Thus, the characterization formula considering the mechanical contribution of waviness and unevenness needs to be further studied. In this study, the standard joint roughness coefficient (JRC) profiles were first decomposed into waviness and unevenness. Then, three types of joint specimens with different asperity orders (flat, the standard JRC profile, and the profile containing only waviness) were prepared by the 3D engraving technique. Finally, direct shear tests were carried out on 39 sets of red sandstone joint specimens under three normal stresses. The mechanical contributions of waviness and unevenness were studied, the relationship between the mechanical contribution and the morphology contribution of waviness and unevenness was analyzed, and the characterization formula considering the mechanical contribution of waviness and unevenness was established. The results showed that the following: (1) the method combining the ensemble empirical mode decomposition (EEMD) and the critical decomposition level could be used to separate the waviness and unevenness from the joint surface; (2) the mechanical contribution of the waviness and unevenness decreased with the increase in normal stress; (3) the relationship between the mechanical contribution ratio and the statistical parameter ratio of the waviness and unevenness can be describe by power function; and (4) the roughness characterization formula considering the mechanical contribution and morphology contribution was established. This study will enhance the accurate evaluation of the roughness coefficient and shear strength of the joint specimen.

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3D scanning-based morphological characterization of rammed layer interfaces: a case study of the Ming Great Wall in northwestern China

Zhang

Chen

et al. 2022

Bull Eng Geol Environ

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Suggested New Statistical Parameter for Estimating Joint Roughness Coefficient considering the Shear Direction

Cited by 3 publications

References 35 publications

An Investigation on Local Shearing Mechanisms of Irregular Dentate Rock Joints Using the PFC

An Investigation on Local Shearing Mechanisms of Irregular Dentate Rock Joints Using the PFC

A New Characterization Method for Rock Joint Roughness Considering the Mechanical Contribution of Each Asperity Order

3D scanning-based morphological characterization of rammed layer interfaces: a case study of the Ming Great Wall in northwestern China

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