Deformation Failure and Support Test of Surrounding Rock in Deep Arched Roadway with Straight Wall

Pan, Shuqi; Liu, Shuaitao; Cao, Liming; Guo, Junfeng; Che, Yong

doi:10.1155/2021/3208974

Cited by 2 publications

(2 citation statements)

References 18 publications

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“…Based on the elastic-plastic mechanics, the radius R of the plastic zone of the roadway is derived R = italica true[ ( p 0 + c ⁢ cot ⁡ φ ) ( 1 − sin ⁡ φ ) P i + c nobreak0em0.25em⁢ cot nobreak0em.25em⁡ φ true] 1 − sin ⁡ φ / 2 ⁢ sin ⁡ φ where R is the radius of the plastic zone, m; P 0 is the initial primary rock stress, MPa; P i is the support resistance, MPa; φ is the angle of friction, deg; c is internal cohesion, MPa; a = K S π , the rectangular section roadway K takes 1.2; S is the cross-sectional area of the roadway, m 2 .…”

Section: Surrounding Rock Control Principle Of Water-drenching Roadwa...mentioning

confidence: 99%

Bolt–Cable–Mesh Integrated Support Technology for Water Drenching Roadway in Thick Coal Seam

Jia

Fan

et al. 2022

ACS Omega

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Aiming at the problems of large deformation and difficult control of the mining roadway water drenching in a thick coal seam, the principle of double-arch zoning cooperative surrounding rock control is studied by using the combined method of theoretical analysis, numerical simulation, and industrial experiment. The water–rock interaction of the surrounding rock of water-drenching roadway is proposed, taking into account the damage to the mechanical parameters of the surrounding rock caused by soaking water. The water-mechanical-damage coupling model for surrounding rock of a coal seam roadway is constructed, and is numerically solved by the code development using the FISH language. The principle of “high prestressed bolt–cable–mesh” zone coordinated control is revealed, and the existence of a compressive stress arch is verified by FLAC3D software. The three support schemes were compared and analyzed by numerical simulation software. We affirmed the bolt length of 2400 mm, spacing of 0.9 m, row spacing of 1 m, cable length of 7300 mm, and arrangement 3–2–3 as the optimal support scheme and applied this scheme in the Zhangcun Coal Mine. The results show that the maximum deformation of the roadway roof is 142 mm, and the ultimate convergence of the two sides is 83 mm. The surrounding rock has been effectively controlled.

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Section: Surrounding Rock Control Principle Of Water-drenching Roadwa...mentioning

confidence: 99%

Bolt–Cable–Mesh Integrated Support Technology for Water Drenching Roadway in Thick Coal Seam

Jia

Fan

et al. 2022

ACS Omega

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“…At present, scholars at home and abroad mainly focus on the mechanical effect of anchor cables but ignore the influence of surrounding rock and the relative relationship between the anchor cable and surrounding rock [14]. A large number of studies show that the deformation and failure of surrounding rocks in deep roadways are gradual [15][16][17][18][19]. Previous studies do not reflect the influence of the progressive failure behavior of surrounding rock and mechanical characteristics of cable wells, and the internal load transfer behavior and mechanism of anchor cable still cannot be explained quantitatively and evaluated correctly.…”

Section: Introductionmentioning

confidence: 99%

Load Transfer Behavior and Failure Mechanism of Bird’s Nest Anchor Cable Anchoring Structure

2022

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To research the internal load transfer behavior and failure mechanism of a bird’s nest anchor cable anchoring structure based on a pull-out test, a bond-slip failure model is established on the basis of statistical damage theory, and the distribution formula of shear stress at anchorage agent–rock interface is deduced. Combined with theoretical analysis, bird’s nest anchor cable pulling out test and particle flow code (PFC) numerical simulation test, as well as axial force distribution of the cable and shear stress distribution of its interface, help reveal its load transfer behavior and failure mechanism. Results show that: (1) The established bond-slip model can reflect the internal load transfer behavior and failure process of bird’s nest anchor cable anchorage structure. (2) The shear stress of the anchorage agent interface increases exponentially to the peak value and then decreases exponentially to the residual strength. The process is repeated at every location of the anchorage agent interface. The curve of the axial force and shear stress of the bird’s nest anchor cable is a negative exponential distribution with anchorage depth, and the maximum value occurs at the load end. (3) The crack of the anchorage agent interface extends from the load end to the other end and finally cuts through the whole interface. Rock mass generates radial cracks by the split effects of the bird’s nest. The failure mode is a combination of the debonding slip of the interface and the shear failure of the rock mass. The shear stress distribution and failure mode of the anchor structure are basically consistent according to laboratory tests and simulation tests, and PFC2D better reflects the internal load transfer behavior, failure mechanism, and failure process of the bird’s nest anchor cable under tensile loads.

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Deformation Failure and Support Test of Surrounding Rock in Deep Arched Roadway with Straight Wall

Cited by 2 publications

References 18 publications

Bolt–Cable–Mesh Integrated Support Technology for Water Drenching Roadway in Thick Coal Seam

Bolt–Cable–Mesh Integrated Support Technology for Water Drenching Roadway in Thick Coal Seam

Load Transfer Behavior and Failure Mechanism of Bird’s Nest Anchor Cable Anchoring Structure

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