Anchoring effect and energy-absorbing support mechanism of large deformation bolt

Tong-bin Zhao; Ming-lu Xing; Wei-yao Guo; Cun-wen Wang; Bo Wang

doi:10.1007/s11771-021-4622-0

Journal of Central South University ›› 2021, Vol. 28 ›› Issue (2) : 572 -581. DOI: 10.1007/s11771-021-4622-0

Article

Anchoring effect and energy-absorbing support mechanism of large deformation bolt

Author information +

History +

PDF

Abstract

To research the anchoring effect of large deformation bolt, tensile and drawing models are established. Then, the evolution laws of drawing force, bolt axial force and interfacial shear stress are analyzed. Additionally, the influence of structure element position on the anchoring effect of large deformation bolt is discussed. At last, the energy-absorbing support mechanism is discussed. Results show that during the drawing process of normal bolt, drawing force, bolt axial force and interfacial shear stress all gradually increase as increasing the drawing displacement, but when the large deformation bolt enters the structural deformation stage, these three values will keep stable; when the structure element of large deformation bolt approaches the drawing end, the fluctuation range of drawing force decreases, the distributions of bolt axial force and interfacial shear stress of anchorage section are steady and the increasing rate of interfacial shear stress decreases, which are advantageous for keeping the stress stability of the anchorage body. During the working process of large deformation bolt, the strain of bolt body is small, the working resistance is stable and the distributions of bolt axial force and interfacial shear stress are steady. When a rock burst event occurs, the bolt and bonding interface cannot easily break, which weakens the dynamic disaster degree.

Keywords

rock burst / large deformation bolt / numerical simulation / pull-out test / anchoring effect / energy-absorbing mechanism

Cite this article

Download citation ▾

Tong-bin Zhao, Ming-lu Xing, Wei-yao Guo, Cun-wen Wang, Bo Wang. Anchoring effect and energy-absorbing support mechanism of large deformation bolt. Journal of Central South University, 2021, 28(2): 572-581 DOI:10.1007/s11771-021-4622-0

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	LiZ-l, DouL-m, WangG-f, CaiW, HeJ, DingY-L. Risk evaluation of rock burst through theory of static and dynamic stresses superposition [J]. Journal of Central South University, 2015, 22: 676-683

[2]	GuoW-y, ZhaoT-b, TanY-l, YuF-h, HuS-c, YangF-Q. Progressive mitigation method of rock bursts under complicated geological conditions [J]. International Journal of Rock Mechanics and Mining Sciences, 2017, 96: 11-22

[3]	WangJ, QiuP-q, NingJ-g, ZhuangL, YangS. A numerical study of the mining-induced energy redistribution in a coal seam adjacent to an extracted coal panel during longwall face mining: A case study [J]. Energy Science & Engineering, 2020, 8(3): 817-835

[4]	GuoW-y, YuF-h, TanY-l, ZhaoT-B. Experimental study on the failure mechanism of layer-crack structure [J]. Energy Science & Engineering, 2019, 7: 2351-2372

[5]	LuoY, GongF-q, LiX-b, WangS-Y. Experimental simulation investigation of influence of depth on spalling characteristics in circular hard rock tunnel [J]. Journal of Central South University, 2020, 27: 891-910

[6]	GongF-q, LuoY, LiX-b, SiX-f, TaoM. Experimental simulation investigation on rockburst induced by spalling failure in deep circular tunnels [J]. Tunnelling and Underground Space Technology, 2018, 81: 413-427

[7]	ZhaoT-b, GuoW-y, TanY-l, YinY-c, CaiL-s, PanJ-F. Case studies of rock bursts under complicated geological conditions during multi-seam mining at a depth of 800 m [J]. Rock Mechanics and Rock Engineering, 2018, 51: 1539-1564

[8]	LI Li-ping, HU Jie, LI Shu-cai, QIN Cheng-shuai, LIU Hong-liang, CHEN Di-yang, WANG Jing. Development of a novel triaxial rock testing method based on biaxial test apparatus and its application [J]. Rock Mechanics and Rock Engineering, 2020. DOI: https://doi.org/10.1007/s00603-020-02329-3.

[9]	TanY-l, GuoW-y, ZhaoT-b, MengX-J. Coal rib burst mechanism in deep roadway and “stress relief-support reinforcement” synergetic control and prevention [J]. Journal of China Coal Society, 2020, 45(1): 66-81(in Chinese)

[10]	LiC C, DoucetC. Performance of D-bolts under static loading [J]. Rock Mechanics and Rock Engineering, 2012, 45: 183-192

[11]	KabweE, WangY-M. Review on rockburst theory and types of rock support in rockburst prone mines [J]. Open Journal of Safety Science & Technology, 2015, 5(4): 104-121

[12]	HeM-c, GuoZ-B. Mechanical property and engineering application of anchor bolt with constant resistance and large defromation [J]. Chinese Journal of Rock Mechanics and Engineering, 2014, 33(7): 1297-1308(in Chinese)

[13]	HeM-c, GongW-l, WangJ, QiP, TaoZ-g, DuS, PengY-Y. Development of a novel energy-absorbing bolt with extraordinarily large elongation and constant resistance [J]. International Journal of Rock Mechanics & Mining Sciences, 2014, 67: 29-42

[14]	LiC C. Field observations of rock bolts in high stress rock masses [J]. Rock Mechanics and Rock Engineering, 2010, 43: 491-496

[15]	PhillipsS H EFactors affecting the design of anchorages in rock [R], 1970, London, Cementation Research Ltd

[16]	WANG Ming-shu, HE Xiu-ren, ZHENG Yu-tian. Mechanical model of full grouting bolt and its application [J]. Metal Mine, 1983 (4): 24–29. (in Chinese)

[17]	YouC-a, GaoM, ZhangL-m, ZhanY-b, WangJ-H. Experimental research on stress distribution in anchorage body [J]. Rock and Soil Mechanics, 2004, 25(S): 63-66(in Chinese)

[18]	ZhaoT-b, YinY-c, TanY-l, QiuY. Mechanical test of bolt interface and microscopic simulation of transfer law for shear stress [J]. Journal of Mining & Safety Engineering, 2011, 28(2): 220-224(in Chinese)

[19]	YinY-c, ZhaoT-b, TanY-l, ZhangZ. Research of stress distribution evolution law and influencing factors [J]. Journal of Mining & Safety Engineering, 2013, 30(5): 712-714(in Chinese)

[20]	ZhanY-b, BiX-k, YouC-a, LuX-l, SunF. Numerical simulation on stress distribution in anchorage body [J]. Rock and Soil Mechanics, 2006, 27(S): 935-938(in Chinese)

[21]	HeR-l, ZhangP, LiuB-C. Theoretical and numerical analysis of bolt pull-out test [J]. Rock and Soil Mechanics, 2006, 27(S): 855-858(in Chinese)

[22]	ZhouS-c, ZhuW-c, YuS-S. Analysis of load transfer mechanism for fully grouted rockbolts based on the bi-exponential shear-slip model [J]. Chinese Journal of Rock Mechanics and Engineering, 2018, 37(2): 3817-3825(in Chinese)

[23]	MaS-w, ZhangM, CaoC, ZhangH-d, RenT, HanJ. Numerical simulation study on rib spacing anchorage optimization of right-handed rebar bolts [J]. Coal Science and Technology, 2019, 47(6): 117-125(in Chinese)

[24]	ZhangH-j, LiH-y, ZhangT-p, WangQ, WangW, WangX, ZhaoH, ChangT, GuoT-C. Research and engineering application of high pre-stressed resistance enhancement large deformation bolt in deep soft rock roadway-[J]. Journal of China Coal Society, 2019, 44(2): 409-418(in Chinese)

[25]	HuS-c, TanY-l, ZhouH, RuW-k, NingJ-g, WangJ, HuangD-m, LiZ. Anisotropic modeling of layered rocks incorporating planes of weakness and volumetric stress [J]. Energy Science and Engineering, 2020, 8(3): 789-803

[26]	WangJ, ZhangY, QinZ, SongS-g, LinP. Analysis method of water inrush for tunnels with damaged water-resisting rock mass based on finite element method-smooth particle hydrodynamics coupling [J]. Computers and Geotechnic, 2020, 126103725