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Rock Mechanics and Rock Engineering
Erschienen in: Rock Mechanics and Rock Engineering 1/2020

19.07.2019 | Original Paper

Stability Analysis of a Non-pillar-Mining Approach Using a Combination of Discrete Fracture Network and Discrete-Element Method Modeling

verfasst von: G. L. Zhu, R. L. Sousa, M. C. He, P. Zhou, J. Yang

Erschienen in: Rock Mechanics and Rock Engineering | Ausgabe 1/2020

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Abstract

This paper presents a study on the stability of a mine entry of an innovative approach to non-pillar coal mining—gob-side entry retaining using cantilever beam theory (GERMC). This method is on the rise in China and it has shown to increase the coal seam rate of recycling and mining productivity. The method utilizes the caved-in material resulting from the mining activities to fill the gob area and ensure the stability of the roof of the already mined area. The caved-in material will form the gob-side wall of the retained entry. This characteristic is unique to this method. Thus, there are not many studies that analyze the stability of the filling material and of the gob-side entry wall under these circumstances, which is a vital element for the safety of the mining operations. This paper studies the stability of the gob-side retained entry of the Hongjingta underground coal mine in China. The authors perform the analysis using a discrete fracture network (DFN) model developed by the Massachusetts Institute of Technology (MIT), GEOFRAC, in combination with the discrete-element method (DEM) software UDEC. GEOFRAC estimates the rock blocks (fracture networks) in the filling body, from fracture traces measured along the gob-side wall of the entry. Statistical methods are used to estimate the fracture intensity and the mean fracture areas, which are inputs to the DFN. The generated fracture networks are then inputted into the DEM code, UDEC, to evaluate the stability of the mine-retained entry. For this study, we developed two types of models in UDEC, one considering the fractures generated by the DFN model and another considering the gob-filling material as a continuum. This methodology—combined DFN–DEM—is unique and provides a more realistic representation of the gob-filling material by considering the fractures in the filling body and by estimating those fractures (interfaces between rock blocks) using field data. In addition to this, we also considered the effects of uncertainties that are associated with estimating three-dimensional (3-D) fractures’ networks/rock blocks from two-dimensional (2-D) field data. Finally, the results of the simulations were compared with the measurements from the mine and are in good agreement.
Vorheriger Artikel Ultimate Bearing Capacity of Rock Mass Foundations Subjected to Seepage Forces Using Modified Hoek–Brown Criterion
Nächster Artikel Highly Efficient and Simplified Method for Measuring the Permeability of Ultra-low Permeability Rocks Based on the Pulse-Decay Technique

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Literatur
Bat JB, Zhou HQ, Hou CJ, Tu XZ, Yue DZ (2004) Development of support technology beside roadway in goaf-side entry retaining for next sublevel. J China Univ Min Technol 33(2):183–186 (Zhongguo Kuangye Daxue Xuebao in Chinese)
Dershowitz WS (1985) Rock Joint System. PhD Thesis. Massachusetts Institute of Technology
Dershowitz WS, Einstein HH (1988) Characterizing rock joint geometry with joint system models. Rock Mech Rock Eng 21(1):21–51CrossRef
Dershowitz WS, Herda HH (1992) Interpretation of fracture spacing and intensity. In: Proceedings, 33rd U.S. Symposium on Rock Mechanics, Balkema, Rotterdam, Netherlands, 757–766
Dershowitz WS, Foxford T, Doe T (1998) Research report on fracture data analysis technology. Golder Associates, Redmond
Dershowitz WS, Hermanson J, Follin S, and Mauldon M (2000) Fracture intensity measures in 1-D, 2-D, and 3-D at Aspo, Sweden. In: 4th North American Rock Mechanics Symposium. American Rock Mechanics Association
He TJ (2000) The breaking place prediction of face end main roof flap top in the gob-side entry retaining. J China Coal Soc 25(1):28–31 (In Chinese)
He MC, Gong WL, Wang J, Qi P, Tao ZG, Du S et al (2014) Development of a novel energy-absorbing bolt with extraordinarily large elongation and constant resistance. Int J Rock Mech Min Sci 67:29–42CrossRef
He MC, Zhu GL, Guo ZB (2015) Longwall mining “cutting cantilever beam theory” and 110 mining method in China—the third mining science innovation. J Rock Mech Geotech Eng 7(5):483–492CrossRef
He MC, Gao YB, Yang J, Gong WL (2017) An innovative approach for gob-side entry retaining in thick coal seam longwall mining. Energies 10(11):1785CrossRef
He MC, Gao YB, Yang J, Wang JW, Wang YJ, Zhu Z (2018) Engineering experimentation of gob-side entry retaining formed by roof cutting and pressure release in a thick-seam fast-extracted mining face. Rock Soil Mech 39(1):254–264
Hua XZ (2004) Study on gob-side entry retaining technique with roadside packing in longwall top-coal caving technology. J Coal Sci Eng 10:9–12
Ivanova VM (1995) Geologic and Stochastic Modeling of Fracture Systems in Rocks. M.Sc. Thesis. Massachusetts Institute of Technology
Ivanova VM, Sousa RL, Murrihy B, Einstein HH (2014) Mathematical algorithm development and parametric studies with the GEOFRAC three-dimensional stochastic model of natural rock fracture systems. Comput Geosci 67:100–109CrossRef
Liang Y (2009) Theory and practice of integrated pillarless coal production and methane extraction in multiseams of low permeability. Eng Sci 11:72–80
Ma ZM, Guo ZB, Liu XY, Wang HH (2017) Study on bulking rule and mechanical characteristics of fallen gangue in roof-cutting entry retaining. Coal Engineering 49(11):94–98
Qian MG (1981) The equilibrium condition for overlying strata in the stope. J China Inst Min Technol 2:31–40 (In Chinese)
Rohrbaugh MB Jr, Dunne WM, Mauldon M (2002) Estimating fracture trace intensity, density, and mean length using circular scan lines and windows. AAPG Bull 86(12):2089–2104
Song ZQ (1982) Rules for the stope bearing pressure and its application. J Shandong Inst Min Technol 1:1–25 (In Chinese)
Song ZQ, Cui ZD, Xia HC, Tang JQ, Wen ZJ (2010) The fundamental theoretical and engineering research on the green safe no coal pillar mining model by mainly using coal gangue backfill. Meitan Xuebao J China Coal Soc 35(5):705–710 (In Chinese)
Tan Y, Yu F, Ning J, Zhao T (2015) Design and construction of entry retaining wall along a gob-side under hard roof stratum. Int J Rock Mech Min Sci 77:115–121CrossRef
Tao ZG, Song ZG, He MC, Meng ZG, Pang S (2018) Principles of the roof cut short-arm beam mining method (110 method) and its mining-induced stress distribution. Int J Min Sci Technol 28(3):391–396CrossRef
US DOE (1995) Longwall mining archived 2009-08-17 at the wayback machine, office of coal, nuclear, electric and alternate fuels. US Department of Energy, March 1995, pp 9–10
Wang Q, He M, Yang J, Gao H, Jiang B, Yu H (2018) Study of a no-pillar mining technique with automatically formed gob-side entry retaining for longwall mining in coal mines. Int J Rock Mech Min Sci 110:1–8CrossRef
Xue Y (2013) From tradition to modern times: evolution of coal mining technology in China. J Hubei Polytech Univ (Humanit Soc Sci) 30(05):7–15 (In Chinese)
Yang H, Cao S, Wang S, Fan Y, Wang S, Chen X (2016) Adaptation assessment of gob-side entry retaining based on geological factors. Eng Geol 209:143–151CrossRef
Zhan XY, Wu RZ, Wang F (2016) No pillar mining flexible filling let Berm Lane Filling wall and its construction method. Chinese Patent for invention, no. CN 103485820 B (in Chinese)
Zhang L, Einstein HH (2000) Estimating the intensity of rock discontinuities. Int J Rock Mech Min Sci 37(5):819–837CrossRef
Zhang L, Einstein HH, Dershowitz WS (2002) Stereological relationship between trace length and size distribution of elliptical discontinuities. Geotechnique 52(6):419–433CrossRef
Zhang GF, He MC, Yu XP, Huang ZG (2011) Research on the technique of no-pillar mining with gob-side entry formed by advanced roof caving in the protective seam in Baijiao coal mine. J Min Saf Eng 28(4):511e6 (In Chinese)
Zhang N, Yuan L, Han C, Xue J, Kan J (2012) Stability and deformation of surrounding rock in pillar-less gob-side entry retaining. Saf Sci 50(4):593–599CrossRef
Zhu GL, Sousa RL, Zhou P and Yang J (2018) Numerical Analysis of the Stability of a Gob-side Entry Retaining in Non-pillar Coal Mining using Discrete Fracture Network Modeling. In: Proceedings of the 52nd US Rock Mechanics/Geomechanics Symposium, American Rock Mechanics Association
Metadaten
Titel
Stability Analysis of a Non-pillar-Mining Approach Using a Combination of Discrete Fracture Network and Discrete-Element Method Modeling
verfasst von
G. L. Zhu
R. L. Sousa
M. C. He
P. Zhou
J. Yang
Publikationsdatum
19.07.2019
Verlag
Springer Vienna
Erschienen in
Rock Mechanics and Rock Engineering / Ausgabe 1/2020
Print ISSN: 0723-2632
Elektronische ISSN: 1434-453X
DOI
https://doi.org/10.1007/s00603-019-01901-w

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