2019
DOI: 10.3390/en12153009
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Control Technology of Soft Rock Floor in Mining Roadway with Coal Pillar Protection: A case study

Abstract: This study considered the mining roadway with coal pillar protection in the fully mechanized caving face of the Dananhu No.1 Coal Mine, China. Theoretical analysis, numerical simulation, and field tests were conducted, and the stress environment, deformation, and failure characteristics of the mining roadway in the fully mechanized caving face were analyzed. The results revealed that the intrinsic cause for the large asymmetrical floor deformation in the mining roadway is the asymmetrical phenomenon of the sur… Show more

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Cited by 23 publications
(16 citation statements)
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“…For example, when b = 2.6 m, a maximum bending moment of 175 kN m is observed (still located at both ends), and the bending moment at the center is 89 kN m. The reduction factors are 9.43 and 9.27, respectively, indicating that the double‐row reinforced concrete pillars can effectively support the goaf roof, increase the constraint points of the roof, and reduce the roof span to further improve the roof stress state. Accordingly, it is possible to prevent roof separation instability, and even roof falls 69,70 . However, with an increase in b (2.6 m → 3.1 m → 3.6 m → 4.1 m), the bending moments at the center and action positions of the pillars significantly increase.…”
Section: Resultsmentioning
confidence: 99%
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“…For example, when b = 2.6 m, a maximum bending moment of 175 kN m is observed (still located at both ends), and the bending moment at the center is 89 kN m. The reduction factors are 9.43 and 9.27, respectively, indicating that the double‐row reinforced concrete pillars can effectively support the goaf roof, increase the constraint points of the roof, and reduce the roof span to further improve the roof stress state. Accordingly, it is possible to prevent roof separation instability, and even roof falls 69,70 . However, with an increase in b (2.6 m → 3.1 m → 3.6 m → 4.1 m), the bending moments at the center and action positions of the pillars significantly increase.…”
Section: Resultsmentioning
confidence: 99%
“…Accordingly, it is possible to prevent roof separation instability, and even roof falls. 69,70 However, with an increase in b (2 .6 m → 3.1 m → 3.6 m → 4.1 m), the bending moments at the center and action positions of the pillars significantly increase. Thus, the pillars can be arranged on both sides of the main roadway (b = 2.75 m) in view of the field engineering experience.…”
Section: The Equilibrium Equation Of the Mechanical Model Is Given Asmentioning
confidence: 99%
“…In terms of control of the floor heave, Jia et al [15] believed that the lateral side-cutting pressure relief of the roadway can be used to control the deformation. Xie and Chang [16] proposed the use of grouting anchors and concrete backfill to control the bottom roadway of deep roadways.…”
Section: Introductionmentioning
confidence: 99%
“…e instability mechanisms of these two structures are not the same, but they will cause the working resistance of the working face bracket to be too large. Research on coal roadways under close coal seams includes roof span, prestressed load-bearing structure of the anchor cable, and roof tensile and shear failure [14][15][16][17]. e study of the stability of the surrounding rocks for coal seams under close coal seams includes the compression bearing capacity of the coal and rock mass, the relative proportions of the coal and rock mass, and the coal and rock roadway tensile shear failure structure [18][19][20][21].…”
Section: Introductionmentioning
confidence: 99%