煤层塑性区对坚硬顶板力学特性影响分析

doi:10.13722/j.cnki.jrme.2015.0083

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摘要矿压分析中常将坚硬顶板下部煤层的支承关系全简化为弹性地基，忽略工作面前方煤层塑性区支承力降低的影响。针对此问题，将煤层分为靠近煤壁的塑性区和其前方的弹性区。鉴于煤层支承力峰值位于煤层塑、弹区交界处及塑、弹区段对顶板反力为连续的实际工况，提出一个煤层塑性区支承力非线性表达式，给出其支承力峰值确定法和2个峰值精度验证法。在已有研究中全为弹性地基(支承)假定的顶板分析基础上，对煤层塑、弹区支承的初次来压前推进某阶段坚硬顶板的力学特性进行分析。给出煤层塑性区段顶板挠度方程形式解，求得五段式顶板挠度方程中全部积分常数。算例表明：随采空区步距的增大，顶板下沉量不断增大，煤层塑性区支承力峰值逐渐增大和煤壁处煤层支承力有所减小，煤壁前方与采空区跨中的顶板弯矩均随之增大，但煤壁前方的弯矩峰值始终大于采空区跨中弯矩。在此阶段如顶板因弯矩过大发生断裂，断裂线将发生在煤壁前方煤层塑性区段。将所得结果与全为弹性地基(支承)假定的顶板特性进行比较。得到如下认识：顶板与煤层是承受上覆荷载的共同体，全为弹性地基(支承)假定的顶板在煤壁处所受煤层反力，是塑性区煤层对顶板支承力的若干倍。强大反力的支承使顶板弯曲程度小(相应弯矩峰值小)，弯曲范围小(弯矩峰超前距小)；煤层塑性区支承的顶板在煤壁处所受煤层支承力远小于前者，顶板通过加大弯曲变形和弯曲范围去抵抗顶板的上覆荷载，这使得顶板弯矩峰值和弯矩峰超前距有明显增加，顶板挠度比全为弹性地基(支承)假定的顶板挠度有全面、大幅度增加。顶板弯矩峰超前距与顶板超前断裂距相关，基于煤层塑性区支承的顶板弯矩峰超前距均在4 m以上，与大多现场检测到的顶板超前断裂距接近，相应的顶板的内力和挠度特性描述要更为贴近实际。

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关键词 ：采矿工程, 坚硬顶板, 支承压力, 塑性区, 弹性地基, 力学特性

Abstract：In ground control theory，the supporting action of a coal seam under a tight roof has often been simplified to that of an elastic foundation，which ignores the influence of the decreasing bearing capacity in the plastic zone of the coal seam near the working face. In order to solve this problem，in this research，the coal seam was divided into two regions：a plastic zone near and an elastic zone ahead of the working face. A nonlinear expression for calculating the supporting force in the plastic zone of the coal seam was proposed based on the fact that the variation of the coal seam supporting force is continuous and the maximum supporting force occurs at the boundary between the plastic and the elastic zones. The calculation method to determine the maximum supporting force and two methods to assess the accuracy of this value are presented. The supporting mechanism of the elastic and plastic zones and the hard roof mechanical behaviour were analyzed by extending the traditional assumption that the roof is fully supported by an elastic foundation. An equation for roof deflection above the plastic zone of the coal seam was derived and constants were obtained for all five parts of the equation. A numerical example has demonstrated that with increasing step size of gob area，the deflection of the roof，the maximum supporting force in the plastic zone，and the bending moment of the roof between the working face and the middle of the gob area all increase，while the supporting force near the working face decreases slightly. However，the maximum bending moment ahead of the working face is always greater than that in the middle of the gob area. Therefore if failure occurs because of too large a bending moment，the fracture lines will be in the plastic zone of the coal seam ahead of the working face. Compared with the traditional approach of assuming a fully elastic foundation，our analysis has led to the following new conclusions. The roof and the coal seam work together to support the weight of overlying rocks. The supporting force of the coal seam at the working face assuming a fully elastic foundation is several times greater than that obtained when the plastic zone of the coal seam is considered. Consequently，when fully elastic foundation is assumed，the roof deflection is small due to small bending moments in the roof，and the range of significant deflection in the roof is also small. However，when the plastic zone is considered，the supporting force of the coal seam near the working face reduces significantly and therefore the roof will take more of the weight of the overlying rock，resulting in much greater deflection in more areas of the roof. This leads to significant increases in both the maximum bending moment and the distance from where it occurs to the working face，which is directly related to the fracture failure in the roof ahead of the working face. The predicted distance based on the plastic zone approach in this case is greater than 4 m，which agrees well with in-situ observations of the fracture failure in the roof ahead of the working face，suggesting the bending force and deflection of the roof calculated based on the proposed approach are much closer to reality.

Key words： mining engineering hard roof supporting force plastic zone elastic foundation mechanical behaviour

引用本文:

潘岳1，顾士坦2，3，王志强1. 煤层塑性区对坚硬顶板力学特性影响分析[J]. 岩石力学与工程学报, 2015, 34(12): 2486-2499.
PAN Yue1，GU Shitan2，3，WANG Zhiqiang1. INFLUENCE OF COAL SEAM PLASTIC ZONE ON HARD ROOF MECHANICAL BEHAVIOUR. , 2015, 34(12): 2486-2499.

链接本文:

http://www.rockmech.org/CN/10.13722/j.cnki.jrme.2015.0083 或 http://www.rockmech.org/CN/Y2015/V34/I12/2486

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