Key Technologies and its Application of Gob-Side Entry Retaining by Roof Cutting in a Deep Mine

IF 1.2 4区工程技术 Q3 MINING & MINERAL PROCESSING

Archives of Mining Sciences Pub Date : 2023-07-20 DOI:10.24425/ams.2022.140702

Shang-Jen Chen, Q. Lv

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引用次数: 1

Abstract

There are many problems associated with the surrounding rocks of the gob-side entry retaining by roof cutting (gERRC) as they are difficult to stabilise in deep mines. The following needs to be studied to understand the problems such as the pressure relief mechanism, evolution law of the surrounding-rock stress and the key technologies of gERRC in deep mines. Cracks are formed by advanced directional blasting to sever the path of stress transmission from the roof of the goaf to the roof of the entry and reduce the lateral cantilever length of the roof. Therefore the surrounding-rock stress and roof structure are optimised. The broken and expanded gangue formed by the collapse of the strata in the range of roof cutting fills the mining space adequately, which avoids a rapid pressure increase caused by the roof breaking impact and slows down the movement of overlying strata. The deformation of the deep surrounding rocks is transformed from “abrupt” to “slow”, and the surrounding-rock deformation of the retained entry in deep mines is significantly reduced. The average pressure and periodic pressure of the supports near the blasting line can be reduced by the blasting cracks to a certain extent, mainly due to the reduction of the length of the immediate roof cantilever and the effective load of the main roof. The combined support technologies for gERRC in deep mines were proposed, and field tests were performed. The monitoring results show that the coordinated control system can effectively control the deformation of deep rock masses, and all indexes can meet the requirements of the next working face after the retained entry is stabilised.

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深部采场采空区顶板掏槽支护的关键技术及其应用

深部采空区采空区顶板支护围岩难以稳定，存在许多问题。为了了解深部矿山gERRC的卸压机理、围岩应力演化规律和关键技术等问题，需要进行以下研究。裂缝是通过先进的定向爆破形成的，以切断采空区顶板向入口顶板的应力传递路径，减少顶板的横向悬臂长度。因此，优化了围岩应力和顶板结构。顶板切割范围内的地层坍塌形成的破碎膨胀脉石充分填充了开采空间，避免了顶板破碎冲击引起的压力快速增加，减缓了上覆地层的运动。深部围岩变形由“突变”变为“缓慢”，深部矿山留矿巷道围岩变形明显减小。爆破裂缝可以在一定程度上降低爆破线附近支架的平均压力和周期压力，这主要是由于直接顶板悬臂长度和主顶板有效载荷的减小。提出了gERRC在深部矿山的联合保障技术，并进行了现场试验。监测结果表明，该协调控制系统能有效控制深部岩体的变形，各项指标均能满足留巷稳定后下一工作面的要求。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Archives of Mining Sciences 工程技术-矿业与矿物加工

CiteScore

2.40

自引率

16.70%

发文量

审稿时长

20 months

期刊介绍： Archives of Mining Sciences (AMS) is concerned with original research, new developments and case studies in mining sciences and energy, civil engineering and environmental engineering. The journal provides an international forum for the publication of high quality research results in: mining technologies, mineral processing, stability of mine workings, mining machine science, ventilation systems, rock mechanics, termodynamics, underground storage of oil and gas, mining and engineering geology, geotechnical engineering, tunnelling, design and construction of tunnels, design and construction on mining areas, mining geodesy, environmental protection in mining, revitalisation of postindustrial areas. Papers are welcomed on all relevant topics and especially on theoretical developments, analytical methods, numerical methods, rock testing, site investigation, and case studies.