Optimization of Support and Relief Parameters for Deep-Buried Metal Mine Roadways

IF 1.2 4区 地球科学 Q3 GEOCHEMISTRY & GEOPHYSICS
Geofluids Pub Date : 2024-05-20 DOI:10.1155/2024/8816030
MingWei Jiang, YuYun Fan, WeiWei Su, Jincheng Wang, Ming Lan, Qibin Lin
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引用次数: 0

Abstract

The management of rock mass deformation in high-stress roadways is a pivotal aspect of deep geotechnical engineering. Given the fruitful outcomes of research in rock mechanics regarding traditional confining pressure control methods, scholars have increasingly turned their attention to exploring pressure-relieving techniques, including borehole pressure relief and blasting pressure relief. However, there is limited research on pressure relief methods for deep-buried hard rock tunnels. This article commences with an overview of pressure relief in the roadway and conducts a detailed study on the parameters and methods of pressure relief in the roadway. To address safety and mining efficiency challenges, such as severe deformation leading to support failures, this study conducted a parameter analysis using the Sanshandao Gold Mine as a case study. Based on existing support methods, a strategy for arranging pressure relief roadways at varying distances from the main roadway is proposed, significantly enhancing the stress environment there. Numerical simulation software was employed to model two scenarios: (1) excavating the pressure relief roadway, main roadway, and maintenance roadway simultaneously and (2) first excavating the pressure relief roadway, followed by the main roadway and the maintenance roadway simultaneously. Simulation results indicated that the first pressure relief approach outperforms the second. The optimal position for both pressure relief roadways is 15 m from the main roadway, resulting in maximum deformation of the main roadway within 100 mm. These findings align with on-site stress monitoring data and satisfy safety production criteria. The research offers a theoretical foundation for similar pressure relief techniques in deeply buried, high-stress roadways.

Abstract Image

深埋金属矿巷道支护和支护参数的优化
管理高应力巷道中的岩体变形是深层岩土工程的一个关键方面。鉴于岩石力学研究在传统约束压力控制方法方面取得了丰硕成果,学者们越来越多地将注意力转向探索减压技术,包括钻孔减压和爆破减压。然而,关于深埋硬岩隧道泄压方法的研究还很有限。本文从巷道降压概述入手,对巷道降压的参数和方法进行了详细研究。为应对安全和采矿效率方面的挑战,如严重变形导致支护失效,本研究以三山岛金矿为例进行了参数分析。在现有支护方法的基础上,提出了一种在与主巷道不同距离处布置卸压巷道的策略,大大改善了该处的受力环境。采用数值模拟软件对两种情况进行了建模:(1) 同时开挖泄压巷道、主巷道和维护巷道;(2) 首先开挖泄压巷道,然后同时开挖主巷道和维护巷道。模拟结果表明,第一种泄压方法优于第二种。两种泄压巷道的最佳位置都是距离主巷道 15 米,从而使主巷道的最大变形不超过 100 毫米。这些研究结果与现场应力监测数据一致,符合安全生产标准。该研究为深埋高应力巷道的类似泄压技术提供了理论基础。
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来源期刊
Geofluids
Geofluids 地学-地球化学与地球物理
CiteScore
2.80
自引率
17.60%
发文量
835
期刊介绍: Geofluids is a peer-reviewed, Open Access journal that provides a forum for original research and reviews relating to the role of fluids in mineralogical, chemical, and structural evolution of the Earth’s crust. Its explicit aim is to disseminate ideas across the range of sub-disciplines in which Geofluids research is carried out. To this end, authors are encouraged to stress the transdisciplinary relevance and international ramifications of their research. Authors are also encouraged to make their work as accessible as possible to readers from other sub-disciplines. Geofluids emphasizes chemical, microbial, and physical aspects of subsurface fluids throughout the Earth’s crust. Geofluids spans studies of groundwater, terrestrial or submarine geothermal fluids, basinal brines, petroleum, metamorphic waters or magmatic fluids.
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