乌拉尔地区矿床岩体的应力应变状态

Q4 Engineering Gornaya Promyshlennost Pub Date : 2022-11-03 DOI:10.30686/1609-9192-2022-5-79-82
R. Krinitsyn
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引用次数: 0

摘要

关于深部采矿,确保硐室稳定性、方位选择和支架选择等问题仍处于设计阶段,尤其重要。在大型构造扰动附近的深处,自然岩石压力因素开始在地下结构的稳定性中发挥决定性作用,而提高地下结构安全性的要求的不断增长,预先决定了采用现代方法使用数值模拟识别应力-应变状态的必要性。在没有模拟的情况下做出设计决策可能会导致经济效益和生产安全性下降,有时甚至导致无法完全回收储量。本工作中使用的有限元模拟是确定矿体一次切割最佳方案和开采位于大规模构造扰动附近的富矿体的主要方法之一,大规模构造扰动会引发矿体本身的复杂应力状态。在实践层面上,有限元方法可能会受到质疑,因此,为了正确识别本工作中最合适的采矿方案,需要描述构建和校准矿体一次切割(采矿方案)的有限元模型的技术序列。综合方法包括:建立复杂的矿体空间几何模型,考虑层理形态;将模型分为发展阶段,并形成不同的发展变体;确定柯西张量校正任务的边界条件;变形模型的确定和物理力学参数的分配;进行验证计算;所有模型变量的计算、分析和选择最优化的矿床开采技术;将数据插入地质力学块体模型,以便选择和证实支撑参数,并使用分析工具计算洞室稳定性。
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Stress-and-strain state of the rock mass in mining deposits in the Urals
With regard to mining at depths the issues of ensuring the chambers stability, the choice of their orientation and the support selection still at the design stage are particularly relevant. At depths, near large tectonic disturbances, the factor of natural rock pressure starts to play a defining role in the underground structures stability, and the constant growth of requirements for improving safety of underground structures predetermines the need to incorporate modern approaches to identify the stressstrain state using numerical simulation. Making design decisions without simulation can lead to a decrease in economic performance and production safety, and sometimes entail the impossibility of full recovery of reserves. The finite element simulation used in this work as one of the main methods for determining the optimal option for primary cutting of the ore body and mining a rich ore body located in close proximity to large-scale tectonic disturbance that provokes a complex stress state of the ore body itself. On a practical level, the finite element method can be discredited, and therefore a description of the sequence of techniques for constructing and calibrating finite element models of primary cutting of the ore body (mining options) is required for correct identification of the most suitable mining option, that is done in this work. The integrated approach includes: formation of complex spatial geometric model of ore bodies, taking into account the morphology of bedding; separation of the model into stages of development and forming different variants of development; determination of borderline conditions for Cauchy tensor correct task; determination of deformation model and assignment of physical and mechanical parameters; carrying out verification calculations; calculation of all model variants, their analysis and selection of the most optimal ore deposit mining technique; interpolation of data into geomechanical block model for the possibility of selecting and substantiating the supports parameters and calculating the stability of chambers using analytical tools.
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来源期刊
Gornaya Promyshlennost
Gornaya Promyshlennost Engineering-Industrial and Manufacturing Engineering
CiteScore
1.10
自引率
0.00%
发文量
100
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