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1.
我国西部神府东胜煤田主要赋存浅埋近距煤层,煤层埋藏浅,覆岩上部厚松散层大范围分布,近距煤层开采导致覆岩与地表裂缝发育严重,加剧了原本脆弱的生态环境进一步恶化。为探究浅埋近距煤层开采覆岩与地表采动裂缝发育规律,掌握其控制方法,以柠条塔煤矿1-2煤层和2-2煤层开采为背景,结合实测统计分析、物理模拟和分形理论,掌握浅埋顶部单一煤层开采和重复采动下覆岩与地表裂缝发育特征,揭示煤柱布置对裂缝发育的控制作用。研究表明,煤层开采导致的地表裂缝可分为平行于工作面的动态裂缝和工作面开采边界地表裂缝(切眼边界侧地表裂缝和区段煤柱侧地表裂缝),动态裂缝在开采后能够实现自修复,工作面开采边界的地表裂缝不能自修复。下煤层开采区段煤柱侧覆岩与地表采动裂缝发育严重,其与区段煤柱错距密切相关。1-2煤层开采后,基岩垮落角为60°,土层垮落角为65°,边界煤柱侧地表裂缝的宽度为0.26 m。下部2-2煤层开采,煤柱叠置、错距20、40 m时,区段煤柱侧覆岩采动裂缝宽度分别为0.81、0.45和0.22 m,地表裂缝宽度分别为0.65、0.30和0.12 m。通过确定合理煤柱布置方式,能够有效控制覆岩和地表采动裂缝的发育程度,据此确定柠条塔煤矿1-2煤层和2-2煤层开采的合理煤柱错距应大于40 m。 相似文献
2.
Some villages and bridges are located on the ground surface of the working district no. 7 in the Wanglou Coal Mine. If longwall mining is adopted, the maximum deformation of the ground surface will exceed the safety value. Strip mining is employed for the working district no. 7 which is widely used to reduce surface subsidence and the consequent damage of buildings on the ground surface. To ensure the safety of coal pillars and improve the recovery coefficient, theoretical analysis and numerical simulation (FLAC 3D) were adopted to determine the coal pillar and mining widths and to discuss the coal pillar stress distribution and surface subsidence for different mining scenarios. The results revealed that the width of coal pillars should be larger than 162 m, and the optimized mining width varies from 150 to 260 m. As the coal seam is exploited, vertical stress is mainly applied on the coal pillar, inducing stress changes on its ribs. The coefficient of mining-induced stress varies from 2.02 to 2.62 for different mining scenarios. The maximum surface subsidence and horizontal movement increase as the mining width increases. However, when the mining width increases to a certain value, increasing the pillar width cannot significantly decrease the maximum subsidence. To ensure the surface subsidence less than 500 mm, the mining width should not be larger than 200 m. Considering the recovery coefficient and safety of the coal pillar, a pillar width of 165 m is suggested. 相似文献
3.
黄土丘陵区房柱式开采地表塌陷特征及机理分析——以陕北府谷县新民镇小煤矿为例 总被引:2,自引:0,他引:2
通过对陕北府谷县新民镇小煤矿采煤地表大面积塌陷的调查和分析,总结出黄土丘陵区房柱式开采地表的塌陷特征,并以西岔沟煤矿房柱式开采为例,对其两种参数顶板岩梁应力、煤柱载荷、煤柱强度进行分析及对比,结果表明合理设计煤柱和煤房尺寸可以防止采煤地表大面积塌陷。 相似文献
4.
Large underground caverns are increasingly being considered for the construction of industrial facilities and transportation infrastructure in order to optimize the use of surface land in large urban cities. Due to the geological constraints underground, it is sometimes necessary to construct a cavern close to an existing cavern. Pillars serve as an underground support element in twin caverns, without which it is difficult to sustain the weight of the overburden materials. If the strength of a pillar is exceeded, it will fail, and the load that it carried will be transferred and thereby contribute to the collapse of the twin caverns. The lack of confinement in slender pillars also contributes to the complete collapse of pillars at relatively low stress magnitudes. From a design point of view, understanding the pillar failure mechanism and the interaction effect between twin caverns is essential. This paper presents a numerical investigation on the influence of various design parameters on twin cavern interaction. Pillar performances with respect to the changes to the maximum principal stress in the pillar, the peak vertical stress, and the peak principal stress difference in the pillar core are studied in order to examine the failure mechanisms and to identify situations in which there is significant cavern interaction and overlap of the plastic zones. Copyright © 2014 John Wiley & Sons, Ltd. 相似文献
5.
The study of rock pillar failure mechanisms is an issue that is faced routinely in mining and civil industries. In mining operation, the establishment of several mining levels is often necessary to ensure adequate production. This result in the formation of pillars that must be recovered under often high stress conditions at later stages of excavation. It is, therefore, beneficial to develop guidelines that can be used in the design of rock pillars. The aim of this paper is to delve into the mechanisms involved in pillar failure as well as to investigate the non-linear behavior of rock pillars. An extensive numerical analysis was carried out to study the pillar deformation and failure process under natural loading conditions. Effects of pillar geometry and pillar strength parameters on pillar behavior were investigated for hard rock material typical of Canadian mining conditions. Numerical data were compared against field data recorded in Canadian mines. A fairly good match was achieved between numerical and field data and the conducted analysis can be used as a qualitative guideline in the design of rock pillars in underground structures. 相似文献
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7.
侧向支承压力分布、资源回收率以及煤柱和巷道的稳定性是大采高综放面区段煤柱宽度留设要兼顾的因素,为了确定大采高综放面区段煤柱宽度,以某矿8103面为工程背景,首先,采用理论计算和现场应力监测等方法确定大采高综放工作面倾向支承压力分布规律,得出应力降低区宽度约为8 m,原岩应力区为巷帮侧28 m外。其次,采用工程类比方法确定大采高综放工作面巷帮外侧煤体严重破裂区宽度约为4 m。最后,采用FLAC3D数值软件分析了下区段工作面回采时窄煤柱(6、8 m)和宽煤柱(28、30 m)的应力场、位移场及塑性区特征,获得不同煤柱宽度时巷道和煤柱力学特征。研究表明:当煤柱宽度6 m和8 m时,在采动支承压力下煤柱几乎无承载能力,且巷道变形量较大;当煤柱宽度28 m和30 m时,在采动支承压力下煤柱中央仍有一定的弹性核,煤柱保持稳定且巷道变形量较小。综合考虑资源回收、巷道稳定性、次生灾害控制等因素,确定大采高综放工作面区段煤柱宽度为28 m。 相似文献
8.
The reasons that pillars with small width-to-height ratios fail remain unclear. This study established a mechanical model for the buckling failure of a thin pillar subjected to compressive forces to investigate the stability of reserved thin pillars (RTPs) on both sides of mining units during barrier pillar recovery. The critical buckling stress of the thin pillar was obtained using the energy variational method, and its relationship to the aspect ratio (length-to-width ratio) was investigated. The buckling instability of RTPs can be determined by comparing the RTP stress obtained from numerical simulations with the buckling stress derived from the mechanical model. 相似文献
9.
采前煤柱稳定性研究是工作面冲击危险性评估和开采方案设计的关键。以山东某矿深井巨厚砾岩条件工作面开采遗留煤柱为背景,采用案例调研、理论分析、数值模拟和工程实践等方法,对巨厚岩层-煤柱协同变形机制及其煤柱稳定性进行了研究,建立了巨厚岩层-煤柱协同变形的简化力学模型,探讨了引起煤柱变形的主要应力来源和变形形式,推导了在协同变形条件下煤柱的应力-应变关系。以此为基础,综合煤柱煤体应力、围岩稳定性和变形特征等条件,提出了煤柱整体失稳的力学判据。研究结果表明:巨厚岩层-煤柱失稳诱发冲击与煤柱的位置、尺寸和上覆岩层运动或变形关系密切,上覆岩层运动或变形是诱发煤柱失稳的动力因素;巨厚岩层-煤柱的变形主要包括受集中力F压迫的协同挠曲压缩变形和受集中力G作用的重力沉降变形,二者保持内在协调性;巨厚岩层下煤柱整体失稳的工程判据为煤柱煤体平均支承应力p超过其平均极限支承强度Rc(p≥Rc);评估得到遗留的50 m煤柱具有强冲击危险性,并通过优化开采设计,取得了良好的效果。该研究成果对相似条件煤柱留设及其稳定性分析具有参考意义。 相似文献
10.
Manoj Khanal Deepak Adhikary Chandana Jayasundara Rao Balusu 《Geotechnical and Geological Engineering》2016,34(1):217-235
This paper investigates various multiseam mining related parameters using mine site specific data and numerical simulations. Two important mining effects—subsidence and stress—are analysed for different possible mining layouts. A geological mine dataset has been used to generate a numerical model. The predicted surface subsidence magnitude and surface profile have been compared under different scenarios to assess potential options in multiseam mining strategies. The effects that seam separation distances, mining offset, panel layout and panel orientation each have on surface subsidence and chain pillar stress magnitude have been investigated. The numerical simulation shows that ascending or descending mining directions have little impact on controlling the surface subsidence in multiseam mining and predicted an almost identical maximum stress development at the chain pillars. Numerical simulations infer that the orientation of the top panels control the subsidence profile. 相似文献
11.
A number of pillars are left developed in some of the Chinese metal mines due to careless mining and lack of proper planning. There are pillars in such mines which do not contribute much in supporting the covered rock mass. Re-exploitation of these standing (non-supporting) pillars can be an efficient method for resource recovery if the remaining pillars ensure the stability of the covered host rock. In this study, a tungsten mine in Jiangxi Province, China, was chosen as a case for studying this pillar recovery scheme. Based on accurate in situ stress measurement data in the original and disturbed host rock, the storage energy in the rock mass could be estimated by numerical simulation methods. After comparing the storage energy to the sum of the fractured energy consumption and friction energy consumption (obtained from lab tests), the recyclable pillars can be identified by a cyclic judgment programming process. 相似文献
12.
Huaizhan Li Guangli Guo Jianfeng Zha Yan He Zhiyong Wang Shuangyu Qin 《Environmental Earth Sciences》2017,76(20):704
We studied an underground coal gasification technique using strip mining-face mining gasifier controlled retraction injection technology (SMFM). This green mining approach offers several advantages over conventional strip mining but the stress distribution and stability of SMFM operations remain largely untested. In particular, hyperbolic coking pillars are used in SMFM compared with rectangular pillars used in traditional strip mining, which can influence the ultimate bearing capacity and stability. We use numerical simulations to investigate the influence of different factors (arch height, pillar height and width, mechanical characteristics), under the coupling effect of high temperature, on the ultimate bearing capacity of hyperbolic pillars. Our results indicate that arch height has a strong influence on pillar stress, while changes in pillar width and height are less significant. A stability evaluation method is proposed and tested on a case study in Inner Mongolia. Our theoretical results have practical significance for the promotion and application of SMFM. 相似文献
13.
Solid backfill mining for coal pillar recovery in industrial squares has to ensure that the mine infrastructure, such as the shafts and substations, is not degraded or has its utility impaired by that mining. At the same time, it is important to recover as much coal as possible. As a result, it is necessary to predict mining subsidence during solid backfilling mining of coal pillars in industrial squares and to optimize the design of the working faces. At the Baishan coal mine in Anhiu province, China, there are thick layers of unconsolidated overburden above the coal seam so it is not appropriate to use the surface subsidence prediction method of equivalent mining height to predict subsidence during the mining of the coal pillars there. In order to find a reasonable coal pillar recovery scheme for the Baishan mine, a numerical simulation method is used to determine the relationships between the compression ratio of the backfilling material and the surface subsidence prediction parameters. Research was done to determine the appropriate parameters, and based on the final prediction parameters and taking the mandated protection standards for buildings and structures into account, surface subsidence is predicted and a backfill mining scheme for pillar recovery is proposed. The results show that of the six mining schemes considered, scheme 5 is the best scheme for coal pillar recovery in the industrial square at the Baishan mine. The research results are significant for similar mines with thick unconsolidated overburden anywhere in the world. 相似文献
14.
S. Y. Wang S. W. Sloan M. L. Huang C. A. Tang 《Rock Mechanics and Rock Engineering》2011,44(2):179-198
Using a numerical modelling code, rock failure process analysis, 2D, the progressive failure process and associated acoustic
emission behaviour of serial and parallel rock samples were simulated. Both serial- and parallel sample models are presented
for investigating the mechanism of rock pillar failure. As expected, the numerical results show that not only the stiffness,
but also the uniaxial compressive strength of the rock plays an important role in pillar instability. For serial pillars,
the elastic rebound of a rock pillar with higher uniaxial compressive strength can lead to the sudden failure of an adjacent
rock pillar with lower uniaxial compressive strength. The failure zone forms and develops in the pillar with lower uniaxial
compressive strength; however, the failure zone does not pass across the interface of the two pillars. In comparison, when
two pillars have the same uniaxial compressive strengths but different elastic moduli, both serial pillars fail, and the failure
zone in the two pillars can interact, passing across the interface and entering the other pillar. For parallel pillars, damage
always develops in the pillar having the lower uniaxial compressive strength or lower elastic modulus. Furthermore, in accordance
with the Kaiser effect, the stress-induced damage in a rock pillar is irreversible, and only when the previous stress state
in the failed rock pillar is exceeded or the subsequent applied energy is larger than the energy released by the external
loading will further damage continue to occur. In addition, the homogeneity index of rock also can affect the failure modes
of parallel pillars, even though the uniaxial compressive strength and stiffness of each pillar are the same. 相似文献
15.
Jixiong Zhang Qiang Sun Nan Zhou Jiang Haiqiang Deon Germain Sami Abro 《Arabian Journal of Geosciences》2016,9(10):558
In China’s western coal mining area, the traditional room mining technology is facing coal pillar instability, mine earthquake, large-area roof subsidence in the goaf, surface subsidence, water and soil loss, vegetation deterioration, and other environmental problems. To solve the aforementioned problems and to improve coal recovery, the roadway backfill coal mining (RBCM) method was proposed as a solution and its technical principle and key equipment were presented in this paper. In addition, the microstructure and mechanical behavior (strain-stress relation in confined compressive test) of aeolian sand and loess backfill materials were studied for a rational backfill design for underground mines. Further, coal pillar stress, plastic zone change, and surface deformation of the RBCM schemes were studied using the FLAC3D numerical simulation software, and a reasonable mining scheme of “mining 7 m and leaving 3 m” was determined. The engineering application in Changxing Coal Mine shows that the RBCM method with loess and aeolian sand as backfill materials allows a stable recovery of coal pillars with a recovery ratio of more than 70 %. The maximum accumulated surface subsidence and the maximum horizontal deformation were measured to be 15 mm and 0.8 mm/m respectively, indicating that the targeted backfilling effect can help protect the environment and also control surface subsidence. 相似文献
16.
作为具有大跨度、超浅埋等特点的千年古地下洞室群,龙游石窟吸引着众多前来研究的岩石力学家和工程地质学家。近些年来,龙游石窟的3号洞顶板多处出现了开裂和离层。安装在3-1号岩柱周围起支撑洞室作用钢柱上的应变片数值也发生了变化。据分析,这些现象出现的一个重要原因是3-2号岩柱强度降低引起洞室围岩受力条件的改变。利用FLAC3D数值软件,借鉴强度折减法,对3-2号岩柱强度降低引起上述变化的情况进行了模拟。数值模拟的结果可以较好地解释上述现象。在此基础上,进一步对3号洞顶板和其他岩柱的应力变化等进行了数值分析。结果表明:①3-2号岩柱的强度已有所下降,并有继续降低的趋势;②随着3-2号岩柱强度的降低,顶板的裂缝将不断增长、增多。其结果可为3-2号岩柱强度降低过程中洞室围岩力学行为的科学分析、预测及石窟的保护等提供依据。 相似文献
17.
Gypsum is an important mineral resource. Bulk mining of gypsum will cause serious gob collapse. At present, the research on gob collapse of gypsum mine mainly focuses on the stability of pillars and top layers in the gob area. The research on the surface deformation in gob collapse areas and the monitoring and forecasting methods is rare. What’s more, there is also a lack of effective methods. This article focuses on the study of surface deformation characteristics and collapse characteristics after gypsum mining. The surface deformation characteristics before gob collapse can be obtained from the InSAR monitoring data analysis on ground deformation in the mining area. According to the calculation and analysis of InSAR monitoring data of Pingtai and Xizhou mine from 2007 to 2018, it can be seen that the surface deformed gradually in the early stage before gob collapse. The deformation amount and scale can be used to analyze the gob type and scale. This research can provide data basis and scientific evidence for monitoring, forecasting and preventing ground collapse in gypsum mining area. 相似文献
18.
石膏是一种重要的矿产资源,但石膏矿的大量开采会产生严重的采空塌陷隐患。目前关于石膏矿采空塌陷的研究多集中于采空区矿柱和护顶层的稳定性等方面,有关矿区采空塌陷地表变形及监测预报方面的研究甚少,也缺乏有效的研究方法。针对石膏矿开采后地面变形特征及塌陷特征研究,通过对矿区InSAR监测数据进行地表变形分析,确定了采空塌陷前的地表变形特征。根据邳州平台矿和希州矿2007—2018年InSAR监测数据进行计算分析,可以看出地面塌陷前,地表存在早期缓慢变形,可根据变形量及范围判断塌陷类型及范围。对InSAR监测数据的计算和分析可为矿区地面塌陷地质灾害的监测、预报及防治提供数据资料与科学依据。 相似文献
19.
崩塌冲击或崩积物重力加载作用都可能诱发坡脚滑坡的变形或失稳。在查明坡体结构的基础上,采用3DEC离散元数值模拟方法,对高陡斜坡在地下开采作用下崩塌所产生的机理、失稳模式、破坏规模、运动轨迹进行了全过程模拟,特别是斜坡失稳后和坡脚滑坡的相互作用效应进行了深入分析。结果表明:通过地下开采诱发的崩塌过程模拟及其研究,发现斜坡在地下开采的扰动下会产生大规模的崩塌,其滚石会对滑坡体产生强烈的冲击作用,且所形成的崩积物会对滑坡体产生重力加载作用。再通过监测数据以及现场收集的资料分析得出滑坡的蠕滑变形主要是由于崩积物重力加载作用引起的,且有继续变形的趋势,在暴雨季节时,滑坡的变形速率可能会增大,有潜在大规模滑动的危险,需做好相应的防护工作。 相似文献
20.
H. N. Maleki J. F. T. Agapito M. Wangsgard J. Cort 《Geotechnical and Geological Engineering》1986,4(2):111-127
Summary Results of instrumentation, test mining and computer aided stability analyses were combined to design the most stable gate road layout for two-seam longwall mining at the Plateau Mining Company. Five layouts were evaluated; these layouts used a combination of yield and/or large pillars with either three-entry or two-entry development systems.A layout which used a yield pillar within a two-entry development system resulted in the most stable gate roads for two-seam mining. Another layout using a yield and large pillar was shown to be most stable for single-seam mining of the top seam, but it was unsuitable for two-seam mining because of seam interaction problems.The size of the yield pillar was determined by satisfying several design requirements, as well as by limited test mining; test results showed good, medium-term stability for the yield pillars, with a possible need for rib control. It was shown that the yield pillars might be effective in controlling the floor heave, and could minimize interaction problems in two-seam mining. 相似文献