Stress distribution rule of roadway affected by overhead mining in gently inclined coal seams group

In light of the severe deformation and destruction of the district raise tunnel in the mining area at the northern part of the Lubanshan colliery, by the theoretic analysis and numerical simulation, both the mining stress distribution in seams group and the deformation and destruction mechanism of floor district raise were investigated. The results show that, at the maximum vertical distance of 40 m, the abutment stress has an influence on the recovery of 2# and 3# coal seam and 8# coal seam at distance of 30 m. As a result, the recovery of 8# is rather than those of 2# or 3# coal seam, which contributes to the deformation and destruction of the district raise surrounding rock. The major factors affecting the abutment stress include the mining depth, mining height, residual gob space, adjacent working faces and short spacing coal seam recovery.

Mechanical mechanism of overlying strata breaking and development of fractured zone during close-distance coal seam group mining

This study mainly investigates the mechanical mechanism of overlying strata breaking and the development of fractured zones during close-distance coal seam group mining in the Gaojialiang coal mine.First,a mechanical model for the second"activation"of broken overlying strata is established,and the related mechanical"activation"conditions are obtained.A recursive formula for calculating the separation distance of overlying strata is deduced.Second,a height determining method for predicting the height of fractured zones during close-distance coal seam group mining is proposed based on two values,namely,the separation distance and ultimate subsidence value of overlying strata.This method is applied to calculate the fractured zone heights in nos.20107 and 20307 mining faces.The calculated results are almost equal to the field observation results.Third,a modified formula for calculating the height of a waterflowing fractured zone is proposed.A comparison of the calculated and observed results shows that the errors are small.The height determining method and modified formula not only build a theoretical foundation for water conservation mining at the Gaojialiang coal mine,but also provide a reference for estimating the height of water-flowing fractured zones in other coal mines with similar conditions.

Numerical simulation and experimental research of surrounding rock deformation of floor roadway under short-distance coal seam group combined mining

According to the influence of the combination of short-distance coal seam group on mining roadway, using numerical simulation software FLAG2D to draw the abutment pressure distribution ahead the working face and the area of influence in fully-mechanized mining conditions, the variation rules of surrounding rock supporting pressure of floor roadway and the deformation rules were summarized. GYS-300 anchor dynamometer was used to measure the roadway surface displacement, and the conclusions of numerical simulation were verified.

Geological modeling of coalbed methane reservoirs in the tectonically deformed coal seam group in the Dahebian block,western Guizhou,China

The widely spread Carboniferous-Permian coal seam group in southern China has great potential for coalbed methane resources,but the extensively developed tectonically deformed coal seriously restricts its development.Taking the Dahebian block in western Guizhou as the study area,the geological model of coalbed methane reservoirs in the tectonically deformed coal seam group was established,and the spatial distribution pattern of model parameters was clarified by clustering algorithms and factor analysis.The facies model suggests that the main coal body structures in Nos.1,4,and 7 coal seams are cataclastic coal and granulated coal,whereas the No.11 coal seam is dominated by granulated coal,which has larger thicknesses and spreads more continuously.The in situ permeability of primary undeformed coal,cataclastic coal,granulated coal,and mylonitized coal reservoirs are 0.333 mD,0.931 mD,0.146 mD,and 0.099 mD,respectively,according to the production performance analysis method.The property model constructed by facies-controlled modeling reveals that Nos.1,4,and 7 coal seams have a wider high-permeability area,but the gas content is lower;the high-permeability area in the No.11 coal seam is more limited,but the gas content is higher.The results of the self-organizing map neural network and K-means clustering indicate that the geological model can be divided into 6 clusters,the model parameter characteristics of the 6 clusters are summarized by data analysis in combination with 6 factors extracted by factor analysis,and the application of data analysis results in multi-layer coalbed methane co-development is presented.This study provides ideas for the geological modeling in the tectonically deformed coal seam group and its data analysis.

Technical scheme and application of pressure-relief gas extraction in multi-coal seam mining region

A pressure relief gas extraction technical model of a typical mining area is proposed based on coal and gas simultaneous extraction theory. Flac3 Dwas employed to model vertical stress and displacement contour plot characteristics of non-outburst coal seam(No. 4) on top of outburst coal seam(No. 2) along strike and incline directions. Field investigations were also conducted to verify the scientific nature of the simulation. The results demonstrate that gas pressure in No. 2 coal seam dropped to approximately 0.55 MPa in the pressure relief multi-coal seam. The highest expansion rate of the coal mine reached up to 2.58%.The pressure-relief angle was 76° along the incline direction and 60° along the strike direction. As the expansion rate and pressure-relief angle increased and the gas pressure decreased, a large amount of gas flowed into the gob of No. 4 from No. 2 coal seam and was later discharged through specific gas pipes,which eliminated No. 2 outburst risks. This study resulted in positive outcomes in that gas extraction time was reduced by 13.5 days, due to pressure relief, and drilling work load was reduced by 0.1161 m/t coal. This method ensures that gas is discharged from the outburst coal seam quickly and safely,demonstrating that the proposed technical model of pressure-relief gas extraction is effective in a multi-coal seam region.

近距离煤层底板应力分布规律及巷道布置研究

为探究上煤层遗留煤柱对底板的应力影响及下煤层回采巷道的合理布置,以唐山沟煤矿为研究对象,运用理论分析和数值模拟等方法并综合多种影响因素构建了上煤层遗留煤柱与铰接岩块的协同承载结构模型和底板应力传递计算模型,对上煤层遗留煤柱下底板应力及影响因素展开研究。结果表明:上煤层遗留煤柱对底板的应力影响以垂直应力为主,影响程度随底板深度的增加而降低;遗留煤柱下底板应力增高区呈椭球形,对底板应力增高区的影响因素展开分析,得到了不同因素对应力增高区范围影响的量化关系,其中煤柱峰值应力对底板应力增高区分布起决定性作用;根据底板应力分布特征并结合理论计算及数值模拟结果,确定唐山沟煤矿8煤遗留煤柱与11^(-1)煤回采巷道合理错距值应为20~25 m。该研究揭示了上煤层遗留煤柱下底板应力传递机理,明确了底板应力增高区的分布及影响因素,并得到了巷道-煤柱合理错距值的确定方法,可为下煤层回采巷道的合理布置提供理论依据。

极近距离煤层下伏回采巷道分区支护技术及应用

针对极近距离煤层下伏回采巷道距上覆采空区间距不等的特点,采用统一性的支护方案易造成支护稀疏或支护过度的问题。基于有效锚固层“叠加梁”理论,根据极近距离煤层层间距变化将实验地段风巷划分为“大于6.0m、4.0~6.0m和小于4.0m”三个区域,针对性提出极近距离煤层回采巷道顶板分区域支护方案,通过数值模拟计算论证了方案的可行性,并在任楼煤矿工作面回采巷道进行工业性试验。结果表明:不同区域采用针对性支护后围岩均较稳定,巷道围岩变形得到了合理的控制,巷道总体变形量较小,分区域式支护技术有效控制下伏巷道围岩变形,保证了矿井安全生产,降低了企业成本。

倾斜煤层群覆岩“三场”非对称特征及靶向抽采机制

倾斜煤层群“三场”(应力场、位移场和裂隙场)演化规律较为复杂,对卸压瓦斯运移和储集具有重要意义。为了探究倾斜煤层群“三场”演化规律,研究以新疆1930煤矿为对象,开展了倾斜煤层群多重采动相似模拟实验。分析了上覆岩层垮落形态,获得了覆岩应力演化特征,分析了覆岩位移分布和移动方向特征,阐明了采动裂隙分布特征。进而探究了三场演化规律对瓦斯运移的影响,并开展了定向钻孔瓦斯抽采现场试验进行验证。研究结果表明:倾斜煤层群多重采动下,采动裂隙矩形梯台呈现明显的非对称特征。低位侧覆岩应力变化较大,随开采次数增加,卸压效应更为明显,而高位侧覆岩应力变化较小;结合重力−倾角效应,高位侧覆岩更易破坏,垮落次序优先,呈非对称特征。覆岩位移分布呈非对称特征,高位侧位移显著且移动方向变化较大。高位侧裂隙区网格内采动裂隙频数明显高于低位侧;高位侧裂隙区破断裂隙分布更多,且开度较大;采动裂隙呈“高位扩展−低位压缩”的非对称特征。多重采动使得“三场”非对称特征更为显著。此外,覆岩贯通度存在“慢速减小−快速减小”的现象。基于“三场”演化特征和瓦斯运移的关系,揭示了瓦斯抽采靶向优选机制。结合试验结果,构建了基于“三场”演化规律的裂隙带瓦斯抽采靶点区判定流程。现场瓦斯抽采效果良好,保证了工作面安全高效回采。研究结果为倾斜煤层群卸压瓦斯精准抽采提供了理论参考,旨在提高倾斜煤层群瓦斯抽采量,防止上隅角瓦斯超限,实现倾斜煤层群安全高效开采。

近距离特厚煤层回采巷道合理布置优化研究

针对近距离煤层开采后遗留煤柱下位特厚煤层回采巷道布置的技术难题,以开滦集团唐山矿为研究对象,综合采用理论分析、数值模拟和现场实测等研究手段,对上位煤层采动后的底板破坏深度、残留煤柱底板应力分布及下位煤层巷道顶板非均布载荷下易被破坏的原因进行了研究。研究表明:上位煤层开采引起的支承应力导致的最大破坏深度为31.5 m,对下位煤层回采巷道布置产生影响;煤柱底板的垂直应力分布具有明显的非均布性,下位煤层回采巷道更易达到抗拉极限而产生变形破坏。同时对比了下位煤层四种巷道布置方式下的主应力分布特征,优选出内错式和平移式布置方式。进一步,通过巷道的应力改变量Δσ和位移改变量ΔD评估回采巷道顶板受应力及变形的不均衡程度,结合数值模拟计算和现场工业性试验数据印证,得出9~#煤层工作面回采巷道最佳内错距离为37.5 m,为特厚煤层回采巷道布置提供了借鉴依据。

近距离煤层区段煤柱集中应力传递特征试验研究

探究煤柱应力向底板传递特征对确定近距离煤层巷道围岩控制方法具有指导作用。以山西杜儿坪矿近距离煤层为原型,开展上煤层开挖相似模型试验,利用DIC技术采集底板深度不同水平层位应变数据,分析垂直、水平、及剪切三种应变的分布特征和应变峰值距煤柱边界水平距离的变化规律,探究上煤层开采后区段煤柱集中应力向底板的传递特征。结果表明:煤柱底板区,三种应变均以煤柱中心为轴呈非对称双峰分布特征,垂直、剪切两种应变峰值为先开挖面煤柱侧小于后开挖面煤柱侧,而水平应变峰值则恰好相反,三种应变峰值均随底板深度增加而减小;采空区底板,垂直、剪切两种应变远离煤柱边界逐渐趋于0,而水平应变则显现出反复增减多变特征。三种应变峰值距煤柱边界的水平距离表现为垂直应变为先开挖面煤柱侧大于后开挖面煤柱侧,但剪切应变则刚好相反,而水平应变则先后开挖面煤柱侧均相等,且三种应变距煤柱边界水平距离均随底板深度增加而增大。垂直、水平应力分别为压、拉应力,而先后采面煤柱侧剪切应力则不同分别为拉、压应力;垂直、剪切两种应力均显现为高应力水平,但水平应力甚小;垂直、水平两类应力峰值均位于煤柱底板区,而剪切应力峰值却位于采空区底板;垂直、剪切两种应力随远离煤柱边界均趋于0,水平应力则显现反复转化增减特征。选择近距离煤层巷道围岩控制方法既应重视垂直应力的作用,也应关注剪切应力对其失稳破坏的影响。

神东矿区浅埋煤层开采地表裂隙分布及动态演化特征研究

神东矿区浅埋煤层群开采导致地表裂隙发育良好,立体漏风复杂。为研究神东矿区地表裂隙分布特征及动态演化规律,以大柳塔煤矿活鸡兔井和补连塔煤矿浅埋藏开采为工程背景,采用现场无人机定点观测、红外、地质雷达等技术相结合的方法,研究地表宏观裂隙、隐蔽裂隙分布特征,并对裂隙动态演化规律进行分析。结果表明:神东矿区浅埋煤层开采工作面采空区对地表走向裂隙的影响相比于倾向裂隙较大,其中活鸡兔井12下206工作面101条裂隙有效影响范围35 m,补连塔煤矿22310工作面122条裂隙为62 m,走向裂隙最大裂隙宽度达到80 cm,倾向裂隙普遍在10 cm以下;随工作面的推进,裂隙宽度逐渐变大,直至发育完全,裂缝位置不连续断面间距变大,落差增大;宽度较大的裂隙(裂隙宽度大于10 cm),如果距离工作面较近,随着工作面的推进,裂隙宽度会逐渐缩小,甚至可能闭合。

煤层群叠加开采覆岩裂隙演化及卸压瓦斯抽采研究

针对采动裂隙带卸压瓦斯抽采效果不佳导致的工作面上隅角瓦斯超限的问题。以赵家寨煤矿11210工作面为工程背景,采用物理相似模拟实验方法,研究了煤层群叠加开采对上覆岩层采动裂隙的演化特征,并通过现场验证确定了瓦斯抽采的最优层位。结果表明:煤层群叠加开采过程中,在卸压区域外,形成了较大的应力集中,在卸压保护范围内,应力集中现象不明显,且应力峰值小于二1煤层原始应力;煤层群叠加开采引起了采场上覆岩层的叠加卸压,使上覆岩层的位移场发生了叠加变化,岩层最大下沉量进一步增加;煤层群叠加开采结束后,采空区上覆岩层中部岩层被压实,两端岩层裂隙较为发育,形成了一定范围的裂隙发育区。通过现场试验,确定了裂隙带定向长钻孔合理层位的选择,并在现场进行钻孔监测,验证了物理相似模拟结果的合理性。

近距离下煤层上覆岩层裂隙发育规律与上行开采研究

针对上行开采覆岩运动可能会使上覆煤层的整体性遭到破坏,造成上覆煤层无法开采的技术难题,以某矿9煤工作面开采对上覆5煤的影响为工程背景,采用理论分析、数值模拟、相似材料模拟等手段,研究了近距离煤层下煤开采后上覆岩层覆岩破坏情况、岩层裂隙发育规律及工作面矿压显现规律等问题,得到如下结论:近距离煤层下伏9煤开采后上覆岩层塑性区范围,其中三带判别法得垮落带高度平均9 m,导水裂隙带高度36 m;比值分析法K为19.99,大于中硬岩层7.5;围岩平衡法得上覆5煤安全开采的必要层间距为45 m,远小于5煤与9煤层间距60 m;数值模拟表明,近距离煤层下伏9煤工作面开采后上覆5煤位于下煤层开采后形成的塑性区域内,在留设保护煤柱区域内不会存在应力集中现象;相似模拟表明,近距离下伏9煤开采后,5煤最大下沉值为10 mm,模型垮落带高度基本在15 cm左右,符合矿山压力及覆岩运动发展规律;该矿近距离下伏9煤开采后上覆5煤开采是可行的。

覆岩应力-漏风综合影响下浅埋煤层群下煤层开采巷道布置研究

针对浅埋近距离煤层群上部遗留煤柱影响下的下部工作面巷道合理布置位置确定问题,以活鸡兔井为例,采用离散元方法(DEM)模拟研究了遗留煤柱底板应力分布与上、下煤层开采采空区裂隙发育特征。结果表明:12号煤层开采过后,22号煤层水平距上覆煤柱20 m内为垂向应力与主应力差增高区,22号煤层水平应力在区段煤柱内侧较低;下煤层巷道布置采用外错式与重叠式时,巷道两侧围岩主应力差较大,且外错式与重叠式布置方式下22号煤层工作面开采时夹层与上部老空区覆岩二次运移剧烈,采空区两侧斜向裂缝带发育与贯通较好;采用内错式,巷道两侧围岩主应力差随与煤柱距离增大先降低、后升高,在距煤柱25~35 m处主应力差达到最低,且该布置方式下上部采空区覆岩沉降均衡,裂缝带闭合性较好,极大阻止了地表与层间贯通漏风通道的发育。

深部近距离煤层群下分层巷道分区支护技术

为实现深部近距离煤层群下分层巷道安全,以张双楼煤矿21916工作面为工程背景,分析了工作面冲击地压影响因素,划分了21916工作面掘进期间巷道冲击危险区域;建立了煤层合并区域下分层回采巷道数值模型,研究了9煤层21916工作面巷道内错7煤采空区不同距离时应力和位移分布规律,确定了下分层巷道合理位置;基于冲击危险区域划分结果,提出了分区支护技术,并设计了支护参数。现场实测表明,下分层巷道最大两帮移近量为164 mm,最大顶底板移近量为84 mm,顶板深部和浅部的离层量不大于3 mm,帮部锚杆和顶部的锚索受力变化较小,顶锚杆受力从8 kN增加到12 kN后趋于稳定,表明21916工作面巷道布置合理,分区防冲支护技术合理,支护质量与效果显著。研究结果可为类似条件工作面防冲支护提供借鉴。

煤层群采动下围岩应力演化规律及协同控制技术研究

针对煤层群开采过程中巷道支护困难问题,以贵州土城矿212回风石门为工程背景。综合采用现场调研、数值模拟、相似模拟及现场试验等手段,揭示了212回风石门应力演化规律,并提出了“卸−转−固”协同控制技术。研究结果表明:212回风石门遭受破坏的主要原因是煤层群采动过程中存在的地质力学问题导致了围岩失稳。巷道底板及两帮在采动过程中产生不同程度的应力集中。当遭受垂直应力挤压时,巷道底部承受的挤压力较大,而顶部围岩承受的拉伸力较大,由于力学不平衡导致围岩的破坏。基于此提出了“卸−转−固”协同控制技术。通过爆破卸压的方式,利用爆破产生的冲击波引起围岩的震动和应力波动,使表层围岩中原本集中的应力分散到更深的围岩区域,降低表层围岩的应力集中程度。同时,利用爆轰和封孔工艺进一步加固卸压孔周围的围岩,形成两个承载结构。即由巷道支护体形成的内承载体和由深部围岩形成的外承载体。两者相互作用有效承受巷道浅部及深部围岩的应力,并转移到支护结构,起到保护和稳定围岩的作用。利用该技术在212回风石门现场试验,结果显示:使用该技术区域应力长期趋于稳定甚至缓慢降低,巷道顶底板及两帮移近速率分别降低了74.49%及47.67%,底鼓量降低了77.2%。而未使用该技术区域应力出现不同程度的上升,表面位移收敛严重。由此可得,围岩控制效果显著。该技术已成功推广到贵州其他不同地质环境的煤矿,均取得了显著效果。

缓倾斜煤层群开采辅助运输系统改造及开拓优化设计

针对缓倾斜煤层群开发过程中由于辅助提升及运输系统复杂引起的一系列问题,提出以无轨化辅助运输系统为改造目标,以新建缓坡斜井为改造方式,对沙吉海一号矿井进行辅助提升及运输系统改造。结合井筒布置情况,对矿井进行开拓优化设计,采用缓坡斜井兼做采区辅助运输上山的方式开发煤层群,减少采区个数,延长各采区服务年限,有利于缓解矿井采掘接续紧张的局面。对于新疆地区煤层群开发,沙吉海一号矿井开拓优化思路有一定的借鉴意义。

浅埋近煤层群采动“三区”漏风裂隙场时空演化规律数值模拟

浅埋近煤层群采动下,地面采空区工作面“三区”之间易形成连通的漏气通道引发工作面低氧和采空区煤自燃,如何厘清采动效应下浅埋煤层群“三区”漏气通道的时空分布演化规律是有效防控煤自燃和低氧的关键。以陕煤柠条塔煤矿S1232工作面为研究背景,采用理论与数值模拟相结合的方法,研究了单一煤层、复合煤层重复开采下覆岩破坏特征,分析了煤层间距与采厚对裂隙二次发育的影响规律。结果表明:浅埋近煤层群开采下上覆岩层裂隙仅存在垮落带与裂缝带,主关键层破断后裂缝带快速发育至地表,关键层周期破断控制地表裂隙周期生成与下沉;上煤层裂隙密度发育由原始阶段先后经历快速增长、稳定和二次增长3个阶段;随采厚增大,各区间裂隙密度增大,大裂隙发育更充分,裂隙宽度整体增大;随煤层间距增大,小于0.2 m的裂隙宽度随采厚增大,且增加的速度逐渐加快,大于0.2 m的裂隙宽度随采厚增大,但增加速度逐渐变缓;采厚相同时,裂隙宽度大于0.2 m的裂隙密度随着煤层间距的增大逐渐减小。

低透气性突出煤层群首采层水力割缝卸压抽采技术研究

针对中近距离松软低透气性突出煤层群抽采防突难题,以皖北矿区任楼煤矿突出煤层群瓦斯地质条件为工程背景,在对松软煤层水力割缝卸压增透机制、首采层割缝工艺参数等研究的基础上,提出了首采层煤巷条带水力割缝卸压增透、煤层群瓦斯联合抽采的综合治理技术,优化了钻孔布置方式,并进行了工程应用。结果表明:割缝实施后钻孔的瓦斯抽采浓度、单孔日均抽采纯量分别是常规钻孔的4.27倍、3.94倍,煤层透气性提高了22~31倍,首采层72号煤层割缝后的防突有效半径可提高至5 m以上,检验抽采半径5 m处的瓦斯含量指标为4.13 m 3/t,在有效解决首采层煤巷条带瓦斯灾害的同时,钻孔工程量降低了2/3以上。

远距离斜交工作面上行开采上组煤垂直应力演化规律

为探究平煤八矿远距离煤层群斜交工作面上行开采过程中上组煤层垂直应力演化规律,采用数值模拟计算的方法展开研究。研究结果表明,己_(15)-21030工作面回采过程中与上覆戊_(9.10)-21070工作面依次形成相离、相交和重叠的空间关系,因此会使上组煤层应力增高或降低。相离区域为应力升高区,受下组煤采动影响应力整体呈升高趋势,应力集中系数最大为1.18;相交区域为卸压过渡区,戊_(9.10)-21070工作面应力由增压变为卸压,最大卸压值较原始应力降低了25%,倾向卸压影响范围为55 m;重叠区域为卸压区,受己_(15)-21030工作面采动影响卸压效果及卸压范围均进一步增大,最大卸压值较原始应力降低了40%,倾向卸压影响范围增大至180 m。将戊组煤层戊_(9.10)-21070工作面根据应力分布云图依次划分为增压区、应力过渡区、卸压区和稳定卸压区。通过现场瓦斯含量测试验证了卸压区残余瓦斯含量比原始区域残余瓦斯含量降低32.9%,远距离煤层群上行开采形成卸压区有利于瓦斯治理工作的开展。