深井软岩巷道底板卸压钢丝绳网锚注支护技术研究

针对平顶山天安煤业股份有限公司一矿深井软岩回风上山巷道工程地质条件和围岩变形特征,采用数值计算方法,研究了底板卸压槽卸压前后巷道围岩应力场、塑性区的变化规律,分析了底板卸压槽卸压机理,提出了钢丝绳网锚注支护技术,并进行了工业性试验。研究结果表明:(1)巷道底板开掘卸压槽卸压后,底板围岩垂直应力和水平应力的高应力区及其峰值应力均向底板深部转移。卸压后底板同一深度的围岩应力均小于卸压前的围岩应力;卸压后巷道顶底板和两帮围岩的塑性区范围均增大,底板卸压效果明显。(2)深井巷道围岩的破碎区和部分塑性区是支护的重点。回风上山巷道采取开挖底板卸压槽、钢丝绳网锚杆支护和围岩注浆加固等支护措施后,在围岩中形成了锚注体支护圈,提高了围岩的强度和自身承载能力。巷道围岩经历加速变形阶段、减速变形阶段和稳定变形阶段后,一直处于稳定变形状态。卸压槽+钢丝绳网锚注支护在回风上山巷道的支护试验取得成功,可为深井软岩巷道支护提供参考依据。     

深埋回采巷道围岩塑性区演化规律研究

基于某矿地应力实测结果,在拟定回采巷道开掘方案及支护参数的前提下,采用Hoekbrown准则、"当量半径"简化、弹塑性平衡理论计算得到巷道掘进支护后围岩塑性区半径公式,假定其他因素不变代入支护强度、侧压系数后得到巷道初掘期间不同部位塑性区与p0、λ耦合关系曲线,为巷道布置及支护强度定量设计提供重要的参数;回采期间假定前两者已定,得到工作面前方14~44 m巷道内围岩塑性区随地质强度因素GSI、支承压力P'变化的演化规律。通过UDEC大变形数值模拟计算获得工作面前方巷道围岩塑性区演化规律和同距离段理论计算结果基本吻合。对掘进、回采期间矿压观测结果表明,基于实测地应力的深埋回采巷道围岩塑性区演化规律研究具有针对性、定量性及实用性,能为巷道布置、支护参数设计及围岩稳定性判定提供可靠的依据。     

Hoek-Brown破坏准则求解圆形硐室塑性区半径与修正的芬纳公式比较

目的 为定量确定围岩塑性区半径和给支护锚杆的深度设计提供科学依据.方法 以Hoek-Brown破坏准则为极限平衡条件,推求侧压力系数为1.0时圆形硐室理想弹塑性围岩的弹塑性应力和塑性区半径,运用Mohr-Coulomb准则直线拟合Hoek-Brown准则曲线和面积差补方法 ,求取等效的岩体Mohr-Coulomb强度参数后,建立相对塑性区半径随支护力和地质强度指标变化的二元非线性回归数学模型,并与源自于Mohr-Coulomb强度准则为屈服条件的修正的芬纳公式进行比较研究.结果 支护力每增加1.0 MPa,就可确保地质强度指标降低10～20的岩体中不会出现塑性区.在支护力较小和岩体质量较差情况下,采用Hoek-Brown破坏准则推导得出的塑性区半径和修正的芬纳公式计算得出的塑性区半径差别稍大.相对塑性区半径与地质强度指标都呈负乘幂函数关系,随着支护力的增大,塑性区半径随着岩体质量等级的升高而下降的趋势逐渐变缓.建立的相对塑性区半径随地质强度指标和支护力变化的二元非线性回归数学模型简明,使支护力连续变化,提高了工程实用性.结论 在岩体质量较差情况下,锚杆深度取1.8～3.0倍硐半径为宜.     

园形洞室最小支护抗力和最大允许变形探讨

本文从围岩弹塑性理论基本方程出发,考虑形变压力,松动压力和塑性区围岩粘结力c值降低的影响,通过弹塑性理论推导,建立了塑性区半径与维持围岩塑性极限平衡所需支护抗力的关系,进一步导出了最小支护抗力和最大允许变形的计算公式,并举例说明了计算公式的应用.分析计算表明,是否考虑塑性区围岩c值降低和松动压力,对园形洞室最小支护抗力和最大允许变形计算结果有明显的影响.     

“三软”煤层回采巷道钻孔卸压参数研究

回采巷道围岩控制一直是"三软"煤层开采高产高效的制约因素之一.根据永华一矿的地质条件,针对传统支护方式无法解决"三软"煤层回采巷道支护的难题,采用理论分析、现场试验的方法,提出了钻孔卸压与U型钢支架耦合支护技术.即通过在巷道U型钢支架之间打卸压钻孔,为巷道围岩变形留设变形空间,降低围岩应力,达到巷道稳定的目的.试验表明,U型钢支架耦合支护和钻孔卸压能够有效地控制巷道围岩变形,支护效果良好,为"三软"煤层回采巷道围岩控制提供了实践和理论依据.     

深井软岩巷道预留刚隙柔层厚度的确定及应用

针对深井软岩巷道围岩变形、破坏的特点,提出了预留刚隙柔层的厚度就是巷道围岩出现松动破坏前的塑性区径向位移．采用Bonaitin-Thomson模型对分区的巷道围岩进行了力学分析,推导出黏弹性区、稳定塑性区的径向位移计算式,并讨论了影响预留刚隙柔层厚度的主要因素．结果表明：巷道围岩位移与时间有关,且随时间的增长而增加,并最终趋于一稳定值．预留刚隙柔层厚度随巷道半径和原岩应力的增大而加大,随一次支护强度的增加而减小,但受一次支护强度的影响较小．曲江矿运输大巷预留刚隙柔层37cm,使巷道围岩充分释放变形能的同时又不损害围岩自身的支撑能力,二次支护后,巷道围岩变形量较小．     

对轴对称荷载作用圆巷围岩理想弹塑性分析解的讨论

对轴对称荷载作用圆巷围岩理想弹塑性分析解——Kastner解适用于软岩和小变形情况,若用于非软岩和大变形情况,从Kastner方程会导得：不论巷道围岩塑性变形多大,巷道周边切应力恒等于岩体峰值强度;围岩所承受的地应力可以随围岩塑性区半径增大而持续增大,随巷道周边位移增大而持续增大;此外,Kastner解中切应力分布曲线在围岩弹、塑性区交界处有尖峰向上的应力集中.采用符合岩石实际的弹性、非线性硬化和软化光滑连接的应力-应变关系得到的巷道围岩分析解,可以弥补以上三点不足,恰当地反映巷道临界深度和巷道围岩自承地应力极限问题;所绘出的切应力分布曲线在围岩弹、塑性区交界处光滑连接,因而有更广的适用性和精确性,对巷、隧道围岩大变形支护设计有参考作用.     

软岩巷道支护荷载的确定方法

通过分析巷道围岩与支护的相互作用原理 ,得出了软岩巷道失稳的原因是由于围岩自承力与支护力不足的结果 .认为一个优化的软岩巷道支护设计应在确保支护稳定的前提下 ,最大限度地释放围岩的能量 ,使以变形形式转化的工程力达到最大 ,同时最大限度地发挥围岩的自承能力 ,使工程支护力达到最小 ,而其关键是确定变形能释放时间和最佳支护时间 .软岩巷道开挖后 ,通常在巷道周围形成塑性软化区和塑性流动区 ,实施支护力就是要控制塑性流动区的范围与发展 ,达到最佳支护时间时的支护荷载为最小支护荷载 ,可以通过塑性软化区和塑性流动区内岩石的重力求得     

考虑剪胀和软化的巷道围岩弹塑性分析

在应力跌落模型的基础上引进软化阈值,建立了弹塑脆性模型,模拟岩土材料的脆性软化性质。基于Mohr-Coulomb准则,考虑了岩土材料屈服后的塑性软化和体积膨胀,推导了圆形巷道围岩的软化区半径、塑性区半径、洞周位移及围岩内应力表达式,最后通过算例分析了剪胀、软化程度和弹模劣化对破裂区范围的影响,为巷道的稳定分析以及支护设计提供理论依据。     

破碎围岩梯度支护模型及分级控制研究

针对深部巷道大变形难控制问题,基于深部巷道围岩梯度破坏机理及巷道等强支护理论,进一步提出了围岩梯度支护分级控制原理和屈服破坏判据.针对巷道围岩破碎区,采取锚杆和高强水泥材料加固控制;对围岩塑性区,采取锚索和纳米基水泥材料控制,由此实现基于梯度破坏机理的巷道围岩分级三维承压壳控制.研究结果表明：破碎半径、支护强度以及加固厚度对梯度支护模型的敏感度较大,当r=R₁和r=R_p时,基于围岩梯度破坏的梯度承压壳发生屈服破坏的极限强度分别约为25和15 MPa;理论分析验证加固后的梯度承压壳可以实现破碎区边缘和塑性区围岩的恢复,理论得出最好状态分别能近似恢复至初始状态的52%和95%左右.梯度支护模型和分级控制方法在一定程度上为深部巷道围岩控制提供了理论和实践指导.     

三软综放沿空锚网索支护巷道回采期间围岩变形特征

针对三软综放沿空巷道围岩大变形、难支护的特点,提出采用锚网索支护新技术,通过对试验巷道数值模拟以及表面位移、围岩深部位移和围岩应力的现场监测,分析了试验巷道矿压显现活动规律,掌握了试验巷道在锚网索支护下的围岩变形规律,这为锚网索支护在三软煤层巷道的推广应用和支护参数设计提供了科学依据.     

综放回采巷道围岩力学特征实测研究

通过对综放面回采巷道围岩的深部位移、表面位移、应力分布以及支架荷载的实测分析，得出综放面回采巷道围岩力学特征分布规律．研究表明，临近工作面巷道围岩处于支承压力降低区，支架荷载下降，但支架和围岩变形最剧烈，表明巷道围岩处于岩石峰后的力学状态．围岩变形主要发生支承压力影响区，合理的巷道支护应能控制采动影响剧烈阶段的围岩变形，顺槽支护设计理念应从载荷控制向变形控制转变．     

Influence of dynamic pressure on deep underground soft rock roadway support and its application

Due to high ground stress and mining disturbance, the deformation and failure of deep soft rock roadway is serious, and invalidation of the anchor net-anchor cable supporting structure occurs. The failure characteristics of roadways revealed with the help of the ground pressure monitoring. Theoretical analysis was adopted to analyze the influence of mining disturbance on stress distribution in surrounding rock,and the change of stress was also calculated. Considering the change of stress in surrounding rock of bottom extraction roadway, the displacement, plastic zone and distribution law of principal stress difference under different support schemes were studied by means of FLAC3D. The supporting scheme of U-shaped steel was proposed for bottom extraction roadway that underwent mining disturbance. We carried out a similarity model test to verify the effect of support in dynamic pressure. Monitoring results demonstrated the change rules of deformation and stress of surrounding rock in different supporting schemes. The supporting scheme of U-shaped steel had an effective control on deformation of surrounding rock. The scheme was successfully applied in underground engineering practice, and achieved good technical and economic benefits.     

Deformation characteristics of surrounding rock of broken and soft rock roadway

A similar material model and a numerical simulation were constructed and are described herein. The deformation and failure of surrounding rock of broken and soft roadway are studied by using these models. The deformation of the roof and floor, the relative deformation of the two sides and the deformation of the deep surrounding rock are predicted using the model. Measurements in a working mine are compared to the results of the models. The results show that the surrounding rock shows clear rheological features under high stress conditions. Deformation is unequally distributed across the whole section. The surrounding rock exhibited three deformation stages: displacement caused by stress concentration, rheological displacement after the digging effects had stabilized and displacement caused by supporting pressure of the roadway. Floor heave was serious, accounting for 65% of the total deformation of the roof and floor. Floor heave is the main reason for failure of the surrounding rock. The reasons for deformation of the surrounding rock are discussed based on the similar material and numerical simulations.     

Deformation mechanism and stability control of roadway along a fault subjected to mining

It is difficult to maintain the roadway around a fault because of the fractured surroundings, complex stress environment, and large and intense deformation in the mining process. Based on a tailgate of panel S2205 in Tunliu colliery, in Shanxi province, China, we investigated the evolution of stress and displacement of rocks surrounding the roadway during the drivage and mining period using theoretical analysis, numerical simulation and field trial methods. We analyzed the deformation and failure mechanisms of the tailgate near a fault. The deformation of surrounding rock caused by unloading in the drivage period is large and asymmetric, the roadway convergence increases with activation of the fault and secondary fracture develops in the mining period. Therefore, we proposed a specific control technique of the roadway along a fault as follows: (1) High-strength yielding bolt not only supports the shallow rock to load-bearing structures, but also releases primary deformation energy by use of a pressure release device in order to achieve high resistance to the pressure retained; (2) Grouting of near-fault ribside after initial stabilization of the rock deformation is used to reinforce the broken rock, and to improve the integral load-bearing capacity of the roadway. The research results were successfully applied to a field trial.     

Support technology for mine roadways in extreme weakly cemented strata and its application简

For the engineering geology conditions of bad mine roadway roof and floor lithology in extremely weak cemented strata, the best section shape of the roadway is determined from the study of tunnel surrounding rock displacement, plastic zone and stress distribution in rectangular, circle arch and arch wall sections, respectively. Based on the mining depth and thickness of the coal seam, roadway support technology solutions with different buried depth and thickness of coal seam are proposed. Support schemes are amended and optimized in time through monitoring data of the deformation of roadway, roof separation, I-beam bracket, bolt and anchor cable force to ensure the long-term stability and security of the roadway surrounding rock and support structure. The monitoring results show that mine roadway support schemes for different buried depth and section can be adapted to the characteristics of ground pressure and deformation of the surrounding rock in different depth well, effectively control the roadway surrounding rock deformation and the floor heave and guarantee the safety of construction and basic stability of surrounding rock and support structure.     

巷道围岩应力空间分布仿真分析

为得出巷道围岩应力空间分布特征,以圆形断面巷道为例,采用复变函数方法得出其应力解,并把映射空间解转化为巷道所在空间解后对巷道周围岩体应力场进行仿真分析,得出了巷道周围岩体应力场分布直观图,可方便直观的了解巷道围岩任意位置应力分布情况。并考虑不同半径、不同侧压系数对围岩应力场的影响,得出了：圆形巷道围岩应力峰值及其出现方向与半径无关;侧压系数小于1/3时,顶底板开始产生拉应力,大于3时两帮围岩开始产生拉应力;以及环向、径向、剪切应力及最大、最小应力的变化规律。     

移动压力支承作用下底板巷道围岩变形与采深的关系

本文阐明了移动支承压力影响区与采深的关系，提出了用有效载荷系数来反映动压作用下底板巷道围岩变形量的大小，结合孙村煤矿实测资料，总结出在跨采期间，底板巷道围岩变形量与有效载荷系数之间的定量关系，为深井开采移动支承压力作用下，底板巷道围岩变形量预测预报提供了一种方法。     

Stress distribution and surrounding rock control of mining near to the overlying coal pillar in the working face

The occurrence of overlying coal pillar (OCP) exerts a strong effect on the stress and strain distribution of the surrounding rock in the stope. In this paper, the stress distribution characteristics are analyzed via the numerical calculation with the account of OCP presence or absence. In addition, this study revealed the joint effect of side pressure relief area of the goaf and stress concentration in OCP on the final stress distribution. Furthermore, the rules of abutment stress distribution affected by three influencing factors, namely horizontal-vertical distances between OCP and working face and buried depth of OCP, are analyzed. The functional model linking the peak stress of surrounding rock with the above influencing factors is developed. The field application of the above results proved that the rib spalling and deformation of a 2.95 m-high and 5.66 m-wide roadway could be efficiently controlled by rationally adjusting working states of the support, and adopting the hydraulic prop coordinated with the π type metal beam and anchor cable to strengthen the surrounding rock of working face and roadway, respectively. The proposed measures are considered appropriate to satisfy the safe operation requirements.     

Permeability and pressure distribution characteristics of the roadway surrounding rock in the damaged zone of an excavation

Research on the permeability and pressure distribution characteristics of the roadway surrounding rock in the excavation damaged zone(EDZ) is beneficial for the development of gas control technology. In this study, analytical solutions of stress and strain of the roadway surrounding rock were obtained, in which the creep deformation and strain softening were considered. Using the MTS815 rock mechanics testing system and a gas permeability testing system, permeability tests were conducted in the complete stress-strain process, and the evolution characteristics of permeability and strain were studied over the whole loading process. Based on the analytical solutions of stress and strain and the governing equation of gas seepage flow, this paper proposes a hydro-mechanical(HM) model, which considers three different zones around the roadway. Then the gas flow process in the roadway surrounding rock in three different zones was simulated according to the engineering geological conditions, thus obtaining the permeability and pressure distribution characteristics of the roadway surrounding rock in three different zones. These results show that the surrounding rock around the roadway can be divided into four regions-the full flow zone(FFZ), flow-shielding zone(FSZ), transitive flow zone(TFZ), and in-situ rock flow zone(IRFZ). These results could provide theoretical guidance for the improvement of gas extraction and gas control technology.