特厚煤层褶曲构造区冲击地压主控因素分析及防治研究

针对褶曲构造区特厚煤层开采冲击地压防治问题,以孟村煤矿401103工作面为例,深入分析了该工作面褶曲构造区冲击地压的主控因素,其中坚硬顶板破断释放的强动载和巷道围岩受构造应力作用存在的高静载极易诱发冲击地压。针对坚硬顶板强动载影响,在工作面采前,先采用地面水平井分段水力压裂处理上覆高位坚硬顶板;同时运用井下定向长钻孔水力压裂处理褶曲构造区上覆中位坚硬顶板,在回采过程中,超前实施顶板深孔预裂爆破处理上覆低位顶板,达到立体防治的目的,有效降低了坚硬顶板破断释放的强动载影响。针对巷道围岩高静载状态,对巷道帮部采取大直径水力扩孔掏槽卸压措施,在底板采取“钻-爆”联合卸压的强化卸压手段,进一步增大卸压范围,降低高静载应力水平。现场实践证明,对褶曲构造区特厚煤层开采采用以上动、静载分源防控措施,能大幅降低工作面冲击危险性,对类似条件下冲击地压煤层开采具有一定的指导、借鉴意义。

Numerical and analytical simulation of the structural behaviour of fully grouted cable bolts under impulsive loading

Designing reliable yielding support system to mitigate the effect of the kinetic energy in burst-prone conditions in mining and tunneling excavations is one of the challenges for geotechnical engineers. A combination of the support elements can be used to increase rock strength and minimise the displacement of unstable rock mass. It is important to understand how the support system works to ensure the stability of underground excavations. Cable bolts have been commonly used as an effective underground support system and an element of reinforcement to improve rock stability. Cable bolts are usually considered to be subjected to static loads under relatively low stress environments, however, in burst-prone conditions, they might be subjected to dynamic loads. Cable bolts as well as other support elements are used in burst-prone conditions to absorb the kinetic energy of the removed rock to avoid sudden and violent failures. This paper develops numerical and a novel analytical simulation technique for cable bolts to assess their structural behaviour under static and dynamic loading conditions. The numerical and analytical models are then validated against experimental observations reported in the literature, which demonstrates the reliability of the proposed models.

宽输入范围DC/DC变换器Burst与双前馈复合控制策略

蓄电池储能是新能源发电及微电网的核心装备,高动态响应始终是双向DC/DC储能变换器的关键指标.在冲击性负载等大信号变化场景下蓄电池将高倍率放电,内阻因素导致其端电压大幅跌落,限制了后级DC/DC变换器的快速输出能力.为了提升DC/DC变换器在宽输入范围场景下的响应能力,在传统电压闭环基础上,提出了一种Burst模式与输入电压和输出负载前馈的复合控制策略.通过建立输入电压vin和负载电流iload对输出电压vo的扰动函数,分析扰动通道的作用机理和影响因素,快速估算跟踪变换器的稳态工作点,并建立扰动抑制前馈函数,对占空比d进行调节以提升系统的响应速度.进一步设计输出电压vo滞环,通过滞环调节使变换器进入Burst模式以限制大信号变化场景下电压vo的超调和振荡.最后搭建了一台功率为48 kW的实验样机,实验结果表明本文所提出的Burst与双前馈复合控制策略可有效提升大信号干扰下DC/DC变换器的响应速度,更适用于大功率、宽输入电压范围的应用场景.

Load Transfer Test of Post-Tensioned Anchorage Zone in Ultra High Performance Concrete

Researches on ultra-high performance concrete (UHPC) have been conducted worldwide owing to its outstanding durability and strength performances. The exploitation of the mechanical properties of UHPC will render it possible to achieve economic design through substantial reduction in the cross sectional dimensions and simplification in the reinforcement arrangement. This paper investigates experimentally the load transfer in the prestressed concrete anchorage zone. To provide distinctive features of UHPC compared to ordinary concrete, the cross sectional dimensions of the member were reduced and the stress distribution, deformation and cracking pattern of the PS anchorage zone were examined experimentally according to the degree of reinforcement of the members chosen. The distributions of the bursting stress, spalling stress and longitudinal edge stress in the specimens were observed according to the various types of reinforcement. All the specimens satisfied the load-bearing capacity criterion specified by the European ETAG-013 guidelines and their stress distributions were similar to those in the PS anchorages of post-tensioned members applying ordinary concrete. The cracks propagated longitudinally with lengths up to twice the cross sectional dimensions and their width was smaller than when applying ordinary concrete owing to the bridging effect of the steel fibers in UHPC. Accordingly, the exploitation of the high strength of UHPC enabled us to secure the resistance of the anchorage with no need for particular reinforcing devices.

Application of high-pressure water jet technology and the theory of rock burst control in roadway

This paper puts forward using high-pressure water jet technology to control rock burst in roadway, and analyzes the theory of controlling rock burst in roadway by the weak structure zone model. The weak structure zone is formed by using high-pressure water jet to cut the coal wall in a continuous and rotational way. In order to study the influence law of weak structure zone in surrounding rock, this paper numerically analyzed the influence law of weak structure zone, and the disturbance law of coal wall and floor under dynamic and static combined load. The results show that when the distance between high-pressure water jet drillings is 3 m and the diameter of drilling is 300 mm, continuous stress superposition zone can be formed. The weak structure zone can transfer and reduce the concentrated static load in surrounding rock, and then form distressed zone. The longer the high-pressure water jet drilling is, the larger the distressed zone is. The stress change and displacement change of non-distressed zone in coal wall and floor are significantly greater than that of distressed zone under dynamic and static combined load. And it shows that the distressed zone can effectively control rock burst in roadway under dynamic and static combined load. High-pressure water jet technology was applied in the haulage gate of 250203 working face in Yanbei Coal Mine, and had gained good effect. The study conclusions provide theoretical foundation and a new guidance for controlling rock burst in roadway.

Mechanism of rock burst caused by fracture of key strata during irregular working face mining and its prevention methods

To study the occurrence mechanism of rock burst during mining the irregular working face,the study took irregular panel 7447 near fault tectonic as an engineering background.The spatial fracture characteristic of overlying strata was analyzed by Winkler elastic foundation beam theory.Furthermore,the influence law of panel width to suspended width and limit breaking span of key strata were also analyzed by thin plate theory.Through micro-seismic monitoring,theoretical analysis,numerical simulation and working resistance of support of field measurement,this study investigated the fracture characteristic of overlying strata and mechanism of rock burst in irregular working face.The results show that the fracture characteristic of overlying strata shows a spatial trapezoid structure,with the main roof being as an undersurface.The fracture form changes from vertical‘‘O-X"type to transverse‘‘O-X"type with the increase of trapezoidal height.From the narrow mining face to the wide mining face,the suspended width of key strata is greater than its limit breaking width,and a strong dynamic load is produced by the fracture of key strata.The numerical simulation and micro-seismic monitoring results show that the initial fracture position of key strata is close to tailgate 7447.Also there is a high static load caused by fault tectonic.The dynamic and static combined load induce rock burst.Accordingly,a cooperative control technology was proposed,which can weaken dynamic load by hard roof directional hydraulic fracture and enhance surrounding rock by supporting system.

变区段煤柱工作面诱冲机理及防治技术研究

针对某矿变区段煤柱工作面开采冲击危险性较高的问题,运用数值模拟方法对工作面采掘过程中煤柱区域垂直应力分布规律进行研究,分析了不同宽度区段煤柱应力积聚特征,揭示了变区段煤柱工作面诱冲机理,并制定了“近场-远场”协同卸压方案。研究结果表明,较宽的区段煤柱(30 m和55 m)受采空区侧向支承压力和超前支承压力影响,煤柱应力集中程度较高;受“近场高静载+远场动载”叠加影响,变区段煤柱工作面回采期间易诱发冲击地压;采取近场高承压煤体强卸压+远场高位坚硬顶板超前预裂断顶卸压协同控制方案后,微震能量事件始终维持在104J以下,表明控制方案能够有效降低工作面采掘期间的冲击危险性。

强冲击载荷下巷道围岩变形破坏特征及控制技术

针对冲击地压巷道围岩及支护结构变形破坏难题,采用数值计算、现场实测、现场试验等研究方法,分析了强冲击载荷下巷道围岩及支护结构变形破坏特征,研究了冲击载荷、采动应力等对巷道围岩和支护结构动态力学响应的影响,开发了抗冲击支护材料,提出了支护-卸压联合控制技术,并选择典型冲击地压矿井进行了应用。研究结果表明:巷道顶板发生冲击时,巷道顶板、两帮和底板质点最大振速分别为1.41、0.63、0.25 m/s,迎波侧巷表围岩受冲击影响最大,侧向次之,背波侧最小。在采动应力与冲击载荷叠加作用下巷道破坏范围更大,塑性区面积达到原岩应力时的2.1倍。随着冲击能量的增加,巷道变形量和质点振动速度峰值均急剧增大,且锚杆(索)受力也出现明显波动。爆破卸压对巷帮锚杆锚固力影响不大,而对锚索锚固力有明显影响,锚索锚固力平均降低26.7%。高冲击韧性锚杆屈服强度800 MPa,断后伸长率20%,冲击吸收功150 J;高延伸率锚索最大力延伸率8%,抗拉强度1770 MPa。联合控制技术在宽沟煤矿进行了现场应用,巷帮锚杆受力53~84 kN,顶板锚索受力122~219 kN,锚杆(索)受力均处于安全允许范围之内,顶板浅部和深部未发生离层,在大能量微震事件作用下,支护系统也能保持稳定。

区块链架构下蜂蜜供应链可信监管溯源模型

针对传统蜂蜜溯源效率低下、可信度较低等问题进行了研究,在分析了蜂蜜溯源标准后,结合区块链技术和IPFS技术构建了高可信蜂蜜溯源方案。首先提出了分层存储策略,解决了信息上链及溯源效率较低的问题;然后以多链构架隔离数据,提出基于外部随机预言的代理重加密方案,由智能合约完成密文重加密,同时附上消息认证码,解决了信息可信度低、假冒伪造和隐私数据泄露风险;最后,为防止突发性负载导致的数据不一致,提出了预上链机制,即“高流量打包预先上链,低流量补充上链”方案。为验证可行性,对上述方案使用Apache Bench工具进行仿真测试,结果表明,该方案实现了基本数据的有效上链、可控监管和可信溯源,能够满足企业、监管部门和用户的多级需求。

底板岩层冲击倾向性分类及指数测定方法

底板型冲击是冲击地压灾害的显现方式之一,明确底板内在冲击属性可以更好地评估底板型冲击危险性,指导底板型冲击地压灾害防治。在参照顶板岩层冲击倾向性分类及指数测定方法基础上,通过简化简支梁受力模型,借助小变形位移相等、岩梁长度相等方法,将底板岩层受力作用等效为均布载荷,基于薄板理论推导临界应力表达式,确定底板主控岩层位置和弯曲变形岩层层数,计算底板岩层弯曲能量指数,判断底板岩冲击倾向性,基于此建立底板岩层冲击倾向性分类和鉴定流程;以义马矿区跃进煤矿为例对该方法进行了验证,应用结果表明跃进煤矿2-1煤底板岩层的冲击倾向性由弱变强,更符合结合现场实际情况,证明了该方法的合理性和可行性。

不同加载速率下煤单轴抗压强度测试与冲击倾向性影响分析

针对冲击倾向性测试中煤样单轴抗压强度数据随加载速率变化和离散性问题,以内蒙古鄂托克前旗长城六号煤矿3号煤为研究背景,通过设置0.50、0.75、1.00 MPa/s三种不同加载速率进行煤样标准件的分组测试。测试结果表明,3种不同加载速率测试得到煤的单轴抗压强度测试值均存在离散性;加载速率与单轴抗压强度测试值无明显线性关系;在舍去每组离散性较大的最大值和最小值后,再次计算在不同加载速率条件下煤单轴抗压强度的平均值和标准差,可以得到离散性相对较小的测试值;煤样单轴抗压强度测试值与加载速率无明显比例关系,加载速率的变化可导致同煤层冲击倾向性等级的变化。

引水式电站压力钢管爆裂洪水对厂区影响研究

为研究引水式电站压力钢管发生爆管事故后对厂区建筑物的影响,采用重力相似准则设计了大沫水电站压力钢管爆裂影响区域物理模型,对钢管爆裂事故影响情况开展了系统试验,比较了压力管道局部破裂和完全破裂后爆管水流运动过程的差异,研究了管道完全破裂后不同响应时间和前池水量下爆管水流的水力参数特征。结果表明,压力管道局部破裂与完全破裂时水流流态存在明显差异,对下游建筑物淹没过程和冲击荷载也明显不同。局部破裂时水流沿环向缺口喷出并形成大量散裂水滴覆盖厂房和水处理室,并未对建筑物产生明显冲击荷载;完全破裂后爆管水流直冲下游建筑物,并沿建筑物墙面爬升到较大高度,对建筑物底部产生较大冲击荷载。爆管水流对房屋的最大淹没深度和最大冲击荷载与爆管发生后前池通过压力钢管泄露水量密切相关。爆管事故发生后,缩短响应时间(尽快关闭钢管进口事故闸门),可有效降低各建筑物被淹没的时间。研究结果可为制定引水式水电站压力钢管爆裂事故应急抢修预案提供参考。

迈步式吸能支架-巷道围岩系统动力响应数值分析

为防止吸能支架与冲击地压引起的围岩发生共振,提高巷道支护围岩体系的安全性。采用理论分析和数值模拟方法,建立吸能支架-巷道围岩系统模型,考虑初始应力条件,通过在巷道上方施加简谐激励以模拟动载作用,研究在不同动载频率下吸能支架动力响应规律。研究结果表明:当外界扰动频率接近系统固有频率时,会发生共振现象。动载作用下,吸能支架最大位移发生在顶梁,而顶梁位移分布呈中间大两端小趋势,应力分布呈中间高两边低趋势;靠近顶板和靠近动载源处的围岩的加速度幅值较大。动载频率为吸能支架固有频率时,立柱的振动频率与围岩振动频率相差较小。研究结果为动载作用下巷道围岩控制提供有益参考。

复杂高应力区掘进工作面冲击地压发生机理与防治技术研究

复杂高应力区冲击地压高发,并且破坏能量大,对煤矿生产造成极大影响。以赵楼煤矿7303工作面的冲击地压防治为例,通过应力检测、CT反演分析和微震检测等技术对现场进行分析,同时分析了媒体大直径钻孔卸压的效果。通过分析7303初采阶段冲击危险影响因素,建立了复杂高应力采场支承模型,通过计算得7303采空区侧向支承压力影响范围为134m,应力峰值距离煤壁67m,峰值应力为78MPa,并针对性的提出放冲措施。

基于LLC谐振变换器的四脉冲ZVS间歇控制方法

由于LLC(谐振变换器电路中的谐振电感L_(r)、励磁电感L_(m)、谐振电容C_(r),统称LLC)谐振变换器在DC-DC变换中具有良好的特性,但在间歇控制模式下,仍存在每个控制周期内开关管的第一次开启过程会产生硬开关现象,限制了谐振变换器在轻载条件下进一步提高运行效率的可能性。为了解决这些问题,提出了一种全新的四脉冲模式间歇控制策略。该策略在三脉冲模式的基础上在副边侧设计了一个新脉冲来进行驱动,目的是将副边的能量返流到原边,通过原边开关管在结电容返流完成且体二极管导通时,发出的触发信号,实现原边开关管在第一个触发脉冲导通,从而将变换器运行在效率最优轨迹中。实验结果表明,所提出的控制策略在电压降低工况下可进一步提高了变换器的轻载运行效率,证明此策略的有效性。

卸荷及瓦斯作用下煤体冲击倾向性特征试验研究

卸荷损伤作用下含瓦斯煤体冲击倾向性研究对于探明地下深部矿井中煤与瓦斯复合型冲击地压形成机理起着关键作用。为了探究卸荷作用对含瓦斯煤体冲击倾向性的影响,对含瓦斯煤体进行了不同卸荷幅度下变上限循环加卸载。试验结果表明:瓦斯对煤体力学性质具有劣化作用,9 MPa围压下经过1 MPa与2 MPa瓦斯作用后的煤试件抗压强度分别降低了11.2%及18.7%;在卸荷幅度分别为3 MPa与6 MPa作用下,煤试件抗压强度分别降低了12.6%与36.5%,剩余弹性能指数分别降低了10.4%与16.7%;含1 MPa瓦斯煤试件抗压强度分别降低约13.5%与39.8%,剩余弹性能指数分别降低了15.9%与43.6%;含2 MPa瓦斯煤试件抗压强度分别降低约16.7%与47.2%,剩余弹性能指数分别降低了20.3%与48.5%;随着卸荷幅度的增加,煤试件力学性能不断降低,且瓦斯作用会进一步加剧卸荷劣化程度,同时随着瓦斯压力的增加,劣化程度逐步加深;此外,卸压作用能够有效降低煤体冲击倾向性,同时含瓦斯煤体经过卸荷作用后冲击倾向性指标劣化程度高于原始煤试件,且随着瓦斯压力的增加,剩余弹性能指数降低程度越高。

矿震诱发冲击地压机理研究

根据弹性波理论推导出矿震产生的应力波诱发动力扰动的公式,建立冲击地压理论模型从而推导出冲击地压发生的发生理论;并利用ABAQUS数值模拟技术模拟了矿震诱发冲击地压的过程;并探究围岩巷道受到静—动荷载叠加作用时,冲击地压的发生条件;根据现实中某矿矿震引发的冲击地压测得的数据,验证了矿震诱发冲击地压这一理论。模拟结果表明,当围岩巷道受到的地应力静载过大,达到临界塑性区时,微小的矿震会引发围岩巷道出现冲击地压现象。

基于地震波CT探测的冲击地压危险性评价与防治

为了解决工作面回采过程中存在的冲击危险区域的不确定性和煤岩体内部静载荷分布的模糊性,采用地震波CT探测技术,对回采工作面采取静载荷探测和冲击危险性评估,对冲击危险区域进行了重新确定,并制定了有针对性的卸压方案,提高了工作面回采期间的冲击地压防治效果。结果表明,小庄煤矿40302工作面回采期间,发现中等危险区域共9处,弱危险区域14处,其他区域为无冲击危险区域。通过采用地面L型水平井分段压裂技术、煤层大直径卸压钻孔、煤层爆破及顶板预裂爆破技术对冲击危险区域进行卸压,有效降低了工作面回采期间的冲击风险,为工作面安全回采提供了保障。

厚硬顶板刀把形采空区下综放工作面冲击地压机制研究

不规则的开采空间结构可增大煤矿冲击地压危险,研究多煤层复杂开采空间结构下工作面冲击机制对煤炭资源安全采出具有重要意义。综合采用理论分析、数值模拟、现场监测等方法,研究了某矿井W1123综放工作面的动静载分布特征,分析了冲击显现机制,提出了针对性的防冲措施并进行现场应用。结果表明,上覆刀把形采空区和厚硬顶板综合作用下W1123工作面动静载分布具有区域性特征,当工作面仅受到刀把形采空区的“刀柄”作用或同时受“刀柄”和“刀身”作用时,工作面中下部和区段煤柱静载集中、动载扰动剧烈,工作面回风巷围岩也存在动静载集中,且距离刀把形采空边界越近则围岩动静载越高;仅受“刀身”作用时,工作面回风巷围岩静载集中受动载扰动。工作面静载集中区和动载扰动区重合,动静载叠加造成冲击显现。依据刀把形采空区结构特征,W1123工作面回采期间冲击类型依次为强动载型、高静载强动载型、高静载型。数值模拟和现场监测揭示的冲击危险区与理论分析结果一致。针对W1123工作面静动载分布特征,优化设计了冲击地压防治措施,增大了厚硬顶板处理高度和破碎程度、增加了工作面运输巷煤体爆破和煤柱切顶以降低顶板和煤体应力和能量集中;优化措施实施后,工作面微震事件日均能量总体下降54%,大能量事件大幅减少,冲击地压危险显著降低。该研究结果可为相似条件矿井的冲击地压防治提供借鉴。

深井断层切割煤柱冲击地压防治实践

针对大采深影响下断层切割煤柱区域冲击地压防治难题,采用理论分析、现场实测方式对断层切割煤柱区域冲击危险性进行了分析与研究,得到如下结论:断层切割煤柱区域在静载条件下趋近于失稳状态,推采过程中动静载应力叠加,煤柱冲击危险性升高;通过断层切割煤柱失稳模型和现场微震、应力及其它数据监测分析发现,工作面初采阶段及单、双工作面见方阶段,微震能量积聚显著,应力集中区域明显,在此过程中断层切割煤柱存在整体失稳现象,通过大直径钻孔卸压、爆破预裂顶板及加强支护等冲击地压防护措施加强对此区域的冲击地压监测与防治,实现断层切割煤柱区域的安全回采。