断续节理岩体中地震波响应的数值与理论分析

为研究地震产生的应力波在断续节理岩体中的传播规律和应力分布趋势,首先,采用数值模拟方法分析应力波通过贯通节理的传播规律,并与已有理论研究结果进行对比,验证数值分析的准确性和适用性;然后,对应力波在断续节理岩体中的传播进行数值模拟,分析透射系数在水平方向的分布趋势以及不同节理连续性对波传播的影响,并结合波的衍射原理,给出定性的理论解释。结果表明:应力波通过断续节理时,节理的透射作用会使应力波振幅减小,引起波的衰减,岩桥的衍射作用则会使波阵面由平面变为曲面,波的传播方向发生改变,从而导致应力波振幅在水平方向的分布发生变化;应力波通过断续节理的透射系数与岩桥尺寸L_r和衍射角μ相关,当衍射角比较小时,透射系数主要受岩桥尺寸L_r的影响,当衍射角较大时,岩桥尺寸L_r和衍射角μ共同影响应力波在岩体中的传播。      

水平地震力作用下岩体破坏机理探究

基于摩尔库伦强度准则和波动理论对地震作用下岩体的破坏机理进行研究。结果表明:当埋深在一定范围内,水平地震作用下岩体的内聚力c和正应力σn与振动速度和埋深呈线性关系。当埋深一定时,振动速度越大c值越小;在振动速度增大的过程中岩体的应力状态由压应力逐渐转变为拉应力,且拉应力随振动速度的增大而增大;当振动速度一定时,岩体埋深越大c值越小;埋深越浅,拉应力越大,当埋深达到一定值时岩体就只在其弹性极限内振动而不产生破坏。     

岩体结构面动态剪切试验研究现状评述

针对岩体结构面动态剪切问题,总结了国内外能用于测试岩体结构面动态剪切强度特性的直剪试验仪和相关室内试验研究现状:目前国内外能用于测试岩体结构面动态剪切强度特性的仪器不多,且仪器指标参数如剪切速率、法向应力加载条件以及试样尺寸变化范围等无法完全满足相关试验要求;对于剪切速率较低的定速率剪切试验,人工岩体结构面峰值抗剪强度随剪切速率的变化而变化,且变化趋势因结构面硬度等物理力学性质的不同而不同,变化幅度随法向应力的增大而增大、随初始起伏度的增大而增大、随循环次数的增加而减小;天然岩体结构面动态剪切试验较少,较高剪切速率和变速率剪切试验数据不足,未见尺寸效应和壁岩强度对结构面动态剪切强度影响的试验成果.研发新的岩体结构面动态剪切强度特性测试的室内试验系统是未来岩体结构面动态剪切问题研究的必由之路.     

芦山MS7.0、玛多MS7.4地震前大地电场异常变化特征

1 研究背景 岩石破裂实验结果表明,地震是应力持续加载并最终导致岩体突然张裂、断裂和错动的结果,伴随着应力应变的持续积累,岩土介质的物性参数会发生变化,在孕震晚期会产生电磁辐射,而且,地电场在多次中强地震前具有中短期异常.因此,开展大地电场观测与研究,有助于深入认识地壳构造运动规律,同时对地震灾害短临预测研究具有重要意义.     

岩石破裂电磁辐射频率与岩石属性参数的关系

为进一步明确岩石破裂电磁辐射频率特征,基于岩石破裂电磁辐射是由岩石破裂时传播裂纹引起原子扰动产生的假说, 通过断裂力学理论中小范围屈服条件下张开位移法计算岩石破裂时的裂纹宽度,由单脉冲电磁辐射频率与裂纹宽度之间的关系,研究电磁辐射频率与岩石属性参数之间的关系,并给出了它们之间的关系表达式;单独讨论了不同属性参数对电磁辐射频率的影响.结果表明,电磁辐射频率随弹性模量增大而增大,随岩样尺寸和强度增大而减小,随泊松比的变化、岩石弹模的不同电磁辐射频率有变化;当弹模较小时,泊松比的影响也较小,而当弹模很大,即岩石刚度很大时,泊松比的增大会导致频率的增大;裂纹初始长度的变化受试件尺寸的影响,进而影响频率,当尺寸较大时,裂纹长度对频率影响较小,当尺寸较小时,频率随裂纹长度增大而增大.通过计算几种常见岩石破裂时电磁辐射频率值发现,岩石破裂时电磁辐射频率达到10⁵ Hz量级,这与现有的实验结果相吻合.     

地应力对裂隙岩体渗透特性的影响

提出了地应力场中岩体不连续面变形的本构关系，讨论了渗流与应力耦合条件下裂隙岩体渗透张量的计算方法，阐述了地应力对裂隙岩体渗透特性的影响．研究表明，地应力对岩体渗透特性的影响主要是通过改变不连续面的开度和不连续面网络的水力传导路径而产生的；裂隙岩体渗透性随岩体埋深的增加呈负指数减小，随侧压系数的增大呈双曲线减小．渗流场与应力场的耦合理论可望应用于水库诱发地震的研究中     

作为地震动物异常行为的蚕的定向排列以及断层的电磁模型——理论与实验

在假定地震动物异常行为(SAAB)是对地震电信号(SES)的电生理反应的前提下,通过施加电场、实验再现了神户地震所报道的SAAB————蚕及鱼的定向排列．由于垂直于电场时动物体内骨格肌的阻抗较平行时大,动物表现出沿垂直于电场方向排列的行为．基于偶极电荷q源于地震应力(t)的变化,提出了一断层的电磁模型:dq/dt=－(d/dt)－q/,其中是一表征电荷生成的常数,比如压电系数;为介电常数,为花岗岩的电阻率．一长2a且位错或破裂时间为的断层,由于应力的变化将产生脉冲状的偶极电荷(面密度):+q(t,x)和－q(t,x+2a),或由地震矩M0而给出偶极矩P(t)=2aAq(t)=M0［/(－)］(e－t/z－e－t/)．断层位错D、位错速率D和应力降满足=D/D=(/0)(a/)．断层域的电场强度F及电流密度J可由F=q/及J=F/得到．若为水的电阻率,则可得到J=0.1～1 A/m2,该值足以引起动物的异常行为．由P(t)所产生的近场甚低频(ULF)波可解释与距离R成反比的SES．      

地应力对裂隙岩体渗透特性的影响

提出了地应力场中岩体不连续面变形的本构关系，讨论了渗流与应力耦合条件下裂隙岩体渗透张量的计算方法，阐述了地应力对裂隙岩体渗透特性的影响．研究表明，地应力对岩体渗透特性的影响主要是通过改变不连续面的开度和不连续面网络的水力传导路径而产生的；裂隙岩体渗透性随岩体埋深的增加呈负指数减小，随侧压系数的增大呈双曲线减小．渗流场与应力场的耦合理论可望应用于水库诱发地震的研究中．      

垂直向地震作用对节理岩体失稳破坏的影响

基于线弹性断裂力学理论分析了垂直向地震作用对节理岩体地震动力破坏的影响。在仅考虑峰值时,最不利的单向地震动加速度方向是水平倾向坡外,双向则依据破裂机制是拉剪或压剪,加速度分别是水平倾向坡外与向下或向上的组合。地震动的幅值、作用方向及双向地震动的组合都可使岩体的破坏机制发生转化,并且是突变的、不可逆的。较低峰值的双向地震动产生的应力强度因子可能大于较高峰值的单向地震动所产生的应力强度应子。在岩体节理分布特征和静态应力场一定的初始条件下,第一个导致岩体中产生破裂的地震动加速度幅值及其方向的组合唯一地决定了岩体不可逆破坏发展的方向、机制及最终的破坏特征,其复杂性远大于静力作用时的情况。对岩体地震动力破坏问题的认识应充分考虑垂直向地震动的重要影响。     

2003年大姚Ms 6.2、Ms 6.1地震序列环境剪应力τ0值时空分布

以Brune中小地震圆盘形破裂位错模式为基础,用地面运动峰值参数(r．u)直接求出震源处环境应力τ0值。结果表明：大姚地震序列是一次中等强度应力序列;Ms6．2序列平均τ0值为3．3MPa,存在大于15MPa的高应力地震,而Ms6．1序列平均τ0值为2．8MPa,无大于15MPa的高应力地震,Ms6．2地震序列整体应力水平要高于Ms6．1序列;在Ms6．2序列中,τ0值随时间不衰减,而Ms6．1地震序列τ0值衰减较快;τ0值存在随震级的增加而增大的趋势。     

Dynamic stress concentration in pre-stressed poroelastic media due to moving punch influenced by shear wave

During the occurrence of earthquake, the shear wave propagates in the rocks present inside/at the Earth’s crust. The propagation of shear wave may lead to the progression of punch present inside the rock medium. As a result of this, substantial stress accumulated at the vicinity of propagating punch inside rock medium which significantly affects the stability of various geological and human-made structure and, hence, may cause failure of structure. Therefore, the analysis of stress concentration at the vicinity of punch moving due to shear wave propagation has become prominent in the area of seismology. In the present paper, an analytical perspective has been employed to discuss the influence of velocity of moving punch associated with the propagation of shear wave on developed dynamic stress concentration (DSC) in three types of pre-stressed vertical transversely isotropic (VTI) poroelastic media viz. granite (an igneous rock); sandstone (a sedimentary rock); and marble (a metamorphic rock). The closed form expression of DSC for the force of constant intensity has been derived with the aid of Weiner-Hopf technique along with Galilean and two-sided Fourier integral transformations. The noticeable influence of different affecting parameters (viz. velocity of moving punch associated with the shear wave propagation, horizontal compressive/tensile initial stresses, vertical compressive/tensile initial stress, porosity, and anisotropy parameter) on dynamic stress concentration has also been reported. Numerical computation and graphical illustrations have been carried out for the aforementioned three different types of porous rocks to investigate the profound impact of affecting parameters on DSC. Moreover, some noteworthy peculiarities have also been derived from the obtained expression of dynamic stress concentration.     

煤岩变形破坏电磁辐射记忆效应的力电耦合规律

理论分析了煤岩变形破坏过程中电磁辐射脉冲数与损伤之间的关系,探讨了煤岩变形破坏电磁辐射产生机制及电磁辐射记忆效应的力电耦合规律,建立了等围压三轴应力状态下含瓦斯煤岩变形破坏电磁辐射记忆效应的力电耦合模型,实验测定并分析了单轴压缩状况下含瓦斯煤岩变形破坏电磁辐射记忆效应的力电耦合规律.结果表明,含瓦斯煤岩变形破坏电磁辐射记忆效应力电耦合模型很好地反映了煤岩变形破坏电磁辐射记忆效应特征规律和微观损伤机理.     

The mechanism and dynamics of rock fracture upon mechanical impact and electric discharge

The mechanism and dynamics of the deformation and fracture of quartz, granite, and marble samples under the striker blow on their surface and electric discharge inside them are studied by the fractoluminescence (FL), electromagnetic (EME), and acoustic emission (AE) methods with 10-ns resolution. The impact excites a forced deformation wave with a velocity within 0.8 to 2 km/s depending on the mineral. The atomic bonds rupture and microcracks are formed at the nodes of the wave, which leads to the emergence of the FL flashes and disruption of the time dependences of EME. Based on the intensity of the flashes, the dimensions of microcracks are estimated to vary from 2 to 70 µm depending on the mineral. In turn, the emergence of microcracks initiates additional deformation waves.The discharge inside the studied samples excites a pressure shock wave which transforms into the tension wave after reflection from the surface. According to the analysis of FL spectra, this leads to the breakdown of the rocks into positively charged ions and electrons. The shock wave velocity in granites is measured at 4.8 km/s, which is close to the velocity of the longitudinal acoustic vibrations ~5 km/s. The microcracks in the rock have not enough time to form with this loading velocity. It is supposed that the shock wave stretches the deformed interatomic bonds at the dislocation nuclei in the crystal lattices of the minerals up to their breakdown into positively charged ions.     

Obliquely incident wave propagation across rock joints with virtual wave source method

Due to the presence of joints, waves are greatly attenuated when propagating across rock masses. Zhu et al. (2011) (Normally incident wave propagation across a joint set with virtual wave source method. J. Appl. Geophys.73, 283–288.) studied normally incident wave propagation across a joint set with the virtual wave source method (VWSM). The introduced VWSM has merits in some aspects, especially the capability of separating differently arriving transmitted waves. However, normal wave incidence is only the special case for wave incidence with arbitrary incident angles. Obliquely incident wave propagation across a joint set is more complicated than normally incident wave propagation due to wave transformation at the joints. As a continuation of the previous paper, this work is extended to analytically study obliquely incident wave propagation across joints with VWSM. Complete theoretical reflection and transmission coefficients across single joint described by displacement discontinuity model are derived through plane wave analysis. The superposition of P wave and S wave is for the first time mathematically expressed and studied. The VWSM is verified through comparison with the propagation matrix method. Through extensive parametric studies on wave transmission across single and multiple parallel joints, it is shown that transmitted wave energy is mainly constrained in the transmitted wave of the same type as the incident wave. And with increasing joint stiffness, the transmission coefficients across single joint increases except those whose wave type is different from the incident wave. The amplitude of superposed transmitted wave for P wave incidence increases with incident angle, which is coincident with field observations. Both joint spacing and number of joints have significant effects on transmission coefficients. We find that when joint spacing is sufficiently large, the transmission coefficient is no longer a constant as the normally incident wave propagation case (Zhu et al., 2011). And when joints are very closely spaced, wave attenuation depends little on the number of joints, which is different from the conclusions from equivalent medium method.     

岩石破裂电磁辐射的频率特性

本文提出岩石破裂时产生的低频电磁辐射起源于微破裂引起的电子发射，并用电四极子模型计算了近区电磁场的频率特性．结果表明，近区电磁场的频率与样品尺寸和初始裂纹长度有关，利用典型实验样品尺寸和花岗岩初始裂纹数据计算出近区电磁场的频率为５０ｋＨＺ－１ＭＨｚ量级．它与已有实验测量结果相符．     

Propagation characteristics of blast-induced shock waves in a jointed rock mass

The propagation characteristics of blast-induced shock waves in a jointed rock mass have been monitored and studied. Accelerometers were set up on a rock surface along three lines, at 0°, 45° and 90° with respect to the orientation of the predominant joint strikes. Cylindrical charges were detonated in a charge hole, and ground accelerations in both vertical and radial directions at various points on the rock surface were recorded. Results show that rock joints have significant effects on the propagation characteristics of blast-induced shock waves. The amplitude and principal frequency of shock waves attenuate with the increase of distance from the charge centre, and the increase of incident angle between the joint strike and the wave propagation path. The measured data were compared with the empirical equations of shock wave attenuation proposed by other authors. The mechanism of rock joint effect, the attenuation of shock waves in relation to the propagation distance, the charge weight and the incident angle, are discussed in this paper.     

煤岩变形破坏电磁辐射记忆效应实验研究

实验研究了原煤、型煤单轴压缩电磁辐射记忆效应特征、记忆内容及变化规律，探讨并分析了煤岩电磁辐射记忆效应机理.结果表明，煤岩变形破坏电磁辐射具有记忆先期最大应力、纵向应变、横向应变和体应变的能力，最直接的记忆内容是先期受到的应力、纵向应变和横向应变；当先期施加的应力水平大于70%～80%时，电磁辐射记忆能力迅速减弱，甚至根本失去记忆能力；煤岩损伤破坏过程的不可逆决定了电磁辐射过程的不可逆，电磁辐射过程的不可逆是煤岩变形破坏电磁辐射记忆效应的直接原因.煤岩电磁辐射记忆效应理论在地应力测试、巷道围岩不同应力区范围的确定及煤岩动力灾害预测等方面具有广阔的应用前景.     

高地应力V级围岩相似材料研制及岩体开挖卸载模型试验分析

以黄土、砂为骨料,石膏、水泥为胶结材料,水为调节剂,以正交试验方法配制出V级围岩相似材料,该材料能够很好的模拟隧道Ⅴ级软弱围岩。在此基础上,以钢筒模型试验为媒介,通过千斤顶配合反力架加载,观察不同材料配比下的试验组应力变化斜率、自稳时间、应变大小等方面的差异,结合加载完成后模型开口处岩体变化情况,探索高地应力下Ⅴ级围岩开挖卸载效应。试验结果表明:虽然相似材料会因配比不同改变物理力学性质,但主要是对弹性模量的影响较大;在增大垂直压力作用下,试验中材料自稳时间变长,应力释放也较为彻底,但整体趋势放缓。