Weighted-elastic-wave interferometric imaging of microseismic source location

Knowledge of the locations of seismic sources is critical for microseismic monitoring. Time-window-based elastic wave interferometric imaging and weighted- elastic-wave （WEW） interferometric imaging are proposed and used to locate modeled microseismic sources. The proposed method improves the precision and eliminates artifacts in location profiles. Numerical experiments based on a horizontally layered isotropic medium have shown that the method offers the following advantages： It can deal with Iow-SNR microseismic data with velocity perturbations as well as relatively sparse receivers and still maintain relatively high precision despite the errors in the velocity model. Furthermore, it is more efficient than conventional traveltime inversion methods because interferometric imaging does not require traveltime picking. Numerical results using a 2D fault model have also suggested that the weighted-elastic-wave interferometric imaging can locate multiple sources with higher location precision than the time-reverse imaging method.

Propagation patterns of microseismic waves in rock strata during mining:an experimental study

Microseismic monitoring has been widely used in mines for monitoring and predicting dynamic disasters such as rockbursts and waterbursts. However, to develop high-precision microseismic monitoring systems, the propagation patterns of microseismic waves under complex geological conditions must be elucidated. To achieve this aim, a simulation model of a typical coalmine was designed using similar materials according to the similarity theory to simulate the mining process. Geophones were embedded into the model to detect the propagation of elastic waves from microseisms. The results show that in an unmined solid rock mass, the wave velocity in shallow rock strata is mainly affected by geologically weak planes, whereas in deep strata it is affected mainly by the density of the rock mass. During propagation, the amplitude first decreases and then increases rapidly with increasing propagation distance from the coal layer. After mining, our results indicate that the goaf causes significant attenuation of the wave velocity. After the goaf was backfilled, the velocity attenuation is reduced to some extent but not eliminated. The results of this study can be used as guidelines for designing and applying microseismic monitoring systems in mines.

3D near-surface P-wave velocity structure imaging with Distributed Acoustic Sensing and electric hammer source

Distributed Acoustic Sensing(DAS) is an emerging technique for ultra-dense seismic observation, which provides a new method for high-resolution sub-surface seismic imaging. Recently a large number of linear DAS arrays have been used for two-dimensional S-wave near-surface imaging in urban areas. In order to explore the feasibility of three-dimensional(3D) structure imaging using a DAS array, we carried out an active source experiment at the Beijing National Earth Observatory. We deployed a 1 km optical cable in a rectangular shape, and the optical cable was recast into 250 sensors with a channel spacing of 4 m. The DAS array clearly recorded the P, S and surface waves generated by a hammer source. The first-arrival P wave travel times were first picked with a ShortTerm Average/Long-Term Average(STA/LTA) method and further manually checked. The P-wave signals recorded by the DAS are consistent with those recorded by the horizontal components of short-period seismometers. At shorter source-receiver distances, the picked P-wave arrivals from the DAS recording are consistent with vertical component recordings of seismometers, but they clearly lag behind the latter at greater distances.This is likely due to a combination of the signal-to-noise ratio and the polarization of the incoming wave. Then,we used the Tomo DD software to invert the 3D P-wave velocity structure for the uppermost 50 m with a resolution of 10 m. The inverted P-wave velocity structures agree well with the S-wave velocity structure previously obtained through ambient noise tomography. Our study indicates the feasibility of 3D near-surface imaging with the active source and DAS array. However, the inverted absolute velocity values at large depths may be biased due to potential time shifts between the DAS recording and seismometer at large source-receiver distances.

Source-independent wave-equation based microseismic source location using traveltime inversion

A new source location method using wave-equation based traveltime inversion is proposed to locate microseismic events accurately. With a sourceindependent strategy, microseismic events can be located independently regardless of the accuracy of the source signature and the origin time. The traveltime-residuals-based misfit function has robust performance when the velocity model is inaccurate. The new Fréchet derivatives of the misfit function with respect to source location are derived directly based on the acoustic wave equation, accounting for the influence of geometrical perturbation and spatial velocity variation. Unlike the mostly used traveltime inversion methods, no traveltime picking or ray tracing is needed.Additionally, the improved scattering-integral method is applied to reduce the computational cost. Numerical tests show the validity of the proposed method.

Microseismic observations reveal that internal waves intensify seabed methane release

Internal waves transport material and energy from the upper water column to the deep ocean, disturbing seabed sediments and resulting in phenomena such as seabed erosion and changes in topography. On the northern slope of the South China Sea and in many coastal margins worldwide, the zones with internal wave action closely overlap with areas where natural gas hydrates are present. However, due to significant differences in the spatial and temporal scales, understanding the influence of internal waves on methane releases from deep seabeds is challenging. In this study, in situ observations of seabed microseismicity and internal waves are conducted at water depths of 655 meters and 1450 meters in the Pearl River Canyon of the South China Sea. The microseismicity caused by internal waves and seabed methane releases is identified, and a method to establish the correlation between internal waves and seabed methane releases through the use of microseismic recordings is proposed, aiming to obtain direct observational evidence of internal waves intensifying seabed methane releases. The results show that internal waves and seabed methane releases generate significant microseismic signals, indicating the continuous influence of internal waves on the deep seabed of the northern slope of the South China Sea and revealing active methane release phenomena on the seabed. At both long and short time scales, internal waves increase the frequency of seabed methane releases by 4.2 times and 2.4 times, respectively, while also enhancing the intensity of these releases. These changes are influenced by the alterations in seabed flow velocity, pressure, and temperature that are induced by internal wave activities. This study emphasizes that microseismic signals are effective carriers of information for multiscale geological processes on seabeds and suggests that internal waves exacerbate marine geological hazards and contribute to global climate change by intensifying seabed methane releases.

基于Tene-cor自动聚焦成像算子的弹性波微地震逆时定位

微地震震源定位是微地震研究中的关键技术,微地震震源位置可以通过微地震信号的逆时反传来确定。在弹性介质逆时定位过程中,微地震信号中的P波、S波会耦合在一起,在震源聚焦结果中产生假象,影响震源方位的拾取。提出了基于Tene-cor聚焦成像算子的弹性波微地震逆时定位算法,首先,通过纵横波解耦的弹性波方程得到P波和S波的逆时波场,然后,施加Tene-cor成像算子对解耦的逆时波场记录进行互相关成像得到震源位置。分别利用合成数据和野外实际数据测试了该算法的定位效果。数值算例表明,该定位算法除了能够压制成像结果中因波场耦合导致的串扰噪声外,还可以聚焦因干涉成像产生的辐射状假象,在不同检波器采集条件、频带缺失和速度模型不精确的条件下,该算法相较于传统定位成像算法能够有效提高震源定位分辨率。

矿山微震震源定位精度分析

定量研究初至拾取精度和速度模型对矿山微震震源定位精度的影响直接关系到矿山开采质量评估和矿山风险预警。由于矿山微地震监测主要接收岩石破裂激发的P波,故往往采用基于P波到时的同型波时差法进行震源定位,基于数值模拟方法研究了速度模型和初至拾取精度对同型波时差法矿山微震震源定位精度的影响。结果表明:反演速度模型偏离准确速度模型的误差逐渐增大时,震源定位精度表现出降低的趋势;初至拾取精度降低时,震源定位的精度随之降低;当速度模型误差和初至拾取误差分别控制在200 m/s和10 ms以内时,同型波时差法在矿山微震震源定位中的误差整体控制在20 m以内,可以满足矿山微震质量控制和风险预警的要求。

近距离冲击地压煤层开采遗留煤柱与断层复合影响下冲击危险性研究

我国主要冲击地压矿井往往同时赋存多层可采煤层,多煤层协同安全开采是事关我国能源安全的重要课题。近距离冲击地压煤层开采时,上部煤层留设的煤柱承载了较高的上覆岩层载荷,给下部煤层开采带来了较大的风险。当遗留煤柱下发育断层时,该遗留煤柱导致的应力集中区与断层围岩附近的应力异常区产生的复合作用对工作面开采产生巨大影响。本文以陕西彬长大佛寺煤矿40201工作面为研究对象,理论分析了上煤层遗留煤柱和断层复合作用对下部冲击地压煤层开采时冲击危险性的影响,采用地震波层析成像技术和微震监测技术,分别探明了遗留煤柱和断层复合作用下工作面围岩静载荷、动载荷分布规律。研究结果表明:煤层中的断层破碎带在上覆遗留煤柱作用下产生的静载荷集中区域会向断层两盘远处转移,使得断层更易发生滑移失稳;在遗留煤柱和断层的复合作用下,工作面“见方”区域来压早于理论预测结果,且来压强度增大;工作面动载显现以遗留煤柱下区域为主,遗留煤柱的存在增大了工作面超前支承压力的影响范围。本文研究可对类似条件下的冲击地压煤层开采提供一些借鉴。

采空区覆岩波速模型及微震源定位方法

为构建煤矿小尺度区域微震波传播速度模型,提高矿井含采空区复杂地质结构内微震源定位精度。依据矿山采空区覆岩“三带”岩层变形、层面离层、层内断裂和裂隙发育以及岩体扩容等特征,构建圆弧层面波速模型,分区描述采空区覆岩波速结构。并提出采用考虑岩层变形特征的微震波绕射传播路径增量和基于时间平均方程的裂隙岩层波速折减进行波速模型修正。基于层状均匀介质假设和斯奈尔定律,推导微震波传播路径和走时计算公式,并计算各传播方向上的异向等效波速。基于到时理论定位原理,选择以实测到时差与理论走时差之差构建震源求解目标函数,采用模式搜索算法进行震源位置求解。形成了基于采空区覆岩异向波速模型的微震源定位方法。通过三维算例和煤矿地面微震监测定位应用,验证了所提方法的可行性与定位效果。研究表明:①由于煤矿地质环境中采空区遍布和微震波经由采空区传播的必然性,针对煤矿含采空区复杂地层结构特征,建立相应的异向波速模型,是提高矿山环境下微震源定位精度的关键;②采空区覆岩波速模型充分考虑了岩层形态、离层、断裂、裂隙发育和岩体扩容等对微震波传播路径和等效波速的影响,并通过定量确定微震波传播绕射路径增量和岩层波速折减,宏观表现出采空区地层结构的典型波速异向特征;③针对分层介质下的震源定位,在三维算例中选用异向等效波速模型的定位方法相较于全局平均波速模型,定位结果的平均误差由9.7558 m降至0.4186 m,有效降低了定位误差;④以矿井大能量微震事件的井下微震定位结果为参照,在现场地面微震监测中应用采空区覆岩波速模型,得出该模型定位结果较待定波速而言更接近现场调查结果中确定的煤岩体破裂影响范围。综上,对于依赖波速模型的定位方法,根据地质结构特征建立相应的异向波速模型是高效开展微震监测,提高微震源定位精度的突破点之一。

四川LZ页岩储层现今地应力方向及主控因素——以龙一段为例

现今地应力场方向是影响页岩储层压裂改造效果的主要因素之一,进行现今应力场方向展布特征及其主要影响因素分析对页岩气开发应用具有重要的意义。利用古地磁结合波速各向异性法、微地震监测法、测井资料3种方法来判别地应力方向,对LZ地区地应力方向平面展布特征及主控因素分析。结果表明:宽缓向斜处3种解释方法都适用,准确度和可信度排序为岩心实验测试、偶极横波测井、电成像测井。断裂影响区域偶极横波测井不再适用,岩心实验测试结果可信度大于电成像测井。裂缝发育强构造变形区域对3种方法解释结果均有影响,需多种方法结合分析;LZ地区龙马溪组现今最大主应力方向变化范围在90°~125°。得胜、宝藏、云锦向斜的最大主应力方向在约115°,福集向斜最大水平主应力方向偏转最大,在80°~100°,可能与西侧华蓥山断裂逆冲兼具走滑有一定关系。断裂规模越大其扰动范围和强度越大。Ⅰ、Ⅱ、Ⅲ、Ⅳ级断裂最大扰动范围分别为1100、850、500、300 m。紧闭背斜褶皱变形区,受褶皱顶部派生的拉张应力影响,地应力方向沿着褶皱轴向偏转,靠近褶皱顶部,受拉张应力影响大,偏转角度最大。研究成果可为后期水平井井位轨迹优化及压裂改造工程提供理论支撑。

基于改进支持向量机的微震初至波到时自动拾取方法

微震初至波到时拾取是实现微震震源高精度定位的重要前提。传统的人工拾取方法效率低,而自动拾取方法在低信噪比条件下难以准确拾取初至波到时。针对上述问题,提出了一种基于改进支持向量机(SVM)的微震初至波到时自动拾取方法。首先,对原始微震数据进行归一化处理、线性校正和适当裁剪,将微震数据的振幅、能量和相邻时刻的能量比作为特征对数据标记不同类别;然后采用粒子群优化(PSO)算法和网格搜索法优化SVM的惩罚参数和核函数参数,即先利用PSO算法对参数进行大范围的快速定位,得到初步最优解,再以该解为初始位置重新构建参数搜索区间,设置小步长的网格搜索法对参数进行精细搜寻,得到最优参数,并将该最优参数代入SVM模型进行训练,得到改进SVM模型;最后根据改进的SVM模型对微震数据进行分类识别,定义微震波第1个采样点对应的时刻为初至波到时。采用某矿井下微震监测数据进行实验,结果表明:该方法对微震初至波到时的拾取准确率达96.5%,平均拾取误差为3.8 ms,在低信噪比情况下仍可对微震初至波到时进行准确拾取,拾取精度高于自动拾取方法中常用的长短时窗能量比(STA/LTA)法。

基于微震在线监测的实时震源波速反演技术应用

为了提高冲击地压监测精度、监测范围和监测结果的时效性,基于微震在线监测的实时震源波速反演技术对综采工作面高应力区以及冲击危险区域进行探测。结果表明,高应力分布区域与大能量微震事件震源点位置基本一致,结合大能量微震事件发生前相应区域地音活动特征,验证了震源波速反演结果中应力集中区域与煤岩体中高应力分布区域基本吻合,实时震源波速反演对于探测煤层高应力区域分布规律具有较好的适用性,该技术可直观反馈工作区域应力场的变化。

基于横波分裂的井中微地震资料三分量波场特征分析

井中微地震压裂裂缝监测资料波场复杂,尤其当横波遇到裂缝时会分裂为偏振方向互相垂直的快、慢两种横波,而如果纵波波场与横波波场及横波分裂后的快、慢横波波场识别错误,会直接影响解释成果的准确性。为了提高井中微地震资料解释成果的准确性,在前人分析的不同裂缝尺度对快、慢横波传播速度影响的基础上,根据不同入射角与检波器三分量之间的关系,分析了纵波、横波、快横波、慢横波在三分量检波器的波场特征,得出利用横波分裂事件定位反演结果会造成压裂裂缝解释误差过大。以新平XX井微地震压裂监测资料为例,分别拾取了纵波、横波、快横波、慢横波微地震记录,通过纵、横波初至拾取的走时反演定位算法,完成了纵波+横波、快横波+慢横波、纵波+快横波+慢横波等波场的微地震定位反演。经对比发现,利用纵波+横波微地震事件定位结果判定事件方位、距离更可靠,其解释的裂缝形态更符合压裂裂缝生长规律,同时也证明了快、慢横波影响井中微地震定位反演结果。

基于小波分形特征与模式识别的矿山微震波形识别研究

在前人研究的基础之上,探讨、验证了矿山微震信号的分形特征,并根据微震信号的特征确立了相关的无标度区间及分形盒维数算法。利用矿山爆破振动、岩石破裂及电磁干扰3类信号频谱分布不同这一特征,结合小波分析与分形理论,通过MATLAB编制相应程序,对3类信号进行了5层小波包分解,求取了指定特征频带上重构信号的分形盒维数。以该盒维数为信号特征,建立23维特征向量,通过SVM支持向量机对300组矿山现场微震信号进行了训练和分类识别。研究结果表明:特征频带上的分形盒维数与信号的整体盒维数接近,表明特征频带上的分形盒维数表征了整体的分形特征;3类信号具有明显分形特征,电磁干扰信号最为明显;SVM识别网络识别微震信号,识别正确率高,但运算速度及识别效率仍有待提高。

单事件多通道微震波形的特征提取与联合识别研究

通过对矿山现场数据的处理分析,提出一种基于微震单事件的多通道联合识别方法,建立了"初步判断"、"联合识别"及"优化判断"的微震波形识别机制。对矿山微地震信号进行滤波等预处理,采用经典STA/LTA算法拾取波形的到时与终时,截取整个信号中的有效部分,并进行波形校正;建立波形的频谱特征(f)、时长(L)、振幅特征(A)、振幅分布(AD)、门限阈值特征(TS)及互相关特征(R)的定量描述方法,并求取相应的特征值;分层次对有效岩石破裂波形进行有效性判断与识别,优化选取最终定位通道。以山东某矿的一次微震事件为例对该方法进行了验证研究。结果表明,该方法能够有效提取波形的特征,并能实现对单事件多通道波形电磁干扰、底部噪声等的快速分类识别,识别精度满足现场应用需求。

华北地区地下介质波速比值(V_P/V_S)研究

文中利用分别独立反演得到的华北地区 16个台的S波和P波速度结构 ,计算了各台站下方分层速度结构各层的波速比值 ,发现在强震区的波速比总体上高于弱震区 ,且地壳中的一些低速层位会出现 >1 8的波速比值 ,而在弱震区或稳定块体内部 ,各层波速比一般都低于正常波速比 1 732 ,平均值甚至 <1 7;在过渡区域 ,如位于盆地边缘或稳定块体边缘的台站 ,其波速比值有高有低 ,一般情况下 >1 732。在此基础上 。

煤矿深部采场爆破地震波传播规律的微震原位试验研究

采用本质安全型微震监测系统,在煤矿深部采场布置了微震监测台网,对测区内的爆破波信号进行了原位采集试验。提出了地震波"穿层"和"顺层"传播的概念,得到了地震波振幅的衰减曲线和回归方程。试验结果表明,振幅随传播距离的增大呈幂级衰减;"穿层"传播的衰减速率远大于"顺层"传播;地震波"穿层"传播200 m后,振幅损失严重,初始到时点开始模糊,需对到时进行补偿后方可参与震源定位。该结果进一步证实了该监测台网布置的合理性(测点平均间距60 m)。微震监测和音频电透视结果证明,岩体破裂区和富集水区的存在加速了波的衰减。这些定性和定量的研究结论将为进一步研究微震监测台网布置的优化方案提供理论依据,也可为其他地球物理监测或探测手段提供实测的基础参数。

地震波传播速度原位试验及计算

采用本质安全型微震监测系统,在煤矿深部采场的顶底板中布设微震监测台网,对测区内的校验炮微震信号进行了原位采集实验。分别采用组合法、走时残差优化法、定位误差优化法、定位残差优化法和联合反演法进行了地震波速度的优化计算。通过计算结果的对比分析,认为定位误差优化法计算结果最可靠,定位残差优化法计算结果是不可靠的;这一结论对于缺少校验数据情况下的速度选取具有重要意义,也证明了在存在速度误差的情况下,走时残差最小并不能保证可靠的定位精度;在缺少原位试验数据情况下,速度和震源参数的联合反演结果,对速度参数的选取具有重要意义。通过对顶、底板地震波传播速度分析计算,认为煤层和巷道是造成底板地震波平均速度较低的原因。

微震波自动拾取与多通道联合定位优化

依托河北某煤矿的科研项目,进行了以微震波初始到时自动拾取和高精度定位为目的的研究。在采用经验模态分解(EMD)法消噪、滤波的前提下,通过改进传统滑动时窗能量法,加入边界检测因子和稳定因子约束,实现对"起跳模糊、起跳不干脆以及背景干扰过大"波形到时的准确拾取。建立多通道内微震波的联合识别体系,提出利用"到时-振幅"与"时-距差速度"判断法剔除异常波形,拾取有效微震事件。现场监测数据验证表明,以改进滑动时窗能量法拾取初始到时,可有效拾取到时不清晰波形的到时,减少因人工拾取带来的误差;通过多通道内波形的联合识别、定位,削弱"远波先至"、"到时紊乱"等异常事件的干扰,实现了对震源的高精度定位。

微地震波在煤矿岩层中的传播特征研究

在塔山矿8103工作面微地震监测中,测到距离震源远的底板孔检波器比距离震源近的顶板孔检波器先接收到微地震波的异常现象。研究表明,微地震波的直达波和透射直达波两种传播模式是造成这一异常现象的主要原因。在性质相近的介质中,微地震波是按直达波模式传播,现场监测到的"顶板断裂产生震动波—顶板—顶板检波器"的路径是典型的"直达"传播模式。而在性质差异较大介质的界面处,微地震波在入射界面上的入射点将形成新的震源点,并以新震源点为起始点,再按直达波模式传播,从而形成"透射–直达"传播模式,现场监测到的"顶板断裂产生震动波—综放支架—底板—底板检波器"的路径是典型的"透射–直达"传播模式,这是造成微地震监测中"远点先达"现象的重要原因。根据微地震波在煤矿岩层中的传播特征可以确定合理的定位方法和验证震源定位的准确性。实践证明,在性质差异较大的介质中定位震源时,需将性质相近介质中的检波器信号放在一起定位,这样可以减弱"透射–直达"传播模式造成"远点先达"现象的影响,提高定位精度。