共查询到18条相似文献,搜索用时 140 毫秒
1.
对煤巷小构造地震波场进行了数值模拟研究,分析了层状煤层中地震波的传播特征.研究表明:(1)在煤巷迎头前方煤层内以纵波震源激发的Rayleigh型槽波相对于体波能量较强,波列较长,波速较低.(2)沿煤层传播的Rayleigh型槽波在小构造面上产生Rayleigh型槽波反射波,反射Rayleigh型槽波垂直分量相对于水平分量能量较强.沿煤层反向传播的反射Rayleigh型槽波在煤巷迎头面上转换为沿煤巷底板传播的Rayleigh面波.沿煤巷底板可以接收到能量较强的反射Rayleigh型槽波产生的Rayleigh面波,其可以作为超前探测小构造面的特征波.在地震记录上反射Rayleigh型槽波产生的Rayleigh面波波至最迟,在时间域与其他波列时间间隔较大,其垂直分量能量相对于水平分量较强,在地震记录上容易识别.(3)在相同的地质条件下应用反射地震超前探测方法,标志煤巷迎头前方存在小构造面的反射地震波能量较弱,受煤巷顶、底板界面和采煤迎头面的强反射波干扰,在地震记录中难以识别. 相似文献
2.
井下槽波地震勘探——预防煤矿灾害的一种地球物理方法 总被引:3,自引:0,他引:3
当在煤层中激发地震波时,由于顶、底板围岩速度明显高于煤层中地震波的传播速度,当地震波入射角大于临界角时会发生全反射,经过多次全反射混合叠加,在煤层中形成槽波.槽波是一种围限波,它最大的特点是频散现象,槽波在煤层中传播时还具有速度低、衰减弱等特点,因此可以用来探测煤层中的采空区、断层等地质构造.本文初步阐述了槽波地震勘探技术的研究现状,槽波的形成,槽波的特点、槽波地震勘探的工作方法以及应用实例等内容,并基于其特点对槽波地震勘探技术作出了展望. 相似文献
3.
《应用地球物理》2016,(4)
当前煤巷地震槽波超前探测数值模拟主要以二维波场研究为主,难以精确模拟三维全波场特征和全空间观测方式接收的地震记录。本文应用三维弹性波动方程的交错网格有限差分算法模拟了在巷道迎头前方煤层中以纵波震源激发的三维全波场。采用取平均值的办法实现了交错网格地震波场模拟的振动速度三分量同点记录。查明了三维顶底板对称煤巷模型和非对称模型中传播的波型及其传播特征。研究发现巷道迎头前方煤层内Rayleigh型槽波能量较强,Love型槽波能量较弱,煤层内巷道迎头反射Rayleigh型槽波在煤层顶、底板中泄露能量较小,在煤层中传播距离较远;在巷道周围存在巷道面波和折射头波;在煤巷两侧煤层内接收的地震记录中Rayleigh型槽波能量较强,受头波和面波的干扰较弱,而Love型槽波能量较弱,受到相对强能量头波和面波干扰,难以识别;增加接收点在煤层中的深度可以有效降低面波对Rayleigh型槽波的干扰,但不能有效减弱面波对Love型槽波的干扰。基于以上波场认识,发现传统的采煤工作面Love型槽波构造探测方法难以适用于掘进煤巷构造超前探测,Rayleigh型槽波可以用于掘进煤巷构造超前探测。 相似文献
4.
本文提出解调包络方法来重构地震记录中缺失的低频信号,同时该方法能够降低全波形反演的非线性程度;提出伴随状态震源函数反演方法来得到精确的震源函数,并推导了梯度计算公式;解调包络方法结合低通滤波技术,实现了从低频到高频的多尺度反演策略,有效缓解了全波形反演的周波跳跃问题.数值算例证明了解调包络、伴随状态震源函数反演方法和低通滤波多尺度反演策略的可行性及优越性.震源函数反演精度测试结果表明:即使观测记录在缺失低频信息的情况下,也能反演得到精确的震源函数.缺失低频测试和抗噪能力测试结果表明:即使地震数据中缺失9Hz以下的低频信号或者信噪比极低的情况下,利用反演得到的精确震源函数进行解调包络多尺度全波形反演,同样可以得到高精度的全波形反演结果.与Hilbert包络全波形反演对比结果表明:解调包络在重构低频和降低伴随震源主频方面具有一定优势. 相似文献
5.
《地球物理学进展》2017,(6)
近年来透射法槽波地震勘探技术在煤矿勘探领域取得广泛应用,该技术依据槽波频散特征,对特定频率下槽波走时进行层析速度反演成像,在煤层厚度探测方面效果明显.由于煤矿巷道施工的特殊性,震源和检波器布置在巷帮煤层中,观测系统多采用两边式或三边式,导致槽波传播角度有限,容易对层析成像造成误差.在层析正演中采用最短路径与射线弯曲法联合,兼顾走时计算的精度和效率,在层析反演中进行正则化约束,利用平滑和阻尼因子提高算法的精度.通过对大量模型进行正反演发现,当煤层中存在垂直巷道异常体或局部异常体时,透射槽波层析反演不存在假象;当存在平行巷道的条带异常体时,层析结果出现交叉状速度异常假象.这是由于透射槽波采集得到的走时不受异常体位置影响,高值区在平面上表现为交叉型,导致层析反演出现假象.实际勘探施工条件允许情况下,可在煤层工作面四周布置震源和检波器消除这类假象. 相似文献
6.
多煤层的反射地震响应特性研究 总被引:1,自引:1,他引:0
本文在不考虑地震波吸收和几何扩散衰减的情况下,利用单频谐和平面纵波垂直入射到煤层上,来研究煤层的调频效应,正演模拟地震波的频率与反射系数的关系,分析了频率对反射系数的影响.研究表明:当地下只有一组煤时,在中高频段煤层反射系数较大,当存在两组煤或是更多组煤层时,受上组煤层的屏蔽,下组煤在低频段的反射系数明显大于中高频段的反射系数,从而为克服上组煤层的屏蔽,得到好的下组煤层反射波提供了理论基础.在此基础上提出了提高下组煤反射波质量的采集方案.由于历史的原因,煤田勘探一般使用中高频检波器(主频60 Hz或是100 Hz),虽然有利于提高中高频反射波的能量,但牺牲了信号的低频部分,不利于提高反射波的分辨率,同时损失了下组煤层中起主要作用的低频反射波,得到的下组煤反射波资料一般很差. 相似文献
7.
本文提出非稳态相位校正时频域目标函数,通过缩小观测数据与模拟数据在波形相位上的差异来缓解全波形反演过程中对应波形匹配错位的问题(周波跳跃).同时引入自适应相位校正因子,可以根据观测数据与模拟数据的差异来调整相位校正量的大小.在构建非稳态相位校正时频域全波形反演目标函数的基础上,利用链式法则详细推导了对应的伴随震源,并从理论上证明了该方法的可行性与优越性.数值测试过程中结合了低通滤波多尺度反演策略,进一步缓解全波形反演过程中的强非线性问题.缺失低频分量测试结果表明,利用自适应非稳态相位校正时频域多尺度全波形反演方法结合常规全波形反演方法在缺失7 Hz以下低频分量的地震数据中仍然能够得到高精度的反演结果.震源不准确测试结果表明,即使震源子波相位差异较大,利用非稳态相位校正方法仍然能够一定程度上缓解周波跳跃现象.测试结果综合证明了本文提出的方法在构建初始速度建模,缓解周波跳跃等方面具有一定的优势. 相似文献
8.
《应用地球物理》2019,(3)
时频电磁法勘探系统兼有频率测深与瞬变电磁测深系统双重特点,可同时在频率域和时间域求取视电阻率,从而获得更加准确可信的地电信息。实测时频电磁勘探数据中的主要噪声有50 Hz工频及其谐波干扰噪声、高频随机脉冲噪声以及低频干扰噪声三种类型,本文针对这些噪声类型以及时频电磁法的方波信号特点,提出分段拓展中值滤波方法和拟合固定极值点EMD方法分别去除高频随机脉冲噪声和低频干扰噪声,提出基于方差和偏度系数的中值滤波窗口大小试验选取方法,采用频域带阻滤波方法去除50 Hz工频及其谐波干扰噪声。并设计了一个相应的去噪流程,以充分发挥各自的去噪方法的优势。经理论分析以及实际观测数据的应用实验验证,本文提出的去噪方法和设计的去噪处理流程合理有效,准确保留了时域信号波形的相位和幅值信息,得到令人满意的高质量时域信号波形,为准确地提取时域瞬变电磁衰减信号打下良好的基础。 相似文献
9.
本文使用炮并行和区域分解(物理上分割模型,使用基于MPI的分布式存储架构的计算集群,节约单个CPU内核的内存使用量,快速进行正演数值模拟)两种并行算法.该方法的每一步迭代都能确保近似海森矩阵的正定,因此,算法稳健.将时间正向传播的炮波场和反向逆时间传播的残差波场(伴随波场)进行零延迟互相关计算,得到误差泛函的梯度,然后对梯度乘以一个预条件算子,从而加快反演的收敛速度.通过抛物线搜索方法而估计步长,使用L-BFGS算法(限定内存的BFGS算法)求解模型的更新量,进行二维时间空间域弹性波全波形反演.将该反演方法应用到Marmousi2弹性波理论模型,分别反演Marmousi2理论模型的纵波速度、横波速度以及密度等三个参数.我们分别使用截止频率为2 Hz、5 Hz、10 Hz和20 Hz四个阶段的低通巴特沃斯滤波器,采用多尺度的策略,从理论模型数据的低频分量开始反演,将低频分量的反演结果作为高频分量反演时的初始模型,然后依次反演数据的高频分量.理论模型数值试验反演所得到的结果证实:二维时间空间域弹性波全波形反演计算灵活,适用于各种观测系统,能够方便地对地震数据进行加时窗;二维时间空间域弹性波全波形反演所得纵波速度模型的分辨率最高,横波速度模型的分辨率次之,密度模型的分辨率稍微差些. 相似文献
10.
针对地震槽波在低速层的传播特性,开展了煤层内地震槽波勘探的数值模拟和物理模拟研究的初探工作.在数值模拟研究方面,采用交错网格有限差分法对煤层中的地震槽波进行三分量全波场模拟.基于波场快照和人工合成地震记录研究了不同模型中的波场特征和各种波型的传播规律.在物理模拟方面,通过选用不同配比的环氧树脂和硅橡胶类材料构建地震槽波物理模型,利用透射法和反射法观测系统获得了清晰的地震槽波记录以研究槽波的地震学特征.研究表明,在煤层内槽波的地震波场中,Love型槽波的能量小于Rayleigh型槽波的SV分量,大于Rayleigh型槽波的SH分量.相对于Love型槽波和Rayleigh型槽波的SH分量,Rayleigh型槽波的SV分量在围岩中的泄露能量较强.在煤层界面附近的围岩中,地震波仍以槽波形式传播,随着距离的增加能量逐渐衰减.随着煤层变薄,煤层槽波主频向高频方向移动,频散现象增强,传播速度增大. 相似文献
11.
In-seam seismic survey currently is a hot geophysical exploration technology used for the prediction of coal seam thickness in China. Many studies have investigated the relationship between the group velocity of channel wave at certain frequency and the actual thickness of exposed coal beds. But these results are based on statistics and not universally applicable to predict the thickness of coal seams. In this study, we first theoretically analyzed the relationship between the depth and energy distribution of multi-order Love-type channel waves and found that when the channel wave wavelength is smaller than the thickness of the coal seam, the energy is more concentrated, while when the wavelength is greater than the thickness, the energy reduces linearly. We then utilized the numerical simulation technology to obtain the signal of the simulated Love-type channel wave, analyzed its frequency dispersion, and calculated the theoretical dispersion curves. The results showed that the dispersion characteristics of the channel wave are closely related to the thickness of coal seam, and the shear wave velocity of the coal seam and its surrounding rocks. In addition, we for the first time realized the joint inversion of multi-order Love-type channel waves based on the genetic algorithm and inversely calculated the velocities of shear wave in both coal seam and its surrounding rocks and the thickness of the coal seam. In addition, we found the group velocity dispersion curve of the single-channel transmitted channel wave using the time–frequency analysis and obtained the phase velocity dispersion curve based on the mathematical relationship between the group and phase velocities. Moreover, we employed the phase velocity dispersion curve to complete the inversion of the above method and obtain the predicted coal seam thickness. By comparing the geological sketch of the coal mining face, we found that the predicted coal seam thickness is in good agreement with the actual thickness. Overall, adopting the channel wave inversion method that creatively uses the complete dispersion curve can obtain the shear wave velocities of the coal and its surrounding rocks, and analyzing the depth of the abruptly changed shear wave velocity can accurately obtain the thickness of the coal seam. Therefore, our study proved that this inversion method is feasible to be used in both simulation experiments and actual detection. 相似文献
12.
煤层内裂隙较为发育,具有明显的各向异性.目前槽波理论研究以各向同性介质为主,对HTI介质中槽波及其频散性质研究很少.本文以弱各向异性、含垂直裂隙HTI煤层介质为研究对象,研究了HTI煤层介质中的三维槽波波场,采用交错网格高阶有限差分法模拟槽波,推导了三层水平层状HTI煤层介质的Love型槽波理论频散公式和振幅深度分布,分析了HTI各弹性参数对频散曲线的影响.HTI介质和各向同性介质基阶Love槽波频散曲线差异较小,高阶较大;煤厚主要影响Airy相频率,而Airy相速度不变;煤层vs对Airy相速度影响很大;煤层γ对基阶Love槽波影响很小,高阶稍大.各波偏振方向不再与波的传播方向平行或垂直,而是呈一定夹角.利用基阶Love槽波频散曲线推测裂隙发育较为困难,可利用高阶频散曲线. 相似文献
13.
Finite‐difference P‐SV simulations of seismic scattering characteristics of faulted coal‐seam models have been undertaken for near‐surface P‐ and S‐wave sources in an attempt to understand the efficiency of body‐wave to channel‐wave mode conversion and how it depends on the elastic parameters of the structure. The synthetic seismograms clearly show the groups of channel waves generated at the fault: one by the downgoing P‐wave and the other by the downgoing S‐wave. These modes travel horizontally in the seam at velocities less than the S‐wavespeed of the rock. A strong Airy phase is generated for the fundamental mode. The velocity contrast between the coal and the host rock is a more important parameter than the density contrast in controlling the amplitude of the channel waves. The optimal coupling from body‐wave energy to channel‐wave energy occurs at a velocity contrast of 1.5. Strong guided waves are produced by the incident S‐sources for source angles of 75° to 90° (close to the near‐side face of the fault). As the fault throw increases, the amplitude of the channel wave also increases. The presence of a lower‐velocity clay layer within the coal‐seam sequence affects the waveguiding characteristics. The displacement amplitude distribution is shifted more towards the lower‐wavespeed layer. The presence of a ‘washout’ zone or a brecciated zone surrounding the fault also results in greater forward scattering and channel‐wave capture by the coal seam. 相似文献
14.
在地下煤田的开发中,工作面内的小构造、异常体、煤层厚度变化等是需要解决的关键问题,而槽波探测则为这些问题的解决提供了重要的物探方法.本文对河南义马矿区11061工作面进行槽波透射法测量,在巷道显示的煤层厚度变化为1.5~8 m,从理论频散曲线分析速度与厚度关系,确定125 Hz频率槽波主要用于观测厚度约为2~5 m的煤层厚度变化;有效提取了684个频散曲线,并分别拾取了125 Hz时槽波群速度与走时,采用走时层析成像方法获得工作面内煤层速度、厚度以及高应力区分布特征,回采验证了结果的正确性. 相似文献
15.
We present dispersion curves, and amplitude-depth distributions of the fundamental and first higher mode of Love seam waves for two characteristic seam models. The first model consists of four layers, representing a coal seam underlain by a root clay of variable thickness. The second model consists of five layers, representing coal seams containing a dirt band with variable position and thickness. The simple three-layer model is used for reference. It is shown that at higher frequencies, depending on the thickness of the root clay and the dirt band, the coal layers alone act as a wave guide, whereas at low frequencies all layers act together as a channel. Depending on the thickness, and position of the dirt band and the root clay, in the dispersion curves of the group velocity, secondary minima grow in addition to the absolute minima. Furthermore, the dispersion curves of the group velocity of the two modes can overlap. In all these cases, wave groups in addition to the Airy phase of the fundamental mode (propagating with minimum group velocity) occur on the seismograms recorded in in-seam seismic surveys, thus impeding their interpretation. Hence, we suggest the estimation of the dispersion characteristics of Love seam waves in coal seams under investigation preceding actual field surveys. All numerical calculations were performed using a fast and stable phase recursion algorithm. 相似文献
16.
Bao-Li Wang 《应用地球物理》2018,15(1):118-124
Accurately detecting the arrival time of a channel wave in a coal seam is very important for in-seam seismic data processing. The arrival time greatly affects the accuracy of the channel wave inversion and the computed tomography (CT) result. However, because the signal-to-noise ratio of in-seam seismic data is reduced by the long wavelength and strong frequency dispersion, accurately timing the arrival of channel waves is extremely difficult. For this purpose, we propose a method that automatically picks up the arrival time of channel waves based on multi-channel constraints. We first estimate the Jaccard similarity coefficient of two ray paths, then apply it as a weight coefficient for stacking the multichannel dispersion spectra. The reasonableness and effectiveness of the proposed method is verified in an actual data application. Most importantly, the method increases the degree of automation and the pickup precision of the channel-wave arrival time. 相似文献
17.
D. J. BUCHANAN 《Geophysical Prospecting》1978,26(1):16-28
The problem of detecting discontinuities which interrupt coal seams is of great importance to the coal mining industry. One possible method of detecting such discontinuities is that of in-seam seismology where both source and detectors are placed under- ground on the coal face. In this paper the propagation of SH waves from a line source in the seam is investigated. There exists a particular set of waves–channel waves–, confined to the coal seam. These waves are dispersive and have an associated Airy phase whose geometrical attenuation is least. However, if absorption of energy within the coal is included then the Airy phase is the dominant wavegroup only for distances less than a certain maximum. If a detection criterion proposed by Dresen and Freystätter applies, then there is a lower limit to the frequency that should be used for exploration. This requirement may be in conflict with attenuation considerations. 相似文献
18.
Numerical simulations of full-wave fields and analysis of channel wave characteristics in 3-D coal mine roadway models 总被引:2,自引:0,他引:2
Currently, numerical simulations of seismic channel waves for the advance detection of geological structures in coal mine roadways focus mainly on modeling twodimensional wave fields and therefore cannot accurately simulate three-dimensional (3-D) full-wave fields or seismic records in a full-space observation system. In this study, we use the first-order velocity–stress staggered-grid finite difference algorithm to simulate 3-D full-wave fields with P-wave sources in front of coal mine roadways. We determine the three components of velocity Vx, Vy, and Vz for the same node in 3-D staggered-grid finite difference models by calculating the average value of Vy, and Vz of the nodes around the same node. We ascertain the wave patterns and their propagation characteristics in both symmetrical and asymmetric coal mine roadway models. Our simulation results indicate that the Rayleigh channel wave is stronger than the Love channel wave in front of the roadway face. The reflected Rayleigh waves from the roadway face are concentrated in the coal seam, release less energy to the roof and floor, and propagate for a longer distance. There are surface waves and refraction head waves around the roadway. In the seismic records, the Rayleigh wave energy is stronger than that of the Love channel wave along coal walls of the roadway, and the interference of the head waves and surface waves with the Rayleigh channel wave is weaker than with the Love channel wave. It is thus difficult to identify the Love channel wave in the seismic records. Increasing the depth of the receivers in the coal walls can effectively weaken the interference of surface waves with the Rayleigh channel wave, but cannot weaken the interference of surface waves with the Love channel wave. Our research results also suggest that the Love channel wave, which is often used to detect geological structures in coal mine stopes, is not suitable for detecting geological structures in front of coal mine roadways. Instead, the Rayleigh channel wave can be used for the advance detection of geological structures in coal mine roadways. 相似文献