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1.
速度、加速度检波器及其获取信息的研究(英文) 总被引:1,自引:0,他引:1
本文从两种类型的地震检波器(10hz动圈式速度检波器和压电加速度检波器)及其检测介质的两种运动动参数(速度和加速度)入手,测试和对比分析了它们的频率响应函数,指出了二者的差异。又对两种检波器进行了冲击振动试验和结果对比,分析了其响应信号的特征和携带信息的能力。并于某地区在可比条件下进行了地震数据采集对比试验,对用两种检波器采集得到的单炮资料和叠加时间剖面进行了对比分析。结果表明,加速度信号更能满足当前和今后地震勘探对地震信号的高信噪比、高精度、高分辨率和大信息量的要求。 相似文献
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在石油勘探中,动圈式速度型检波器以及MEMS加速度型检波器是当前野外采集施工中应用最为广泛的两类检波器.两类检波器采集数据的信噪比存在差异,往往前者较后者稍高.作者在分析了两种典型检波器工作原理、野外采集阶段有效信号与噪声的比较特征以及不同信噪比计算方法的基础上,模拟、分析了两种典型检波器数据信噪比存在较大差异的表现以及原因.认为地震数据用加速度表征后,时域的视觉信噪比降低了,但是数据所代表机械振动中信号与噪声的物理能量对比并没有随着表征量纲的差异而改变;也就是说,数据背后的“物理信噪比”并没有改变-无论采用何种量纲进行表征.加速度表征地震数据的视觉信噪比降低是由于地震信号的低频端较高频端具有更高的“物理信噪比”导致的.速度、加速度两种类型检波器的信噪比比较应该在同一个域内进行. 相似文献
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采用数值仿真的方法建立了动圈式检波器的仿真模型,推导检波器传递函数,通过对实际动圈式检波器频率特性的测试,验证了动圈式检波器数值仿真模型的正确性,分析动圈检波器频率响应特性,分别对动圈式检波器的自然频率、灵敏度、阻尼比进行仿真,对不同自然频率、灵敏度、阻尼比对检波器输出频率特性的影响进行了分析,使用二阶二次型反馈补偿方法,设计检波器低频补偿结构,结果表明:数值仿真模型与实际检波器的频率响应一致,补偿结构使检波器自然频率由2 Hz降低至0.2 Hz. 相似文献
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本文分析了海陆两栖地带地震勘探中同时使 用的速度检波器和加速度检波器存在的差异及其对 地震信号的影响;在此基础上,设计研制出了陆用 压电检波器,并对其性能特点进行了分析;通过试 验资料分析,消除了海陆两种不同机理的检波器资 料的相位差的问题,陆用压电检波器和水中压电检 波器记录信号的频带和能量达到一致,提高了地震 资料的分辨率;实现了海陆地区可以同时采用相同 机理的检波器进行地震信号的接收,解决了滩海地 区速度检波器和加速度检波器长期混用的问题。 相似文献
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光纤光栅地震检波器结构设计与性能仿真研究 总被引:3,自引:0,他引:3
地震检波器是近年来石油勘探领域向前发展的一项瓶颈技术。本文基于光纤光栅的传感特性设计了不同结构的光纤光栅地震检波器,借助于有限元分析软件对光纤光栅地震检波器的传感特性进行了仿真研究,并分析了一些重要参数如光纤光栅波长、质量块的大小和光纤的长度等对地震检波器性能的影响规律,给出了不同结构的特性参数。本文研究结果对光纤光栅地震检波器的实用有一定的参考价值。 相似文献
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《地球物理学进展》2020,(4)
川南地区重要产气层之一的震旦系灯影组埋深约9000 m,以往多期地震勘探未能取得高品质资料,原因之一就是灯影组反射信息频率较低,而常规检波器(六串两并20DX-10 Hz速度型检波器)在低频段衰减严重,未能完整接收到地震反射信息.为得到深层高品质的资料,在川南赤水地区开展了不同类型检波器试验研究工作,首先研究了3种检波器(20 DX-10 Hz速度型检波器、自然频率5 Hz速度型检波器、单点陆用压电加速度检波器)的幅频特征,分析了不同检波器对低频信号接收能力的差异;对比测试了3种检波器对主频为25 Hz的雷克子波的波形、频率响应;结合实际地震资料,分析了加速度型检波器的实际地震资料在加速度域和速度域的频率特征;最后将加速度检波器地震资料转换至速度域,与其他两种速度型检波器地震资料对比分析得到以下认识:(1)加速度检波器具有宽频带特性,对提高分辨率较为有利,适用于勘探目的层相对较浅地区的高分辨率勘探.(2)加速度检波器地震资料在加速度域、速度域两种不同域的资料差别较大,前者积分转换虽然提高了低频段响应但频带变窄,不利于提高分辨率,生产中使用原始域数据更为合适.(3)野外实际资料表明,低频速度型检波器在保持常规20DX-10 Hz的勘探效果的基础上提高了低频段的响应,与加速度检波器转域后的低频效果接近,频带比加速度检波器转域后要宽,更加适合超深层地震勘探. 相似文献
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滩浅海两栖地区油气地震勘探激发接收技术研究 总被引:6,自引:2,他引:4
针对海陆两栖地区地震勘探激发、接收中存在的问题,通过改造炸药震源的装药结构和起爆方式,研制出了一种新型激发震源,提高了激发信号的品质,减小了与气枪震源之闻的信号差异;在接收技术上,研制了新型压电检波器以代替常规的沼泽机电检波器,提高了接收地震信号的频率,实现了水陆相同感应机理的检波器同时接收地震信号,消除了两种不同检波器造成的信号差异;通过对两种新技术的试验分析,认为明显提高了地震资料的分辨率和信噪比,促进了海陆两栖地区地震勘探技术的发展. 相似文献
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数字检波器是近年来发展起来的一种新型检波装置.为了对比数字检波器与普通模拟检波器的差别,我们选择数字检波器DSU3与模拟检波器20 dx进行了一个针对性的野外试验.从试验结果上来看,二者主要存在四个方面的差异.通过分析差异的原因,我们认为模拟检波经过多年的应用,从理论认识到实践操作都非常成熟,但是存在容易受到电磁干扰、信号串音、漏电等现象;同时,即使经过‘类检波器反褶积’后,模拟检波器仍然难以补偿数据的‘极低频’部分;模拟检波器的灵敏度有待于进一步提高,以便降低电噪声在全部信号中所占的比例,提高信噪比;数字检波器确实在电学指标方面取得了一些进步,尤其在灵敏度、线性畸变、线性频带范围、适量保真度等方面;但是,数字检波器在耦合效应,一致性、稳定性或者抗干扰能力均存在一些问题.同时,在石油勘探中‘强噪音’以及‘多次覆盖’的双重背景下,受当前处理能力的限制,检波器电学性能方面的‘极高指标’,并不能保证地震数据的‘极高质量’.我们的研究表明:使检波器更小、更轻、更好耦合的努力与电学指标的改进具有同等重要的意义;具有良好的电学性能,更好的耦合参数,稳定性好,耐用,价格合理的检波器是我们追求的目标. 相似文献
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在地震勘探中,P波和S波入射到一固体液体分界面处时,在该分界处的水平检波器和垂直检波器将接受到相位的响应垂直的响应。垂直检波器的响应与在自由界面处的垂直检波器 响应大概相同,而水平检波器对P波的响应相对于对S波的 来说要强。 相似文献
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M. H. SAFAR 《Geophysical Prospecting》1978,26(3):538-549
It is well known that the application of the “bright spot’ technique has been more successful in marine prospecting than in land prospecting. This is due partly to the problem of distortion of the seismic signal caused by the geophone-ground coupling, especially when carrying out high resolution, shallow seismic surveys in swampy terrain. The effect of geophone-ground coupling on the response of a single geophone to the incident compressional waves has been treated by several authors. However, they have always neglected the influence of mutual interaction between an array of geophones on the response of each geophone forming the array. We show that mutual interaction, which results from the re-radiation of the incident compressional waves by the geophones forming the array, can have considerable effect on the response of each geophone. The effect of the geophone-ground coupling on the response of a seismic channel is considered in the absence and presence of mutual interaction between a group of geophones for the case when the shear wave velocity of the soil varies by a factor of three. 相似文献
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For seismic observations in mines or wells, instead of three-component geophones, four-component ones with sensors located along the tetrahedral axes are sometimes used. When a geophone is placed in a hard-to-reach area for a long time, the requirements on its reliability increase, so it is necessary to monitor its operation. From this viewpoint, a four-component geophone has certain advantages over the conventional three-component geophone, the three ones being suppression of instrument noise for the recalculation of a four-component record into a three-component one, saving of the polarization analysis data in case one geophone component fails, and sensitivity control of individual geophone components. To suppress instrument noise in records from a four-component geophone, the following processing should be performed: first, calculation of the covariance matrix of recording components, second calculation of the eigenvalues and eigenvectors of the covariance matrix, and third, the parameter used to assess the ratio of instrument noise to the useful signal is calculated. After that, the operator projecting a four-component displacement vector onto a three-dimensional subspace is constructed. Application of this operator to data suppresses interference or noise (which do not correspond to motion in three-dimensional space). The output of the processing is data partially cleaned of instrument noise. In this paper, using model examples, we analyze the features of processing data from four-component geophones. The possibility of suppressing instrument noise and controlling the sensitivities of individual geophone components is demonstrated, and the effect on polarization analysis results is shown. 相似文献
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In recent years some authors have given a certain amount of attention to towed seismic reflection acquisition systems. Based on some of these works we sought to design and test a system making use of currently available geophones instead of specifically designed sensors as employed in some previous works. Thus, bearing in mind that the geophone's characteristics are achieved in the conditions that they are originally designed to be employed in, i.e., coupled with a spike driven into the ground, we devoted our attention to some of the variables involved in the geophone's performance, namely the total weight, the effect of a spikeless geophone and the surfaces on which the geophone is placed. Previously, we had experimentally verified some variations in the signal response due to coupling geophones in different surface materials, such as hard soil, asphalt and concrete pavement and we noticed that these surface materials were in fact an important factor in the overall response. Hence, these materials, or as we also called them coupling agents, could be employed as a base material in the construction of a mobile seismic acquisition device composed of blocks of a certain size, on which the geophone would be then inserted and thus making it into a spikeless surface towable system. Therefore, various materials were tested in order to select one that could maintain a similar fidelity to that of the spike coupled geophone and thus contribute towards building a more time efficient and towable geophone and block system. Pinging tests revealed variations in the coupling frequency and damping characteristics of each coupling agent and from all of these tested materials one was selected for field comparative tests with the normally planted geophones with spike coupling. Finally a seismic reflection profile was acquired simultaneously with both systems, i.e., spike coupling versus cement block coupled geophones. This field test showed similar results in terms of signal levels and frequency content and therefore it was possible to observe the presence of the same reflectors and other seismic events in either of the time sections. With this experiment we propose not only a system that allows a time efficient seismic field operation but we also aim to encourage more research into the response dependency of the coupling agent of which the towable base block is made of. 相似文献
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In this paper, we review the differences between velocity geophones (VG) and acceleration geophones (AG) and their effect on seismic signals acquired in onshore-offshore transition areas. We present a new generation of Land Piezoelectric Geophone (LPG) and analyze its performance. Our field experiments demonstrate that our new LPG can be used to substitute for VGs in order to eliminate phase, frequency and energy differences between different geophone systems commonlv used in transition areas. 相似文献
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Previously ignored characteristics of the seismic recording instrument are presently experienced as limitations as more sophisticated interpretive methods using wider frequency ranges are developed to extract stratigraphic information from seismic land data for hydrocarbon and mineral exploration. Most of these limitations arise from inadequate characteristics of the first element of the seismic instrument: the geophone. A geophone does not faithfully follow the motion of the earth for higher frequencies due to poor geophone-earth coupling. This filtering effect brings about time shifts that are dependent on the frequency and the soil type. A geophone can also produce spurious outputs, brought about by the motion of the suspended part of the geophone, with a magnitude comparable to that of the desired output. The suspension is made very compliant to obtain the required sensitivity. A compliant suspension, however, gives a large sag. The geophone can therefore only be used in one position, tolerating little tilt. A compliant suspension also widens the traveling range of the movable part. Minor sensitivity changes with travel are then noticeable as nonlinearity, since the surface wave is large with respect to the reflected wave. A compliant suspension is usually realized in the form of thin, spirally shaped spring-spiders. Such suspensions exhibit transverse or rotational resonances that are in or close to the seismic frequency band. Excited by ground roll, they can produce considerable undesirable output. The novel geophone we describe is a light-weight (17 g) acceleration-sensitive transducer which gives good ground coupling and partial correction for the increasing damping in the earth with increasing frequencies. It employs internal hybrid electronics for a magnetodynamic velocity-nulling feedback system. Velocity nulling makes the movable part of the geophone virtually rigid with respect to the housing. This makes the geophone characteristics independent of the suspension. The springs used are stiff in a transverse and rotational direction so that the suspension resonances are well outside the useful frequency band. This suspension also allows the geophone to be used in any orientation while being only sensitive to the vibration component along the main axis. The feedback system makes the sensitivity flat within 1 dB from 2 Hz to 500 Hz, with a phase tolerance smaller than 5°. The geophone is robust, has no moving internal wires, employs a current output [sensitivity 1 mA/(m s?2)] and internal gain so that the signal-to-cable-noise ratio is improved. This type of output allows parallel connection without any interaction between the geophones. 相似文献
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By summing geophone and hydrophone data with opposite polarity responses to water layer reverberation, the ocean bottom cable dual-sensor acquisition technique can effectively eliminate reverberation, broaden the frequency bandwidth, and improve both the resolution and fidelity of the seismic data. It is thus widely used in industry. However, it is difficult to ensure good coupling of the geophones with the seabed because of the impact of ocean flow, seafloor topography, and field operations; therefore, geophone data are seriously affected by the transfer function of the geophone-seabed coupling system. As a result, geophone data frequently have low signal-to-noise ratios (S/N), which causes large differences in amplitude, frequency, and phases between geophone and hydrophone data that severely affect dual-sensor summation. In contrast, the hydrophone detects changes in brine pressure and has no coupling issues with the seabed; thus, hydrophone data always have good S/N. First, in this paper, the mathematical expression of the transfer function between geophone and seabed is presented. Second, the transfer function of the geophone-seabed is estimated using hydrophone data as reference traces, and finally, the coupling correction based on the estimated transfer function is implemented. Using this processing, the amplitude and phase differences between geophone and hydrophone data are removed, and the S/N of the geophone data are improved. Synthetic and real data examples then show that our method is feasible and practical. 相似文献
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We introduce a method to detect and compensate for inconsistent coupling conditions that arise during onshore seismic data acquisitions. The reflected seismic signals, the surface waves, or the ambient-noise records can be used for the evaluation of the different coupling conditions of closely spaced geophones. We derive frequency-dependent correction operators using a parametric approach based upon a simple model of the interaction between geophone and soil. The redundancy of the measurements available permits verification of the assumptions made on the input signals in order to derive the method and to assess the validity of the model used. The method requires point-receiver data in which the signals recorded by the individual geophones are digitized. We have verified the accuracy of the method by applying it to multicomponent ambient-noise records acquired during a field experiment in which the coupling conditions were controlled and modified during different phases of the experiment. We also applied the method to field data, which were acquired without the coupling conditions being controlled, and found that only a few geophones showed an anomalous behaviour. It was also found that the length of the noise records routinely acquired during commercial surveys is too short to provide enough statistics for the application of our method. 相似文献