Effect analysis of borehole microseismic monitoring technology on shale gas fracturing in western Hubei

Hydraulic fracturing technology is an important means of shale gas development,and microseismic monitoring is the key technology of fracturing effect evaluation.In this study,hydraulic fracturing and microseismic monitoring were simultaneously conducted in the Eyangye 2HF well(hereinafter referred to as EYY2HF well).The target stratum of this well is the second member of the Doushantuo Formation of the Sinian System,which is the oldest stratum of horizontal shale gas wells in the world.A total of 4341 microseismic fracturing events were identified,and 23 fracturing stages of the well were defined.The fluctuation of the number of events showed a repeating“high-low”pattern,and the average energy of these events showed minimal differences.These findings indicate that the water pressure required for the reconstruction of the EYY2HF well is appropriate.The main body of the fracture network extended from northwest to southeast,consistent with the interpretation of regional geological and seismic data.The stimulated rock volumes showed a linear increase with the increase of the fracturing stage.Some technological measures,such as quick lift displacement,quick lift sand ratio,and pump stop for secondary sand addition,were adopted during fracturing to increase the complexity of the fracture network.Microseismic fracture monitoring of the well achieved expected eff ects and guided real-time fracturing operations and fracturing eff ect evaluation.

Microseismic Imaging of Hydraulically Induced-Fractures in Gas Reservoirs: A Case Study in Barnett Shale Gas Reservoir, Texas, USA

Microseismic technology has been proven to be a practical approach for in-situ monitoring of fracture growth during hydraulic fracture stimulations. Microseismic monitoring has rapidly evolved in acquisition methodology, data processing, and in this paper, we evaluate the progression of this technology with emphasis on their applications in Barnett shale gas reservoir. Microseismic data analysis indicates a direct proportion between microseismic moment magnitude and depth, yet no relation between microseismic activity and either injection rate or injection volume has been observed. However, large microseismic magnitudes have been recorded where hydraulic fracturing stimulation approaches a fault and therefore the geologic framework should be integrated in such programs. In addition, the geometry of fracture growth resulted by proppant interactions with naturally fractured formations follows unpredictable fashion due to redirecting the injection fluids along flow paths associated with the pre-existing fault network in the reservoir. While microseismic imaging is incredibly useful in revealing the fracture geometry and the way the fracture evolves, recently several concerns have been raised regarding the capability of microseismic data to provide the fracture dimensional parameters and the fracture mechanism that could provide detailed information for reservoir characterization.

Fault detection based on microseismic events

In unconventional reservoirs, small faults allow the flow ofoil and gas as well as act as obstacles to exploration; for, （1） fracturing facilitates fluid migration, （2） reservoir flooding, and （3） triggering of small earthquakes. These small faults are not generally detected because of the low seismic resolution. However, such small faults are very active and release sufficient energy to initiate a large number of microseismic events （MEs） during hydraulic fracturing. In this study, we identified microfractures （MF） from hydraulic fracturing and natural small faults based on microseismicity characteristics, such as the time-space distribution, source mechanism, magnitude, amplitude, and frequency. First, I identified the mechanism of small faults and MF by reservoir stress analysis and calibrated the ME based on the microseismic magnitude. The dynamic characteristics （frequency and amplitude） of MEs triggered by natural faults and MF were analyzed; moreover, the geometry and activity types of natural fault and MF were grouped according to the source mechanism. Finally, the differences among time-space distribution, magnitude, source mechanism, amplitude, and frequency were used to differentiate natural faults and manmade fractures.

Evaluation of Microseismicity Related to Hydraulic Fracking Operations of Petroleum Reservoirs and Its Possible Environmental Repercussions

Petroleum reservoir operations such as oil and gas production, hydraulic fracturing, and water injection induce considerable stress changes that at some point result in rock failure and emanation of seismic energy. Such seismic energy could be large enough to be felt in the neighborhood of the oil fields, therefore many issues are recently raised regarding its environmental impact. In this research we analyze the magnitudes of microseismicity induced by stimulation of unconventional reservoirs at various basins in the United States and Canada that monitored the microseismicity induced by hydraulic fracturing operations. In addition, the relationship between microseismic magnitude and both depth and injection parameters is examined to delineate the possible framework that controls the system. Generally, microseismicity of typical hydraulic fracturing and injection operations is relatively similar in the majority of basins under investigation and the overall associating seismic energy is not strong enough to be the important factor to jeopardize near surface groundwater resources. Furthermore, these events are less energetic compared to the moderately active tectonic zones through the world and usually do not extend over a long period at considerably deep parts. However, the huge volume of the treatment fluids and improper casing cementing operation seem to be primary sources for contaminating near surface water resources.

不同压裂规模下煤储层缝网形态对比研究——以延川南煤层气田为例

以大砂量、大液量为特点的储层改造技术推动深层煤层气开发取得突破,煤层气增储上产保持着良好势头。为探索深部煤储层水力压裂过程中裂缝扩展形态,在鄂尔多斯盆地延川南煤层气田开展不同压裂规模煤储层改造的矿场试验,对比分析压后裂缝扩展形态和储层改造面积,查明了不同类型气井、不同施工规模下裂缝形态的差异性,分析投产后的产气效果,形成了适合研究区深部煤储层改造工艺。结果表明:①低效老井多次中等规模压裂、新井多次大规模压裂和新井单次超大规模压裂均能有效延伸裂缝长度、扩大储层改造面积,但缝网形态存在较大差异。受排采过程和诱导应力影响,低效老井经多次中等规模压裂后,形成主裂缝延伸、次裂缝扩展的“玫瑰花”型缝网;新井压裂改造后形成的缝网形态呈“长椭圆”型,但单次超大规模的液体使用效率更高,相同规模下裂缝半长和改造面积更大。②随压裂次数增加,裂缝半长和改造面积均呈对数增加的趋势,且有明显的递减效应,试采证实2次大规模压裂施工具有良好的经济性,研究结果为井网部署提供了依据。以柴油为动力来源的压裂设备较难适应提升规模后的连续施工,电驱动压裂装置是未来整装煤层气田开发的可靠途径。

页岩油藏水平井分段多簇压裂全井段裂缝扩展数值模拟——以济阳坳陷沙河街组为例

济阳坳陷古近系页岩油资源量达40.5×10^(8) t,展现出良好的勘探开发前景。但页岩油储层埋藏较深、构造复杂、非均质性强,页岩油储层水力压裂裂缝扩展规律尚不明确。为准确预测水力压裂裂缝的扩展形态,建立了基于无量纲近似解的裂缝扩展流固耦合模型。根据济阳坳陷页岩油储层地质工程特征,对该区块一口典型的页岩油水平井开展了裂缝扩展模拟,并将微地震和示踪剂监测结果与模拟结果进行了对比。结果表明:模拟缝长与微地震折算缝长的整体趋势基本一致;模拟结果和示踪数据监测结果的吻合度高于其与微地震监测结果的吻合度;在某些井段,示踪剂结果和微地震结果与模拟结果高度一致。该研究可为济阳坳陷页岩油藏压裂方法设计提供指导。

煤矿坚硬顶板灾害水力压裂防治技术监测及评估

水力压裂技术具备安全性好、施工工艺简单的优点,被广泛应用于煤层坚硬顶板灾害治理。但由于岩体的不均质性,压裂孔周围裂隙网络扩展规律复杂,水力压裂裂纹监测精度低,压裂效果评估难度大。针对上述问题,通过对比分析常见水力压裂监测方法及监测方案的差异,揭示微震监测技术的优越性,并对水力压裂效果评估技术进行了讨论。研究表明,微震监测技术具有监测范围广、灵敏度高、连续性好的优点;地面监测、井下监测、联合监测等微震监测方法适用工况不同,监测精度相差较大,应根据现场工程布置与实际岩层条件选取合适的监测方法。坚硬顶板水力压裂效果评估多采用裂缝发育长度、来压步距等间接指标,基于微震参变量直接指标的效果评估相对较少。在此基础上,提出了水力压裂效果评估精细化的发展建议。研究成果对开展坚硬顶板水力压裂现场监测、优化坚硬顶板水力压裂工程设计具有重要指导意义。

高能气体致裂技术在低渗砂岩型铀矿地浸开采中的应用

鄂尔多斯盆地北部巴音青格利铀矿床赋存于直罗组下段下亚段中,矿体平均铀品位为0.057 1%,平均平米铀量为6.69 kg/m^(2);但其渗透系数仅为0.065 m/d,属典型低渗砂岩型铀矿。在常规地浸开采中,易出现抽注液量低、生产不经济等问题。为提高该矿床矿层的渗透性,选取注液能力较差的Z5井开展高能气体致裂增渗试验,同时使用微地震法在Z5井周围对高能气体压裂产生的裂缝发育情况进行监测。试验结果表明,致裂后Z5井注液量得到明显改善,平均注液量增加了126.34%,微地震监测事件点的纵向跨度在3.8~4.5 m,未破坏含矿含水层顶底板。高能气体致裂增渗技术能够使近井地带渗透能力得到改善,且方便实施,成本较低。

分段多簇密切割压裂技术在淮南矿区煤层气抽采中的应用

针对淮南矿区碎软低渗煤层瓦斯抽采技术难题,以13-1煤层为例,在分析煤层及其顶底板概况的基础上,采用煤层顶板分段压裂水平井技术,充分利用水平井水平段,单段分3簇射孔,簇间距25 m,实现分段多簇密切割体积压裂改造。微地震监测结果表明,单段裂缝长度102.5~211.4 m,缝高17.3~27 m,裂缝主体向下延伸,实现了井筒与煤层的沟通。排水采气效果表明,最高产气量1519 m^(3)/d,取得了良好的产气效果。研究成果为淮南矿区煤层气地面预抽和瓦斯区域治理提供了工程借鉴。

基于微地震裂缝监测技术的煤层气压裂效果评价——以贵州六盘水地区DC1井组为例

贵州作为煤层气资源大省,其煤储层具有复杂特性,需采用水力压裂等技术进行改造。微地震监测技术能有效评估水力压裂效果,为优化设计和决策提供依据。采用微地震裂缝监测技术对六盘水地区3口煤层气井的压裂施工进行微地震裂缝监测,获取了压裂缝网展布范围、延伸方向等几何参数。结果显示,压裂裂缝总体延伸方向为130°左右,与最大主应力方向基本一致,裂缝长度为200~280 m,总体延伸长度较好。通过对压裂效果进行评价,分析了天然裂缝对压裂缝网发育的影响,为压裂施工调整、压后效果评估提供了有效指导,获得了较好效果,为本工区后期压裂工艺改进提供了有效参考。

宁夏韦州矿区煤层气压裂智能微地震地面监测技术应用研究

对韦州矿区煤层气压裂直井实施智能微地震地面监测,布设高精度检波器40台,采用STA/LTA方法进行有效事件检测,利用REAL方法对拾取事件进行定位,压裂段累计识别有效微地震事件53件次,推断压裂施工最大平均影响半径178m,裂缝组合以近水平为主,最大延伸缝长约210m,最大延伸缝宽约10m,最大延伸缝高约6m,地应力方向以NNW-SSE为主,与推测主应力方向一致。监测结果表明,在厚覆盖层区域开展煤层气压裂微地震地面监测具有一定的适用性。

井上下一体化微震联合监测技术在防治水中的应用研究

针对ARAMIS M/E井下微震监测系统在垂直层位上定位精度较差问题,构建一种ARP 2000 P/E+ARAMIS M/E一体化联合监测系统,对2022年3月期间1550个有效微震事件在垂直方向上分布特征及数量特性进行分析,深入研究微震事件分布规律与导水断裂带发育高度之间的关系。结果表明:微震事件在平面上主要集中在工作面两端,且垂直方向上主要分布在煤层顶板至上方80 m内,与导水断裂带的发育高度紧密相关。联合监测系统获得的定位结果与覆岩“三带”现场实测结果高度一致,证实该联合监测系统在震源垂直定位精度上的有效性,ARP 2000 P/E+ARAMIS M/E一体化联合监测系统可为矿井防治水提供一种有效的技术手段。

微震监测技术探查导水裂隙带发育高度及规律实测研究

为了防止煤层开采后导水裂隙带导通主要含水层对工作面开采造成影响,故开展煤层顶板导水裂隙带发育高度及规律实测研究。利用地表微动监测探查导高新技术,通过现场实测得出数据与公式理论计算、井下压水试验与井下钻孔电视成像、室内数值模拟等研究成果,综合分析,证明地表微动监测探查导高技术是可行的。克服了钻孔施工、压力试验等繁琐工程施工,避免了电视成像卡孔等技术难题,可以确定煤层顶板变形坏后裂隙的发育规律,为煤层开采顶板导高预计以及顶板水害防治工程设计提供参数依据。

微震监测技术探查导水裂隙带发育高度实测研究

为了防止煤层开采后导水裂隙带导通主要含水层对工作面开采造成影响,利用地表微震监测技术探查导水裂隙带发育高度。通过现场实测得出数据与公式理论计算、井下压水试验与井下钻孔电视成像、室内数值模拟等研究成果,综合分析,证明地表微震监测探查导水裂隙带发育高度技术是可行的。该技术克服了钻孔施工、压力试验等繁琐工程施工工序,避免了电视成像卡孔等技术难题,可以确定煤层顶板变形损坏后裂隙的发育规律,为煤层开采顶板裂隙带发育高度预计以及顶板水害防治工程设计提供参数依据。

强冲击特厚煤层地面压裂覆岩运动规律

坚硬覆岩运动是诱发冲击地压的关键因素之一。为揭示覆岩运动对工作面冲击的孕育致灾过程及诱冲机理,以孟村煤矿401102工作面为工程背景,采用理论分析的方法研究了覆岩空间结构演化特征。针对高位覆岩坚硬顶板实施地面L型水平井分段水力压裂技术,结合理论分析以及现场监测的方法,分析了压裂后采场覆岩运动时空演化规律。结果表明,地面压裂弱化区域硬厚复合砂岩层得到充分弱化,高能微震事件大幅降低;而地面压裂盲区硬厚复合砂岩层形成悬顶结构,弹性能没有得到提前释放,导致工作面开采至下方时会诱发岩层的突然断裂与运动,形成高能微震事件并释放巨大的微震能量。

煤矿冲击地压的微地震监测研究

为了研究煤矿冲击地压与岩层在三维空间破裂之间的关系,进而探索依据岩层破裂规律预测和预报冲击地压的可能性,文中采用自行研制的防爆型微地震定位监测(MS)系统,基于定位原理,监测了山东华丰煤矿冲击地压煤层(四层煤)及其解放层(六层煤)开采过程中的岩层破裂过程和二次应力场分布变化的过程,得到了如下结论:冲击地压的发生与岩层破裂密切相关,四层煤下顺槽处于六层煤顶板破裂区的外边缘时,正处于高应力区内,在此处掘进容易引发冲击地压,必须将六层煤下顺槽位置向实体煤侧移动20 m以上,或将四层煤下顺槽位置内移20 m以上,才能消除四层煤的冲击地压;六层煤和四层煤开采时,工作面前方断层活化的距离分别为250 m和350 m左右,根据这一距离,及时对断层带进行卸压处理,可以消除由断层带引发的冲击地压;监测显示了工作面周围岩层的三维破裂形态和范围,为矿井确定防水煤柱的高度提供了可靠的依据;监测证明了厚层砾岩的破裂、断层活化、采场附近关键层的破裂是引起冲击地压的主要原因,证明了所研制的硬件和定位软件具有较高的精度和实用性,可以在煤矿和边坡、隧道等领域应用.

苏里格气田致密砂岩气藏水平井体积压裂矿场试验

基于苏里格气田致密砂岩储集层天然微裂缝发育情况、岩石脆性、两向应力等地质条件,分析苏里格气田采用体积压裂技术增产的可行性,并通过现场试验进行验证。苏里格气田致密砂岩天然微裂缝较发育、裂缝复杂指数主要分布在0.3-0.5、岩石脆性指数分布在36-52、两向应力非均质系数为0.17,对比国外非常规气藏开发经验,苏里格气田具备开展体积压裂试验的地质条件。通过室内模拟和现场先导性试验研究,形成了＂低黏度液体造缝、高黏度液体携砂、多尺度支撑剂组合、高排量大规模注入＂的体积压裂工艺技术。截至2013年底,已在苏里格气田试验42口水平井,投产初期日均产气量是邻近常规压裂水平井的1.2倍,实现了苏里格气田水平井单井产量的大幅提高。

中国石油集团非常规油气微地震监测技术现状及发展方向

水力压裂、酸化压裂是致密储层改造的重要手段,在致密砂岩、碳酸盐岩、火山岩、页岩、煤层等储层连通性改造中广泛使用。对压裂效果的评估以及对裂隙的空间描述,是编制开发方案、提高产能的关键环节。微地震监测技术是目前比较有效、可靠性高的一种压裂裂缝监测及储集体空间描述技术,能够实时监测压裂裂缝的空间展布,被国内外广泛应用于压裂裂缝监测和油藏动态监测。本文分析了非常规油气微地震监测技术的需求、国内外(包括中国石油集团)微地震监测技术现状及微地震监测技术面临的挑战,指出了中国石油集团非常规领域微地震监测技术的发展方向。

水平压裂裂缝形成机理及监测——以七里村油田为例

压裂裂缝形态对低渗透油藏的生产影响较大。为了判断低渗透油藏人工压裂裂缝形态,采用公式计算、Kaiser效应地应力实验、微地震识别结合现场生产效果分析及监测等手段,研究了七里村特低渗透油藏压裂水平缝的形成机理及形成条件,并验证了水平缝的形成。结果表明,当浅层油藏垂向主地应力最小时,压裂产生水平缝,深层油藏压裂则更容易产生垂直缝;压后产量增加明显、微地震直接显示水平缝特征,以及生产中不存在二次压裂过程中压裂液窜层返排,均验证了七里村油田浅层压裂产生水平缝;通过将公式计算、室内实验、微地震检测等结果与压裂前后产量变化、现场施工结果加以综合分析,能够判断并监测水平缝。该研究成果适用于同类低渗透油藏压裂水平缝的监测。

煤层气井压裂裂缝井下微地震监测技术应用分析

分析了井下微地震裂缝监测测试技术原理、震源定位计算方法及现场测试方法。介绍了沁水盆地南部柿庄南区块煤层气井井下微地震裂缝监测测试解释结果。通过对监测解释结果分析,认识到柿庄南区块煤层压裂裂缝形态复杂,空间展布显现出网络裂缝及非对称裂缝的特征,裂缝延伸方位为北东向或东南向,与断层走向平行或垂直,各种压裂工艺形成的裂缝形态及几何尺寸差异较大;结果对压裂工艺选择、施工参数优化设计及井网部署提供了重要的依据。