The Relationship between Fractures and Tectonic Stress Field in the Extra Low-Permeability Sandstone Reservoir at the South of Western Sichuan Depression

The formation and distribution of fractures are controlled by paleotectonic stress field, and their preservative status and effects on development are dominated by the modern stress field. Since Triassic, it has experienced four tectonic movements and developed four sets of tectonic fractures in the extra low-permeability sandstone reservoir at the south of western Sichuan depression. The strikes of fractures are in the S-N, NE-SW, E-W, and NW-SE directions respectively. At the end of Triassic, under the horizontal compression tectonic stress field, for which the maximum principal stress direction was NW.SE, the fractures were well developed near the S-N faults and at the end of NE-SW faults, because of their stress concentration. At the end of Cretaceous, in the horizontal compression stress fields of the NE-SW direction, the stress was obviously lower near the NE-SW faults, thus, fractures mainly developed near the S-N faults. At the end of Neogene-Early Pleistocene, under the horizontal compression tectonic stress fields of E-W direction, stress concentrated near the NE-SW faults and fractures developed at these places, especially at the end of the NE-SE faults, the cross positions of NE-SW, and S-N faults. Therefore, fractures developed mostly near S-N faults and NE-SW faults. At the cross positions of the above two sets of faults, the degree of development of the fractures was the highest. Under the modern stress field of the NW-SE direction, the NW-SE fractures were mainly the seepage ones with tensional state, the best connectivity, the widest aperture, the highest permeability, and the minimum opening pressure.

Application of Comprehensive Geophysical Techniques to Predict Carbonate Fractured Reservoirs inQingxi Oilfield

Inter-crystalline pores, cavities, and fractures created from diagenetic shrinkage of dolomite are inter-connected each other, forming fine oil- and gas-bearing reservoirs. It is hard to predict these complex fracture-cavity reservoirs because of their random distribution, different growth timing, and so on. Taking the lacustrine dolomite fracture-pore reservoir in the Lower Cretaceous Xiagou Formation in the Qingxi oilfield within the Jiuquan basin as an example, we put forward a comprehensive geophysical method to predict carbonate fractures.

Quantitative Prediction of Fracture Distribution of the Longmaxi Formation in the Dingshan Area, China using FEM Numerical Simulation

Fracture prediction is a technical issue in the field of petroleum exploration and production worldwide.Although there are many approaches to predict the distribution of cracks underground,these approaches have some limitations.To resolve these issues,we ascertained the relation between numerical simulations of tectonic stress and the predicted distribution of fractures from the perspective of geologic genesis,based on the characteristics of the shale reservoir in the Longmaxi Formation in Dingshan;the features of fracture development in this reservoir were considered.3 D finite element method(FEM)was applied in combination with rock mechanical parameters derived from the acoustic emissions.The paleotectonic stress field of the crack formation period was simulated for the Longmaxi Formation in the Dingshan area.The splitting factor in the study area was calculated based on the rock breaking criterion.The coefficient of fracture development was selected as the quantitative prediction classification criteria for the cracks.The results show that a higher coefficient of fracture development indicates a greater degree of fracture development.On the basis of the fracture development coefficient classification,a favorable area was identified for the development of fracture prediction in the study area.The prediction results indicate that the south of the Dingshan area and the DY3 well of the central region are favorable zones for fracture development.

Revolutionizing Tight Reservoir Production: A Novel Dual-Medium Unsteady Seepage Model for Optimizing Volumetrically Fractured Horizontal Wells

This study presents an avant-garde approach for predicting and optimizing production in tight reservoirs,employing a dual-medium unsteady seepage model specifically fashioned for volumetrically fractured horizontal wells.Traditional models often fail to fully capture the complex dynamics associated with these unconventional reservoirs.In a significant departure from these models,our approach incorporates an initiation pressure gradient and a discrete fracture seepage network,providing a more realistic representation of the seepage process.The model also integrates an enhanced fluid-solid interaction,which allows for a more comprehensive understanding of the fluid-structure interactions in the reservoir.This is achieved through the incorporation of improved permeability and stress coupling,leading to more precise predictions of reservoir behavior.The numerical solutions derived from the model are obtained through the sophisticated finite element method,ensuring high accuracy and computational efficiency.To ensure the model’s reliability and accuracy,the outcomes were tested against a real-world case,with results demonstrating strong alignment.A key revelation from the study is the significant difference between uncoupled and fully coupled volumetrically fractured horizontal wells,challenging conventional wisdom in the field.Additionally,the study delves into the effects of stress,fracture length,and fracture number on reservoir production,contributing valuable insights for the design and optimization of tight reservoirs.The findings from this study have the potential to revolutionize the field of tight reservoir prediction and management,offering significant advancements in petroleum engineering.The proposed approach brings forth a more nuanced understanding of tight reservoir systems and opens up new avenues for optimizing reservoir management and production.

A Comprehensive Evaluation Method for Low-permeability Reservoirs

According to the geological characteristics and their influential factors of the low-permeability reservoirs, a comprehensive method for evaluation of low-permeability reservoirs is put forward. The method takes a matrix system as the basis, a fracture system as the focus and a stress field system as the restricted factor. It can objectively reflect not only the storage capability and seepage capability of low-permeability reservoirs, but also the effect on development as well. At the same time, it can predict the seepage characteristics at different development stages and provide a reasonable geological basis for the development of low-permeability reservoirs.

碳酸盐岩储层高精度构造应力场模拟与裂缝多参数分布预测方法及其应用

构造裂缝是碳酸盐岩的主要储集空间之一,局部应力导致的构造破裂是影响裂缝发育的重要因素。基于有限元方法的构造应力场模拟已成为构造裂缝预测的重要方法,但尚未能解决模型设置与实际地质情况相差较大、最优边界条件获取效率低以及构造裂缝发育的主控因素不清晰等问题。①引入非均质岩石力学模型构建方法和自适应边界条件约束算法以提升应力场模拟的精度,根据储层破裂率和断裂活动性等参数定量表征储层裂缝发育特征;②定量探讨走滑断裂变形特征的差异和应力扰动对构造裂缝发育的影响,优选控制构造裂缝发育的最强因素构建碳酸盐岩裂缝型储集体发育指数并定量研究其主控因素;③以储集体发育规模预测为基础,结合单井裂缝测井和岩心解释成果,建立不同级别碳酸盐岩裂缝型储集体的地质模式。将该方法在中国塔里木盆地顺北地区18号断裂带及邻区奥陶系碳酸盐岩储层中应用。结果表明,张扭段、平移段与压扭段的裂缝发育程度依次降低。地层变形幅度越大,裂缝发育程度越高。储层岩石力学参数、距断裂的距离、水平两向应力差、应力非均质性系数和综合破裂率被用于构建裂缝型储集体发育指数,其分级结果与实际地质情况匹配度较高。

基于MLR–ANN算法的地应力场反演与裂缝预测

中国页岩气储层埋藏深,受构造运动影响,地应力分布规律复杂,传统方法很难准确反演区域地应力大小和方向。提出多元线性回归和人工神经网络的耦合算法,对川南长宁—建武区块的页岩气储层及周边地应力场进行反演,并采用综合破裂系数法,对储层裂缝进行预测,划分裂缝发育区域。研究表明,基于多元回归和神经网络的耦合算法能准确反演区域的地应力场分布规律。研究区的地应力以挤压应力为主,方向在NE115°左右。受构造运动产生的断层周边应力较为集中,易发育剪切裂缝,裂缝以发育和较发育程度为主。研究区在邻近龙马溪组底部的五峰组上段和构造大断层部位裂缝发育程度较高。研究成果对该区块完善页岩气开采的井网布置、压裂优化设计和套管损坏防治等有一定的参考价值。

致密碳酸盐岩气藏裂缝预测及主控因素分析——以四川盆地G气田震旦系灯影组为例

四川盆地G气田致密碳酸盐岩储层裂缝发育控制因素认识不清。考虑岩性弹脆性差异,分析岩心单井裂缝发育特征和裂缝形成期次,进行应力场数值模拟,建立应力场—能量—裂缝参数计算模型;结合多期裂缝叠加算法,预测G气田灯影组储层裂缝,分析裂缝发育主控因素。结果表明:G气田灯影组储层裂缝具有多期性与多样性,以高角度、半充填张剪缝为主。研究区中部褶皱顶部及断层影响区是碳酸盐岩裂缝优势发育带,裂缝密度为1.10~2.30条/m,开度大于1.5 mm;泥岩裂缝发育程度弱,裂缝密度低于0.50条/m,开度小于0.4 mm,泥岩隔层裂缝发育总体低于碳酸盐岩层的,且规律性差。裂缝发育符合断层—褶皱—裂缝共生模式。岩性、断层与构造形态共同控制碳酸盐岩储层裂缝发育规模与分布范围。该结果有助于提高同类型致密碳酸盐岩储层裂缝预测效果,改进油气藏开发方案。

鄂西荆门地区志留系龙马溪组古构造应力场研究及裂缝预测

鄂西地区志留系龙马溪组页岩储层发育,由于页岩低孔低渗的特性,构造裂缝成为了页岩气运移和聚集的主控因素。本文以鄂西荆门地区志留系龙马溪组页岩为例,基于地震资料、岩石力学实验、野外实测资料,利用有限元数值模拟技术、岩石破裂准则,解析古构造应力场分布规律,预测构造裂缝分布特征。结果表明,荆门地区发育的构造裂缝主要以中燕山晚期形成的NNW向和NE向共轭剪切缝为主,其次为中燕山早期形成的NNE向和NEE向共轭剪切缝。构造裂缝的分布受断层、岩石物理参数和构造应力的影响较大,Ⅲ级裂缝发育区和断层区域综合破裂系数均大于1.1,构造裂缝最为发育,页岩气保存效果最差;Ⅱ级裂缝发育区综合破裂系数在1.0~1.1之间,为页岩气保存效果较好区域;Ⅰ级裂缝发育区综合裂缝破裂系数在0.85~1.0之间,处于“破而不裂”的状态,为页岩气最优保存区。

页岩气储层多期构造应力场反演与裂缝演化

川南泸州区块五峰组—龙马溪组的页岩气蕴藏量大,构造运动使地应力局部集中,从而引起裂缝和断层的产生,对页岩气的勘探开发有较大影响。为了优选页岩气勘探区,采用地震综合资料、古构造图和岩石力学参数测试等方法,运用神经网络算法和地质力学建模方法,对研究区多期古构造应力场进行反演,并对应力影响下的储层裂缝发育规律进行预测。研究结果表明:采用数值模拟和神经网络算法,可以进行多期构造作用下的地应力场反演。多期构造运动使地应力发生调整变化,地层背斜部位应力较为集中,背斜核部受到强烈构造作用而发生破裂,应力逐步释放;多期构造运动使储层岩石承受的应力逐步变化,易出现破裂带而形成断层,应力逐步减小;原有断层周边裂缝发育较为强烈,易出现应力衰减区域,从而出现多而短的小型裂缝。现今应力场受多期构造运动综合影响,分布较复杂,裂缝发育规律性不强,对页岩气钻井、开发等影响较大。研究成果对深层页岩气的勘探开发具有一定的指导意义。

顺北地区走滑断裂带奥陶系碳酸盐岩裂缝分布预测与主控因素研究

构造裂缝是碳酸盐岩的主要储集空间之一,能为致密灰岩提供油气运移的良好通道和储集空间。构造裂缝的发育受构造位置、岩性、地层厚度、温度、围压和构造破裂等多种因素的影响,其中区域构造应力场的局部构造应力导致的构造破裂是控制构造裂缝发育的主导因素。针对碳酸盐岩储层的特点与裂缝发育特征,采用在单井动态岩石力学参数标定下,基于三维地震数据体的岩石力学参数反演功能获取非均质岩石力学模型,以提升应力场模拟中模型力学参数的真实性和准确性;引入自适应边界条件约束方法,以自动获取模拟结果与实测结果误差最小时的最优边界条件,从而显著提升应力场模拟的精度与可靠性。并在此基础上,通过储层张破裂率、剪破裂率、综合破裂率、水平两向应力差、应力非均质系数和断裂面滑动趋势系数等参数,定量表征了SHB16号断裂带及邻区的储层裂缝发育特征与活动性。储层裂缝的发育特征与断裂的活动关系密切,故定性或定量研究了水平两向应力差、距断裂的距离和断裂的垂向活动强度等参数对储层裂缝发育特征的控制作用,用斯皮尔曼等级相关系数定量研究变量之间的相关性。在明确储层裂缝发育的控制因素的基础上,构建奥陶系碳酸盐岩储层规模储集体发育指标,将奥陶系碳酸盐岩储层划分为从最优至最差的Ⅰ~Ⅳ类储集体,并明确了走滑断裂的变形方式和规模储集体发育程度的相关性,进一步建立了不同类型储集体中钻井奥陶系碳酸盐岩储集体发育的地质模式。该地质模式不仅提升了基于应力场模拟的裂缝发育特征及多参数分布定量预测的准确性和可靠性,而且对碳酸盐岩储层裂缝发育的控制因素的定性或定量研究、规模储集体发育指标的构建以及单井储集体发育的地质模式的建立、对碳酸盐岩储集体的勘探与开发进程的加快,具有重要的参考价值。

页岩油储层补能前后四维地应力模拟及加密井复杂裂缝扩展规律研究

针对安83井区长7含油层水平井区采出程度低、剩余油丰富的问题,结合考虑页岩油储层地质力学参数、天然裂缝等的非均质性和各向异性,建立一套地应力场与渗流场耦合机理模拟方法,将传统油藏渗流模拟与地质力学模拟相结合,并通过压裂施工参数、现场试井数据、微地震监测数据等,开展了储层补能前后四维地应力模拟及加密井复杂裂缝扩展规律研究。研究结果表明,该区储层杨氏模量高、泊松比低,易发生破裂;大规模压裂可以形成复杂裂缝,基本上为长250 m、宽80 m的多簇式裂缝条带;水介质补能能够起到均匀补能效果,效果比气介质好;老井补能至原始压力的80%时,压裂裂缝改造充分,裂缝扩展均衡,老井单井补能液量5000 m^(3)最优;300 m加密井补能至原始地层压力的120%时,压裂后改造较充分,单井补能液量25000m^(3)左右最优。该模拟分析方法对同类型油藏地应力模拟及裂缝扩展规律研究有重要指导意义。

M油田碳酸盐岩裂缝研究与含水动态分析

M油田为陆上推覆构造背景下的白垩系厚碳酸盐岩储层。复杂的生产历史及微裂缝的发育导致水淹规律比较复杂,因而在后续开发方案动态调整中,需要准确判别开发过程中水淹规律以及水进趋势。利用三维地震多方位角数据分析预测储层裂缝,结合目标地层构造形态与受力变形特征,分析地层裂缝参数以及应力场空间分布,研究储层裂缝发育特征,综合解释碳酸盐岩油藏内部流体运移方向与水驱强弱关系,判别开发过程中油田的水淹规律以及水进趋势。生产动态分析表明,目标储层内注入水流动趋势和水驱速度主要受井点周边的裂缝发育程度和裂缝方向控制。基于对地震各向异性和构造应力场的综合裂缝分析研究,明确了目标层段的裂缝发育强弱、裂缝方向和裂缝联通特征,对各个注水井的不同效率做了进一步解释。如果注水井位于裂缝不发育的区域或水进与裂缝方向垂直,水驱速度则比较稳定,周边受效井效果比较好;反之,受效井含水上升就比较快。裂缝发育特征与含水动态关联分析为后续井位的调整与开发方案的优化提供了具体指导。

致密碳酸盐岩气藏裂缝预测与主控因素分析——以四川盆地高石梯地区灯影组储层为例

天然裂缝是致密碳酸盐岩气藏重要的储集空间和渗流通道,定量预测其发育程度与分布规律、揭示主控地质因素,对气藏开发具有重要实践意义。本文以四川盆地中部乐山—龙女寺古隆起的高石梯地区灯影组致密碳酸盐岩储层为研究对象,在裂缝参数表征基础上建立应力场-能量-裂缝参数的计算模型,结合多期裂缝叠加算法定量预测裂缝发育分布规律,并重点分析了岩性、断层和构造形态对裂缝发育的影响。结果表明:①高石梯地区灯影组储层裂缝表现为张剪缝为主、高角度缝、半充填特征,裂缝优势走向为NW-SE与近N-S方向,裂缝密度在0~2条/m,高值区主要分布在断层带及中部地区;②高石梯地区的天然裂缝长度与裂缝密度呈负指数幂关系,裂缝发育具层间差异性,灰岩储层的缝发育程度高,泥岩对裂缝延伸具阻挡作用;③裂缝发育规模及产状发育受断层、褶皱影响显著,断层周围裂缝密度大、开度大、长度小,剪切缝与走滑断层近于平行或呈低角度,张性缝与主走滑断层呈高角度;褶皱主要通过构造曲率影响裂缝开度,弯曲变形程度高的构造部位裂缝开度大,翼部变形小,裂缝开度小。研究成果可为研究区及其他类似地质条件地区气藏高效勘探开发提供参考与借鉴。

大牛地气田奥陶系岩溶缝洞型储层识别预测方法

大牛地气田下古生界气藏主要发育中小尺度岩溶缝洞型储层,与塔里木盆地、四川盆地相比,缝洞定量识别评价难度大。通过岩心、薄片、常规-成像测井及物探等资料,明确了岩溶缝洞型储层类型和发育特征,形成一套储层定量识别和储层预测方法,主要取得了以下认识:①结合地质特点,将研究区储集岩的孔隙类型划分为孔隙型、裂缝-孔洞型和缝洞型三大类,建立了岩溶缝洞型储层综合识别模板;②通过基于贝叶斯准则的逐步判别法实现了不同类型储层定量划分,判别模型解释的储层类型与实钻资料对比基本一致;③利用基于极大似然属性的蚂蚁体和瞬时频率属性分别对岩溶缝洞型储层及含气性进行预测,形成一套井震联合的岩溶储层预测方法,为储层空间展布研究、井位部署优化及压裂改造提供重要依据。

储层构造裂缝定量预测中地质数学模型的建立与应用研究

储层裂缝的空间分布和裂缝表征参数的定量研究是石油地质学前沿问题,人们常用三维有限元数值模拟技术进行构造裂缝的定量预测[1],确定储层裂缝的组系、方位和密度,弄清储层裂缝的三维分布。以辽河欢喜岭地区为实例进行了中生界古构造研究与恢复,反演了古区域应力场,建立了三维地质模型与相应的应力场计算模型,从构造力学和应力场的角度进行了该区中生界火山岩储层的裂缝预测[2]。

页岩储层构造应力场模拟与裂缝分布预测方法及应用

裂缝是页岩气富集高产的关键因素。页岩储层相对于其他类储层,其塑性相对较强,非构造裂缝比较发育。构造裂缝除了高角度的张性裂缝以外,还发育有较多近水平的层理缝和低角度构造滑脱缝等。针对页岩储集层的特点和裂缝发育特征,从地质成因的角度,明确了页岩储层构造应力场模拟数值模拟与裂缝分布预测的方法,其核心在于建立模拟地区目的层的精确地质模型、力学模型和计算模型。利用页岩的单轴和三轴压缩变形试验和声发射古、今地应力测试结果进行应力场数值模拟,获得研究区构造应力场分布,将应力场模拟果与实际地质资料对比分析,进一步检验校正已建立地质模型的合理性;在此基础上,针对富有机质页岩主要发育张裂缝和剪裂缝的特殊性,分别采用格里菲斯、库伦-摩尔破裂准则计算页岩储层张破裂率、剪破裂率,依据张裂缝与剪裂缝所占的比例关系,求取页岩储层的综合破裂率,据此分别定量表征页岩储层中张裂缝、剪裂缝和构造裂缝的发育程度及分布特征;并在全面考虑影响页岩储层裂缝发育程度的综合破裂率、脆性矿物含量、有机碳含量多种主控因素的基础上,进一步提出了页岩"裂缝发育系数"作为最终判别指标,综合定量表征页岩储层裂缝的发育程度和预测裂缝的分布,页岩裂缝发育系数越大,裂缝发育程度则越高。该方法在我国渝东南地区下志留统龙马溪组页岩储层裂缝分布预测中得到了有效应用。此不仅为页岩气甜点优选提供了一种新的技术方法,而且模拟成果对页岩气水平井和压裂改造方案的设计具有重要的参考价值。

低渗透砂岩储层构造裂缝预测及开启性分析

在户部寨地区区域地质特征研究基础上,运用地质成因的应力应变分析方法,利用3DMove裂缝预测技术对沙河街组沙四段的裂缝分布进行了预测,并对不同方向裂缝的开启程度进行了分析。实践证明,裂缝预测和开启性评价结果与实际钻井情况基本吻合,对该区以构造成因为主的裂缝油气藏的勘探和开发具有一定的指导意义。

油气盆地储层构造裂缝定量预测研究方法及其应用

构造裂缝预测研究的基本方法有岩石破裂法、主曲率法、能量法、统计学方法。针对不同类型致密油气(田)藏,可采用不同方法或多方法综合处理。以川西新场气田为例,采用统计法和岩石破裂法相结合,预测了新场晚侏罗统蓬莱镇组中、上砂层组(J3p1、J3p2)、中侏罗统沙溪庙组(J2s)"A"和"C"砂岩层和千佛岩组(J2q)砂砾岩层中裂缝发育状况。结果表明,研究区大部分高产气井和产气井与预测的喜马拉雅期构造运动形成的裂缝发育区-次发育区有很好的对应关系,具有两层以上裂缝发育区的叠合区,是天然气聚集最有利区块。

古构造应力场与低渗煤储层的相对高渗区预测

利用古构造应力场模拟成果,结合钻孔煤芯描述、煤矿井下观测和煤层气井试井渗透率资料,在低渗煤储层广泛发育的淮南煤田预测了相对高渗区.综合分析表明,古应力高的地区也是构造煤发育区,而构造煤是导致煤储层渗透性降低的主要因素.因此,古应力较低的区域,可能是原生结构煤发育的相对高渗区.