核磁共振与高压压汞实验联合表征致密油储层微观孔喉分布特征

第40卷第2期 2018年3月石油实验地质PETROLEUM GEOLOGY & EXPERIMENTV〇1.40,N〇.2Mar. ,2018文章编号：100卜6112(2018)02-0280-08 doi：10.n78L/sysydz201802280运用高压压汞及扫描电镜多尺度表征致密砂岩储层微纳米级孔喉特征—以渤海湾盆地沾化凹陷义176区块沙四段致密砂岩储层为例严强张云峰付航u，3,姜美玲王军4,隋淑玲4,付晗1,2,郝芮1,2,郭明翰1,2(1.东北石油大学地球科学学院，黑龙江大庆163318;2.油气藏形成机理与资源评价重点实验室，黑龙江大庆163318;3.大庆油田有限责任公司第三采油厂第一油矿，黑龙江大庆163318;4.中国石化胜利油田分公司勘探开发研究院，山东东营257015)摘要:选取渤海湾盆地沾化凹陷义176区块沙河街组四段32块致密砂岩样品进行高压压汞、覆压孔渗等实验，结合环境扫描电镜的镜下特征，探讨致密砂岩储层的微观孔喉结构特征及其渗透性，特别是流体在纳米级及微米级喉道的渗流特征。

实验表明：研究区的排替压力分布范围大,结合孔喉的分布情况和渗透率的相对大小，将该区的储层分成4大类6亚类;d V d(lo g d)能够准 确形象地反映各级孔喉分布情况，结合环境扫描电镜对孔喉相对大小的识别结果，将研究区的孔喉体系分为纳米级、微纳米级、纳微米级及微米级等4类，将喉道分为纳米级喉道和微米级喉道;通过相关性分析，发现纳米级喉道控制着渗透率，而微米级喉道更多贡献于孔隙度；高压压汞在研究致密储层的孔喉特征时，不仅能够表征常规孔喉的结构特征，同时也能反映微纳米级孔喉的大小及流体在其中的渗流特征，对进一步精细评价储层具有良好效果。

关键词：高压压汞;扫描电镜;微纳米孔喉;致密砂岩储层;渤海湾盆地中图分类号:TE122.2 文献标识码：AHigh pressure mercury injection and scanning electron microscopy applied to characterize micro- and nano-scale pore throats in tight sandstone reservoirs ：A case study of the fourth member of Shahejie Formationin Y i176 block,Zhanhua Sag,Bohai Bay BasinY A N Qiang1’2,Z H A N G Y u n f e n g1，2,F U H a n g1’2’3,J I A N G Meiling1，2,W A N G Jun4,S UI Shuling4,F U H a n1’2,H A O R u i1’2,G U O M i n g h a n1，2(1. Department of Earth Sciences，Northeast Petroleum, University，Daqing，Heilongjiang163318, China；2. Oil and Gas Reservoir Forming Mechanism and Resource Evaluation Key Laboratory，Daqing，Heilongjiang163318, China；3. First Oil Mine of Third Oil Plant，Daqing Oil Field Limited Liability Company，Daqing，Heilongjiang163318，China；4. Exploration and Development Institute，SINOPEC Shengli Oilfield Company，Dongying，Shandong 257015，China) Abstract：Thirty-two samples of tight sandstone from the fourth m e m b e r of Shahejie Formation in Y i176 block, Zhanhua S a g,Bohai Bay Basin were selected for high pressure mercury injection and overpressure pore infiltration experiments.The microscopic pore throat structure and permeability of tight sandstone reservoirs,especially the flow characteristics of fluid in nano-and micro-scale throats,were discussed along with their microscopic features observed with environmental scanning electron microscopy (S E M).Experiments showed that the discharge pressure in the study area has a wide distribution.According to the distribution of pore throats and relative permeability,the reservoirs in this area were divided into 4 major types and 6 sub-categories.dv/d(logd)reflects the distribution of pore throats at all levels.C o m b i n e d with the identification of the relative sizes of pore throats by environmental S E M, the pore throat system in the study area was divided into4 categories：nano scale,micro-nano scale,nano-micro 收稿日期：2017-06-30;修订日期：2018-01-09。

致密油储层岩石孔喉比与渗透率、孔隙度的关系李伟峰;刘云;于小龙;魏浩光【摘要】Pore-throat ratio is one of the most important microscopic physical properties of tight oil reservoir rocks and it has great effect on the remaining oil distribution and displacement pressure of reservoirs. After pore structure parameters of reservoir rocks were analyzed, such as pore-throat ratio, coordinate number, pore radius and throat radius, the theoretical relation between microscopic physi-cal properties and macroscopic physical properties (porosity and permeability) of tight oil reservoir rocks was established by using the composite capillary model. Then, constant-rate mercury injection experiment data of 44 suites of cores taken from Chang 6 oil formation in Banqiao area were used for fitting. It is indica ted that the porosity (φ) and permeability (k) of tight oil reservoir rocks are controlled by pore radius and throat radius, respectively. There is a good mathematical relationship between pore-throat ratio and φ0.5/k0.25. Oil dis-placement experiment was performed on two suites of cores whose permeabilities are close and porosities are more different. It is verified that the water displacing oil resistance in tight sandstones with higher φ0.5/k0.25 is higher.%孔喉比是致密油储层岩石最重要的微观物性之一,对储层的剩余油分布与驱替压力影响很大.利用复合毛细管模型,考虑储层岩石的孔喉比、配位数、孔隙半径和喉道半径等孔隙结构参数,建立了致密油储层岩石的微观物性与宏观物性孔隙度、渗透率之间的理论关系式.并用44组板桥地区长6油层组致密油储层岩心的恒速压汞实验数据进行拟合.结果表明:致密油储层岩石孔隙度φ 主要受孔隙半径影响,喉道半径控制岩石的渗透率k,孔喉比与φ0.5/k0.25间具有确定的函数关系.利用2组渗透率接近、孔隙度差异较大的岩心驱油实验,证实φ0.5/k0.25值大的致密砂岩,水驱油阻力大.【期刊名称】《石油钻采工艺》【年(卷),期】2017(039)002【总页数】5页(P125-129)【关键词】致密油;孔喉比;孔隙度;渗透率;驱油阻力;恒速压汞实验【作者】李伟峰;刘云;于小龙;魏浩光【作者单位】延长油田股份有限公司勘探开发研究中心;西北大学地质系;延长油田股份有限公司勘探开发研究中心;延长石油集团研究院钻采所;中国石化石油工程技术研究院【正文语种】中文【中图分类】TE311致密储层岩石的储集空间主体为纳米级孔喉系统，具有小孔微喉或者细孔微喉的特征，孔喉比能达到几十甚至数百，贾敏效应严重［1-5］。

天 然 气 工 业NATURAL GAS INDUSTRY 第40卷第3期2020年 3月· 38 ·联合高压压汞和核磁共振分类评价致密砂岩储层——以鄂尔多斯盆地临兴区块为例孔星星1　肖佃师1　蒋恕2　卢双舫1　孙斌1　王璟明11. 中国石油大学（华东）地球科学与技术学院2.构造与油气资源教育部重点实验室•中国地质大学（武汉）摘要：致密砂岩气藏储层的孔渗关系通常都较差，沿用常规的储层分类方案难以满足该类储层分类评价的需要。

为此，以鄂尔多斯盆地东缘临兴区块二叠系致密砂岩气藏为例，借助高压压汞、核磁共振和扫描电镜等多种手段，刻画致密砂岩储层微观结构，研究微观结构参数对宏观物性的控制作用，进而在此基础上开展致密砂岩储层分类评价。

研究结果表明：①核磁共振能够识别不同大小的孔隙分布，高压压汞能够反映储层的孔喉配置关系及渗流能力；②两种手段刻画结果吻合较好，随T2谱右峰比例的增加，进汞曲线呈现下凹形、孔喉半径增大，孔隙类型由粒内溶蚀孔和晶间孔逐渐过渡为粒间孔和粒间溶蚀孔，储层品质变好；③微观孔隙结构控制储层物性及流体可动性，大孔的孔隙度和有效孔隙度的相关性最佳，大孔孔隙度可用于评价致密砂岩的储集能力；④高压压汞获得的孔喉半径R15与孔隙度、渗透率相关性最佳，可用于评价致密砂岩的渗流能力；⑤综合大孔孔隙度和R15将临兴区块致密砂岩储层分为4类，分类结果与现场试气结果吻合度较高。

结论认为，高压压汞和核磁共振两种方法相结合，能够有效识别反映致密砂岩储集能力和渗流能力的关键参数，提高储层分类的可靠性和完整性；通过优选反映储集能力和渗流能力的关键参数，可以指导致密砂岩储层的分类评价。

关键词：致密砂岩气藏；储集层分类；储集能力；渗流能力；高压压汞；核磁共振；鄂尔多斯盆地；临兴区块；二叠纪DOI: 10.3787/j.issn.1000-0976.2020.03.005Application of the combination of high-pressure mercury injection and nuclear mag-netic resonance to the classification and evaluation of tight sandstone reservoirs:A case study of the Linxing Block in the Ordos BasinKONG Xingxing1, XIAO Dianshi1, JIANG Shu2, LU Shuangfang1, SUN Bin1, WANG Jingming1(1. School of Geosciences and Technology, China University of Petroleum - East China, Qingdao, Shandong 266580, China;2. Key Labora-tory of Tectonic and Hydrocarbon Resource, Ministry of Education//China University of Geosciences - Wuhan, Wuhan, Hubei 430074, China) NATUR. GAS IND. VOLUME 40, ISSUE 3, pp.38-47, 3/25/2020. (ISSN 1000-0976; In Chinese)Abstract: Tight sandstone gas reservoirs have poorer porosity–permeability relationships, so conventional reservoir classification schemes can hardly satisfy the classification and evaluation demand of this type of reservoirs. To solve this problem, this paper took the Permian tight sandstone gas reservoir in the Linxing Block along the eastern margin of the Ordos Basin as an example to describe the micro-structures of the tight sandstone reservoirs by means of high-pressure mercury injection, nuclear magnetic resonance (NMR), scanning electron microscope (SEM) and so on. Then, the control effect of micro-structure parameters on the macrophysical properties was studied. Finally, classification and evaluation of tight sandstone reservoirs were carried out on this basis. And the following research results were obtained. First, NMR can identify the distribution of pores of different sizes, and high-pressure mercury injection can re-flect the pore-throat configuration and percolation capacity of a reservoir. Second, both methods are better coincident in the description results. With an increase of the right peak of T2 spectra, the mercury intrusion curve presents a concave shape and the pore throat radius increases while the pore type gradually changes from intragranular dissolution pores and intercrystalline pores to intergranular pores and intergranular dissolution pores and the reservoir quality gets better. Third, micro-pore structure controls reservoir physical properties and fluid mobility. And the porosity of large pores is best correlated with the effective porosity, so it can be used to evaluate the reservoir ca-pacity of tight sandstone. Fourth, the throat radius R15 obtained by high pressure mercury injection is in the best correlation with porosity and permeability, so it can be used to evaluate the percolation capacity of tight sandstone. Fifth, by combining the porosity of large pores with the R15, the tight sandstone reservoirs in the Linxing Block are classified into 4 categories, and the classification results are in a good agreement with the on-site well test data. It is concluded that the combination of high-pressure mercury injection and NMR can effective-ly identify the key parameters which reflect the reservoir capacity and percolation capacity of tight sandstone, and improve the reliability and integrity of reservoir classification. And by selecting the key parameters that reflect reservoir capacity and percolation capacity, it can provide the guidance for the classification and evaluation of tight sandstone reservoirs.Keywords: Tight sandstone gas reservoir; Reservoir classification; Reservoir capacity; Percolation capacity; High-pressure mercury in-jection; Nuclear magnetic resonance; Ordos Basin; Linxing Block; Permian基金项目：国家自然科学基金项目“基于图像法和流体法融合的致密砂岩全孔径孔喉表征及建模”（编号：41602141）、国家自然科学基金项目“压裂液在原位页岩气层中渗吸、滞留机理及影响”（编号：41972139）、高校自主创新基金项目“海相页岩气储层有机非均质性成因及其对孔隙结构的影响”（编号：18CX02069A）。

基于核磁共振测井的致密砂岩储层孔喉空间有效性定量评价罗少成;成志刚;林伟川;张海涛;杨小明;肖飞;唐冰娥【摘要】油气储层孔隙可分为毫米级孔隙、微米级孔隙和纳米级孔隙3种类型,常规储层的孔喉直径一般大于1 μm,致密含气砂岩储层的孔喉直径为0.03～1 μm,纳米级孔隙是致密砂岩储层连通储集空间的主体,因此对其储层有效性评价的难度较大.核磁共振T2谱与压汞曲线均能很好地反映储层的孔隙结构,利用核磁共振T2谱与压汞实验的相关性,将核磁共振T2谱转化为孔喉分布图谱.在此基础上对岩心核磁共振T2谱和压汞实验数据进行深入处理分析,并结合前人研究成果,确定SLG油田致密砂岩储层孔喉空间的有效性划分标准为:孔喉半径小于0.04μm孔喉体系为粘土束缚水体积,孔喉半径为0.04～0.1 μm孔喉体系为非泥质微孔隙地层水体积,孔喉半径为0.1 ～0.2μm的孔喉体系为毛细管束缚水体积,孔喉半径大干0.2 μm 的孔喉体系为可采出流体体积.实践证实,该方法可以对孔喉空间进行快速地定量计算,明确孔隙中的含水特征与赋存状态,实现了对致密砂岩储层孔喉空间的有效性定量评价.【期刊名称】《油气地质与采收率》【年(卷),期】2015(022)003【总页数】6页(P16-21)【关键词】致密砂岩;核磁共振T2谱;压汞;孔喉空间;有效性【作者】罗少成;成志刚;林伟川;张海涛;杨小明;肖飞;唐冰娥【作者单位】中国石油测井有限公司油气评价中心,陕西西安710077;中国石油测井有限公司油气评价中心,陕西西安710077;中国石油测井有限公司油气评价中心,陕西西安710077;中国石油长庆油田分公司勘探开发研究院,陕西西安710018;中国石油长庆油田分公司勘探开发研究院,陕西西安710018;中国石油测井有限公司油气评价中心,陕西西安710077;中国石油测井有限公司长庆事业部,陕西西安710201【正文语种】中文【中图分类】P631.823随着世界油气需求的持续增长与常规油气资源的不断减少，具有较大资源潜力的非常规油气逐渐成为新的研究领域，受到各国和石油公司的高度重视［1-2］。