基于有机孔隙校正的泥灰岩储层含油饱和度预测新方法

doi:10.3969/j.issn.2096-1693.2026.01.010

石油科学通报 ›› 2026, Vol. 11 ›› Issue (2): 442-455. doi: 10.3969/j.issn.2096-1693.2026.01.010

基于有机孔隙校正的泥灰岩储层含油饱和度预测新方法

史原鹏¹(), 肖阳², 李梦蕾²^,^*(), 蔡文渊³, 廖广志⁴, 吴健平², 李彬², 胡延旭², 黄芸², 谢莹²

¹ 中国石油华北油田公司勘探事业部，任丘 062552
² 中国石油华北油田公司勘探开发研究院，任丘 062552
³ 中国石油集团测井有限公司华北分公司，任丘 062552
⁴ 中国石油大学(北京)地球物理学院，北京 102249

收稿日期:2025-11-11 修回日期:2026-02-06 出版日期:2026-04-15 发布日期:2026-04-30
通讯作者: ^*李梦蕾(1993年—)，博士，工程师，主要从事非常规油气勘探等方面研究，lfml1993@163.com。
作者简介:史原鹏(1965年—)，教授级高工，公司高级专家，主要从事石油天然气地质综合研究，ktb_syp@petrochina.com.cn。

A new approach for oil saturation prediction in marl reservoirs based on organic pore correction

SHI Yuanpeng¹(), XIAO Yang², LI Menglei²^,^*(), CAI Wenyuan³, LIAO Guangzhi⁴, WU Jianping², LI Bin², HU Yanxu², HUANG Yun², XIE Ying²

¹ Exploration Division, PetroChina Huabei Oilfield Company, Renqiu 062552, China
² Research Institute of Exploration and Development, PetroChina Huabei Oilfield Company, Renqiu 062552, China
³ Huabei Branch, China National Logging Corporation, Renqiu 062552, China
⁴ College of Geophysics, China University of Petroleum, Beijing 102249, China

Received:2025-11-11 Revised:2026-02-06 Online:2026-04-15 Published:2026-04-30
Contact: ^*lfml1993@163.com

摘要/Abstract

摘要：

泥灰岩储层是页岩油勘探开发的关键目标层，含油饱和度作为表征油气富集程度与评估储层开发潜力的核心参数，其预测精度直接决定“甜点”区筛选效率与开发策略制定的科学性。传统Archie模型建立于均质砂岩储层的理想化假设，在沉积环境复杂、非均质性强的泥灰岩储层中应用时，存在饱和度预测精度不足的缺陷。为解决这一问题，以束鹿凹陷沙三下段泥灰岩储层为研究对象，提出一种基于有机孔隙校正的Archie模型改进方法。首先使用基于流体与有机质联合校正的HERRON模型预测总孔隙度，将元素测井中矿物的质量含量转化为体积含量，根据总有机碳含量、有机质密度及岩石体积密度建立有机质体积分数模型，将转换后的矿物与骨架密度建立线性公式，校正密度孔隙度和中子孔隙度，优化后得到总孔隙度；然后根据总有机碳含量和有机质转化率计算有机质孔隙度，总孔隙度与之相减得到无机孔隙度值；最后使用有机孔隙校正的Archie模型预测研究区饱和度。结果表明，有机孔隙校正的Archie模型增强了孔隙度与饱和度关联的物理合理性，大幅提高预测精度，能够适配研究区复杂的地质背景和较强的非均质性，为泥灰岩储层“甜点区”识别、产能潜力评估以及开发方案优化提供技术支撑。

关键词: 束鹿凹陷, 泥灰岩, 页岩油, 饱和度, 孔隙度, 测井

Abstract:

Marlstone reservoirs stand as the pivotal and primary target formations throughout the entire process of shale oil exploration and development. Oil saturation functions as the fundamental core parameter utilized for characterizing the degree of hydrocarbon enrichment within reservoir rocks and assessing the inherent development potential of subsurface reservoir systems, and its corresponding prediction accuracy exerts a decisive influence on both the screening efficiency of favorable sweet-spot zones and the scientific rigor and rationality in the formulation of practical development strategies for shale oil reservoirs. The conventional Archie model was initially formulated and established on the basis of a set of idealized assumptions that are exclusively applicable to relatively homogeneous sandstone reservoirs. When this classical model is implemented and utilized in marlstone reservoirs characterized by highly complex sedimentary environments and significant reservoir heterogeneity, it is confronted with prominent defects such as insufficient accuracy in the prediction of oil saturation. To address the inherent applicability limitations of conventional methodologies, the present study has conducted systematic petrophysical investigations targeting the Es_3x marlstone reservoir intervals within the Shulu Sag, culminating in the development of an advanced Archie model modification methodology incorporating organic porosity corrections. Initially, compute total porosity utilizing an enhanced Herron petrophysical model incorporating joint corrections for pore fluids and organic constituents, subsequently transform mineral mass fractions derived from elemental spectroscopy logging into mineralogical volume fractions. Establish a volumetric quantification model for organic matter fraction through integration of total organic carbon concentration, kerogen-bitumen density characteristics, and formation bulk density measurements, subsequently formulating a multivariate linear regression relationship between transformed mineralogical volume constituents and dry matrix grain density parameters. Calibrate and correct density-derived porosity and neutron-derived porosity measurements, then optimize these values to obtain total porosity. Subsequently, computationally derive organic-hosted porosity through petrophysical integration of total organic carbon concentration and kerogen transformation ratio parameters, then arithmetically isolate inorganic porosity by subtracting this quantitatively determined organic-hosted porosity component from the pre-established total porosity value. Ultimately, apply the Archie formation resistivity relationship, calibrated specifically for organic porosity systems, to predict hydrocarbon saturation distributions throughout the study area’s reservoir interval. The results indicate that the organic porosity-corrected Archie model enhances the physical plausibility of the relationship between porosity and saturation, significantly improves prediction accuracy, and demonstrates strong adaptability to the complex geological settings and pronounced heterogeneity of the study area. This model provides technical support for the identification of “sweet spot” zones, productivity potential evaluation, and development plan optimization in marlstone reservoirs.

Key words: Shulu Sag, marl, shale oil, saturation, porosity, well logging

中图分类号:

TE19
P618.13

史原鹏, 肖阳, 李梦蕾, 蔡文渊, 廖广志, 吴健平, 李彬, 胡延旭, 黄芸, 谢莹. 基于有机孔隙校正的泥灰岩储层含油饱和度预测新方法[J]. 石油科学通报, 2026, 11(2): 442-455.

SHI Yuanpeng, XIAO Yang, LI Menglei, CAI Wenyuan, LIAO Guangzhi, WU Jianping, LI Bin, HU Yanxu, HUANG Yun, XIE Ying. A new approach for oil saturation prediction in marl reservoirs based on organic pore correction[J]. Petroleum Science Bulletin, 2026, 11(2): 442-455.

https://sykxtb.cup.edu.cn/CN/Y2026/V11/I2/442

图/表 11

图1 研究区区域位置图

Fig. 1 Regional location map of the study area

图2 束鹿凹陷沙三下段岩石组分图

Fig. 2 Rock composition diagram of the Lower Es₃ Member in the Shulu Sag

图3 J1井全岩矿物组分图

Fig. 3 Diagram of whole-rock mineral composition of well J1

图4 研究区J1井场发射扫描电镜图

Fig. 4 Field emission scanning electron microscopy images of well J1 in the study area

图5 钙镁含量与岩心孔隙度相关性图

Fig. 5 Correlation diagram of (Ca+Mg) Content and core porosity

图6 多孔介质体积模型

Fig. 6 Volumetric model of porous media

表1 不同R_o值对应K_org范围表^[52-53]

Table 1 Range of K_org corresponding to different R_o values

热成熟阶段	R_o/%	K_org范围	有机孔隙发育程度
未成熟(未生烃)	<0.5	0~0.2	无孔隙
生油窗早期(液态烃)	0.5~1.0	0.2~0.6	孔隙开始发育
生油窗晚期(湿气)	1.0~1.3	0.6~0.9	孔隙显著发育(峰值)
过成熟(干气)	>1.3	0.9~1.0	孔隙可能因石墨化减少

图7 J1井计算孔隙度成果图

Fig. 7 Porosity calculation result map of well J1

表2 孔隙度计算成果与岩心实验数据误差与相关性

Table 2 Errors and correlations between porosity calculation results and core experimental data

模型	绝对误差	相对误差/%	与岩心实验相关性(Pearson)
原始HERRON模型	-1.98	36.69	0.43
改进模型	-0.11	2.53	0.79

图8 束鹿凹陷饱和度预测成果图

Fig. 8 Figure of oil saturation prediction results in Shulu sag

表3 含油饱和度计算成果与岩心实验数据误差与相关性表

Table 3 Errors and correlations between oil saturation calculation results and core experimental data

模型	绝对误差	相对误差/%	与岩心实验相关性(Pearson)
J1井原始模型	-26.37	62.22	0.21
J1井改进模型	-4.91	7.72	0.81
J2井原始模型	-19.89	57.39	0.31
J2井改进模型	0.91	7.07	0.83

参考文献 59

[1]	马永生, 蔡勋育, 赵培荣, 等. 中国陆相页岩油地质特征与勘探实践[J]. 地质学报, 2022, 96(1): 155-171.
	[MA Y S, CAI X Y, ZHAO P R, et al. Geological characteristics and exploration practices of continental shale oil in China[J]. Acta Geologica Sinica, 2022, 96(1): 155-171.]
[2]	匡立春, 吴松涛, 邢浩婷, 等. 陆相页岩油规模产出的关键参数与评价方法[J]. 石油勘探与开发, 2025, 52(4): 782-791. doi: 10.11698/PED.20230560
	[KUANG L C, WU S T, XING H T, et al. Key parameters and evaluation methods for large-scale production of lacustrine shale oil[J]. Petroleum Exploration and Development, 2025, 52(4): 782-791.]
[3]	韩登林, 陈丽丘, 马斌玉, 等. 陆相页岩油不同类型储层物性差异及主控机制——以准噶尔盆地吉木萨尔凹陷芦草沟组为例[J]. 长江大学学报(自然科学版), 2025, 22(1): 12-20.
	[HAN D L, CHEN L Q, MA B Y, et al. Differences in physical properties of various types of reservoirs and main controlling mechanisms in continental shale oil reservoirs: A case study of Lucaogou Formation in Jimsar Depression, Junggar Basin[J]. Journal of Yangtze University(Natural Science Edition), 2025, 22(1): 12-20.]
[4]	周旭, 马超, 刘超, 等. 页岩油含油饱和度对渗吸采收率的影响规律研究[J]. 油气藏评价与开发, 2025, 15(1): 73-78, 87.
	[ZHOU X, MA C, LIU C, et al. Study on the influence of shale oil saturation on imbibition recovery rate[J]. Reservoir Evaluation and Development, 2025, 15(1): 73-78, 87.]
[5]	HU S Y, ZHAO W Z, HOU L H, et al. Development potential and technical strategy of continental shale oil in China[J]. Petroleum Exploration and Development, 2020, 47(4): 877-887. doi: 10.1016/S1876-3804(20)60103-3
[6]	NIU X B, LYU C F, FENG S B, et al. Lamina combination characteristics and differential shale oil enrichment mechanisms of continental organic-rich shale: A case study of Triassic Yanchang Formation Chang 73 sub-member, Ordos Basin, NW China[J]. Petroleum Exploration and Development, 2025, 52(2): 316-329. doi: 10.1016/S1876-3804(25)60569-6 URL
[7]	SU X C, ZHU R K, ZHANG J Y, et al. Multi-scale characterization and control factors of bedding-parallel fractures in continental shale reservoirs: Insights from the Qingshankou Formation, Songliao Basin, China[J]. Marine and Petroleum Geology, 2025, 182: 107580. doi: 10.1016/j.marpetgeo.2025.107580 URL
[8]	WANG S, WANG G W, WANG H Z, et al. Logging evaluation of acoustic anisotropy and its relationship with “sweet spots” in lacustrine shale oil reservoirs: The Fengcheng Formation of the Mahu Sag, China[J]. Petroleum Science, 2025, 22(8): 3133-3151. doi: 10.1016/j.petsci.2025.05.014 URL
[9]	杨柳, 鲁环宇, 范鑫, 等. 盐间页岩油储层基质孔隙内盐赋存状态[J]. 科学技术与工程, 2020, 20(5): 1839-1845.
	[YANG L, LU H Y, FAN X, et al. Salt occurrence in matrix pores of intersalt shale oil reservoirs[J]. Science Technology and Engineering, 2020, 20(5): 1839-1845.]
[10]	黄振凯, 郝运轻, 沃玉进, 等. 鄂尔多斯盆地长7段泥页岩层系储层特征及其页岩油意义[J]. 科学技术与工程, 2020, 20(3): 1009-1017.
	[HUANG Z K, HAO Y Q, WO Y J, et al. Reservoir characteristics and shale oil significance of the shale strata in the Chang 7 Member of the Ordos Basin[J]. Science Technology and Engineering, 2020, 20(3): 1009-1017.]
[11]	李志军, 肖阳, 田建章, 等. 渤海湾盆地冀中坳陷新领域、新类型油气勘探潜力及有利方向[J]. 石油学报, 2024, 45(1): 69-98. doi: 10.7623/syxb202401005
	[LI Z J, XIAO Y, TIAN J Z, et al. Potentials and favorable directions for new fields, new types of oil-gas exploration in Jizhong Depression, Bohai Bay Basin[J]. Acta Petrolei Sinica, 2024, 45(1): 69-98.] doi: 10.7623/syxb202401005
[12]	LIU N, QIU N S, CAI C, et al. Geochemical characteristics and natural gas-oil-source correlation of the Shulu depression in the Jizhong Subbasin, Bohai Bay Basin, eastern China[J]. Journal of Petroleum Science and Engineering, 2022, 216: 110831. doi: 10.1016/j.petrol.2022.110831 URL
[13]	游祖辉, 赵建华, 蒲秀刚, 等. 渤海湾盆地黄骅坳陷歧北次凹古近系沙河街组三段一亚段页岩含油性控制因素与页岩油富集模式[J]. 石油与天然气地质, 2025, 46(2): 443-461.
	[YOU Z H, ZHAO J H, PU X G, et al. Controlling factors in oil-bearing properties and shale oil enrichment patterns of the 1st sub-member of the 3rd member of the Paleogene Shahejie Formation, Qibei Sub-sag, Huanghua Depression, Bohai Bay Basin[J]. Oil & Gas Geology, 2025, 46(2): 443-461.]
[14]	高波, 郝芳, 徐尚, 等. 东营凹陷沙三下亚段页岩含油性及赋存特征[J]. 地球科学, 2025, 50(6): 2199-2208.
	[GAO B, HAO F, XU S, et al. Oil content and its occurrence state of lower member of shahejie formation shale in Dongying Sag[J]. Earth Science, 2025, 50(6): 2199-2208.]
[15]	李思佳, 唐玄, 昝灵, 等. 溱潼凹陷阜二段页岩岩相组合特征及其对含油性的影响[J]. 中国海上油气, 2024, 36(2): 37-49.
	[LI S J, TANG X, ZAN L, et al. Shale lithofacies combinations and their influence on oil bearing property in the 2nd Member of Funing Formation, Qintong sag[J]. China Offshore Oil and Gas, 2024, 36(2): 37-49.]
[16]	徐东升, 李映艳, 邓远, 等. 吉木萨尔芦草沟组页岩油储层润湿性特征与影响因素分析[J]. 科学技术与工程, 2023, 23(28): 12038-12044.
	[XU D S, LI Y Y, DENG Y, et al. Investigation on wettability characteristics and influencing factors of Lucaogou shale oil formation in Jimusar[J]. Science Technology and Engineering, 2023, 23(28): 12038-12044.]
[17]	蔺敬旗, 曹志锋, 王先虎, 等. 混积页岩油甜点富集机理与含油性评价方法[J]. 测井技术, 2022, 46(6): 750-756.
	[LIN J Q, CAO Z F, WANG X H, et al. Enrichment mechanism and oil-bearing evaluation method of mixed shale oil sweet spot[J]. Well Logging Technology, 2022, 46(6): 750-756.]
[18]	钱门辉, 王绪龙, 黎茂稳, 等. 玛页1井风城组页岩含油性与烃类赋存状态[J]. 新疆石油地质, 2022, 43(6): 693-703.
	[QIAN M H, WANG X L, LI M W, et al. Oil-bearing properties and hydrocarbon occurrence states of Fengcheng Formation Shale in Well Maye-1, Mahu Sag[J]. Xinjiang Petroleum Geology, 2022, 43(6): 693-703.]
[19]	王安龙, 孙小琴, 李小龙, 等. 南川区块五峰-龙马溪组页岩气储层测井评价方法[J]. 科学技术与工程, 2020, 20(34): 14046-14052.
	[WANG A L, SUN X Q, LI X L, et al. Logging evaluation method for shale gas reservoirs of Wufeng-Longmaxi Formation in Nanchuan Block[J]. Science Technology and Engineering, 2020, 20(34): 14046-14052.]
[20]	蒋云箭, 刘惠民, 柴春艳, 等. 济阳坳陷页岩油测井评价[J]. 油气地质与采收率, 2023, 30(1): 21-34.
	[JIANG Y J, LIU H M, CHAI C Y, et al. Logging evaluation of shale oil in Jiyang Depression[J]. Petroleum Geology and Recovery Efficiency, 2023, 30(1): 21-34.]
[21]	LI N, SUN W J, LI X T, et al. Gas hydrate saturation model and equation for logging interpretation[J]. Petroleum Exploration and Development, 2022, 49(6): 1243-1250. doi: 10.1016/S1876-3804(23)60346-5
[22]	张菲, 李秋政, 蒋阿明, 等. 高邮凹陷花庄地区页岩油二维核磁测井评价应用[J]. 油气藏评价与开发, 2024, 14(5): 707-713.
	[ZHANG F, LI Q Z, JIANG A M, et al. Application of shale oil 2D NMR logging evaluation in Huazhuang area of Gaoyou Sag[J]. Petroleum Reservoir Evaluation and Development, 2024, 14(5): 707-713.]
[23]	郭同政, 张晋言, 柴婧, 等. 基于测录井资料计算页岩含油饱和度与气油比的方法[J]. 石油钻探技术, 2023, 51(3): 126-136.
	[GUO T Z, ZHANG J Y, CHAI J, et al. Methodology of calculating oil saturation and the GOR of shale based on logging data[J]. Petroleum Drilling Techniques, 2023, 51(3): 126-136.]
[24]	陈龙川, 张兆谦, 郑建东, 等. 核磁共振测井在古龙页岩油评价中的应用[J]. 测井技术, 2024, 48(1): 110-116.
	[CHEN L C, ZHANG Z Q, ZHENG J D, et al. Application of NMR logging in the evaluation of Gulong shale oil[J]. Well Logging Technology, 2024, 48(1): 110-116.]
[25]	虞成, 张超谟, 张占松, 等. 海陆过渡相页岩低阻成因分析及饱和度计算——以川东南A地区龙潭组为例[J]. 东北石油大学学报, 2022, 46(5): 55-67.
	[YU C, ZHANG C M, ZHANG Z S, et al. Analysis of low-resistivity genesis and saturation calculation of marine continental transitional shale: A case study of the Longtan Formation in A Area from southeast of Sichuan Basin[J]. Journal of Northeast Petroleum University, 2022, 46(5): 55-67.]
[26]	王民, 赵信斌, 唐育龙, 等. 页岩孔隙度、含油率评价方法现状与研究进展[J]. 石油学报, 2025, 46(9): 1817-1834. doi: 10.7623/syxb202509013
	[WANG M, ZHAO X B, TANG Y L, et al. The current status and research progress of evaluation methods for shale porosity and oil content[J]. Acta Petrolei Sinica, 2025, 46(9): 1817-1834.] doi: 10.7623/syxb202509013
[27]	郭旭升, 申宝剑, 王鹏威, 等. 基于源-储单元的页岩油气甜点段评价优选新思路[J]. 石油与天然气地质, 2025, 46(1): 1-14.
	[GUO X S, SHEN B J, WANG P W, et al. A new approach to the evaluation and optimal selection of shale oil and gas sweet-spot intervals based on source rock-reservoir units[J]. Oil & Gas Geology, 2025, 46(1): 1-14.]
[28]	隋秀英, 张凤生, 梁晓宇, 等. 湖相混积型页岩油储层孔隙度计算方法[J]. 测井技术, 2023, 47(1): 73-78.
	[SUI X Y, ZHANG F S, LIANG X Y, et al. Porosity calculation method of lacustrine mixed shale oil reservoir[J]. Well Logging Technology, 2023, 47(1): 73-78.]
[29]	王燕, 雷有为, 付小平, 等. 元坝地区大安寨段二亚段页岩气储层孔隙度计算方法[J]. 复杂油气藏, 2022, 15(3): 7-10, 50.
	[WANG Y, LEI Y W, FU X P, et al. Calculation method of shale-gas reservoir porosity for the second sub-member of Da’anzhai Member in Yuanba area[J]. Complex Hydrocarbon Reservoirs, 2022, 15(3): 7-10, 50.]
[30]	陈兵. 陆相页岩储层有效孔隙度实验测定及测井表征方法——以博兴洼陷沙四段上亚段纯上次亚段页岩为例[J]. 油气地质与采收率, 2025, 32(3): 47-57.
	[CHEN B. Experimental determination of effective porosity in terrestrial shale reservoirs and logging characterization methods: A case study of shale of E_s4^UC in Boxing Subsag[J]. Petroleum Geology and Recovery Efficiency, 2025, 32(3): 47-57.]
[31]	刘佳杰, 徐川, 解馨慧, 等. 基于GA-1D CNN算法的页岩孔隙度预测方法研究[J]. 物探化探计算技术, 2026, 48(1): 36-46.
	[LIU J J, XU C, XIE X H, et al. Research on shale porosity prediction method based on GA-1D CNN algorithm[J]. Computing Techniques for Geophysical and Geochemical Exploration, 2026, 48(1): 36-46.]
[32]	汪敏, 杨桃, 唐洪明, 等. 迁移深度神经网络的页岩总孔隙度预测[J]. 西南石油大学学报(自然科学版), 2023, 45(6): 69-79. doi: 10.11885/j.issn.1674-5086.2021.06.11.03
	[WANG M, YANG T, TANG H M, et al. Prediction for total porosity of shale based on transfer deep neural network[J]. Journal of Southwest Petroleum University (Science&Technology Edition), 2023, 45(6): 69-79.]
[33]	GAO W Z, ZHANG P F, WANG J J, et al. Insights into shale pore structure and microscopic fluid occurrence characteristics in the Paleogene Funing Formation, Subei Basin, China[J]. Marine and Petroleum Geology, 2025, 179: 107434. doi: 10.1016/j.marpetgeo.2025.107434 URL
[34]	李斌会, 邓森, 刘勇, 等. 松辽盆地古龙页岩油储层可动流体饱和度测定方法[J]. 大庆石油地质与开发, 2022, 41(3): 130-138.
	[LI B H, DENG S, LIU Y, et al. Measurement method of movable fluid saturation of Gulong shale oil reservoir in Songliao Basin[J]. Petroleum Geology＆Oilfield Development in Daqing, 2022, 41(3): 130-138.]
[35]	王继超, 崔鹏兴, 刘双双, 等. 页岩油储层微观孔隙结构特征及孔隙流体划分[J]. 油气地质与采收率, 2023, 30(4): 46-54.
	[WANG J C, CUI P X, LIU S S, et al. Microscopic pore structure characteristics and pore fluid division of shale oil reservoirs[J]. Petroleum Geology and Recovery Efficiency, 2023, 30(4): 46-54.]
[36]	王敏, 王永诗, 朱家俊, 等. 基于孔隙度-饱和度参数分析页岩油富集程度——以沾化凹陷沙三下亚段为例[J]. 科学技术与工程, 2016, 16(32): 36-41.
	[WANG M, WANG Y S, ZHU J J, et al. Enrichment evaluation of shale oil reservoir based on porosity-oil saturation analysis: A case study of Sha 3 Formation in Zhanhua Sag[J]. Science Technology and Engineering, 2016, 16(32): 36-41.]
[37]	刘雅慧, 王才志, 刘忠华, 等. 一种评价页岩油含油性的测井方法——以准噶尔盆地吉木萨尔凹陷为例[J]. 天然气地球科学, 2021, 32(7): 1084-1091. doi: 10.11764/j.issn.1672-1926.2021.02.007
	[LIU Y H, WANG C Z, LIU Z H, et al. A logging method for evaluating oil-bearing property of shale oil: Case study of Jimusar Sag in Junggar Basin[J]. Natural Gas Geoscience, 2021, 32(7): 1084-1091.]
[38]	张晋言, 李淑荣, 王利滨, 等. 低阻页岩气层含气饱和度计算新方法[J]. 天然气工业, 2017, 37(4): 34-41.
	[ZHANG J Y, LI S R, WANG L B, et al. A new method for calculating gas saturation of low-resistivity shale gas reservoirs[J]. Natural Gas Industry, 2017, 37(4): 34-41.]
[39]	黄莉莎, 闫建平, 郭伟, 等. 低电阻率页岩气储层饱和度方程研究及应用——以川南长宁地区五峰组—龙马溪组为例[J]. 地球物理学报, 2024, 67(8): 3196-3210.
	[HUANG L S, YAN J P, GUO W, et al. Research and application of low resistivity shale gas reservoir saturation equation: A case study of WuFeng-Longmaxi Formation in Changning area, southern Sichuan[J]. Chinese Journal of Geophysics, 2024, 67(8): 3196-3210.]
[40]	曹志锋, 蔺敬旗, 王先虎, 等. 基于岩性分类的混积页岩油饱和度计算方法[J]. 测井技术, 2024, 48(1): 35-45.
	[CAO Z F, LIN J Q, WANG X H, et al. Calculation method of oil saturation of mixed shale based on lithology classification[J]. Well Logging Technology, 2024, 48(1): 35-45.]
[41]	黄小平, 柴婧. 阿尔奇公式在泥页岩地层含油饱和度计算中的应用——以沾化凹陷沙三段下亚段为例[J]. 油气地质与采收率, 2014, 21(4): 58-61, 115.
	[HUANG X P, CHAI J. A practical discussion on oil saturation calculation using Archie formula in shale formation: Example from lower Sha3 member of Zhanhua sag[J]. Petroleum Geology and Recovery Efficiency, 2014, 21(4): 58-61, 115.]
[42]	曹晓峰, 陈朝兵, 李静, 等. 碳酸盐质砾岩致密油成藏主控因素研究——以束鹿凹陷沙河街组沙三下亚段砾岩储层为例[J]. 西北地质, 2021, 54(2): 187-202.
	[CAO X F, CHEN Z B, LI J, et al. Study on the main controlling factors of tight oil accumulation in carbonate conglomerate: Taking the conglomerate reservoir of the Lower 3rd Member of Shahejie Formation in Shulu Sag as an example[J]. Northwestern Geology, 2021, 54(2): 187-202.]
[43]	王元杰, 蔡川, 肖阳, 等. 冀中坳陷束鹿凹陷潜山原油地球化学特征与油源对比[J]. 地球科学, 2021, 46(10): 3629-3644.
	[WANG Y J, CAI C, XIAO Y, et al. Geochemical characteristics and oil-source correlation of crude oils of buried hills in Shulu Sag, Jizhong Depression[J]. Earth Science, 2021, 46(10): 3629-3644.]
[44]	高楠安, 汪新伟, 梁海军, 等. 冀中坳陷束鹿凹陷地热系统成因模式[J]. 高校地质学报, 2022, 28(6): 920-932.
	[GAO N A, WANG X W, LIANG H J, et al. Genetic Mechanism of the Geothermal System in Shulu Sag, Jizhong Depression[J]. Geological Journal of China Universities, 2022, 28(6): 920-932.]
[45]	ZHENG L J, WANG C W, JIANG Z X, et al. Classification and reservoir characteristics of lacustrine carbonate conglomerate in the Shulu Sag of the Bohai Bay Basin[J]. Marine and Petroleum Geology, 2024, 164: 106806. doi: 10.1016/j.marpetgeo.2024.106806 URL
[46]	LI Q, YOU X L, JIANG Z X, et al. Lacustrine deposition in response to the middle Eocene climate evolution and tectonic activities, Bohai Bay Basin, China[J]. Marine and Petroleum Geology, 2024, 163: 106811. doi: 10.1016/j.marpetgeo.2024.106811 URL
[47]	张锐锋, 陈柯童, 朱洁琼, 等. 渤海湾盆地冀中坳陷束鹿凹陷中深层湖相碳酸盐岩致密储层天然气成藏条件与资源潜力[J]. 天然气地球科学, 2021, 32(5): 623-632. doi: 10.11764/j.issn.1672-1926.2020.12.004
	[ZHANG R F, CHEN K T, ZHU J Q, et al. Tight gas reservoir forming condition and resource potential in the lacustrine carbonate in the middle-deep layer of Shulu Sag of Jizhong Depression, Bohai Bay Basin[J]. Natural Gas Geoscience, 2021, 32(5): 623-633.]
[48]	HERRON M M, HERRON S L, GRAU J A, et al. Real-time petrophysical analysis in Siliciclastics from the Integration of Spectroscopy and Triple-Combo Logging[C]. SPE Annual Technical Conference and Exhibition, San Antonio, Texas, 2002: SPE-77631-MS.
[49]	MODICA C J, LAPIERRE S G. Estimation of kerogen porosity in source rocks as a function of thermal transformation: Example from the Mowry Shale in the Powder River Basin of Wyoming[J]. AAPG Bulletin, 2012, 96(1): 87-108. doi: 10.1306/04111110201 URL
[50]	李庆, 姜在兴, 由雪莲, 等. 基于成因机理的地层有机质孔隙度的计算—以冀中束鹿凹陷泥灰岩非常规储层为例[J]. 现代地质, 2016, 30(2): 394-405.
	[LI Q, JIANG Z X, YOU X L, et al. Evaluation of organic porosity based on its formation mechanism: An example from an unconventional marlstone reservoir in the Shulu Sag, Jizhong Depression[J]. Geoscience, 2016, 30(2): 394-405.]
[51]	ARCHIE G E. The electrical resistivity log as an aid in determining some reservoir characteristics[J]. Transactions of the AIME, 1942, 146(1): 54-62. doi: 10.2118/942054-G URL
[52]	TISSOT B P. Petroleum Formation and Occurrence[M]. Berlin Heidelberg: Journal of Sedimentary Research, 1978.
[53]	JARVIE D M, HILL R J, RUBLE T E, et al. Unconventional shale-gas systems: The Mississippian Barnett Shale of north-central Texas as one model for thermogenic shale-gas assessment[J]. AAPG Bulletin, 2007, 91(4): 475-499. doi: 10.1306/12190606068 URL
[54]	程丽, 严伟, 李娜. 陆相页岩储集层含水饱和度测井计算方法—以川东南复兴区块凉高山组为例[J]. 新疆石油地质, 2024, 45(3): 371-377.
	[CHENG L, YAN W, LI N. A logging-based method for calculating water saturation in continental shale reservoirs: A case study of Lianggaoshan Formation in Fuxing Block, southeastern Sichuan Basin[J]. Xinjiang Petroleum Geology, 2024, 45(3): 371-377.]
[55]	石文睿, 张占松, 黄梓桑, 等. 低阻页岩气储层含气饱和度计算方法: 以涪陵地区焦石坝区块为例[J]. 断块油气田, 2022, 29(2): 183-188.
	[SHI W R, ZHANG Z S, HUANG Z S, et al. Study on calculation method of gas saturation in low-resistivity shale gas reservoir: A case study of Jiaoshiba Block in Fuling Area[J]. Fault-Block Oil & Gas Field, 2022, 29(2): 183-188.]
[56]	MASHABA V, ALTERMANN W. Calculation of water saturation in low resistivity gas reservoirs and pay-zones of the Cretaceous Grudja Formation, onshore Mozambique basin[J]. Marine and Petroleum Geology, 2015, 67: 249-261. doi: 10.1016/j.marpetgeo.2015.05.016 URL
[57]	KADKHODAIE A, REZAEE R. A new correlation for water saturation calculation in gas shale reservoirs based on compensation of kerogen-clay conductivity[J]. Journal of Petroleum Science and Engineering, 2016, 146: 932-939. doi: 10.1016/j.petrol.2016.08.004 URL
[58]	XU J L, XU L, QIN Y X. Two effective methods for calculating water saturations in shale-gas reservoirs[J]. Geophysics, 2017, 82(3): D187-D197.
[59]	宋明星, 杨川, 郭巧珍, 等. 低阻砂岩气藏测井饱和度计算方法: 以准噶尔盆地玛河气田为例[J]. 科学技术与工程, 2021, 21(19): 7976-7983.
	[SONG M X, YANG C, GUO Q Z, et al. Calculation method of logging saturation in low resistivity sandstone gas reservoir: Case study of the Mahe gas field in Junggar Basin[J]. Science Technology and Engineering, 2021, 21(19): 7976-7983.]

选择文件类型/文献管理软件名称

选择包含的内容

基于有机孔隙校正的泥灰岩储层含油饱和度预测新方法

A new approach for oil saturation prediction in marl reservoirs based on organic pore correction

RichHTML

PDF

可视化

被引次数

摘要/Abstract

引用本文

使用本文

图/表 11

参考文献 59

相关文章 15

编辑推荐

Metrics

本文评价

[1]	任卫涛, 白仕鑫, 杨兵谏, 杨国庆. 咸化湖盆碳酸盐质纹层对页岩油“甜点”的控制机理综述[J]. 石油科学通报, 2026, 11(2): 313-333.
[2]	高强勇, 邵才瑞, 赵志恒, 汪瑞宏, 张福明, 许赛男, 时新磊. BZ地区砂砾岩储层覆压孔渗变化规律及二元校正方法[J]. 石油科学通报, 2026, 11(1): 41-53.
[3]	葛琛琦, 雷征东, 纪东奇, 张原, 刘一杉, 阎逸群, 惠钢, 陈掌星. 页岩油水平井间注气驱替开发可行性研究[J]. 石油科学通报, 2026, 11(1): 239-256.
[4]	张旭阳, 吕柄辰, 李庆, 宋兆杰, 岳大力, 方宇翔, 李哲, 刘曦雨, 王佳琦. 玛湖1井区上乌尔禾组致密砾岩油藏流体赋存控制因素及分级储量表征[J]. 石油科学通报, 2025, 10(6): 1130-1151.
[5]	陈君青, 杨晓斌, 张潇, 王玉莹, 火勋港, 姜福杰, 庞宏, 施砍园, 马奎友. 页岩力学性质研究中机器学习的应用：现状、挑战与展望[J]. 石油科学通报, 2025, 10(5): 849-877.
[6]	李宏宏, 郑力会, 左学谦, 齐涛, 李思琦, 赵鑫祎, 郑马嘉. 基于PU学习与递减模型的页岩油产能预警方法[J]. 石油科学通报, 2025, 10(5): 941-953.
[7]	路保平, 廖东良, 袁多, 刘江涛. 基于钻井地质环境因素的页岩油气地层井眼轨迹优化控制技术[J]. 石油科学通报, 2025, 10(4): 709-718.
[8]	王瀚, 赵伟, 夏轩哲, 贺武, 庞爱兴. 页岩非均质多孔介质中油—水两相流动格子Boltzmann模拟研究[J]. 石油科学通报, 2025, 10(4): 736-746.
[9]	徐希同；赖枫鹏；王宁；苗丽丽；赵千慧. 多因素影响下的页岩油动态渗吸规律数值模拟[J]. , 2025, 10(2): 232-244.
[10]	杨雨萱；王森；陈李杨；刘祖鹏；冯其红. 页岩油压闷采渗流机理的格子Boltzmann模拟[J]. , 2025, 10(2): 298-308.
[11]	邬德刚；吴胜和；张玉飞；余季陶. 小样本条件下的储层物性参数智能解释方法研究[J]. , 2025, 10(2): 378-391.
[12]	王宵宇；廖广志；黄文松；刘海山；孔详文；赵子斌. 基于机器学习的页岩总有机碳含量评价方法[J]. , 2025, 10(2): 392-403.
[13]	孙正心；金衍；孟翰；郭旭洋. 基于深度学习数据融合的测井数据精细表征[J]. , 2025, 10(1): 75-86.
[14]	鲍李银；孙盼科；陈永辉；朱思成；李玢；甘春玲；王江；崔新璇；赵振丞. 陆相页岩油纹层型、夹层型储层孔隙结构特征及其约束下的流体可动性差异[J]. , 2024, 9(6): 866-884.
[15]	周彪；陈志明；赵辉；韩佳鹏；赵续荣；YU Wei. 基于改进DFM-NM的页岩油多井干扰三维数值模型及应用[J]. , 2024, 9(6): 1005-1022.

模态框（Modal）标题

选择文件类型/文献管理软件名称

选择包含的内容

基于有机孔隙校正的泥灰岩储层含油饱和度预测新方法

A new approach for oil saturation prediction in marl reservoirs based on organic pore correction

RichHTML

PDF

可视化

被引次数

摘要/Abstract

引用本文

使用本文

图/表 11

参考文献 59

相关文章 15

编辑推荐

Metrics

本文评价