渤海湾盆地东营凹陷高青地区中生界低渗透碎屑岩有效储层特征及发育控制因素
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摘要
针对东营凹陷高青地区中生界有效储层非均质性强和成岩演化复杂的特点,利用岩石薄片、扫描电镜、阴极发光、高压压汞和流体包裹体等实验分析测试资料,系统研究了中生界有效储层的岩石学、储集和物性特征,并就有效储层和非有效储层在孔隙结构和成岩特征上的差异进行了对比,进一步明确了有效储层发育的控制因素。结果表明:高青地区中生界有效储层中次生孔隙较为发育,储层物性较好,孔隙结构非均质性强,具有中孔喉、小孔喉共存的双峰孔径分布特征。与非有效储层相比,有效储层中压实作用和胶结作用的减孔率显著降低,而溶蚀增孔率显著增加。中生界有效储层的发育受多因素控制,刚性颗粒含量高、分选好的砂岩抗压实能力强,是有效储层形成的物质基础,而早期成因的碳酸盐胶结物具有"减压保孔"的作用;相对开放的水-岩体系有利于溶蚀反应的进行,并抑制了中期方解石胶结;淋滤溶蚀和有机酸溶蚀作用改善了储层的宏观储集物性和微观孔隙结构,是有效储层发育过程中的关键成岩改造作用;断层活动产生的微裂缝会提高储层渗流能力,是控制中生界油气分布的重要因素。
The Mesozoic effective reservoirs in Gaoqing Region,Dongying Depression show strong heterogeneity and complex diagenetic evolution. In order to gain insight into the petrological characteristics and physical properties of the effective Mesozoic reservoirs and clearly demonstrate the controlling factors for the growth of effective reservoirs,tests including the thin section,scanning electron microscope( SEM),cathodoluminescence,high pressure mercury intrusion and fluid inclusion were performed,and a comparative study on pore structure and diagenesis characteristics between effective and non-effective reservoirs was carried out. Results indicate that,the Mesozoic effective reservoirs in Gaoqing Region are characterized by well-developed secondary pores,relatively good physical properties and strong heterogeneity of pore structure with a bimodal distribution of mesopore throats and micropore throats. Compared with non-effective reservoirs,the porosity reduction rate in effective reservoirs significantly decreases due to compaction and cementation,while the porosity enlargement rate with dissolution increases largely. The development of Mesozoic effective reservoirs in Gaoqing Region is controlled by multiple factors. Well-sorted sandstones with high content of rigid particles weaken the porosity reduction owing to compaction,and help compose the material basis of effective reservoirs. Early carbonate cements in effec-tive reservoirs have the ability of "anti-compaction and pore-preserving". The relatively open water-rock system is favorable for dissolution,and inhibits the mid-stage calcite cementation. The leaching dissolution and organic acid dissolution,the dominant mechanisms for diagenetic modification,function to effectively improve the macroscopic reservoir quality and microscopic pore structures. The micro-fractures generated by faulting can improve the seepage capacity of effective reservoirs,and profoundly control the distribution of oil and gas in the Mesozoic.
The Mesozoic effective reservoirs in Gaoqing Region,Dongying Depression show strong heterogeneity and complex diagenetic evolution. In order to gain insight into the petrological characteristics and physical properties of the effective Mesozoic reservoirs and clearly demonstrate the controlling factors for the growth of effective reservoirs,tests including the thin section,scanning electron microscope( SEM),cathodoluminescence,high pressure mercury intrusion and fluid inclusion were performed,and a comparative study on pore structure and diagenesis characteristics between effective and non-effective reservoirs was carried out. Results indicate that,the Mesozoic effective reservoirs in Gaoqing Region are characterized by well-developed secondary pores,relatively good physical properties and strong heterogeneity of pore structure with a bimodal distribution of mesopore throats and micropore throats. Compared with non-effective reservoirs,the porosity reduction rate in effective reservoirs significantly decreases due to compaction and cementation,while the porosity enlargement rate with dissolution increases largely. The development of Mesozoic effective reservoirs in Gaoqing Region is controlled by multiple factors. Well-sorted sandstones with high content of rigid particles weaken the porosity reduction owing to compaction,and help compose the material basis of effective reservoirs. Early carbonate cements in effec-tive reservoirs have the ability of "anti-compaction and pore-preserving". The relatively open water-rock system is favorable for dissolution,and inhibits the mid-stage calcite cementation. The leaching dissolution and organic acid dissolution,the dominant mechanisms for diagenetic modification,function to effectively improve the macroscopic reservoir quality and microscopic pore structures. The micro-fractures generated by faulting can improve the seepage capacity of effective reservoirs,and profoundly control the distribution of oil and gas in the Mesozoic.
引文
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[2]李易隆,贾爱林,何东博.致密砂岩有效储层形成的控制因素[J].石油学报,2013,34(1):71-82.Li Yilong,Jia Ailin,He Dongbo. Control factors on the formation of effective reservoirs in tight sands:examples from Guang’an and Sulige gasfields[J]. Acta Petrolei Sinica,2013,34(1):71-82.
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[4]王艳忠,操应长,李永新,等.渤南洼陷古近系深层有效储层控制因素研究[J].天然气地球科学,2012,23(6):996-1003.Wang Yanzhong,Cao Yingchang,Li Yongxin,et al. Controlling factors on the Paleogene deep effective reservoirs in the Bonan sag[J]. Natural Gas Geoscience,2012,23(6):996-1003.
[5]葸克来,操应长,周磊,等.廊固凹陷河西务构造带沙四上亚段有效储层成因机制[J].吉林大学学报:地球科学版,2014,44(5):1451-1465.Xi Kelai,Cao Yingchang,Zhou Lei,et al. Genetic mechanism of effective reservoirs in the Upper part of the fourth member of the Shahejie Formation in Hexiwu structural zone of Langgu depression[J].Journal of Jilin University:Earth Science Edition,2014,44(5):1451-1465.
[6]张淼.高青—平方王潜山带构造特征与演化[D].青岛:中国石油大学(华东),2012.Zhang Miao. Structural characteristics and evolution of Gaoqing-Pingfangwang buried hill belt[D]. Qingdao:China University of Petroleum(East China),2012.
[7]邹灵.青城凸起中生界储层及圈闭评价[D].青岛:中国石油大学(华东),2013.Zou Ling. Mesozoic reservoir and trap evaluation in Qingcheng Arch[D]. Qingdao:China University of Petroleum(East China),2013.
[8]康晏,邹灵,刘志勇,等.青城凸起中生界内幕断层及油气运聚特征[J].油气地质与采收率,2014,21(6):45-48.Kang Yan,Zou Ling,Liu Zhiyong,et al. Faulted structure and its effect on oil-gas reservoir forming in Qingcheng arch[J]. Petroleum Geology and Recovery Efficiency,2014,21(6):45-48.
[9]张淼,陈清华.东营凹陷高青—平方王潜山带油气藏类型及其成藏控制因素[J].油气地质与采收率,2012,19(3):46-48.Zhang Miao,Chen Qinghua. Reservoir types and its controlling factors of Gaoqing-Pingfangwang buried hill belt in Jiyang depression[J].Petroleum Geology and Recovery Efficiency,2012,19(3):46-48.
[10]郭旭升.高青地区沙三段砂体成因与油气成藏分析[J].石油勘探与开发,2000,27(6):35-36.Guo Xusheng. An analysis of the genesis of sand bodies and oil/gas reservoir forming in Member S3of Gaoqing area[J]. Petroleum Exploration and Development,2000,27(6):35-36.
[11]张鹏,王良书,丁增勇,等.济阳坳陷中—新生代断裂发育特征及形成机制[J].石油与天然气地质,2006,27(4):467-474.Zhang Peng,Wang Liangshu,Ding Zengyong,et al. Characteristics and formation mechanism of the faults in Mesozoic-Cenozoic in Jiyang Depression[J]. Oil&Gas Geology,2006,27(4):467-474.
[12]程明.高青—平方王地区断层输导体量化表征及其控藏作用[D].青岛:中国石油大学(华东),2012.Cheng Ming. Quantitative characterization of fault opening and the control role for hydrocarbon migration in the Gaoqing-Pingfangwang Area[D]. Qingdao:China University of Petroleum(East China),2012.
[13]李文浩,张枝焕,昝灵,等.渤南洼陷北部陡坡带沙河街组砂砾岩有效储层物性下限及其主控因素[J].石油与天然气地质,2012,33(5):766-777.Li Wenhao,Zhang Zhihuan,Zan Ling,et al. Lower limits of physical properties and their controlling factors of effective coarse-grained clastic reservoirs in the Shahejie Formation on northern steep slope of Bonan subsag,the Bohai Bay Basin[J]. Oil&Gas Geology,2012,33(5):766-777.
[14] Lai J,Wang G,Wang Z,et al. A review on pore structure characterization in tight sandstones[J]. Earth-Science Reviews,2018,177:436-457.
[15] Xi K,Cao Y,Haile B G,et al. How does the pore-throat size control the reservoir quality and oiliness of tight sandstones? The case of the Lower Cretaceous Quantou Formation in the southern Songliao Basin,China[J]. Marine&Petroleum Geology,2016,76:1-15.
[16]周林,陈波,凡睿,等.川北地区须四段致密砂岩储层特征及成岩演化[J].石油与天然气地质,2017,38(3):543-550.Zhou Lin,Chen Bo,Fan Rui,et al. Characteristics and diagenesis of tight sandstone reservoirs in the 4thmember of Xujiahe Formation,northern Sichuan Basin[J]. Oil&Gas Geology,2017,38(3):543-550.
[17]楚美娟,郭正权,齐亚林,等.鄂尔多斯盆地延长组长8储层定量化成岩作用及成岩相分析[J].天然气地球科学,2013,24(3):477-484.Chu Meijuan,Guo Zhengquan,Qi Yalin,et al. Quantitative diagenesis and diagenetic facies analysis on Chang 8 reservoir of Yanchang Formation in Ordos Basin[J]. Natural Gas Geoscience,2013,24(3):477-484.
[18] Morad S,Al-Ramadan K,Ketzer J M,et al. The impact of diagenesis on the heterogeneity of sandstone reservoirs:A review of the role of depositional fades and sequence stratigraphy[J]. AAPG Bulletin,2010,94(8):1267-1309.
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