Petroleum Exploration and Development >
Factors controlling the development of tight sandstone reservoirs in the Huagang Formation of the central inverted structural belt in Xihu sag, East China Sea Basin
Received date: 2018-12-02
Revised date: 2019-12-30
Online published: 2020-02-19
Supported by
Supported by the China National Science and Technology Major Project(2016ZX05027-002-006)
By means of thin section analysis, zircon U-Pb dating, scanning electron microscopy, electron probe, laser micro carbon and oxygen isotope analysis, the lithologic features, diagenetic environment evolution and controlling factors of the tight sandstone reservoirs in the Huagang Formation of Xihu sag, East China Sea Basin were comprehensively studied. The results show that: the sandstones of the Huagang Formation in the central inverted structural belt are poor in physical properties, dominated by feldspathic lithic quartz sandstone, high in quartz content, low in matrix, kaolinite and cement contents, and coarse in clastic grains; the acidic diagenetic environment formed by organic acids and meteoric water is vital for the formation of secondary pores in the reservoirs; and the development and distribution of the higher quality reservoirs in the tight sandstones of the Huagang Formation are controlled by sediment source, sedimentary facies belt, abnormal overpressure and diagenetic environment evolution. Sediment provenance and dominant sedimentary facies led to favorable initial physical properties of the sandstones in the Huagang Formation, which is the prerequisite for development of reservoirs with better quality later. Abnormal high pressure protected the primary pores, thus improving physical properties of the reservoirs in the Huagang Formation. Longitudinally, due to the difference in diagenetic environment evolution, the high-quality reservoirs in the Huagang Formation are concentrated in the sections formed in acidic diagenetic environment. Laterally, the high-quality reservoirs are concentrated in the lower section of the Huagang Formation with abnormal high pressure in the middle-northern part; but concentrated in the upper section of Huagang Formation shallower in burial depth in the middle-southern part.
Fanghao XU , Guosheng XU , Yong LIU , Wu ZHANG , Hengyuan CUI , Yiran WANG . Factors controlling the development of tight sandstone reservoirs in the Huagang Formation of the central inverted structural belt in Xihu sag, East China Sea Basin[J]. Petroleum Exploration and Development, 2020 , 47(1) : 101 -113 . DOI: 10.1016/S1876-3804(20)60009-X
| [1] | HE Jiangqi, LIANG Shiyou, CHEN Yongfeng , et al. Control of Cenozoic tectonic evolution on petroleum in Xihu Sag, East China Sea Basin: Taking the oil and gas response of Pinghu Formation as an example. Petroleum Geology & Experiment, 2008,30(3):221-226. |
| [2] | LIU Jinshui, TANG Jiancheng . Mircoscopic pore texture and percolation features in the low permeability reservoirs and their geological significance in Xihu sag: A case of Huagang Formation in HY structure. China Offshore Oil and Gas, 2013,25(2):18-23. |
| [3] | WANG Meng, YANG Yuqing, XU Danian , et al. Optimization factors and method of fracturing tight sandstone gas layer in Xihu Sag of East China Sea. Offshore Petroleum, 2016,36(3):43-48. |
| [4] | YANG Caihong, GAO Zhaohong, JIANG Yiming , et al. Reconsideration of the detrital sedimentary system of the Eocene Pinghu Formation in the Pinghu Slope Belt of the Xihu Depression. Journal of Oil and Gas, 2013,35(9):11-14. |
| [5] | ZHAO Chenglin, ZHU Xiaomin. Sedimentary petrology. 3rd Edition. Beijing: Petroleum Industry Press, 2001. |
| [6] | LIU Baojun. Sedimentary petrology. Beijing: Geological Publishing House, 1980. |
| [7] | National Technical Committee for Oil and Gas Standardization . Geological evaluating methods for tight sandstone gas: GB/T 30501—2014. Beijing: AQSIA, 2014. |
| [8] | JIN Fengming, ZHANG Kaixun, WANG Quan , et al. Formation mechanisms of good-quality clastic reservoirs in deep formations in rifted basins: A case study of Raoyang Sag in Bohai Bay Basin, East China. Petroleum Exploration and Development, 2018,45(2):247-256. |
| [9] | WANG Hairan, ZHAO Hongge, QIAO Jianxin , et al. Theory and application of Zircon U-Pb isotope dating technique. Geology and Resources, 2013,22(3):229-232. |
| [10] | LEI Kaiyu, LIU Chiyang, ZHANG Long , et al. U-Pb dating and provenance tracing of the Late Mesozoic strata in the northern Ordos Basin. Journal of Geology, 2017,91(7):1522-1541. |
| [11] | ZHANG Hangchuan, XU Yajun, DU Yuansheng , et al. Detrital Zircon geochronology of late Paleozoic strata from southern hillside of Taiping Hill in Zhoukoudian Area, Beijing and their tectonic implications. Earth Science, 2018,43(6):2100-2115. |
| [12] | WILKINSON M, DARBY D, HASZELDINE R , et al. Secondary porosity generation during deep burial associated with overpressure leak-off, Fulmar Formation, UK Central Graben. AAPG Bulletin, 1997,81(5):803-813. |
| [13] | OSBORNE M, SWARBRICK R . Diagenesis in North Sea HPHT clastic reservoirs-consequences for porosity and overpressure prediction. Marine and Petroleum Geology, 1999,16:337-353. |
| [14] | HAO Fang, DONG Weiliang . Evolution, fluid flow and accumulation mechanism of overpressure system in sedimentary basins. Advances in Earth Science, 2001,16(1):79-85. |
| [15] | SURDAM R C, CROSSEY L J, HAGEN E S , et al. Organic- inorganic and sandstone diagenesis. AAPG Bulletin, 1989,73(1):1-23. |
| [16] | HEYDARI E, WADE W J . Massive recrystallization of low-mg calcite at high temperatures in hydrocarbon source rocks: Implications for organic acids as factors in diagenesis. AAPG Bulletin, 2002,86(7):1285-1303. |
| [17] | GUO Hongli, WANG Darui . Isotopic composition and genesis analysis of carbonate cement in sandstone reservoirs of Tarim Oil and Gas Area. Petroleum Exploration and Development, 1999,26(3):32-34. |
| [18] | KEITH M L, WEBER J N . Carbon and oxygen isotopic composition of mollusk shells from marine and fresh water environment. Geochimica et Cosmochimica Acta, 1964(28):1757-1786. |
| [19] | LYU Zhengxiang, YANG Xiang, QING Yuanhua , et al. Water-rock-hydrocarbon interactions in the Middle Jurassic Shaximiao Formation sandstones western Sichuan. Oil & Gas Geology, 2015,36(4):545-554. |
| [20] | CHEN Qilin, HUANG Chenggang . Advance in research on reconstruction of reservoirs by sedimentation in sedimentary rocks. Advances in Earth Science, 2018,33(11):1112-1129. |
| [21] | WANG Shenglang, REN Laiyi, WANG Ying , et al. Characteristics of diagenesis saline Iake environment and its effect on high Porosity zones. Petroleum Exploration and Development, 2003,30(5):47-49. |
| [22] | TANG Yangang, LUO Jinhai, MA Yujie , et al. Effect of alkaline diagenetic environment of Lower Jurassic on reservoir property in Kuqa Depression. Xinjiang Petroleum Geology, 2011,32(4):356-358. |
| [23] | ZHOU Yaoqi, ZHOU Zhenzhu, CHEN Yong , et al. Research on diagenetic environmental changes of deep reservoir in Minfeng Area, Dongying Sag. Earth Science Frontiers, 2011,18(2):268-276. |
| [24] | ZHANG C, JIANG Z, ZHANG Y , et al. Reservoir characteristics and its main controlling factors of the Siegenian formation of Devonian in X block, Algeria. Energy Exploration & Exploitation, 2012,30(5):727-752. |
| [25] | ZHANG P, ZHANG J, XIE J , et al. Deposition and diagenesis of steep-slope glutenite reservoirs: Shengtuo Field, eastern China. Energy Exploration & Exploitation, 2014,32(3):483-501. |
| [26] | XU Guosheng, XU Fanggen, YUAN Haifeng , et al. Evolution of pore and diagenetic environment for the tight sandstone reservoir of Paleogene Huagang Formation in the central reversal structural belt in Xihu Sag, East China Sea. Journal of Chengdu University of Technology(Natural Science Edition), 2016,43(4):385-395. |
| [27] | LIU Yong, XU Guosheng, ZENG Bing , et al. Relationship between porosity evolution and hydrocarbon charging in tight sandstone reservoirs in Oligocene Huagang Formation, Xihu Sag, East China Sea Basin. Petroleum Geology & Experiment, 2018,40(2):168-176. |
/
| 〈 |
|
〉 |