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Chemistry and Technology of Fuels and Oils

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08.02.2024 | INNOVATIVE TECHNOLOGIES OF OIL AND GAS

Study on the Geochemical Genesis and Differences of Ordovician Oil and Gas Reservoirs

verfasst von: Yong Feng, Xin Mu, Bin Wang, Jiguang Tang, Tao Feng, Jitian Xiang, Fuxing Peng

Erschienen in: Chemistry and Technology of Fuels and Oils | Ausgabe 6/2024

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Abstract

The study of fluid inclusions in petroliferous basins is an effective method to understand hydrocarbon migration and accumulation. In this paper, the fluid inclusions in the Ordovician carbonate rock samples taken from the TS3, TP18, YQ8 and YJ2-3 wells in Tahe Oilfield are analyzed by experiments, the purpose is to explore the accumulation period of the Ordovician oil and gas reservoirs in the Tahe area and the reasons for the differences between different blocks.The results show that the Ordovician Yingshan Formation and the Yifangfang Formation in the Tahe area are rich in fluid inclusions, and there are only a single phase of oil, gas and brine in the phase. There are also two phases of oil, gas and water mixed with each other. According to the fluorescence characteristics and homogenization temperature of hydrocarbon inclusions, combined with the burial history-thermal evolution history of the study area, it is determined that the Tahe oil and gas reservoir is filled in the fourth stage, in the middle of the Caledonian period (454-446 Ma), and in the late Hercynian-Indosinian period (255-217 Ma), late Yanshanian period(143-99 Ma), Himalayan period (25-5 Ma).Among them, the middle of Caledon is mainly filled with low-mature oil, with a small amount of mature oil; the late high-mature oil in the late Hercynian is filled with some mature oil; the late Yanshan is mainly filled with high mature oil; during the Himalayan period, as the depth of burial continues to increase, the cracking of the accumulated hydrocarbons has occurred, mainly the migration of gas hydrocarbons. The four wells selected in this study belong to different tectonic units, after analysis, the author believes that the difference between single wells is on the one hand the influence of hydrocarbon thermal evolution and the other is influenced by tectonic movement.

Vorheriger Artikel Optimal Design of Adsorbers for Separation of Gas Mixtures

Nächster Artikel Experimental Study on Damage and Control Methods of Fracturing Fluid Retention to Tight Shale Matrix

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Goldstein, R. (2001) Fluid inclusions in sedimentary and diagenetic systems. Lithos. 55(1), 159-193.CrossRefADS

Ma, A., Jin, Z., Zhang, D., et al. (2005) Application of Fluid Inclusion in Oil and Gas Reservoir Formation and Oil Reservoir Evaluation. Offshore Oil. 25(2), 10-14.

Qu, G., Tian, X., Liu, Y. et al. Research on Steam Simulation of the Formation and Gasification of Siliceous Rocks. Chem Technol Fuels Oils 59, 499-506 (2023).CrossRef

Mi, J., Xiao, X., Liu, D., et al. (2003) Study on Upper-Paleozoic deep basin gas migration in Ordos using inclusion information. Acta PetroleiSinica. 24(5), 46-51.

Feng, T., Feng, Y., Tang, J., et al. (2022) Diagenesis Sequence and Hydrocarbon Accumulation Period of the Ordovician Reservoir in Well Tashen-6, Tahe Oilfield, Tarim Basin, NW China. ACS Omega. 7, 29420-29432.CrossRefPubMed

Hu, G., Shan, X., Li, Z., et al. (2005) The component and isotope characterisitics of hydrocarbon in fluid inclusions and its affection on the gas reservoir formation: The case of Ordovician reservoir in the northwest area of Ordos basin. Acta PetrologicaSinica. 21(5), 1461-1466.

Wang, T., Wang, C., He, F., et al. (2004) Determination of double filling ratio of mixed crude oils in the Ordovician oil reservoir Tahe Oilfield. Petroleum Geology & Experiment. 26(1), 74-82.

Gu, Y., Shao, Z., Chen, Q., et al. (2007) Oil migration and accumulation pattern in the Tahe Oilfield. Petroleum Geology & Experiment. 29(3), 224-230.

Lu, H., Zhang, W., Zhang, D., et al. (2008) Study of the evolution process of the Ordovician oil reservoir in the Tahe Oilfield, the Tarim Basin. Petroleum Geology & Experiment. 30(6), 547-551.

10.

Lin, Z.M. (2002) Carbonate rock reservoir features and oil-gas accumulating conditions in the Ordovician of Tahe oilfield in northern Tarim basin. Acta PetroleiSinica. 23(3), 23-27.

11.

Qi, L. (2016) Oil and gas breakthrough in ultra-deep Ordovician carbonate formations in Shuntuoguole uplift, Tarim Basin. China Petroleum Exploration. 21(3), 38-51.

12.

Gao, H., He, D., Tong, X., et al. (2016) Tectonic-depositional environment and proto-type basins during the depositional period of Middle Ordovician Yijianfang Formation in Tarim Basin. Journal of Palaeogeography. 18(6), 986-1001.

13.

Tobin, R., Claxton, B. (2000) Multidisciplinary Thermal Maturity Studies Using Vitrinite Reflectance and Fluid Inclusion Microthermometry: A New Calibration of Old Techniques. AAPG Bulletin. 84(10), 1647-1665.

14.

Burruss, R. (1991) Practical aspects of fluorescence microscopy of petroleum fluid inclusions. SEPM. 25, 1-7.

15.

Liu, J., Chen, H., Li, J., et al. (2005) Using Fluid Inclusion of Reservoir to Determine Hydrocarbon Charing Orders and Times in the Upper Paleozoic of Ordos Basin. Geological Science and Technology Information. 24(4), 60-66.

16.

Oxtoby, N. (2002) Comments on: Assessing the maturity of oil trapped fluid inclusions using molecular geochemistry data and visually-determined fluorescence colours. Applied Geochemistry. 17, 1371-1374.CrossRefADS

17.

Zhao, Y., Chen, H. (2008) The Relationship between Fluorescence Colors of Oil Inclusions and Their Maturities. Earth Science. 33(1), 91-96.

18.

Chen, H., Wu, Y., Feng, Y., et al. (2014) Timing and chronology of hydrocarbon charging in the Ordovician of Tahe oilfield, Tarim Basin, NW China. Oil & Gas Geology. 35(6), 806-819.

19.

Gu, Y. (2000) Forming mechanism of hydrocarbon pools in Tahe oilfield of the northern Tarim basin. Petroleum Geology & Experiment. 22(4), 307-312.

20.

Yan, X., Zhang, T. (2001) Discussion on Forming Mechanism of the Large-scale Carbonate Rock Subtle Reservoir in the Tahe Oilfield. Geological Review. 50(4), 370-376.

21.

Yang, Y., Yang, Y., Wang, C. (2011) Characteristics and major controlling factors of Ordovician carbonates oil and gas reservoir in Tuofutai area, Tahe oilfield. Xinjiang Oil & Gas. 7(1), 6-11.

22.

Wu, B., He, D., Sun, F., et al. (2016) Tectono-Stratigraphic Characteristics of Caohu sag, Northeast Tarim Basin and its evolution. Marine Geology Frontiers. 39(9), 17-25.ADS

23.

Si, S., Chen, H., Feng, Y., et al. (2013) Two sources and three charging events of hydrocarbons in Lower Cretaceous reservoirs in Shaya Uplift, Tarim Basin: evidence from fluid inclusion analusis. Acta PetroleiSinica. 34(115), 12-21.

24.

Chen, Q., Qian, Y., Ma, H., et al. (2003) Diagenesis and porosity evolution of the Ordovician carbonate rocks in Tahe oilfield, Tarim Basin. Petroleum Geology & Experiment. 25(6), 729-734.

25.

Huang, X., Gu, L., Li, S., et al. (2022) Absolute adsorption of light hydrocarbons on organic-rich shale: An efficient determination method. Fuel. 308, 121998.CrossRef

26.

Deng, J., Zhang, A., Ji, Y., et al. Research on Gel Plugging Technology of Coalbed Methanein Deposit. Chem Technol Fuels Oils 58, 895-901 (2022).CrossRef

27.

Mi, J., Dai, J., Zhang, S. (2003) Some problem existed in research of inclusion occurring in oil and gas bearing basin. Natural Gas Geoscience. 16(5), 602-605.

28.

Huang, X., Li, T., Gao, H., et al. (2019) Comparison of SO₂ with CO₂ for Enhancing Shale-hydrocarbon Recovery using Low-field Nuclear Magnetic Resonance. Fuel. 245, 563-569.CrossRef

Titel: Study on the Geochemical Genesis and Differences of Ordovician Oil and Gas Reservoirs
verfasst von: Yong Feng
Xin Mu
Bin Wang
Jiguang Tang
Tao Feng
Jitian Xiang
Fuxing Peng
Publikationsdatum: 08.02.2024
Verlag: Springer US
Erschienen in: Chemistry and Technology of Fuels and Oils / Ausgabe 6/2024
Print ISSN: 0009-3092
Elektronische ISSN: 1573-8310
DOI: https://doi.org/10.1007/s10553-024-01633-w

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