Research on Whole Strata Geological Modeling Technology for CO2 Geological Storage in Salt Water Layer
-
摘要: 咸水层CO2地质封存技术是实现我国“碳达峰、碳中和”目标的重要支撑技术,但目前基于油气开发目的的三维地质建模技术难于满足CO2地质封存的要求,咸水层CO2地质封存数值模拟以及安全性评价等需要从地面至目的层段全部地层,针对Subei盆地Gaoji地区(S盆地G地区),利用Petrel软件以及多种确定性、随机性建模方法开展从目的层到地表的全地层三维模型建模技术研究,主要成果如下:提出利用构造框架构造建模(Structural framework)方法解决由复杂的断层接触关系引起的各种断层建模问题,并利用阶梯状网格化方法解决全地层建模网格要求问题,使全地层模型网格数小于千万;提出在岩性模型约束下采用不同的地质统计学方法依次模拟得到孔隙度、渗透率等模型的方法;结合全地层地质模型特点,采用储层发育特征对比方法对GJ地区的全地层地质模型的精度进行了检验,总体认为本次GJ地区随机建模结果具较高的可信度.本次研究提出的全地层地质建模方法可以为咸水层CO2地质封存后期数值模拟以及安全检查提供可靠完整的地质模型,对咸水层CO2地质封存的发展具有重要意义.Abstract: The CO2 geological storage technology in salt water layer is an important supporting technology for achieving China's carbon peaking and carbon neutrality goals. However, the current 3D geological modeling technology based on oil and gas development purposes is difficult to meet the requirements of CO2 geological storage. Numerical simulation and safety evaluation of CO2 geological storage in salt water layers require a geological model of all strata from the ground to the target layer. Taking the Gaoji area of the Subei basin as an example, using Petrel software and various deterministic and stochastic modeling methods, it conducted research on the three-dimensional modeling technology of the entire strata from the target strata to the surface. The main achievements are as follows. Propose to use the Structural framework method to solve various fault modeling problems caused by complex fault contact relationships, and use the stepped grid method to solve the grid requirements for whole formation modeling. Propose a method of sequentially simulating porosity, permeability, and other models using different geostatistical methods under the constraint of lithological models, and ensure that the number of grids in the entire geological model is less than ten million. Based on the characteristics of the geological model of the entire formation, the accuracy of the geological model of the entire formation in the Gaoji area was tested using the comparison method of reservoir development characteristics. Overall, it is believed that the results of the random modeling in the Gaoji area have high credibility. The geological modeling method proposed in this study can provide a reliable and complete geological model for the numerical simulation and safety inspection of CO2 geological storage in salt water layers, which is of great significance for the development of CO2 geological storage in salt water layers.
-
Key words:
- carbon /
- CO2 geological storage /
- salt water layer /
- geological modeling /
- Gaoji area /
- Subei basin /
- petroleum geology
-
图 1 Jh凹陷构造区划及GJ地区构造位置
Fig. 1. Structural zoning of Jinhu depression and structural location map of Gaoji area
图 2 采用角点网格建模方法建立的GJ地区断层模型(箭头指向正北)
Fig. 2. Fault model in Gaoji area established using corner grid modeling method (arrow pointing due north)
图 3 采用构造框架构造建模方法建立的GJ地区断层模型(箭头指向正北)
Fig. 3. Fault model in Gaoji area established using structural framework modeling method (arrow pointing due north)
图 4 GJ地区层面模型(箭头指向正北)
Fig. 4. High level model of the region (arrow pointing due north)
图 5 GJ地区阶梯状网格化的断层模型(箭头指向正北)
Fig. 5. A stepped grid fault model in the Gaoji area (arrow pointing due north)
图 6 GJ地区全地层格架模型(箭头指向正北)
Fig. 6. The whole strata stratigraphic framework model of Gaoji area (arrow pointing due north)
图 8 GJ地区全地层砂泥岩岩性模型(箭头指向正北)
Fig. 8. Lithological model of sandstone and mudstone in the entire formation of Gaoji area (arrow pointing due north)
图 9 GJ地区全地层孔隙度模型(箭头指向正北)
Fig. 9. The porosity model of the entire formation in the Gaoji area (arrow pointing due north)
图 10 GJ地区全地层渗透率模型(箭头指向正北)
Fig. 10. The permeability model of the entire formation in Gaoji area (arrow pointing due north)
-
Cui, Z. D., Liu, D. A., Zeng, R. S., et al., 2010. Geological Sequestration of CO2 and China's Sustainable Development. China Population. Resources and Evironment, 20(3): 9-13 (in Chinese with English abstract). Edouard, M. N., Okere, C. J., Ejike, C., et al., 2023. Comparative Numerical Study on the Co-Optimization of CO2 Storage and Utilization in EOR, EGR, and EWR: Implications for CCUS Project Development. Applied Energy, 347: 121448. https://doi.org/10.1016/j.apenergy.2023.121448 Gao, S. T., Yang, H. W., Lü, D. L., et al., 2010. Fine Geological Modeling of Complicated Fault-Block Oil Reservoir with Variety of Information. Special Oil & Gas Reservoirs, 17(6): 29-31 (in Chinese with English abstract). doi: 10.3969/j.issn.1006-6535.2010.06.007 Gao, Y., Li, W. F., Shi, X. R., 2008. Sequence Division and Sedimentary Facies Analysis of Funing Formation in Fanzhuang Oilfield of Jinhu Depression. Journal of Oil and Gas Technology, 30(5): 225-227 (in Chinese with English abstract). Huang, W. S., 2022. Multi-Point Statistical Modeling of 3D Seismically Constrained Braided River Reservoirs: A Case Study of Block Venezuela M. Earth Science, 47(11): 4033-4045 (in Chinese with English abstract). Jia, A. L., 2010. Fine Reservoir Description and Geological Modeling Technology. Petroleum Industry Press, Beijing (in Chinese with English abstract). Li, Y., Wang, R., Zhao, Q. M., et al., 2023. Evaluation Method of Carbon Dioxide Sequestration Potential of Salt Water Layer in Petroleum Basin. Petroleum Exploration and Development, 50(2): 424-430 (in Chinese). Li, Z. L., Pan, M., Han, D. G., et al., 2016. 3D Structural Modeling Technology. Earth Science, 41(12): 2136-2146 (in Chinese with English abstract). Lian, Z. G., Li, J., Wang, X., et al., 2019. Comparison of Deterministic Modeling and Stochastic Modeling for Interlayers in Clastic Reservoir Development. Xinjiang Petroleum Geology, 40(5): 605-609 (in Chinese with English abstract). Liu, T., Ma, X., Diao, Y. J., et al., 2021. Research Status of CO2 Geological Storage Potential Evaluation Methods at Home and Abroad. Geological Survey of China, 8(4): 101-108 (in Chinese with English abstract). Ma, Y. K., Lian, Y. X., Yu, X., et al., 2021.3D Geologic Modeling for Complex Fault Block Oil and Gas Reservoirs and Its Application to Nanbaxian Oil and Gasfield, Qaidam Basin. Natural Gas Technology and Economy, 15(1): 18-23 (in Chinese with English abstract). Onoja, M. U., Williams, J. D. O., Vosper, H., et al., 2019. Effect of Sedimentary Heterogeneities in the Sealing Formation on Predictive Analysis of Geological CO2 Storage. International Journal of Greenhouse Gas Control, 82: 229-243. https://doi.org/10.1016/j.ijggc.2019.01.013 Qu, L. C., Bian, C. R., 2012. Application of Fault Modeling Combined with Well Data and Seismic Data in Complicated Fault Block. Fault-Block Oil & Gas Field, 19(4): 426-429 (in Chinese with English abstract). Randi, A., Sterpenich, J., Thiéry, D., et al., 2017. Experimental and Numerical Simulation of the Injection of a CO2 Saturated Solution in a Carbonate Reservoir: Application to the CO2-DISSOLVED Concept Combining CO2 Geological Storage and Geothermal Heat Recovery. Energy Procedia, 114: 2942-2956. https://doi.org/10.1016/j.egypro.2017.03.1423 Sang, S. X., Liu, S. Q., Lu, S. J., et al., 2022. Engineered Full Flowsheet Technology of CCUS and Its Research Progress. Petroleum Reservoir Evaluation and Development, 12(5): 711-725, 733 (in Chinese with English abstract). Shen, X. F., Dong, W. H., Wan, Y. Y., et al., 2021. Numerical Simulation of Effects of Microbial Action on CO2 Geological Storage in Deep Saline Aquifers. Natural Resources Research, 30(2): 1629-1648. https://doi.org/10.1007/s11053-020-09780-7 Shi, Y. C., Chen, M. Q., Zhang, S. Q., et al., 2012. Point-Line-Surface-Geometry Four-Step Structural Modeling for Complex Fault-Block Reservoir. Xinjiang Petroleum Geology, 33(4): 488-490 (in Chinese with English abstract). Sun, Y., Lin, R. Y., Pan, Y., et al., 2021. Experimental Analysis and Numerical Simulation of the Stability of Geological Storage of CO2: A Case Study of Transforming a Depleted Gas Reservoir into a Carbon Sink Carrier. ACS Omega, 6(50): 34832-34841. https://doi.org/10.1021/acsomega.1c05475 Tang, J. F., Tang, M. M., Lu, S. F., et al., 2024. Three- Dimensional Modeling of Estuary Reservoir Based on Coupling Sedimentary Dynamics Simulation and Multipoint Geostatistics Method. Earth Science, 49(1): 174-188 (in Chinese with English abstract). Wang, M. C., Duan, T. Z., Ji, B. Y., 2017. Research Progress and Application of Multipoint Statistics Geological Modeling Technology. Journal of Palaeogeography, 19(3): 557-566 (in Chinese with English abstract). Wang, W. F., Yang, S. C., Jin, Q., et al., 1996. Microscopic Characteristics of the Second Member of Funing Formation in Xiyuan Area of Jinhu Sag. Journal of China University of Petroleum (Edition of Natural Science), 20(5): 12-16 (in Chinese with English abstract). Yang, Y. Z., 2003. Geological Modeling Study of Complex Fault Block Reservoir Transected by Many Interior Faults. Bulletin of Science and Technology, 19(3): 196-200 (in Chinese with English abstract). doi: 10.3969/j.issn.1001-7119.2003.03.005 Yu, X. H., Chen, J. Y., Zhang, Z. J., et al., 2005. Constraint Method of Phased Stochastic Modeling Technology for Oil and Gas Reservoirs. Earth Science Frontiers, 12(3): 237-244 (in Chinese with English abstract). doi: 10.3321/j.issn:1005-2321.2005.03.025 Zhang, J. L., Si, X. Q., Lin, H., 2006. Sedimentary Facies Analysis of the 3rd Member of the Funing Formation in the Jinhu Depression. Periodical of Ocean University of China, 36(4): 535-539 (in Chinese with English abstract). Zhang, W. B., Duan, T. Z., Liu, Y. F., et al., 2019. Application Status and Development Trend of Quantitative Geological Modeling. Geological Science and Technology Information, 38(3): 264-275 (in Chinese with English abstract). Zou, T., Xu, F., 2015. Technical Strategy for Fine Geological Modeling in Later Development Stage of Complex Fault-Block Oilfield. Journal of Southwest Petroleum University (Science & Technology Edition), 37(4): 35-40 (in Chinese with English abstract). 崔振东, 刘大安, 曾荣树, 等, 2010. 中国CO2地质封存与可持续发展. 中国人口·资源与环境, 20(3): 9-13. 高寿涛, 杨宏伟, 吕德灵, 等, 2010. 多资料约束的复杂断块油田精细构造地质建模. 特种油气藏, 17(6): 29-31. 高炎, 李维锋, 施小荣, 2008. 金湖凹陷范庄油田阜宁组层序划分及沉积相分析. 石油天然气学报, 30(5): 225-227. 黄文松, 2022. 三维地震约束辫状河储层的多点统计建模研究: 以委内瑞拉M区块为例. 地球科学, 47(11): 4033-4045. doi: 10.3799/dqkx.2022.203 贾爱林, 2010. 精细油藏描述与地质建模技术. 北京: 石油工业出版社. 李阳, 王锐, 赵清民, 等, 2023. 含油气盆地咸水层二氧化碳封存潜力评价方法. 石油勘探与开发, 50(2): 424-430. 李兆亮, 潘懋, 韩大匡, 等, 2016. 三维构造建模技术. 地球科学, 41(12): 2136-2146. doi: 10.11764/j.issn.1672-1926.2016.12.2136 练章贵, 李君, 王晓, 等, 2019. 碎屑岩油藏开发中隔夹层确定性建模与随机建模对比. 新疆石油地质, 40(5): 605-609. 刘廷, 马鑫, 刁玉杰, 等, 2021. 国内外CO2地质封存潜力评价方法研究现状. 中国地质调查, 8(4): 101-108. 马元琨, 连运晓, 鱼雪, 等, 2021. 复杂断块油气藏三维地质建模技术及其应用: 以柴达木盆地南八仙油气田为例. 天然气技术与经济, 15(1): 18-23. 曲良超, 卞昌蓉, 2012. 井震结合断层建模技术在复杂断块中的应用. 断块油气田, 19(4): 426-429. 桑树勋, 刘世奇, 陆诗建, 等, 2022. 工程化CCUS全流程技术及其进展. 油气藏评价与开发, 12(5): 711-725, 733. 史玉成, 陈明强, 张审琴, 等, 2012. 复杂断块油藏"点-线-面-体" 四步法构造建模技术. 新疆石油地质, 33(4): 488-490. 唐佳凡, 唐明明, 卢双舫, 等, 2024. 基于耦合沉积动力学模拟与多点地质统计学方法的河口湾储层三维建模. 地球科学, 49(1): 174-188. doi: 10.3799/dqkx.2022.199 王鸣川, 段太忠, 计秉玉, 2017. 多点统计地质建模技术研究进展与应用. 古地理学报, 19(3): 557-566. 王伟锋, 杨少春, 金强, 等, 1996. 金湖凹陷西园地区阜宁组二段储层的微观特征. 石油大学学报(自然科学版), 20(5): 12-16. 杨耀忠, 2003. 内部被多条断层切割的复杂断块油藏地质建模研究. 科技通报, 19(3): 196-200. 于兴河, 陈建阳, 张志杰, 等, 2005. 油气储层相控随机建模技术的约束方法. 地学前缘, 12(3): 237-244. 张金亮, 司学强, 林辉, 2006. 金湖凹陷阜三段沉积相分析. 中国海洋大学学报(自然科学版), 36(4): 535-539. 张文彪, 段太忠, 刘彦锋, 等, 2019. 定量地质建模技术应用现状与发展趋势. 地质科技情报, 38(3): 264-275. 邹拓, 徐芳, 2015. 复杂断块油田开发后期精细地质建模技术对策. 西南石油大学学报(自然科学版), 37(4): 35-40. -
下载:
点击查看大图
图(11)
计量
- 文章访问数: 22
- HTML全文浏览量: 9
- PDF下载量: 10
- 被引次数: 0
