饶翔
详细资料
姓名:饶翔
职称:副教授
学科方向:油气田开发工程
研究领域:数值计算方法,无网格油藏数模技术,量子计算,非常规油气藏数值模拟,油气藏智能开发生产优化技术
联系方式:17600401385,邮箱:raoxiang0103@163.com, raoxiang@yangtzeu.edu.cn
所在系所:油气田开发工程
教学情况:主讲《偏微分方程数值解》、《专业英语》、《现代试井解释方法》、《油藏物理与油藏工程》、《群论及其应用》、《薛定谔的猫——量子计算基础概论》等课程
基本信息:
湖北孝感人,1994年1月生,九三学社社员,入选“全球前2%顶尖科学家”、湖北省重大人才项目、湖北省青年科技人才晨光托举工程、“武汉英才”优秀青年人才、长江大学“学科菁英人才”,主持国家自然科学基金面上项目、青年基金项目、国家科技重大专项子任务、国家重点实验室开放基金、省部级科研平台开放基金,担任国家自然科学基金评议专家、SPE Asia Pacific Regional Award评奖委员会委员、多个期刊编辑及客座编辑,获CMES Young Researcher Award以及省部级科技进步一等奖一项,多次担任国际学术会议分论坛主席,以第一作者/通讯作者在《Journal of Computational Physics》、《SPE Jounral》、《Computational Geosciences》、《International Journal for Numerical Methods in Fluids》等SCI/EI高水平期刊发表论文近70篇,独作出版学术专著一部,以第一发明人授权国家发明专利10项,授权美国发明专利3项。
教育及工作经历:
2012.09~2016.06,中国石油大学(北京)石油工程专业,工学学士;
2016.09~2020.06,中国石油大学(北京)油气田开发工程专业,硕博连读,工学博士;
2020.07-2022.12,长江大学石油工程学院,讲师;
2022.12-至今,长江大学石油工程学院,副教授;
2023.01-2024.01,阿卜杜拉国王科技大学,博士后;
2024.09-2025.02,阿卜杜拉国王科技大学,国家公派访问学者;
学术成果:
截至2025年9月,以第一作者或通讯作者发表论文近70篇、出版学术专著一部,部分列举如下:
1 Rao X*, Zhao H, Liu Y. A meshless numerical modeling method for fractured reservoirs based on extended finite volume method[J]. SPE Journal, 2022: 1-40. SPE-210581-PA.
2 Rao X*, He X, Du K, et al. A Novel Projection-based Embedded Discrete Fracture Model (pEDFM) for Anisotropic Two-phase Flow Simulation Using Hybrid of Two-point Flux Approximation and Mimetic Finite Difference (TPFA-MFD) Methods[J]. Journal of Computational Physics, 2024, 499: 112736.
3 Rao X*, Guo S, He X, et al. A first streamline-based simulation method within the projection-based embedded discrete fracture model (pEDFM)[J]. Computers and Geotechnics, 2025, 185: 107357.
4 Rao X*, He X, Kwak H, et al. A Hybrid Method Combining Mimetic Finite Difference and Discontinuous Galerkin for Two‐Phase Reservoir Flow Problems[J]. International Journal for Numerical Methods in Fluids, 2024.
5 Rao X*, Liu Y, He X, et al. Physics-informed Kolmogorov–Arnold networks to model flow in heterogeneous porous media with a mixed pressure-velocity formulation[J]. Physics of Fluids, 2025, 37(7).
6 Rao X*, Liu Y, He X, et al. Physics-Informed Kolmogorov-Arnold Networks (PIKANs) for Solving the Buckley-Leverett Equation in Waterflooding Reservoirs[C]//SPE Reservoir Simulation Conference. SPE, 2025: D012S001R009.
7 Rao X*. The First Application of Quantum Computing Algorithm in Streamline-Based Simulation of Water-Flooding Reservoirs[C]//Abu Dhabi International Petroleum Exhibition and Conference. SPE, 2024: D011S003R006.
8 Rao X*, Luo C, He X, et al. An Efficient Quantum Neural Network Model for Prediction of Carbon Dioxide CO2 Sequestration in Saline Aquifers[C]//Abu Dhabi International Petroleum Exhibition and Conference. SPE, 2024: D021S061R005.
9 饶翔. 投影嵌入式离散裂缝模型[M]. 湖南科学技术出版社, 2024.
10 Huang, H., Wei, J., Zhang, Z., Zhang, X., & Rao, X*. (2025). Two-dimensional black-oil simulation using the meshless extended finite volume method. Physics of Fluids, 37(7).
11 Zhao H, Rao X*, Liu D, et al. A Flownet-Based Method for History Matching and Production Prediction of Shale or Tight Reservoirs with Fracturing Treatment[J]. SPE Journal, 2022: 1-27. SPE-209624-PA.
12 Rao X*, He X, Xu Y, et al. Numerical simulation of carbon dioxide flooding in fractured reservoirs using generic projection-based embedded discrete fracture model[J]. Physics of Fluids, 2024, 36(10).
13 Liu B, Kang L, Rao X*. A numerical simulation method applicable to staggered grids for two-phase reservoir flow problems[J]. Physics of Fluids, 2025, 37(2).
14 Luo C, Rao X*, He X. Numerical simulation of compositional flow in shale gas-condensate reservoirs using generic projection-based embedded discrete fracture model[J]. Physics of Fluids, 2024, 36(9).
15 Rao X*, Du K. Performance Study of Variational Quantum Linear Solver for Linear Elastic Problems[J]. Computational and Experimental Simulations in Engineering: Proceedings of ICCES 2024—Volume 1, 2024, 1: 80.
16 Rao X, Guo S, He X, et al. Hybrid Mimetic Finite Difference and Streamline Methods for Numerical Simulation of Two-phase Flow in Fractured Reservoirs[J]. Computers and Geotechnics, 2024, 166: 106048.
17 Rao X*. Performance study of variational quantum linear solver with an improved ansatz for reservoir flow equations. Physics of Fluids. 2024 Apr 1;36(4).
18 Rao X, He X, Kwak H, et al. A novel streamline simulation method for fractured reservoirs with full-tensor permeability[J]. Physics of Fluids, 2024, 36(1).
19 Rao X*. A generic workflow of projection-based embedded discrete fracture model for flow simulation in porous media[J]. Computational Geosciences, 2023: 1-30.
20 饶翔,徐云峰,刘伟等.油藏组分模型的无网格扩展有限体积法[J/OL].计算力学学报,1-9.
21 饶翔,何旭鹏,赵辉等.基于模拟有限差分法的两相渗流流线模拟新方法[J/OL].计算力学学报,1-9.
22 Rao X*, Zhao H*, Liu Y. A novel meshless method based on the virtual construction of node control domains for porous flow problems[J]. Engineering with Computers, 2023: 1-41.
23 Rao X*. An upwind generalized finite difference method (GFDM) for meshless analysis of heat and mass transfer in porous media[J]. Computational Particle Mechanics, 2022: 1-22.
24 Zhan W, Zhao H, Rao X*, et al. Generalized finite difference method-based numerical modeling of oil–water two-phase flow in anisotropic porous media[J]. Physics of Fluids, 2023, 35(10).
25 Liu Y, Rao X*, Zhao H, et al. A Meshless Solver for Coupled Two-Phase Flow and Geomechanics in Fractured Reservoirs[C]//International Conference on Computational & Experimental Engineering and Sciences. Cham: Springer Nature Switzerland, 2023: 103-115.
26 Liu Y, Rao X*, Zhao H, et al. Generalized finite difference method based meshless analysis for coupled two-phase porous flow and geomechanics[J]. Engineering Analysis with Boundary Elements, 2023, 146: 184-203.
27 Rao X*, Xin L, H, Zhao H*, et al. Numerical simulation of two-phase heat and mass transfer in fractured reservoirs based on projection-based embedded discrete fracture model (pEDFM), Journal of Petroleum Science and Engineering, 2022, 109323.
28 Rao, X.*, Liu, Y., and Zhao, H.*. "An upwind generalized finite difference method for meshless solution of two-phase porous flow equations." Engineering Analysis with Boundary Elements 137 (2022): 105-118.
29 Rao X*, Liu Y. A Numerical Modelling Method of Fractured Reservoirs with Embedded Meshes and Topological Fracture Projection Configurations. Computer Modeling in Engineering & Sciences. 2022. https://doi.org/10.32604/cmes.2022.018879
30 Rao, X.*, Xu, Y., Liu, D., Liu, Y., Hu, Y. A general physics-based data-driven framework for numerical simulation and history matching of reservoirs. Advances in Geo-Energy Research, 2021, 5(4): 422-436, doi: 10.46690/ager.2021.04.07.
31 赵辉*, 刘伟, 饶翔*, 湛文涛. 油藏数值模拟连接元计算方法[J]. 中国科学(技术科学), 2021.
32 Peng X, Rao X*, Zhao Hui*, et al. A proxy model to predict reservoir dynamic pressure profile of fracture network based on deep convolutional generative adversarial networks (DCGAN)[J]. Journal of Petroleum Science and Engineering, 2022.
33 Liu D, Rao X*, Zhao Hui*, et al. An improved data space inversion method to predict reservoir state fields via observed production data [J]. Petroleum Science, 2021.
34 Shi J, Cheng L*, Rao X*. A modified embedded discrete-fracture model to study oil-water two-phase heat and mass transfer in the complex fracture network [J]. International Journal of Heat and Mass Transfer, 2021, 121215.
35 Xu, Y., Hu, Y., Rao X*. "A fractal physics-based data-driven model for water-flooding reservoir (FlowNet-fractal)." Journal of Petroleum Science and Engineering 210 (2022): 109960.
36 Rao X, Zhan Wentao, Zhao Hui*, et al. Application of the least-square meshless method to gas-water flow simulation of complex-shape shale gas reservoirs[J]. Engineering Analysis with Boundary Elements, 2021, 129(1):39-54.
37 Shi J, Cheng L*, Rao X*. A modified embedded discrete-fracture model to study oil-water two-phase heat and mass transfer in the complex fracture network [J]. International Journal of Heat and Mass Transfer, 2021, 121215.
38 Chen, X., Rao, X*., Xu, Y., & Liu, Y. (2022). An Effective Numerical Simulation Method for Steam Injection Assisted In Situ Recovery of Oil Shale. Energies, 15(3), 776.
39 Rao X*, Cheng L, Cao R, et al. A modified projection-based embedded discrete fracture model (pEDFM) for practical and accurate numerical simulation of fractured reservoir[J]. Journal of Petroleum Science and Engineering, 2020, 187: 106852. (SCI/EI)
40 Rao X, Zhao H*, Deng Q. Artificial-neural-network (ANN) based proxy model for performances forecast and inverse project design of water huff-n-puff technology[J]. Journal of Petroleum Science and Engineering, 2020, 107851. (SCI/EI)
41 Rao X*, Cheng L, Cao R, et al. A modified embedded discrete fracture model to study the water blockage effect on water huff-n-puff process of tight oil reservoirs[J]. Journal of Petroleum Science and Engineering, 2019, 181: 106232. (SCI/EI)
42 Rao X*, Cheng, L., Cao, R., Li, N., Jiang, J., & Wang, L. A novel 3D Green element method to simulate counter-current spontaneous imbibition considering the effect of gravity[J]. Journal of Petroleum Science and Engineering, 2019, 175:224-236. (SCI/EI)
43 Liu H, Rao X*, Xiong H*. Evaluation of CO2 sequestration capacity in complex-boundary-shape shale gas reservoirs using projection-based Embedded Discrete Fracture Model (pEDFM)[J]. Fuel, 2020, 118201. (SCI/EI)
44 Rao X*, Cheng L*, Cao R, et al. An efficient three-dimensional embedded discrete fracture model for production simulation of multi-stage fractured horizontal well[J]. Engineering Analysis with Boundary Elements, 2019, 106: 473-492. (SCI/EI)
45 Rao X*, Cheng L.*, Cao R., Jiang, J., Fang, S., Jia, P., & Wang, L. A novel Green element method based on two sets of nodes[J]. Engineering Analysis with Boundary Elements, 2018, 91:124-131. (SCI/EI)
46 Rao X*, Cheng, L.*, Cao, R., Jiang, J., Li, N., Fang, S., Jia, P., & Wang, L. A novel Green element method by mixing the idea of the finite difference method[J]. Engineering Analysis with Boundary Elements, 2018, 95:238-247. (SCI/EI)
47 Rao X*, Cheng, L.*, Cao, R., Zhang, X., & Dai, D. A mimetic Green element method [J]. Engineering Analysis with Boundary Elements, 2019, 99:206-221. (SCI/EI)
48 Rao X*, Cheng, L.*, Cao, R., Song, W., Du, X., He, Y., & Dai, D. Numerical simulation of two-phase flow in porous media based on mimetic Green element method[J]. Engineering Analysis with Boundary Elements, 2019, 101, 113–120. (SCI/EI)
49 Rao X*, Cheng L*, Wang L, et al. Modification of constant volumetric displacement model for the steady-stage SAGD process[J]. Arabian Journal of Geosciences, 2019, 12(9): 295. (SCI/EI)
50 Rao X*, Cheng, L.*, Cao, R., Jia, P., & Du, X. (2019). A Fast Embedded Discrete Fracture Model Based on Proper Orthogonal Decomposition POD Method. SPE Kuwait Oil & Gas Show and Conference. (EI)
51 Rao, X.*, Cheng, L.*, Cao, R., Jia, P., Dong, P., & Du, X. (2019). A Modified Embedded Discrete Fracture Model to Improve the Simulation Accuracy During Early-Time Production of Multi-Stage Fractured Horizontal Well. SPE/IATMI Asia Pacific Oil & Gas Conference and Exhibition. (EI)
52 Rao X,*, Cheng, L.*, Cao, R., Jia, P., & Wu, Y. A novel embedded discrete fracture model based on GEM of two-set nodes. Proceedings of ICCESEN-2018, 2018, 280-284.
53 饶翔, 卢贵武. 关于晶体空间群性质的证明的一个注记[J]. 大学物理, 2019, 38(11).
发明专利:
1. Rao X, He X, Du K, et al. Projection-based embedded discrete fracture model using hybrid of two-point flux approximation and mimetic finite difference (TPFA-MFD) method: U.S. Patent 12,174,331[P]. 2024-12-24.
2. He X, Rao X, Kwak H T, et al. Simulating Multi-phase Flow in Fractured Reservoirs: U.S. Patent Application 18/589,301[P]. 2025-8-28.
3. He, X., Alsinan, M. M., Zhang, Z., Kwak, H. T., Hoteit, H., & Rao, X. (2025). U.S. Patent Application No. 18/492,505.
4. 饶翔,何旭鹏,杜扣,刘怡娜.一种基于TPFA与MFD混合方法的投影嵌入式离散裂缝模型:202310879050.0[P].2024-01-23.
5. 饶翔,何旭鹏,徐云峰,康莉霞,杜扣,郭淑晴,成梦娜.基于通用型pEDFM的裂缝性油藏CO-2驱模拟方法:202410791924.1[P].2025-03-07.
6. 饶翔.一种基于量子计算的油藏数值模拟压力方程求解方法: 202410126362.9 [P].2024-08-30.
7. 饶翔,康莉霞,罗成杰,何旭鹏,杜扣,郭淑晴,成梦娜.基于通用型pEDFM的页岩凝析气藏开发数值模拟方法:202410792120.3[P].2025-03-07.
8. 饶翔,赵辉,徐云峰,等.一种油藏组分模型无网格数值模拟方法[P].CN202310033797.4,2023-10-13.
9. 饶翔,赵辉,徐云峰,等.基于迎风GFDM的多孔介质油水两相流计算方法[P].CN202111323681.1,2023-09-05.
10. 饶翔,赵辉,刘怡娜.用于无网格油藏数值模拟的裂缝网络点云生成方法[P].CN202210531851.3,2023-06-16.
11. 饶翔,赵辉,湛文涛,等.基于广义有限差分方法的各向异性储层渗流模拟方法[P].CN202111323669.0,2023-09-01.
12. 饶翔,赵辉,刘怡娜,等.基于迎风GFDM的储层多孔介质流温耦合模型计算方法[P].CN202111323587.6,2023-08-08.
13. 饶翔,何旭鹏,赵辉,等.一种基于模拟有限差分法的油水两相流线模拟新方法[P].CN202310946821.3,2023-10-10.
科研项目:
1. 基于混合通量估计的裂缝性油藏数值模拟及流动分析新方法研究,国家自然科学基金面上项目,2026-01至2029-12,在研,主持;
2. 井筒与油气藏渗流耦合的智能动态模拟技术,国家科技重大专项子任务,2025-08至2030-12,在研,主持;
3. 基于无网格连接体系的裂缝性油气藏数值模拟新方法,国家自然科学基金青年项目,2022-01至2024-12,结题,主持;
4. 油页岩注蒸汽原位开采三维传热传质数值模拟-历史拟合-生产优化的一体化技术研发,国家油页岩开采研发中心开放基金,2021-06至2022-06, 结题,主持;
5. Natural Fractures Technology (NAFT), 沙特阿美国家石油公司, 2022-09至2025-12,在研,技术骨干;
6. 基于微观力学作用低渗致密油藏复杂缝网系统多相流数值模拟技术研究,延长石油(集团)有限责任公司研究院,2025-04至2026-12,在研,课题4负责人;
7. 化学驱油藏方案智能优化软件开发服务,中海油海能发工程技术分公司,2024-04至2025-05,结题,技术负责人;
8. 基于扩展有限体积法的无网格油藏模拟新技术,油气钻采工程湖北省重点实验室开放基金,2022-04至2024-12,结题,主持;
9. 海上新型油藏数值模拟技术研究,中海油研究总院,2022-11至2025-06,结题,技术骨干;
10. 通用型裂缝性油气藏无网格数值建模方法,非常规油气省部共建协同创新中心开放基金项目,2022-01至2022-12,结题,主持;
11. 非常规储层三维复杂缝网流动的高效高精度数值模拟技术,非常规油气省部共建协同创新中心开放基金项目,2021-01至2021-12,结题,主持;
12. 稠油热采吞吐产能预测方法,中海油服天津分公司,2021-09至2022-12,结题,技术负责人;
13. 蒸汽驱智能注采实时优化软件,中海油服天津分公司,2020-09至2021-09,结题,技术负责人;
14. 超低渗透油藏渗流规律及高效开发的关键科学问题,国家自然科学基金重点支持项目,技术骨干;
15. 超低渗透油藏有效开采技术-超低渗透油藏水平井井网优化设计研究,国家油气重大专项,技术骨干;
鄂尔多斯盆地致密油开发示范工程-长7致密油藏地层压力系统评价及优化,国家油气重大专项,技术骨干。
(2025年9月更新)
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