教育背景
2008.10-2009.09,剑桥大学工程系,公派联合培养博士生
2004.09-2010.07,清华大学热能系,博士学位
2000.09-2004.07,清华大学热能系,学士学位
工作履历
2021.12-今,清华大学能动系,副研究员
2014.05-2021.11,清华大学能动系(原热能系),讲师、助理研究员
2010.08-2014.03,Tohoku University, Japan, Research Associate
学术兼职
1. 工程热物理学会热机气动热力学分会,青年委员
2. 《Propulsion&Energy》及《推进技术》杂志,青年编委
3. 本领域国内外多个期刊审稿人
研究领域
1. 叶轮机械内部流动机理
2. 多物理场耦合及伴随理论和伴随优化
3. 内流复杂湍流机理与模拟模型
4.飞行器外流及内外流一体化
5. 计算流体力学与工业软件
研究概况
在研科研项目
1. 自然科学基金面上项目,全覆盖气膜在三个空间尺度上的关键机制和冷却有效度面分布理论
2. 重大专项基础研究和关键技术研究课题
3. 重大项目关键技术及样机研制
4. 重点研发计划子课题
已完成科研项目
1. 自然科学基金青年项目,基于伴随理论和谐波平衡方法的多级叶轮机械非定常气动设计研究(结题评价“优+”)
2. 自然科学基金面上项目,非均匀边界环境下气冷透平的伴随边界理论及流热机理研究(结题评价“优秀”)
3. 自然科学基金国际合作项目,旋转环境气冷透平动叶叶顶间隙内流动传热特性高精度测量与模拟方法研究
奖励与荣誉
1. Journal of Thermal Science、Chinese Journal of Aeronautics期刊优秀审稿人
2. 动力工程学会透平专委会2016、2018、2020、2023年度优秀论文奖
3. 中国航空学会动力分会2023年优秀论文奖
4. 工程热物理学会2018年度热能动力技术学术会议优秀论文一等奖
学术成果
For more information, please check: https://www.researchgate.net/profile/Xinrong-Su
(1) Hu, K.; Yang, Y.; Zhang, Z.; Su, X.; Yuan, X. Cooling Performance Measurement and Layout Optimization of Full-Coverage Turbine Vane Considering the Inlet Swirl. International Communications in Heat and Mass Transfer 2025, 162, 108623. https://doi.org/https://doi.org/10.1016/j.icheatmasstransfer.2025.108623.
(2) 张振; 叶林; 苏欣荣; 袁新. 用于气膜冷却的机器学习湍流模型. 工程热物理学报 2024, 45 (5), 1324–1331.
(3) 张振; 苏欣荣; 袁新. 基于物理信息神经网络的气膜冷却湍流模型反演学习. 动力工程学报 2024, 44 (9), 1459–1465. https://doi.org/10.19805/j.cnki.jcspe.2024.240201.
(4) 祁明旭; 季正鑫; 龙启运; 苏欣荣. 高负荷涡轮叶栅风洞流动周期性研究. 北京理工大学学报自然版 2024, 44 (9), 970–979. https://doi.org/10.15918/j.tbit1001-0645.2024.038.
(5) 漆粤川; 马灿; 苏欣荣; 袁新. 极小展弦比跨音速汽轮机叶片非定常流动机理研究. In 中国造船工程学会船舶热能动力学术会议, 优秀论文奖; 武汉, 2024.
(6) 杨伊凡; 胡可欣; 丁唯航; 苏欣荣; 袁新. 透平导叶前缘气膜冷却射流与主流交互LES模拟及机理研究. In 中国工程热物理学会热机气动热力学和流体机械学术会议; 成都, 2024.
(7) 严晓; 马灿; 丁唯航; 苏欣荣; 袁新. 叶轮机械设计经验关联式的符号回归构造方法及应用. In 中国工程热物理学会热机气动热力学和流体机械学术会议; 成都, 2024.
(8) 张蔚然; 马灿; 苏欣荣; 陈建; 袁新. 不同加载形式下涡轮叶顶非定常流动研究. In 中国工程热物理学会热机气动热力学和流体机械学术会议; 成都, 2024.
(9) 苏泓州; 卢义; 苏欣荣; 袁新. 基于大涡模拟的涡轮叶片优化探索. In 中国工程热物理学会热机气动热力学和流体机械学术会议; 成都, 2024.
(10) 漆粤川; 马灿; 苏欣荣; 袁新. 极小展弦比跨音速透平叶片通道内的流动结构与损失机理. In 中国工程热物理学会热机气动热力学和流体机械学术会议; 成都, 2024.
(11) 严晓; 马灿; 苏欣荣; 袁新. 基于符号回归的透平经验关联式构造方法. In 中国动力工程学会透平专业委员会, 优秀论文奖; 北京, 2024.
(12) 严晓; 宋玉洋; 苏欣荣; 袁新. 叶轮机械设计经验关联式的符号回归构造方法及应用. In 全国智能流体力学会议; 西安, 2024.
(13) Hu, K.; Yang, Y.; Ma, C.; Su, X.; Yuan, X. Large Eddy Simulation of the Shaped Film Cooling with the Influence of Streamwise Pressure Gradient. In 6th Chinese International Turbomachinery Conference; Sanya, China, 2024.
(14) Yan, X.; Huang, T.; Su, X.; Yuan, X. Effect of Film Cooling Hole Geometry on Thermal Stress Based on Thermo-Solid Coupled Analysis; Turbo Expo: Power for Land, Sea, and Air; 2024; Vol. Volume 7: Heat Transfer: Combustors; Heat Transfer: Film Cooling, p V007T12A021. https://doi.org/10.1115/GT2024-124974.
(15) Zhang, Z.; Hu, K.; Su, X.; Yuan, X. Data-Driven Turbulence Modeling for Film Cooling Heat Transport, Part I: Turbulent Heat Transport Property at Wide Flow Conditions; Turbo Expo: Power for Land, Sea, and Air; 2024; Vol. Volume 7: Heat Transfer: Combustors; Heat Transfer: Film Cooling, p V007T12A023. https://doi.org/10.1115/GT2024-125660.
(16) Hu, K.; Zhang, Z.; Su, X.; Yuan, X. Performance Comparison of Different Leading Edge Cooling Layouts Considering Inlet Swirl; Turbo Expo: Power for Land, Sea, and Air; 2024; Vol. Volume 7: Heat Transfer: Combustors; Heat Transfer: Film Cooling, p V007T12A027. https://doi.org/10.1115/GT2024-126024.
(17) Zhang, Z.; Zhang, W.; Su, X.; Yuan, X. Data-Driven Turbulence Modeling for Film Cooling Heat Transport, Part II: Modeling and Evaluation; Turbo Expo: Power for Land, Sea, and Air; 2024; Vol. Volume 7: Heat Transfer: Combustors; Heat Transfer: Film Cooling, p V007T12A026. https://doi.org/10.1115/GT2024-125854.
(18) Huang, T.; Li, H.; Su, X.; Yuan, X. Influence of Film Hole Arrangement on Cooling and Aerodynamic Performance of Blade Tip with Squealer Structure. International Journal of Thermal Sciences 2024, 195, 108636. https://doi.org/10.1016/j.ijthermalsci.2023.108636.
(19) Mao, Y.; Su, X.; Yuan, X. An Off-Design Flow Angle Model Based on Averaged-Flow Theory and Wake Analysis. Journal of Thermal Science 2023, 32 (2). https://doi.org/10.1007/s11630-023-1774-2.
(20) Zhang, Z.; Hu, T.; Su, X.; Yuan, X. Optimization of the Double-Expansion Film-Cooling Hole Using CFD. Entropy 2023, 25, 3. https://doi.org/10.3390/e25030410.
(21) Zhang, H.; Gou, J.; Yin, P.; Su, X.; Yuan, X. Film-Cooling Hole Optimization and Experimental Validation Considering the Lateral Pressure Gradient. Frontiers in Mechanical Engineering 2023, 8. https://doi.org/10.3389/fmech.2022.973293.
(22) 李会; 黄通; 苏欣荣; 袁新. 基于DDES模拟的叶顶泄漏流与尾迹非定常干涉机理. 航空学报 2023, 44 (14), 628325.
(23) 胡可欣; 张振; 苏欣荣; 袁新. 透平静叶叶身全覆盖气膜冷却有效度实验研究. 工程热物理学报 2023, 44 (7), 1793–1799.
(24) 胡可欣; 苏欣荣; 袁新. 旋流影响下全覆盖气膜冷却机理的实验研究与布局优化. In 中国动力工程学会透平专业委员会, 优秀论文奖; 无锡, 2023.
(25) 张振; 苏欣荣; 袁新. 气膜冷却机器学习湍流传热模型. In 中国航空学会动力分会第二十一届叶轮机专业学术交流会, 优秀论文奖; 贵阳, 2023.
(26) Huang, T.; Su, X.; Yuan, X. Influence of Film Cooling Hole Geometry on the Gas Turbine Blade Strength. In Proceedings of Global Power and Propulsion Society; Hong Kong, 2023.
(27) Hu, K.; Zhang, Z.; Su, X.; Yuan, X. Efficient Assessment of Turbine Blade Performance with Non-Uniform Boundary Condition Using Adjoint Sensitivity. In Proceedings of Global Power and Propulsion Society; Hong Kong, 2023.
(28) Wang, Q.; Su, X.; Yuan, X. Large-Eddy Simulation of Shaped Hole Film Cooling with the Influence of Cross Flow. International Journal of Turbo and Jet Engines 2022, 39 (4), 575–588. https://doi.org/10.1515/tjj-2020-0012.
(29) Mao, Y.; Chen, Z.; Su, X.; Yuan, X. A Novel Model for CFD-Based Throughflow Analysis of Film-Cooled Turbine Blade. Journal of Thermal Science 2022, 31 (5), 1759–1772. https://doi.org/10.1007/s11630-022-1579-8.
(30) Chen, Z.; Su, X.; Yuan, X. Trajectory and Effectiveness of Film Cooling in Endwall Crossflow. Aerospace Science and Technology 2022, 128, 107795. https://doi.org/10.1016/j.ast.2022.107795.
(31) Zhang, Z.; Mao, Y.; Su, X.; Yuan, X. Inversion Learning of Turbulent Thermal Diffusion for Film Cooling. Physics of Fluids 2022, 34 (3), 035118. https://doi.org/10.1063/5.0084237.
(32) Chen, Z.; Mao, Y.; Hu, K.; Su, X.; Yuan, X. Theoretical Model for Two-Dimensional Film Cooling Effectiveness Distribution Prediction. Physics of Fluids 2022, 34 (2), 025122. https://doi.org/10.1063/5.0081694.
(33) Hu, K.; Wang, Q.; Su, X.; Yuan, X. Large-Eddy Simulation of Shaped Hole Film Cooling with the Influence of Streamwise Pressure Gradient. In Proceedings of Global Power and Propulsion Society; Xian, China, 2022.
(34) Huang, T.; Li, H.; Su, X.; Yuan, X. Influence of Depth and Rim Width of Squealer Tip on the Leakage Flow and Heat Transfer. In Proceedings of Global Power and Propulsion Society; Xian, China, 2022.
(35) Mao, Y.; Su, X.; Yuan, X. Unsteady Analysis with Throughflow Concept. In Proceedings of Global Power and Propulsion Society; Xian, China, 2022.
(36) Zhang, Z.; Mao, Y.; Su, X.; Yuan, X. Adjoint-Based Boundary Condition Sensitivity Analysis. AIAA Journal 2022, 60 (6), 3517–3527. https://doi.org/10.2514/1.J061307.
(37) Chen, Z.; Su, X.; Yuan, X. Cooling Performance of the Endwall Vertical Hole Considering the Interaction between Cooling Jet and Leading-Edge-Horseshoe Vortex. Journal of Thermal Science 2022, 31 (5), 1696–1708. https://doi.org/10.1007/s11630-022-1595-8.
(38) Wang, Q.; Su, X.; Yuan, X. Assessment of the Turbulence Characteristics of Shaped Film Cooling Hole with Scale Resolving Simulation. Journal of Thermal Science 2022, 31, 47–61. https://doi.org/10.1007/s11630-022-1545-5.
(39) Su, X.; Yuan, X. Adjoint Boundary Sensitivity Method to Assess the Effect of Nonuniform Boundary Conditions. Chinese Journal of Aeronautics 2022, 35 (2), 12–16. https://doi.org/10.1016/j.cja.2021.04.029.
(40) Chen, Z.; Su, X.; Yuan, X. Interaction Mechanism and Loss Analysis of Mixing between Film Cooling Jet and Passage Vortex. Entropy 2022, 24, 15. https://doi.org/10.3390/e24010015.
(41) Chen, Z.; Hu, K.; Mao, Y.; Su, X.; Yuan, X. Simple Integral Model for Trajectories of Jet Deflection in Crossflow. Physics of Fluids 2021, 33 (11), 111703. https://doi.org/10.1063/5.0073013.
(42) Mao, Y.; Chen, Z.; Li, H.; Su, X.; Yuan, X. On the Relationship between Blade Loading and In-Passage Energy Balance. Aerospace 2021, 8 (11), 324. https://doi.org/10.3390/aerospace8110324.
(43) Chen, Z.; Mao, Y.; Hu, K.; Su, X.; Yuan, X. 2-D Prediction Method for Multi-Row Film Cooling Effectiveness. Applied Thermal Engineering 2021, 199 (25), 117607. https://doi.org/10.1016/j.applthermaleng.2021.117607.
(44) Li, H.; Su, X.; Yuan, X. Analysis of the Relationship between Turbulence Characteristics and Loss Mechanism in the Tip Leakage Flow of Turbine Blade. Proceedings of the Institution of Mechanical Engineers, Part A: Journal of Power and Energy 2021, 235 (6), 1302–1314. https://doi.org/10.1177/09576509211032077.
(45) Su, X.; Bian, X.; Li, H.; Yuan, X. Unsteady Flows of a Highly Loaded Turbine Blade with Flat Endwall and Contoured Endwall. Aerospace Science and Technology 2021, 118, 106989. https://doi.org/10.1016/j.ast.2021.106989.
(46) Zhang, Z.; Li, H.; Su, X.; Yuan, X. In-Hole Characteristic Interface and Film Cooling Interface Model. Journal of Turbomachinery 2021, 143 (10), 101012. https://doi.org/10.1115/1.4050757.
(47) Chen, Z.; Li, Y.; Su, X.; Yuan, X. Scalar Diffusion Equation Based Model to Predict 2-D Film Cooling Effectiveness of a Shaped Hole. Journal of Turbomachinery 2021, 143 (4), 041005. https://doi.org/10.1115/1.4049782.
(48) Wang, Q.; Ma, C.; Su, X.; Yuan, X. Effect of Unsteady Secondary Vortices on the Performance of a 1.5-Stage High-Pressure Turbine. Journal of Thermal Science 2021, 30 (3), 983–998. https://doi.org/10.1007/s11630-020-1371-6.
(49) 陈子聿; 李毅飞; 苏欣荣; 袁新. 基于标量扩散方程的气膜冷却二维分布理论模型. 工程热物理学报 2021, 42 (8), 1958–1963.
(50) 胡可欣; 王青松; 苏欣荣; 袁新. 顺压梯度环境下成型孔气膜冷却射流的大涡模拟. 热能动力工程 2021, 36 (9), 146–153.
(51) 张振; 陈子聿; 苏欣荣; 袁新. 基于孔内流动机理的气膜冷却界面模型. 工程热物理学报 2021, 42 (7), 1692–1699.
(52) 李会; 苏欣荣; 袁新. 基于DDES模拟的叶顶间隙流湍流特性研究. 工程热物理学报 2021, 42 (2), 342–348.
(53) Wang, Q.; Su, X.; Yuan, X. Assessment of the Turbulence Characteristics of Shaped Film Cooling Hole with Scale Resolving Simulation. In Asian Congress on Gas Turbine; Beijing, China, 2021.
(54) Li, H.; Su, X.; Yuan, X. DDES Analysis of Unsteady Characteristics of the Interaction between the Tip Leakage Flow and Wake. In Asian Congress on Gas Turbine; Beijing, China, 2021.
(55) Zhang, H.; Wang, Q.; Chen, Z.; Su, X.; Yuan, X. Effects of Compound Angle on Film Cooling Effectiveness Considering Endwall Lateral Pressure Gradient. Aerospace Science and Technology 2020, 103, 105923. https://doi.org/10.1016/j.ast.2020.105923.
(56) 张振; 苏欣荣; 袁新. 气膜冷却单向弱耦合现象、机理与界面模型. In 中国动力工程学会透平专业委员会, 优秀论文奖; 德阳, 2020.
(57) 卞修涛; 苏欣荣; 袁新. 基于DDES的透平端区湍流特性和损失机理研究. 工程热物理学报 2020, 41 (8), 1895–1902.
(58) 陈子聿; 苏欣荣; 袁新. 气冷透平端区射流与主流的交互作用研究. 风机技术 2020, No. 3, 46–51. https://doi.org/10.16492/j.fjjs.2020.03.0007.
(59) 张浩; 陈子聿; 李毅飞; 苏欣荣; 袁新. 基于多精度代理模型的高效异型气膜孔设计优化和实验验证. 工程热物理学报 2020, 41 (1), 128–134.
(60) Zhang, Z.; Ma, C.; Su, X.; Yuan, X. Accuracy and Efficiency Assessment of Harmonic Balance Method for Unsteady Flow in Multi-Stage Turbomachinery. Journal of Thermal Science 2020, 29, 1569–1580. https://doi.org/10.1007/s11630-020-1201-x.
(61) Bian, X.; Wang, Q.; Su, X.; Yuan, X. Interaction Mechanisms of Shock Wave with Boundary Layer and Wake in a Highly-Loaded NGV Using Hybrid RANS/LES. Chinese Journal of Aeronautics 2020, 33 (1), 149–160. https://doi.org/10.1016/j.cja.2019.07.008.
(62) Chen, Z.; Li, Y.; Su, X.; Yuan, X. Accuracy Assessment of the Sellers Model in Predicting the Multi-Row Film Cooling Performance. In Proceedings of ASME Turbo Expo 2020, GT2020-14323; American Society of Mechanical Engineers: Online, 2020. https://doi.org/10.1115/GT2020-14323.
(63) Zhang, Z.; Chen, Z.; Su, X.; Yuan, X. Non-Uniform Source Term Model for Film Cooling With the Internal Cross Flow. In Proceedings of ASME Turbo Expo 2020, GT2020-14404; American Society of Mechanical Engineers: Online, 2020. https://doi.org/10.1115/GT2020-14404.
(64) Li, H.; Su, X.; Yuan, X. Analysis of the Relationship between Turbulence Characteristics and Loss Mechanism in the Tip Leakage Flow of Turbine Blade. In Chinese International Turbomachinery Conference; Nanchang, China, 2020.
(65) Chen, Z.; Zhang, Z.; Li, Y.; Su, X.; Yuan, X. Vortex Dynamics Based Analysis of Internal Crossflow Effect on Film Cooling Performance. International Journal of Heat and Mass Transfer 2019, 145, 118757. https://doi.org/10.1016/j.ijheatmasstransfer.2019.118757.
(66) Bian, X.; Wang, Q.; Chen, Z.; Su, X.; Yuan, X. Hybrid RANS/LES Study of Complex Turbulence Characteristics and Flow Mechanisms on the Highly-Loaded Turbine Endwall. Aerospace Science and Technology 2019, 94, 105404. https://doi.org/10.1016/j.ast.2019.105404.
(67) Su, X.; Ma, C.; Yuan, X. Adjoint-Based Geometrically Constrained Aerodynamic Optimization of a Transonic Compressor Stage. Journal of Thermal Science 2019, 28 (5), 850–861. https://doi.org/10.1007/s11630-019-1141-5.
(68) Li, H.; Su, X.; Yuan, X. Entropy Analysis of the Flat Tip Leakage Flow with Delayed Detached Eddy Simulation. Entropy 2019, 21 (1). https://doi.org/10.3390/e21010021.
(69) Li, Y.; Su, X.; Yuan, X. The Effect of Mismatching Between Combustor and HP Vanes on the Aerodynamics and Heat Load in a 1-1/2 Stages Turbine. Aerospace Science and Technology 2019, 86, 78–92. https://doi.org/https://doi.org/10.1016/j.ast.2018.12.023.
(70) Zhang, H.; Li, Y.; Chen, Z.; Su, X.; Yuan, X. Multi-Fidelity Model Based Optimization of Shaped Film Cooling Hole and Experimental Validation. International Journal of Heat and Mass Transfer 2019, 132, 118–129. https://doi.org/10.1016/j.ijheatmasstransfer.2018.11.156.
(71) 卞修涛; 林敦; 苏欣荣; 袁新. 高负荷透平叶片流动机理及湍流特性研究. 工程热物理学报 2019, 40 (8), 1758–1766.
(72) 李毅飞; 张扬; 苏欣荣; 袁新. 透平横向流动对成型孔气膜冷却的影响. 工程热物理学报 2019, 40 (6), 1229–1232.
(73) 李会; 苏欣荣; 袁新. 基于混合RANS/LES的跨音速叶栅流动机理与损失分析. 汽轮机技术 2019, 61 (2), 4–8.
(74) Wang, Q.; Li, Y.; Bian, X.; Su, X.; Yuan, X. Large-Eddy Simulation of Shaped Hole Film Cooling with the Influence of Cross Flow. In Proceedings of ASME Turbo Expo 2019, GT2019-90180; Phoenix, USA, 2019. https://doi.org/10.1115/GT2019-90180.
(75) Li, H.; Bian, X.; Su, X.; Yuan, X. Flow Mechanism and Loss Analysis of Tip Leakage Flow with Delayed Detached Eddy Simulation. In Proceedings of ASME Turbo Expo 2019, GT2019-90410; Phoenix, USA, 2019. https://doi.org/10.1115/GT2019-90410.
(76) Zhang, H.; Li, Y.; Chen, Z.; Su, X.; Yuan, X. Multi-Fidelity Based Optimization of Shaped Film Cooling Hole and Experimental Validation. In Proceedings of ASME Turbo Expo 2019, GT2019-90088; Phoenix, USA, 2019. https://doi.org/10.1115/GT2019-90088.
(77) Chen, Z.; Su, X.; Yuan, X. Film Cooling Performance of Endwall Vertical Hole for the Horse Shoe Vortex Formation Region. In Proceedings of International Gas Turbine Congress; Tokyo, Japan, 2019.
(78) Bian, X.; Wang, Q.; Su, X.; Yuan, X. Hybrid RANS/LES Study of the Complex Turbulence Characteristics and Flow Mechanism in a Highly-Loaded Turbine Blade. In Proceedings of International Gas Turbine Congress; Tokyo, Japan, 2019.
(79) Li, H.; Su, X.; Yuan, X. Entropy Transportation Equation Based on Loss Mechanism Analysis with High Fidelity Turbulence Simulation Results. In Proceedings of Global Power and Propulsion Society; Beijing, China, 2019. https://doi.org/10.33737/gpps19-bj-032.
(80) Wang, Q.; Zhang, Z.; Su, X.; Yuan, X. INCREMENTAL PROPER ORTHOGONAL DECOMPOSITION BASED METHOD FOR THE ANALYZATION OF LARGE SCALE HIGH FIDELITY SIMULATION RESULTS. In Proceedings of Global Power and Propulsion Society; Beijing, China, 2019. https://doi.org/10.33737/gpps19-bj-026.
(81) Zhang, Z.; Wang, Q.; Su, X.; Yuan, X. An Analytical Model for the Heat Transfer of Array Impingement. In Proceedings of 24th ISABE conference; Canberra, Australia, 2019.
(82) 陈子聿; 李毅飞; 苏欣荣; 袁新. 基于标量扩散方程的气膜冷却二维分布理论模型. In 工程热物理学会热机气动热力学和流体机械学术会议; 北京, 2019.
(83) 卞修涛; 苏欣荣; 袁新. 基于混合RANS/LES的透平叶片端区湍流特性和损失机理研究. In 工程热物理学会热机气动热力学和流体机械学术会议; 北京, 2019.
(84) 李会; 苏欣荣; 袁新. 基于DDES模拟的叶顶泄漏流湍流特性研究. In 工程热物理学会热机气动热力学和流体机械学术会议; 北京, 2019.
(85) 陈子聿; 王青松; 苏欣荣; 袁新. 基于iPOD算法的大规模非定常流动模态分解与分析方法. In 热能动力技术学术会议; 武汉, 2019.
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(129) Su, X.; Yamamoto, S.; Nakahashi, K. Extending the Building Cube Method to Curvilinear Mesh with Adaptive Mesh Refinement. Journal of Fluid Science and Technology 2014, 9 (5), JFST0074–JFST0074. https://doi.org/10.1299/jfst.2014jfst0074.
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