Priv.-Doz. Dr. Habil. Yan Jin DFG-Heisenberg Fellow
Personal data Sex: male Wedlock: married Nationality: P. R. China Birthday: 28.01.1974 Permanent Residentship: European Union Affiliation: Zentrum für angewandte Raumfahrttechnologie und Mikrogravitation (ZARM), Universität Bremen Tel: +49 179 4098320 Address: Hainholzfeld 1, D-21075, Hamburg Email: [email protected]; [email protected] https://www.zarm.uni-bremen.de/en/research/fluid-dynamics/multiscale-modelling-and-simulation-d fg-heisenberg-program.html; https://www.researchgate.net/profile/Yan_Jin12?ev=hdr_xprf
Research/teaching interest - fluid mechanics, thermodynamics, heat and mass transfer, biological and physiological simulation, molecular dynamics, turbulence modeling, turbomachinery, combustion;
Education 01.03.2009 ~ 10.12.2014 Habilitation, Institute of Thermo-fluid Dynamics, Hamburg University of Technology. venia legendi: Thermo-fluid dynamics Habilitation seminar: “Skin friction drag reduction methods, state of the art” Habilitation: “RANS and DNS solutions for turbulent flows: Their interrelation and analysis based on the second law of thermodynamics”
01.09.1996~01.06.2002 PhD and Master Degree, Department of Thermal Engineering, Tsinghua university, P. R. China
PhD dissertation: “Aeroelastical Study of Fluid-Structure Interaction Problems in Turbomachineries”
01.09.1992~01.07.1996 Bachelor Degree, Department of Thermal Engineering, Harbin Institute of Technology, P. R. China
Yan Jin, ZARM, University of Bremen, +49 1794098320, [email protected]
Work Experience 01.08.2017-today DFG-Heisenberg fellow, Leader of the research group “Multiscale Modeling and Simulation”, Center of Applied Space Technology and Microgravity (ZARM), University of Bremen, Germany
01.03.2009~31.07.2017 Privatdozent (since 2015) / Group leader, Institute of Thermo-fluid Dynamics, Hamburg University of Technology, Germany
Numerical study of the mixed convection in a heated chamber with an advanced similarity method (DFG): Asymptotic method.
Direct numerical simulation of the turbulent flow and heat transfer problem in rough wall channels (DFG): Lattice-Boltzmann method and Finite volume method.
Direct numerical simulation of the turbulent flow in porous media (DFG): Lattice-Boltzmann method and Finite volume method.
17.3.2008~01.03.2009 Post doctor, Department of Chemical Engineering, Monash University, Australia Studying the multi-phase flow and the drying process of milk droplets in a spray dryer (Diary Innovation Australia).
25.03.2007~15.3.2008 Post doctor, Department of Mechanical and Aeronautical Engineering, UC DAVIS, USA Numerical simulation of the oscillation and the combustion of liquid droplets (NASA).
01.04.2003~25.03.2007 Post doctor, Institute of fluid dynamics, Munich University of Technology, Germany Combustion and heat transfer of solid propellants in an airbag inflator (BMW); Numerical simulation of the interaction between rocket nozzle and base flow (DLR); Numerical simulation of the combustion in a liquid rocket engine,Astrium company (EADS).
01.05.2002~30.03.2003 Software engineer, Hi-key Tech, Fluent Company, P. R. China
Teaching experience Giving the following lectures to students: Special topics on fluid dynamics, TU Hamburg-Harburg, 2012-2017 Turbulent flows and modeling, TU Hamburg-Harburg, 2016-2017 Turbulence modeling / Computational fluid dynamics, TU Hamburg-Harburg, 2011.
Supervising master and project thesis: “Turbulent Scalar Transport in Arrays of Spheres, A DNS Study”, Master thesis, TU
2 Yan Jin, ZARM, University of Bremen, +49 1794098320, [email protected]
Hamburg-Harburg, 2017 “Direct numerical simulation of interfacial mass transfer of a deformable single bubble”, Master thesis, TU Hamburg-Harburg, 2017 “Numerical simulation of the turbulent flows in a differentially heated chamber", Master thesis, TU Hamburg-Harburg, 2015 “Topology optimization of turbulent flows with an adjoint method”, project thesis, TU Hamburg-Harburg, 2014 “Numerical simulation of convection in a two-dimensional porous medium", project thesis, TU Hamburg-Harburg, 2015 “Drag reduction by shark-skin like walls”, Master thesis, TU Hamburg-Harburg, 2012 ……
CFD software training: FLUENT, 2002
Experience of applying for funding Principle applicant DFG Heisenberg Stipendium: "Parameter Extension Simulation (PES) und Large Scale Motion Simulation (LSMS) turbulenter Strömungen", 3+2 years, approved, 2016. Chinese Scholarship Council (CSC) PhD Program: “Direct numerical simulation of the turbulent flows in porous media with multiple length scales”, approved, 2017. DFG project: “Direct Numerical Simulation and Modeling of Turbulent Convection in Porous Media”, under review, 2018. DFG project, “Influence of Turbulent Structures on Mass Transfer at Fluidic Interfaces”, revised proposal ready for resubmission, 2018. BMWI (through DLR) project, “Numerical and experimental study of gastric digestion of foods in a stomach model under normal and reduced gravity”, in process, 2018. CSC-DFG post doctor program, “Direct Numerical Simulation (DNS) of Turbulent Flows past Wind Turbine Airfoils”, under review, 2018 - Main participant DFG project, “Strömungen in Kanälen mit rauen Wänden: DNS-Lösungen zur Validierung des RANS-Dissipationsmodells” (Priciple applicant: Prof. H. Herwig), 2010. DFG project, “Grundlegende Untersuchungen zur Turbulenz bei Strömungen durch poröse Medien” (Priciple applicant: Prof. H. Herwig), 2014.
Other experiences Guest editor of the journal “Entropy”; Reviewer of the following international journals: Computers and fluids Drying technology ASME Journal of Heat Transfer International Journal of Thermal Sciences European Journal of Mechanics - B/Fluids AIAA Journal of Thermophysics and Heat Transfer Combustion Theory and Modeling
3 Yan Jin, ZARM, University of Bremen, +49 1794098320, [email protected]
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Language skills Chinese (native language); English; German.
References Prof. Dr.-Ing. habil. Heinz Herwig Prof. Dr.-Ing. habil. Rainer Friedrich Institute for Thermo-Fluid Dynamics Institute of Fluid Mechanics Hamburg University of Technology, Germany TU Muenchen, Germany Email: [email protected] Boltzmannstr. 15, D-85748 Garching, Germany Tel.: ++49 (0)40-42878-3044 Email: [email protected] Tel.: +49 89 289 16144 Prof. Xiao Dong Chen Fax.: +49 89 289 16145 Department of Chemical Engineering Monash University, Australia Prof. Yuan Xin Email: [email protected] Department of Thermal Engineering, Tsinghua Tel.: +61 3 9905 9344 University Email: [email protected] Prof. Benjamin Shaw Tel: +86 10 62794163 Department of Mechanical and Aeronautical Engineering, University of California, Davis, Prof. Andrey V. Kuznetsov USA Department of Mechanical and Aerospace Email: [email protected] Engineering, Tel: +1 530 752 4130 North Carolina State University, Raleigh, North Carolina 27695-7910, USA Email: [email protected]
4 Yan Jin, ZARM, University of Bremen, +49 1794098320, [email protected]
Selected publications * denotes the corresponding author [1] Y. Jin*, A.V. Kuznetsov, “Turbulence modeling for flows in wall bounded porous media: An analysis based on direct numerical simulations”, Physics of Fluids, 29, 2017, 045102. [2] Y. Jin*, J. Du, Z.Y. Li and H.W. Zhang, “Second-Law Analysis of irreversible losses in gas turbines”, Entropy, 19, 2017, 470. [3] M.F. Uth, Y. Jin*, A.V. Kuznetsov and H. Herwig, “A DNS study on the possibility of macroscopic turbulence in porous media: effects of different solid matrix geometries, solid boundaries, and two porosity scales”, Physics of Fluids, 28, 2016, 065101. [4] Y. Jin, M.F. Uth, A.V. Kuznetsov and H. Herwig, “Numerical investigation of the possibility of macroscopic turbulence in porous media: a DNS study”, Journal of Fluid Mechanics, 766, 2015, 76-103. [5] Y. Jin, M.F. Uth and H. Herwig, “Structure of a turbulent flow through plane channels with smooth and rough walls: An analysis based on high resolution DNS results”, Computers and Fluids, 107(31), 2015, 77-88. [6] Y. Jin and H. Herwig, “Turbulent flow in channels with shark skin surfaces: Entropy generation and its physical significance”, International Journal of Heat and Mass Transfer, 70, 2014, 10-22. [7] Y. Jin* and X. D. Chen, “Entropy production during the drying process of milk droplets in an industrial spray dryer”, International Journal of Thermal Sciences, 50, 2011, 615-625. [8] Y. Jin* and B. Shaw, “Computational modeling of n-heptane droplet combustion in air-diluent environments under reduced-gravity”, International Journal of Heat and Mass Transfer, 53, 2010, 5782-5791. [9] Y. Jin and X. D. Chen, “A fundamental model of milk particle deposition incorporated in CFD simulations of an industrial milk spray dryers”, Drying Technology, 28, 2010, 960-971. [10] Y. Jin and X. D. Chen, “Numerical Study of the Behavior of Different Size Particles in an Industrial Spray Dryer”, Drying Technology, 27, 2008, 371-381.
Complete publication list in chronological order, journal papers in the front 2018 [1] P.U. Kränzien and Y. Jin*, “Natural convection in a two-dimensional cell filled with a porous medium: a direct numerical simulation study”, Heat Transfer Engineering, online first, DOI: 10.1080/01457632.2018.1432083, 2018. [2] Z. Lin, H.C. Zhang, A.V. Kuznetsov, M. Avila and Y. Jin*, “Pore-scale determines the macroscopic properties of natural convection in porous media”, submitted to Physical Review Letters for publication, under review, 2018. [3] S. Gasow, A.V. Kuznetsov, M. Schlüter and Y. Jin*, Turbulent forced convection in porous media: a direct numerical simulation study”, IHTC16-22301, Proceedings of the 16th International Heat Transfer Conference, IHTC-16, 2018, Beijing, China.
2017
5 Yan Jin, ZARM, University of Bremen, +49 1794098320, [email protected]
[4] Y. Jin*, A.V. Kuznetsov, “Turbulence modeling for flows in wall bounded porous media: An analysis based on direct numerical simulations”, Physics of Fluids, 29, 2017, 045102. [5] Y. Jin*, J. Du, Z.Y. Li and H.W. Zhang, “Second-Law Analysis of irreversible losses in gas turbines”, Entropy, 19, 2017, 470. [6] Y. Jin*, “Second-Law Analysis: A powerful tool for analyzing computational fluid dynamics (CFD) results”, Entropy, 19, 2017, 679. [7] G.Q. Xu, H.C. Zhang, Q. Zou and Y. Jin, “Predicting and analyzing interaction of the thermal cloaking performance through response surface method”, International Journal of Heat and Mass Transfer, 109, 2017, 746-754. [8] G.Q. Xu, H.C. Zhang, Q. Zou, Y. Jin and M. Xie, “Forecast of thermal harvesting performance under multi-parameter interaction with response surface methodology”, International Journal of Heat and Mass Transfer, 115, Part A, 2017, 682-693. [9] Y. Jin, A.V. Kuznetsov, “Using direct numerical simulations for investigating physics in porous media”, Proceedings of the ASME 2017 Fluids Engineering Division Summer Meeting, FEDSM2017, At Waikoloa, Hawaii, USA, 2017.
2016 [10] M.F. Uth, Y. Jin*, A.V. Kuznetsov and H. Herwig, “A DNS study on the possibility of macroscopic turbulence in porous media: effects of different solid matrix geometries, solid boundaries, and two porosity scales”, Physics of Fluids, 28, 2016, 065101. [11] P.U. Kränzien and Y. Jin* “Natural convection in a two-dimensional cell filled with porous medium: A DNS study”, Proceedings of the 9th International Symposium on Heat Transfer”, ISHT9-F0318, Beijing, 2016.
2015 [12] Y. Jin, M.F. Uth, A.V. Kuznetsov and H. Herwig, “Numerical investigation of the possibility of macroscopic turbulence in porous media: a DNS study”, Journal of Fluid Mechanics, 766, 2015, 76-103. [13] Y. Jin* and H. Herwig, "Turbulent flow in rough wall channels: validation of RANS models", Computers and Fluids, 122, 2015, 34-46. [14] Y. Jin, M.F. Uth and H. Herwig, “Structure of a turbulent flow through plane channels with smooth and rough walls: An analysis based on high resolution DNS results”, Computers and Fluids, 107(31), 2015, 77-88. [15] M. F. Ut, Y. Jin, A.V. Kuznetsov and H. Herwig, "Turbulent flow in the micro structures of porous media", 13th International Conference on Nanochannels, Microchannels and Minichannels (ICNMM), San Francisco, 2015. [16] B. Philippi, Y. Jin*, "Topology Optimization of Turbulent Fluid Flow with a Sensitive Porosity Adjoint Method (SPAM)", arXiv:1512.08445 [physics.flu-dyn], 2015. [17] P. Kis, Y. Jin, H. Herwig, "The physics of stripe patterns in turbulent channel flow determined by DNS results", arXiv:1511.07753 [physics.flu-dyn], 2015.
2014 [18] Y. Jin and H. Herwig, “Turbulent flow in channels with shark skin surfaces: Entropy generation and its physical significance”, International Journal of Heat and Mass Transfer, 70, 2014, 10-22.
6 Yan Jin, ZARM, University of Bremen, +49 1794098320, [email protected]
[19] Y. Jin and H. Herwig, “Effects of shark skin textures on entropy generation for turbulent flow and heat transfer problems”, Proceedings of the International Heat Transfer Conference, Kyoto, 2014, IHTC15-8699. [20] M. F. Uth, Y. Jin, A.V. Kuznetsov and H. Herwig, "Turbulence in porous media: some fundamental questions addressed by DNS solutions", 5th International Conference on Porous Media and its Applications in Science and Engineering ICPM5 June 22-27, 2014, Kona, Hawaii.
2013 [21] Y. Jin and H. Herwig, “From single obstacles to wall roughness: Some fundamental investigations based on DNS results for turbulent channel flow”, Z. Journal of Applied Mathematics and Physics, 64, 2013, 1337-1352. [22] H. Herwig, and Y. Jin, “Entropy generation as a validation criterion for flow and heat transfer models”, 2nd Annual ASME Verification and Validation Symposium, Las Vegas, USA, 2013.
2012 [23] Y. Jin and H. Herwig, “Parameter extension method (PEM): an asymptotic extension of numerical and experimental flow and heat transfer results to further values of the inherent parameters”, Heat and Mass Transfer, 48(5), 2012, 823-830. [24] H.-C. Zhang, Y.-Y. Guo, Y. Jin and Y. Li “An entropy production method to investigate the accuracy and stability of numerical simulation of one-dimensional heat transfer”. Heat transfer research, 2012, 43(7): 669-693. [25] H. Herwig and Y. Jin, “Parameter Extension Method (PEM): An asymptotic extension of numerical and experimental flow and heat transfer results to further values of the inherent parameters”, Proceedings of the 3rd International Forum on Heat Transfer, Nagasaki, Japan, 2012.
2011 [26] Y. Jin and H. Herwig, “Efficient methods to account for variable property effects in numerical momentum and heat transfer solutions”, International Journal of Heat and Mass Transfer, 54, 2011, 2180-2187. [27] Y. Jin* and X. D. Chen, “Entropy production during the drying process of milk droplets in an industrial spray dryer”, International Journal of Thermal Sciences, 50, 2011, 615-625. [28] Y. Jin and H. Herwig, “Variable property effects in momentum and heat transfer”, Developments in Heat Transfer, InTech, 135-152, 2011.
2010 [29] Y. Jin and H. Herwig, “Application of the extended similarity theory to a complex benchmark problem”, Z. Journal of Applied Mathematics and Physics, 61, 2010, 509-528. [30] Y. Jin* and B. Shaw, “Computational modeling of n-heptane droplet combustion in air-diluent environments under reduced-gravity”, International Journal of Heat and Mass Transfer, 53, 2010, 5782-5791. [31] Y. Jin and B. Shaw, “Numerical simulation of unsteady flows and shape oscillations in liquid droplets induced by deployment needle retraction”, Microgravity Science and Technology, 22, 2010, 17-26.
7 Yan Jin, ZARM, University of Bremen, +49 1794098320, [email protected]
[32] Y. Jin and X. D. Chen, “A fundamental model of milk particle deposition incorporated in CFD simulations of an industrial milk spray dryers”, Drying Technology, 28, 2010, 960-971. [33] Y. Jin and H. Herwig, “Similarity theory including variable property effects: a complex benchmark problem”, Proceedings of the International Heat Transfer Conference, Washington, 2010, IHTC14-22457.
Earlier than 2010 [34] Y. Jin and X. D. Chen, “A Three-dimensional numerical study of the gas/particle interactions in an industrial-scale spray dryer for milk powder production”, Drying Technology, 27, 2009, 1018-1027. [35] M. Masquelet, S. Menon, Y. Jin and R. Friedrich, “Simulation of unsteady combustion in a LOX-GH2 fueled rocket engine”, Aerospace Science and Technology, 13(8), 2009, 466-474. [36] Y. Jin and X. D. Chen, “Numerical Study of the Behavior of Different Size Particles in an Industrial Spray Dryer”, Drying Technology, 27, 2008, 371-381. [37] Y. Jin & R. Friedrich, “Large Eddy Simulation of Nozzle Jet - External Flow Interaction”, Notes on Numerical Fluid Mechanics and Multidisciplinary Design, Springer Berlin / Heidelberg, 2007, 57-81. [38] Y. Jin and X. Yuan, “Oscillatory Blowing Control Numerical Simulation of Airfoil Flutter by High-Accuracy Method”, AIAA Journal of Aircraft, 41(3), 2004, 610-615. [39] Y. Jin and X. Yuan, “Numerical Study of Unsteady Viscous Flow Past Oscillating Airfoil”, Wind Engineering, 25(3), 2002, 227-237. [40] Y. Jin & R. Friedrich, “Large Eddy Simulation of the Combustion in a Solid Propellant Airbag Gas Generator”, 2007 Fall Meeting of the Western States Section of the Combustion Institute Sandia National Laboratories, Livermore, CA, 2007. [41] Y. Jin & B. Shaw, “Numerical simulation of unsteady flows and shape oscillations in liquid droplets induced by deployment needle retraction”, 2007 Fall Meeting of the Western States Section of the Combustion Institute Sandia National Laboratories, Livermore, CA, 2007. [42] Y. Jin and X. Yuan, “Numerical Analysis of the airfoil’s Fluid-Structure Interaction Problems at Large Mean Incidence Angle”, 2nd International Conference on Computational Fluid Dynamics, Sidney, Springer 2003. [43] Y. Jin and X. Yuan, “Aeroelastic Analysis of Oscillatory Blowing Control of the Airfoil's Flutter at Large Attack Angle”, American Society of Mechanical Engineers, Applied Mechanics Division, AMD, Proceedings of the 5th International Symposium on Fluid-Structure Interaction, Aeroelasicity, Flow-Induced Vibration and Noise. Volume 1: Part A., 253(1), 2002, 63-69. [44] Y. Jin and X. Yuan, “Numerical Study of Unsteady Viscous Flow Past Oscillating airfoil”, The 2nd International Symposium on Fluid Machinery and Fluid Engineering, Beijing, 2000, 404-411. [45] Y. Jin and X. Yuan, "Numerical analysis of 3D turbine blade's torsional flutter by fluid-structure coupling method", Journal of Engineering Thermophysics, 25(1), 2004, 41-44 (in Chinese). [46] Y. Jin and X. Yuan, “Numerical Simulation of Fluid-Induced vibration in Seals by Fluid-Structure Coupling Method”, Journal of Engineering Thermophysics, 24(3), 2003, 395-399 (in Chinese). [47] Y. Jin and X. Yuan, “Numerical Analasis of 3D Turbine Blade’s Torsional Flutter by Fluid-Structure Coupling Method”, Journal of Engineering Thermophysics, 24(3), 2003,
8 Yan Jin, ZARM, University of Bremen, +49 1794098320, [email protected]
395-399 (in Chinese). [48] Y. Jin and X. Yuan, “Analysis of an airfoil’s flutter control technique of blowing by a fluid - structure coupling method”, ACTA AERODYNAMICA SINICA, 20(3), 2002, 267-273 (in Chinese). [49] Y. Jin, X. Yuan, B. R and Shin, "Aeroelastic analysis of an airfoil's stall flutter at large mean incidence angle", Journal of Engineering Thermophysics, 23(5), 2002, 573-575 (in Chinese). [50] Y. Jin and X. Yuan, "aeroelastic analysis on an airfoil's flutter and flutter control technique of blowing", ACTA Energiae Solaris Sinica, 2002, 403-407 (in Chinese). [51] Y. Jin and X. Yuan, "Numerical simulation of the unsteady flow field around a two-dimensional oscillating airfoil", Journal of Tsinghua University, 42 (5), 2002, 684-687 (in Chinese). [52] L. D. He, X. Yuan and Y. Jin, “Experimental Investigation of the Sealing Performance of Honeycomb Seals Academic Experience”, Chinese Journal of Aeronautics, 14(1), 2001 (in Chinese). [53] X. Yuan and Y. Jin, “Application of High-Order Upwind Scheme to Simulating Submerged Nozzle Flowfield”, Journal of Tsinghua University, 40(6), 2000, 45-48 (in Chinese).
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