周强, 1982年4月生,山东济宁人
工学博士,教授,博导
国家级青年人才 (2016)
西安交通大学青年拔尖人才
化学工程研究所所长
化工多相反应流动青年创新团队负责人
中国化工学会过程模拟及仿真第二届专委会副秘书长
中国颗粒学会第四届青年理事会理事
中国工程热物理学会多相流分会委员
个人信息 - 周 强
单位:西安交通大学化学工程与技术学院
地址:西安市咸宁西路28号
邮编:710049
电话: 029-82664376
使用电子邮箱更容易找到我。
办公地址:中国西部科技创新港19-4190
1.气固反应流动基础研究。
计算流体力学的飞速发展已经在航天航空领域发挥巨大作用,但在与人们生活更密切相关的能源化工领域,其作用还非常有限。这主要是由于能源化工领域内所涉及的流动多为包含颗粒或者气泡的复杂多相流动,人们目前对多相流动中相间相互作用力认识尚不充分。本课题组致力于探索非均匀颗粒结构对气固相间作用力、传热、传质和反应特性的影响规律,重点揭示非均匀结构在不同尺度影响“三传一反”的机理,最终目的是开发能够充分解析介尺度结构影响的介尺度模型,构建高保真的气固反应流动数值方法,使之能够用于预测和优化大尺度反应器内含化学反应的气固流动,为过程工业的数字化和智能化打好理论基础。该方向目前已完成包括重大研究计划项目在内的三项国家自然科学基金。
2.关键反应器多物理场数字孪生技术。
在过程工业中,其关键设备大都涉及极其复杂的多物理场过程,如煤气化炉、催化裂化反应器、催化裂解反应器、冷氢化流化床反应器、颗粒硅流化床、聚合反应器、乙烯裂解炉、精细化工搅拌釜、精馏设备等等,这些关键设备内涉及多相多组分多物理场的耦合作用。课题组致力于基于高保真数值方法所构建的数据库以及现场实时监测数据开发多物理场数字孪生技术,该技术具备(1)实现“黑箱”设备可视化,(2)提产增效充分利用装置潜力,(3)保障设备长周期高效率运行等能力。该技术是通向未来智慧工厂不可或缺的技术之一。
3.碳中和技术及物理储能技术。
欢迎脚踏实地、思维活泼、醉心科学、勇于攀登的同学的加入课题组!
具体研究方向:
1.气固两相流理论及应用、流态化数值模拟、微尺度及介尺度建模
2.多物理场重构、基于人工智能的数字孪生
3.二氧化碳固化技术、沙子电池技术
研究手段:
1.直接数值模拟、双流体模拟、离散元模拟,CFD模拟(MFIX,Fluent,OpenFOAM等)
2.气固流动实验研究
欢迎已毕业或者即将毕业的有能源动力、流体力学、化学工程等方向背景的博士(计算方向或者实验方向)以博士后、副研究员、青年优秀人才、校级青拔人才身份加入本团队!
科研平台:
陕西省能源化工过程强化重点实验室
动力工程多相流国家重点实验室(http://mfpe.xjtu.edu.cn/info/1023/5769.htm)
学生培养一级学科方向:
化学工程与技术
动力工程及工程热物理
2004.9-2010.7 清华大学航天航空学院工程力学专业,流体力学方向博士,导师:何枫
2000.9-2004.7 浙江大学机械与能源工程学院工程力学专业,竺可桢学院工高班,本科,导师:林建忠
2016.10-至今 西安交通大学化工系,教授
2015.08-2016.09 西安交通大学化工系,特聘研究员
2014.01-2015.08 美国俄亥俄州立大学化学与生物分子工程系,Research Associate,导师:Liang-Shih Fan
2010.10-2013.12 美国俄亥俄州立大学化学与生物分子工程系,博士后,导师:Liang-Shih Fan
2023 袁守正 第十二届全国流态化会议暨颗粒技术会议 优秀报告
2023 王凌雪、蒋鸣 第二届百特-《颗粒学报》优秀论文奖 2023 Bettersize–Particuology Excellent Article Award
2023 王凌雪、张宇、段凡、袁守正、赵丽文、贺谢宇 第八届中国国际“互联网+”大学生创新创业大赛陕西赛区省级复赛银奖(产业命题赛道)
2023 王凌雪 “首届未来颗粒前沿论坛” 优秀报告
2020 段凡 第二届全国过程模拟与仿真学术会议-优秀学生报告奖
获取原文请参看https://www.researchgate.net/profile/Qiang_Zhou9
M. Pan, Q. Zhou, Z. Huang*, 2024 Numerical simulation of transpiration cooling in porous nose cone under hypersonic conditions, Applied Thermal Engineering.
段凡, 贺煊, 周强*, 2023, 中等雷诺数双分散悬浮系统流固曳力以及固固曳力[J/OL]. 过程工程学报.
Y. Zhang, Y. Yu, X. Chen, S. Du*, Q. Zhou, 2024 Construction and Analysis of the Mesoscale Drag Force Model Based on Machine Learning Methods, Industrial & Engineering Chemistry Research, 63(4): 2044-2056.
S. Yuan, Y. Zhao, X. Chen, Q. Zhou*, 2024 A corrected filtered drag model considering the effect of the wall boundary in gas-particle fluidized bed, Powder Technology, 2024, 432: 119158.
S. Du, X. Chen, T. Ma, L. Wang, Q. Zhou*, 2023 Verification of a microscale drag model considering the effect of gas–Structure interface via fine-grid two-fluid simulations, Industrial & Engineering Chemistry Research, 2023, 62(29), 11697-11711.
R. Basit, X. Li, Z. Huang, Q. Zhou*, 2023 Effect of particle orientation on heat transfer in arrays of prolate particle, Computer Modeling in Engineering and Sciences, 136(2), 1509-1526.
X. Li, X. Chen, B. Yang, Q. Zhou*, 2023 Direct numerical simulation of moderate-Reynolds-number flow past arrays of ellipsoids, AIChE Journal, 69(10): e18162.
S. Du, Y. Zhao, L. Zhao, Q. Zhou, X. Chen*, 2023 Direct numerical simulation of flow past a reactive/inert mixed particle pair, Physics of Fluids, 35(6), 063308.
X. Chen, Y. Zhao, S. Du, L. Zhao, Q. Zhou*, 2023 Impact of Stefan flow on the interphase scalar transfer in flow past random particle arrays, Chemical Engineering Journal, 470: 143885.
X. Chen, M. Pan, Q. Wan, Q. Zhou, Z. Huang*, 2023 An effective thermal conductivity model for the three-phase porous media based on the numerical simulation, Numerical Heat Transfer, Part A: Applications, 1-16.
袁守正, 陈啸, 蒋鸣, 余亚雄, 周强*, 2023, 气固下行床中壁面对介尺度曳力的影响规律探究. 化工进展, 42(05): 2272-2281.
S. Du, J. Wang, Y. Yu, Q. Zhou*, 2023 Coarse-grained CFD-DEM simulation of coal and biomass co-gasification process in a fluidized bed reactor: Effects of particle size distribution and operating pressure, Renewable Energy, 202, 483-498.
余亚雄, 段凡, 张宇, 周强*, 2022, 粗粒化CFD-DEM的离散松弛模型[J/OL]. 过程工程学报, 22(12): 1652-1665.
马腾, 陈啸, 周强*, 2022, 低雷诺数下气固两相中浓稀相界面对微尺度曳力的影响及建模[J/OL]. 过程工程学报, 22(11): 1490-1503.
蒋鸣, 周强*, 2022, 气固流化床介尺度结构形成机制及过滤曳力模型研究进展[J]. 化工学报, 73(06):2468-2485.
刘怡琳, 李钰, 余亚雄, 黄哲庆, 周强*, 2022, 基于重置温度方法的双参数介尺度气固传热模型构建[J], 化工学报, 2022,73(06):2612-2621.
X. Chen, T. Ma, Q. Zhou*, 2022 Theoretical and numerical analysis of drag force at the interface between the dilute and dense phases, Physics of Fluids, 34(9), 093306.
F. Duan, Y. Yu, X. Chen, Q. Zhou*, 2022 Particle-particle drag force in inertial bidisperse gas-particle suspensions, Journal of Fluid Mechanics, 952: A11.
T. Ma, Y. Li, Q. Zhou, X. Chen*, 2022 Microscale drag model considering the effect of interface between dense and dilute phases for gas-solid suspensions at moderate Reynolds numbers, International Journal of Multiphase Flow, 157, 104270.
Y. Li, S. Han, Y. Yu, X. He, Z. Huang, Q. Zhou*, 2022 Modeling filtered heat transfer model by considering dimensionless temperature difference between gas and solid phases, AIChE Journal, 69(1): e17917.
Z. Huang, Q. Huang, Y. Yu, Y. Li, Q Zhou*, 2022 A comparative study of models for heat transfer in bidisperse gas–solid systems via CFD-DEM simulations. Axioms, 11(4), 179. DOI: 10.3390/axioms11040179
L. Zhao, Q. Zhou, B. Yang, X. Chen*, 2022 Inhomogeneous drag correction based on surrounding solid volume fraction in low-Reynolds-number regime. Powder Technology, 401: 117292.
S. Du, L. Zhao, X. H. Chen, B. Yang, Q. Zhou*, 2022 Effect of Stefan flow on the drag force of single reactive particle surrounded by a sea of inert particles. Chemical Engineering Science, 253, 117546.
L. Wang, M. Jiang, Q. Zhou*, 2022 Development of a filtered drag model considering effect of the solid shear rate. Particuology, 71, 63-74.
T. Fu, Y. T. Tsai, Q. Zhou*, 2022 Numerical simulation of magnesium dust dispersion and explosion in 20 L apparatus via an Euler–Lagrange method. Energies, 15(2), 402.
Y. T. Tsai, T. Fu, Q. Zhou*, 2021, Explosion characteristics and suppression of hybrid Mg/H2 mixtures. International Journal of Hydrogen Energy, 46(78), 38934-38943.
M. Jiang, Y. Zhang, Y. Yu, Q. Zhou*, 2021 A scale-independent modeling method for filtered drag in fluidized gas-particle flows. Powder Technology, 394, 1050-1076.
D. Zhang, T. Min, M. Jiang, Y. Yu, Q. Zhou*, 2021 Numerical simulation of fluidized bed gasifier coupled with solid oxide fuel cell fed with solid carbon. Energies, 14(10), 2800.
Y. Yu, Y. Li, X. Chen, F. Duan, Q. Zhou*, 2021 Improvement of the Coarse-Grained Discrete Element Method for Frictional Particles. Industrial & Engineering Chemistry Research, 60(15), 5651-5664.
Z. Huang, L. Wang, Y. Li, Q. Zhou*, 2021 Direct numerical simulation of flow and heat transfer in bidisperse gas-solid systems. Chemical Engineering Science, 239, 116645.
S. Du, S. Yuan, Q. Zhou*, 2021 Numerical investigation of co-gasification of coal and PET in a fluidized bed reactor. Renewable Energy, 172, 424-439.
L. Zhao, X. Chen, Q. Zhou*, 2021 Inhomogeneous drag models for gas-solid suspensions based on sub-grid quantities. Powder Technology, 385, 170-184.
X. H. Chen, S. Du, L. Zhao, B. Yang, Q. Zhou*, 2021 Effect of Stefan flow on the drag force in flow past random arrays of spheres. Chemical Engineering Journal, 412, 128691.
Z. Huang, L. Wang, Q. Zhou*, 2021 Development of a filtered reaction rate model for reactive gas-solid flows based on fine-grid simulations. AIChE Journal, 67(5): e17185.
Y. Li,Y. Yu,C. Zhang,Z. Huang,Q. Zhou*,2021 Improved filtered mesoscale interphase heat transfer model. Particuology, 57, 176-186.
F. Duan, L. Zhao, X. Chen, Q. Zhou*, 2020 Fluid-particle drag and particle-particle drag in low-Reynolds-number bidisperse gas-solid suspensions. Physics of Fluids, 32(11), 113311.
Romana Basit, X. Li, Z. Huang, Q. Zhou*, 2020 Heat transfer studies of arrays of prolate particles in gas-solid flows. Mathematical Problems in Engineering, 2020, 6639172, Special Issue entitled "Recent Advances in Multiphase Flows in Engineering"
Y. Yu, L. Zhao, Y. Li, Q. Zhou*, 2020 A model to improve granular temperature in CFD-DEM simulations. Energies, 13(18), 4730. Special Issue entitled "DEM of Multiphase Flows and Powder Processing" by Guest Editor Prof. Yutaka Tsuji.
X. Li, M. Jiang, Z. Huang, Q. Zhou*, 2021 Effect of particle orientation on the drag force in random arrays of oblate ellipsoids in low-Reynolds-number flows. AIChE Journal, 67(1), e17040.
赵利, 陈啸, 周强*, 2020, 一种限制周期气固两相流直接数值模拟中整体质量流率的新方法[J], 工程热物理学报, 41(03):648-652.
X. Chen, N. Song, M. Jiang, Q. Zhou*, 2020 Theoretical and numerical analysis of key sub-grid quantities' effect on filtered Eulerian drag force. Powder Technology, 372, 15-31.
Y. Zhang, M. Jiang, X. Chen, Y. Yu, Q. Zhou*, 2020 Modeling of the filtered drag force in gas-solid flows via a deep learning approach. Chemical Engineering Science, 225, 115835.
Y. Yu, Y. Li, M. Jiang, Q. Zhou*, 2020 Meso-scale drag model designed for coarse-grid Eulerian-Lagrangian simulation of gas-solid flows. Chemical Engineering Science, 223,115747.
T. Ma, Y. Yu, X. Chen, Q. Zhou*, 2020 Effect of anisotropic micro-structures on fluid-particle drag in low-Reynolds-number monodisperse gas-solid suspensions. AIChE Journal, 66(4), e16910.
M. Jiang, X. Chen, Q. Zhou*, 2020 A gas pressure gradient dependent subgrid drift velocity model for drag prediction in fluidized gas-particle flows. AIChE Journal, 66(4), e16884.
Z. Huang, C. Zhang, M. Jiang, Q. Zhou*, 2020 Development of a filtered interphase heat transfer model based on fine-grid simulations of gas-solid flows. AIChE Journal, 66(1), e16755.
X. Li, M. Jiang, Z. Huang, Q. Zhou*, 2019 Effect of particle orientation on the drag force in random arrays of prolate ellipsoids in low-Reynolds-number flows. AIChE Journal, 65(8), e16621.
Z. Huang, C. Zhang, M. Jiang, H. Wang, Q. Zhou*, 2019 Effects of particle velocity fluctuations on inter-phase heat transfer in gas-solid flows. Chemical Engineering Science, 206, 375-386.
Z. Huang, H. Wang, Q. Zhou*, T. Li, 2017 Effects of granular temperature on inter-phase drag in gas-solid flows, Powder Technology, 321, 435-443.
Q. Zhou, L.S. Fan*, 2015 Direct numerical simulation of moderate-Reynolds-number flow past arrays of rotating spheres, Physics of Fluids, 27(7), 073306.
Q. Zhou, L.S. Fan*, 2015 Direct numerical simulation of low-Reynolds-number flow past arrays of rotating spheres, Journal of Fluid Mechanics, Vol. 765, 396-423.
周强, 何枫*, 沈孟育, 2014, 可压缩混合层的涡结构演化与流质混合, 空气动力学学报, 32(03), 273-279.
Q. Zhou, L.S. Fan*, 2014 A second-order accurate immersed boundary-lattice Boltzmann method for particle-laden flows, Journal of Computational Physics, Vol. 268, 269-301.
Q. Zhou, L. Zeng, L.S. Fan*, 2013 Syngas chemical looping process: dynamic modeling of a moving bed reducer. AIChE Journal, 59(9), 3432-3443.
H. Yang, Q. Zhou, L.S. Fan*, 2013 Three-dimensional numerical study on droplet formation and cell encapsulation process in a micro T-junction. Chemical Engineering Science, Vol. 87, 100-110.
Z. Sun, Q. Zhou (co-first authors), L.S. Fan*, 2013 Formation of core-shell structure composite micro-particles via cyclic gas-solid reactions. Langmuir, 29(40), 12520-12529.
Z. Sun, Q. Zhou, L.S. Fan*, 2012 Reactive solid surface morphology variation via ionic diffusion. Langmuir, 28(32), 11827-11833.
Q. Zhou, Feng He*, M.Y. Shen, 2012 Direct numerical simulation of a spatially developing compressible plane mixing layer: flow structures and mean flow properties. Journal of Fluid Mechanics, Vol. 711, 437-468.
Q. Zhou, F. He*, M.Y. Shen, 2012 A family of efficient high-order hybrid finite difference schemes based on WENO schemes. International Journal of Computational Fluid Dynamics, Vol. 26(04), 205-229.
周强, 何枫*, 沈孟育, 2010, 可压缩混合层中的激波和涡结构, 空气动力学学报, 28(03), 245-249.
Q. Zhou, Z.H. Yao, F. He*, M.Y. Shen, 2007 A new family of high-order compact upwind difference schemes with good spectral resolution. Journal of Computational Physics, Vol. 227(2), 1306-1339.
周强, 王嘉豪, 蔡昀廷. 一种二氧化碳通过金属氢化物转化为甲烷的方法: 中国, CN202111426033.9[P], CN114105723A,2022-3-1[已授权].
周强, 张东旭, 闵婷, 郝文斌. 一种固体氧化物燃料电池与流化床集成的发电装置及方法: 中国, ZL202110437325.6[P]. 2021-4-22[申请中].
周强, 张东旭, 闵婷, 郝文斌. 一种固体氧化物燃料电池与流化床集成的发电装置: 中国, ZL202120843021.5[P]. 2021-4-22[2021-11-23].
周强, 王嘉豪, 杜少华. 一种制备合成气的循环流化装置及方法:中国, ZL202211027879X[P]. 2022-08-25[申请中].
计算流体力学入门/(美)安德森(Anderson, J. D.)著;姚朝晖,周强编译. --北京:清华大学出版社,2010.12
(创新港)
