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  • 姓名:刘训良
    热科学与能源工程系
    教授
  • 办公地点:
    机电楼1217B
  • 办公电话:
    010-62332730
  • Email:
    liuxl@me.ustb.edu.cn

刘训良热科学与能源工程系



学习工作简历:

本科及以上学位:

1990.09-1994.07   西安交通大学 能源与动力工程学院 制冷与低温专业 工学学士

2000.09-2005.12   西安交通大学 能源与动力工程学院 工程热物理专业 工学博士


工作经历:

1994.07-2000.08  山东鲁抗医药股份有限公司 动力车间,工程师

2005.12-2010.07  北京科技大学 机械工程学院 热科学与能源工程系,讲师

2013.11-2014.11  美国宾夕法尼亚州立大学 工程科学与力学系,访问学者

2010.07-2016.07  北京科技大学 机械工程学院 热科学与能源工程系,副教授

2016.07-2017.06  北京科技大学 能源与环境工程学院 热科学与能源工程系,教授

2017.06 至今    北京科技大学 能源与环境工程学院 热科学与能源工程系,教授/博导/系副主任,冶金工业节能减排北京市重点实验室副主任


研究领域:

1.  化学储能及热管理

2.  锂电池/燃料电池建模及仿真

3.  工业热过程数值模拟及优化

4.  工业节能及污染物减排


研究生培养:

已毕业博士生和硕士生20余名,其中5名毕业研究生获北京科技大学优秀毕业生、优秀毕业论文等称号。除部分硕士生继续攻读博士学位之外,多数毕业生在中核集团、一汽大众、北汽新能源、潍柴动力等国企或研究院从事科研工作。


本科生课程:

1. 动力机械

2. 热过程模拟软件实训


研究生课程:

1. 计算流动与燃烧


社会兼职:

河北省热科学与能源利用技术重点实验室学术委员会委员

北京市热物理与能源工程学会会员


代表性论文:

[1] Yi Xiaoping, Liu Xunliang*, Jiang Kai, Dou Ruifeng, Wen Zhi, Zhou Wenning. Effect of TiC surface oxide overlayer on the control of LixOy behavior in lithium-oxygen batteries: Implications for cathode catalyst design[J]. Applied Surface Science, 2021, 567(30): 150785.

[2] Huo Hailong, Liu Xunliang*, Wen Zhi, Lou Guofeng,. Dou Ruifeng, Su Fuyong, Zhou Wenning, Jiang Zeyi, Case study of a novel low rank coal to calcium carbide process based on techno-economic assessment[J]. Energy, 2021, 228: 120566.

[3] Yi Xiaoping, Liu Xunliang*, Dou Ruifeng, Wen Zhi, Zhou Wenning. Unraveling the Control Mechanism of Carbon Nanotubes on the Oxygen Reduction Reaction and Product Growth Behavior in Lithium–Air Batteries[J]. ACS Applied. Energy Materials, 2021, 4(3): 2148–2157.

[4] Zhang Sizong, Wen Zhi, Wang Gan, Lou Guofeng, Liu Xunliang*. Kinetic analyses of coke combustion and thermal decompositions of limestone and dolomite based on the sintering atmosphere[J]. Fuel, 2021, 289.

[5] Zhang Sizong, Wen Zhi, Liu Xunliang*. Wang Shuai, Zhang Hui. Experimental study on the permeability and resistance characteristics in the packed bed with the multi-size irregular particle applied in the sinter vertical waste heat recovery technology [J]. Powder Technology, 2021, 384: 304-312.

[6] Gao Yanan, Wen Zhi,  Deng Xie, Shi Mingze, Liu Xunliang*. Reconstruction of Carbon Papers and Analysis of Structural and Characteristic Parameters Through Lattice Boltzmann Method [J]. Transport in Porous Media, 2020, //doi.org/10.1007/s11242-020-01510-0.

[7] Yi Xiaoping, Liu Xunliang*, Zhang Peng, Dou Ruifeng, Wen Zhi, Zhou Wenning, Computational insights into LixOy formation, nucleation, and adsorption on carbon nanotube electrodes in nonaqueous Li-O2 batteries[J]. The Journal of Physical Chemistry Letters, 2020, 11: 2195-2202.

[8] Yi Xiaoping, Liu Xunliang*, Xiao Kaiming, Dou Ruifeng, Zhou Wenning, Mechanistic evaluation of Li2O2 adsorption on carbon nanotube electrodes: A theoretical study[J]. Applied Surface Science, 2020, 506(15): 145050.

[9] Jiang Kai, Liu Xunliang*, Lou Guofeng, Wen Zhi, Liu Lin, Parameter sensitivity analysis and cathode structure optimization of a non-aqueous Li–O2 battery model[J]. Journal of Power Sources, 2020, 451(1): 227821.

[10] Song Fuqiang, Wen Zhi, Fang Yuan, Wang Enyu, Liu Xunliang*, Combustion Wave Propagation of a Modular Porous Burner with Annular Heat Recirculation[J]. Journal of Thermal Science, 2020, 29: 98-107.

[11] Song Fuqiang, Wen Zhi, Dong Zhiyong, Wang Enyu, Liu Xunliang*, Numerical study and optimization of a porous burner with annular heat recirculation[J]. Applied Thermal Engineering, 2019, 157: 113741.

[12] Mu Wenyu, Liu Xunliang*, Wen Zhi, Liu Lin, Numerical simulation of the factors affecting the growth of lithium dendrites[J]. Journal of Energy Storage 2019, 26: 100921.

[13] Liu Shuaihua, Liu Xunliang*, Dou Ruifeng, Zhou Wenning, Wen Zhi, Liu Lin, Experimental and simulation study on thermal characteristics of 18,650 lithium–iron–phosphate battery with and without spot-welding tabs[J]. Applied Thermal Engineering, 2019.11.5, 158(1):114648.

[14] Zhou Wenning, Wang Haobo, Yan Yuying, Liu Xunliang, Adsorption mechanism of CO2/CH4 in kaolinite clay: insight from molecular simulation[J]. Energy & Fuels, 2019, 33:6542-6551.

[15] W.N. Zhou, H.L. Huo, Q.Y. Li, R.F. Dou, X.L. Liu*, An Improved Comprehensive Model of Pyrolysis of Large Coal Particles to Predict Temperature Variation and Volatile Component Yields[J]. Energies, 2019, 12(5):884.

[16] Zhou Wenning, Yan Yuying, Liu Xunliang, Chen Hongxia, Liu Baiqian, Lattice Boltzmann simulation of mixed convection of nanofluid with different heat sources in a double lid-driven cavity[J]. International Communications in Heat and Mass Transfer, 2018, 97:39-46.

[17] Liu Xunliang,Gu Lijun,Wen Zhi,A numerical strategy of identifying the shape ofa two-dimensional thermal boundary with known temperature[J]. Heat Transfer Research, 2016, 47(3): 219-229.

[18] Liu Xunliang,Peng Fangyuan,Lou Guofeng,Wen Zhi,Liquid water transport characteristics of porous diffusion media in polymer electrolyte membrane fuel cells: A review[J]. Journal of Power Sources, 2015, 299: 85-96.

[19] Liu Xunliang,Tian Ye,Yu Yue,Wen Zhi,Zhang Daoming,Li Zhi,Feng Xiaohong,Experimental studies on the heating performance and emission characteristics of a W-shaped regenerative radiant tube burner[J]. Fuel, 2014, 135: 262-268.

[20] Liu Xunliang,Yin Xiaojun,Zhang Hao,Reaction Characteristics of CO and Sintering Ore Used as an Oxygen Carrier in Chemical Looping Combustion[J]. Energy & Fuels, 2014, 28(9): 6066-6076.

[21] Liu Xunliang,Song Fuqiang,Wen Zhi,A novel dimensionless form of unreacted shrinking core model for solid conversion during chemical looping combustion[J]. Fuel, 2014, 129: 231-237.

[22] Liu Xunliang,Wang Gan,Pan Gang,Wen Zhi,Numerical analysis of heat transfer and volatile evolution of coal particle[J]. Fuel, 2013, 106: 667-673.

[23] Liu Xunliang,Pan Gang,Wang Gan,Wen Zhi,Mathematical model of lump coal falling in the freeboard zone of the COREX melter gasifier[J]. Energy & Fuel, 2011, 25(12): 5729-5735.

[24] Liu Xunliang,Lou Guofeng,Wen Zhi,Three-dimensional two-phase flow model of proton exchange membrane fuel cell with parallel gas distributors[J]. Journal of Power Sources, 2010, 195(9): 2764-2773.

[25] Liu Xunliang, Tao Wenquan, Li Zengyao, He Yaling, Three-dimensional transport model of PEM fuel cell with straight flow channels[J]. Journal of Power Sources, 2006, 158(1): 23-35.

[26] Liu Xunliang, Tan Yawei, Tao Wenquan, He Yaling, A hybrid Model of cathode of PEM fuel cell using the Interdigitated gas distributor[J]. International Journal of Hydrogen Energy, 2006, 31: 379-389.

[27] Liu Xunliang, Tao Wenquan, He Yaling, A simple method for improving the SIMPLER algorithm for numerical simulations of incompressible fluid flow and heat transfer problems[J]. Engineering Computation, 2005, 22 (8): 921-939.

[28] Liu Xunliang, Tao Wenquan, Chen Ping, He Yaling, Wang Qiuwang, Control of convergence in a computational fluid dynamic simulation using fuzzy logic[J]. Science in China Series E-Technological Sciences, 2002, 45 (5): 495-502.

[29] Song Fuqiang, Wen Zhi, Dong Zhiyong, Wang Enyu, Liu Xunliang*, Ultra-low calorific gas combustion in a gradually-varied porous burner with annular heat recirculation[J]. Energy, 2017, 119: 497-503.

[30] Pan Gang, Liu Xunliang*, Wen Zhi, Three-dimensional numerical study of the combustion of char in the raceway of a COREX melter gasifier[J]. Ironmaking & Steelmaking, 2013,40(4):255-262.

[31] Zhou Wenning, Yan Yueying, Liu Xunliang, Liu Baiqian. Lattice Boltzmann parallel simulation of microflow dynamics over structured surfaces,Advances in Engineering Software[J]. 2017, 107:51-58.

[32] Yang Peipei, Wen Zhi, Dou Ruifeng, Liu Xunliang, Effect of random structure on permeability and heat transfer characteristics for flow in 2D porous medium based on MRT lattice Boltzmann method[J]. Physics Letters A, 2016, (380): 2902-2911.

[33] Dou Ruifeng, Ge Tianran, Liu Xunliang, Wen Zhi, Effects of contact pressure, interface temperature, and surface roughness on thermal contact conductance between stainless steel surfaces under atmosphere condition[J]. International Journal of Heat and Mass Transfer, 2016, (94): 156-163.

[34] Pan Gang,Wen Zhi,Liu Xunliang,Li Yike,Zheng Kuncan,Wu Wenfei,Modelling of solid particle flow in moving bed of COREX melter/gasifier based on discrete element method[J]. Ironmaking and Steelmaking, 2015, 42(7): 489-497.

[35] Liu Ying,Liu Yiping,Tao Shuming,Liu Xunliang,Wen Zhi,Three-dimensional analysis of gas flow and heat transfer in a regenerator with alumina balls[J]. Applied Thermal Engineering, 2014, 69(1-2): 113-122.

[36] Dou Ruifeng,Wen Zhi,Zhou Gang,Liu Xunliang,Feng Xiaohong,Experimental study on heat-transfer characteristics of circular water jet impinging on high-temperature stainless steel plate[J]. Applied Thermal Engineering, 2014, 62(2): 738-746.

[37] Wen Zhi, Shi Hongzhi, Zhang Xin, Lou Guofeng, Liu Xunliang, Dou Ruifeng, Su Fuyong, Numerical simulation and parameters optimization on gas-solid heat transfer process of high temperature sinter[J]. Ironmaking & Steelmaking, 2011, 38(7): 525-529.

[38] Zheng Kuncan,Wen Zhi,Liu Xunliang,Ren Yanqiu,Wu Wenfei,Qiu Haibo,Research Status and Development Trend of Numerical Simulation on Blast Furnace Lining Erosion[J]. ISIJ International,2009,49(9):1277-1282.

[39] Tao Wenquan, Min Chunhua, Liu Xunliang, He Yaling, Yin Binhao,Jiang Wei, The parameter sensitivity examination and discussion on model validation of PEM fuel cell simulation - Part I: Current status of modeling research and model development[J]. Journal of Power Sources, 2006, 160 (1): 359-373.

[40] Min Chunhua, He Yaling, Liu Xunliang, Yin Binhao, Jiang Wei, Tao Wenquan, The parameter sensitivity examination and discussion on model validation of PEM fuel cell simulation - Part Ⅱ: Results of sensitivity analysis and discussion on model validation[J]. Journal of Power Sources, 2006, 160 (1): 374-385.

[41] 刘训良, 陶文铨, 郑平, 何雅玲, 王秋旺, 模糊控制方法在粘性流场迭代计算中的应用[J]. 中国科学(E辑), 2002, 32(4): 472-478.

[42] 刘训良, 陶文铨, 何雅玲, 郑平,用于黏性流场计算的一种改进的模糊控制方法[J]. 西安交通大学学报, 2002, 37(9): 962-965.

[43] 刘训良, 温治, 何雅玲, 陶文铨, 叉指型PEMFC阴极内的两相流动模拟[J]. 太阳能学报, 2007, 28(7): 769-774.

[44] 刘训良, 温治, 陶文铨, 何雅玲,直流道PEMFC的综合三维数学模型及其性能模拟[J]. 沈阳建筑大学学报(自然科学版), 2008, 24(2): 306-310.

[45] 刘训良, 楼国锋, 温治, 直流道PEMFC两相流数学模型[J]. 计算物理, 2012, 29(5): 131-138.

[46] 曹欢, 刘训良*, 温治, 楼国锋, 烧结矿应用于化学链燃烧的反应特性[J].工程科学学报, 2015, 137(4): 422-428.

[47] 代尧, 刘训良*,楼国锋,温治,移动床内合成气化学链燃烧反应的实验研究[J]. 工程热物理学报, 2016, 37(10): 1-5.

[48] 李钦晔, 代尧, 张四宗, 温治, 刘训良*. 铁基载氧体化学链燃烧还原过程的数学模型[J]. 工程科学学报, 2016, 38(12): 1770-1777.

[49] 姜锴; 刘训良*; 温治; 楼国锋; 非水系锂空气电池放电过程模拟, 电源技术, 2020, 44(1): 48-51.

[50] 张四宗, 温治, 刘训良*, 张辉, 刘晓宏, 王帅. 颗粒形状对烧结矿填充床内渗透系数和阻力系数的影响[J]. 中南大学学报(自然科学版), 2021,4: 1066-1075.

 

代表性专利成果:

[1] 一种便于在手套箱内组装的固态电池装置,发明专利,申请,2021,202110909105.9

[2]  一种用于液态金属电池的正极稳定装置,发明专利,授权,ZL201911340572.3

[3] 一种连续运行的移动床化学链反应系统,发明专利,授权,ZL201310331443.4

[4] 一种回转式固定床化学链燃烧反应装置,发明专利,授权,ZL201220375279.8

[5] 一种燃气辐射管,实用新型,授权,ZL200920220381.9

[6] 一种自预热型燃烧器中的换热器,实用新型,授权,ZL200920220382.3

[7] 一种带卷材料径向等效导热系数的测量装置及测量方法,发明专利,授权,ZL201310334215.2

[8] 一种带卷材料径向等效导热系数的测量装置,实用新型,授权,ZL201320470723.9

[9]  烟气循环烧结工艺质—热耦合数值仿真系统软件V1.0,软件著作权,2018SR276780, 2018.

[10] 烧结工艺热平衡质热诊断计算及分析计算软件V1.0,软件著作权,2018SR276780, 2018.

 

代表性科研项目:

1. 国家自然科学基金面上项目(No.52076012)“全固态锂空气电池一体化正极界面输运及反应机制研究”,项目负责人,2021-2024

2. 国家自然科学基金面上项目(No.51676013)“非水锂空气电池空气电极放电过程的介观尺度模拟”,项目负责人,2017-2020

3. 国家自然科学基金面上项目(No.51276015)“移动床气固反应器多相耦合热质传递机制研究”,项目负责人,2013-2016

4. 国家自然科学基金钢铁联合基金重点项目(No. 50934007)“COREX冶炼工艺的煤裂化机理研究”,项目完成人,2010-2013

5. 国家重点研发计划项目(2017YFC0210304)“高温烟气循环分级净化与余热利用技术及示范”,子课题负责人,2017-2020

6. 国家重点研发计划项目(2016YFC0401201)“钢铁流程低品位余热高效利用技术开发与研究”,子课题完成人,2016-2020

7. 企业合作项目(宝钢研究院委托)“焦炉典型炭化室及燃烧室温度测定对比研究”,项目负责人,2019-2020

8. 企业合作项目(宝钢研究院委托)“转炉渣旋流混匀调质过程工艺模拟与实验研究”,项目负责人,2020-2021

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