教育及工作经历

1991年9月～1995年7月 华中理工大学，本科毕业；
1995年8月～1999年8月 巴陵石化公司，技术员；
1999年9月～2004年5月 华中科技大学，获博士学位；
2004年6月～2006年7月 华中科技大学，博士后；
2006年1月～2006年7月 东北师范大学，日语培训；
2006年10月～2008年10月 日本东北大学，博士后；
2009年2月～ 2015年10月 华中科技大学，副教授；
2011年4月～ 2014年4月，工程热物理系副主任；
2011年5月～ 2015年10月，华中科技大学，副教授/博导；
2013年10月～ 2013年12月 日本东北大学，访问学者；
2015年11月～2021年10月  华中科技大学，教授（四级）/博导；
2021年11月～至今  华中科技大学，教授（三级）/博导

研究方向

基础研究：微通道传热；多孔介质传热传质；微小尺度燃烧；多孔介质燃烧
技术研发：电子器件散热技术；低碳燃烧技术；新型卷烟加热技术

科研项目

纵向课题：
1. 国家自然科学基金4项（在研1项，已结题3项）；
2. 湖北省自然科学基金（已结题）；
3. 教育部留学回国人员科研启动基金（已结题）；
4. 武汉市科技攻关重点基金（已结题）；
5. 重庆大学教育部重点实验室开放基金（已结题）；
6. 煤燃烧国家重点实验室开放基金2项（已结题）；
7. 华中科技大学自主创新基金3项（已结题）；
8. 华中科技大学GF创新基金2项（已结题）；
9. 华中科技大学博士论文创新基金2项（已结题）；
10. 华中科技大学教学研究项目（已结题）；

横向课题：
1. 上海中烟工业有限责任公司委托项目（在研）；
2. 汉江国家实验室科研项目（在研）；
3. 老板电器股份有限公司委托项目（已结题）；
4. 湖北迪峰换热器股份有限公司委托项目（已结题）；
5. 湖北中烟工业有限责任公司委托项目2项（已结题）；
6. 美的洗涤电器制造有限公司委托项目（已结题）；
7. 四川空分设备有限责任公司委托项目（已结题）；

代表性论文与专利

著作：
[1] 范爱武，康鑫，李林洪. 微小尺度燃烧稳焰技术，华中科技大学出版社，2023
[2] 范爱武，姚洪，刘伟. 微小尺度燃烧，科学出版社，2012
[3] 刘伟，范爱武，黄晓明. 多孔介质传热传质理论与应用，科学出版社，2006
[4] 黄晓明，刘志春，范爱武. 工程热力学，华中科技大学出版社，2011
[5] 黄晓明，许国良，刘志春，范爱武，方海生. 工程热力学，中国电力出版社，2015
[6] 邹春，王兆文，娄春，范爱武，鲁昊. 基础燃烧学，华中科技大学出版社，2020

国际期刊论文（代表作）：
一、微尺度燃烧
[1] G.Y. Yang, A.W. Fan*, Optimization of a miniature tubular combustor filled with a T-shaped porous zone for flame stability enhancement, Fuel, 391: 134610, 2025
[2] W.H. Liu, S.X. Wang, A.W. Fan*, Numerical investigation on flame behaviors of NH3/H2/air mixtures in a micro-flow reactor with a controlled wall temperature profile, Fuel, 379: 133079, 2025
[3] G.Y. Yang, A.W. Fan*, Enhancement of flame stabilization ability of a miniature tubular combustor by filling T-shaped porous media, Journal of the Energy Institute, 115:101704, 2024
[4] Z.Q. Liu, W.H. Liu, Y.Q. Du, A.W. Fan*, Experimental study on the propagation characteristics of non-premixed H2/air flames in a curved micro-combustor, Energy, 299:131444, 2024
[5] J.X. Li, G.Y. Yang, S.X. Wang, A.W. Fan*, Experimental and numerical investigation on non-premixed CH4/air combustion in a micro Swiss-roll combustor, Fuel, 349:128740, 2023
[6] S.X. Wang, A.W. Fan*, Numerical investigation of CH4/H2/air flame bifurcations in a micro flow reactor with controlled wall temperature profile. Combustion and Flame, 241:112070, 2022
[7] J.L. Wan, A.W. Fan*, Recent progress in flame stabilization technologies for combustion-based micro energy and power systems, Fuel, 286: 119391, 2021
[8] S.X. Wang, A.W. Fan*, Combustion regimes of syngas flame in a micro flow reactor with controlled temperature profile: A numerical study. Combustion and Flame, 230: 111457, 2021
[9] L.H. Li, G.Y. Yang, A.W. Fan*, Non-premixed combustion characteristics and thermal performance of a catalytic combustor for micro-thermophotovoltaic systems, Energy, 214: 118893, 2021
[10] L.H. Li, A.W. Fan*, A numerical study on non-premixed H2/air flame stability in a micro-combustor with a slotted bluff-body, International Journal of Hydrogen Energy, 46: 2658-2666, 2021
[11] M. Zhao, A.W. Fan*, Buoyancy effects on hydrogen diffusion flames confined in a small tube, International Journal of Hydrogen Energy, 45: 19926-19935, 2020
[12] S.X. Wang, Z.L. Yuan, A.W. Fan*, Experimental investigation on non-premixed CH4/air combustion in a novel miniature Swiss-roll combustor, Chemical Engineering and Processing, 139: 44-50, 2019
[13] Y. Xiang, Z.L. Yuan, S.X. Wang, A.W. Fan*, Effects of flow rate and fuel/air ratio on propagation behaviors of diffusion H2/air flames in a micro combustor, Energy, 179: 315-322, 2019
[14] S.X. Wang, L.H. Li, A.W. Fan*, Suppression of flame instability by a short catalytic segment on the wall of a micro channel with a prescribed wall temperature profile, Fuel, 2018, 234: 1329-1336
[15] D.G. Ning, Y. Liu, Y. Xiang, A.W. Fan*, Experimental investigation on non-premixed methane/air combustion in Y-shaped meso-scale combustors with/without fibrous porous media, Energy Conversion and Management, 138: 22-29, 2017
[16] Y. Liu, D.G. Ning, A.W. Fan*, H. Yao, Experimental and numerical investigations on flame stability of methane/air mixtures in mesoscale combustors filled with fibrous porous media, Energy Conversion and Management, 123: 402-409, 2016
[17] J.L. Wan, A.W. Fan*, H. Yao, Effect of the length of a plate flame holder on the flame blowout limit in a micro-combustor with preheating channels, Combustion and Flame, 170:53-62, 2016
[18] J.L. Wan, A.W. Fan*, Y. Liu, H. Yao, W. Liu, X.L. Gou, D.Q. Zhao, Experimental investigation and numerical analysis on flame stabilization of CH4/air mixture in a mesoscale channel with wall cavities, Combustion and Flame, 162: 1035-1045, 2015
[19] J.L. Wan, W. Yang, A.W. Fan*, Y. Liu, H. Yao, W. Liu, Y.Q. Du, D.Q. Zhao, A numerical investigation on combustion characteristics of H2/air mixture in a micro-combustor with wall cavities, International Journal of Hydrogen Energy, 39: 8138-8146, 2014
[20] J.L. Wan, A.W. Fan*, H. Yao, W. Liu, Flame-anchoring mechanisms of a micro cavity-combustor for premixed H2/air flame, Chemical Engineering Journal, 275: 17-26, 2015
[21] A.W. Fan*, H. Zhang, J.L. Wan, Numerical investigations on flame blow-off limit of a novel microscale Swiss-roll combustor with a bluff-body, Energy, 123: 252-259, 2017
[22] A.W. Fan*, J.L. Wan, K. Maruta, H. Yao, W. Liu, Interactions between heat transfer, flow field and flame stabilization in a micro-combustor with a bluff body, International Journal of Heat and Mass Transfer, 66: 72-79, 2013
[23] J.L. Wan, A.W. Fan*, K. Maruta, H. Yao, W. Liu, Experimental and numerical investigation on combustion characteristics of premixed hydrogen/air flame in a micro-combustor with a bluff body, International Journal of Hydrogen Energy, 37: 19190-19197, 2012
[24] A.W. Fan, S. Minaev, E. Sereshchenko, R. Fursenko, S. Kumar, W. Liu, K. Maruta*, Experimental and numerical investigations of flame pattern formations in a radial microchannel. Proceedings of Combustion Institute, 32: 3059-3066, 2009
[25] A.W. Fan*, S. Minaev, S. Kumar, W. Liu, K. Maruta, Regime diagrams and characteristics of flame patterns in radial microchannels, Combustion and Flame, 153: 479-489, 2008
[26] A.W. Fan, S. Minaev, S. Kumar, W. Liu, K. Maruta*, Experimental study on flame pattern formation and combustion completeness in a radial microchannel, Journal of Micromechanics and Microengineering, 17: 2398-2406, 2007

二、电子器件散热
[1] X. Xiang, W. Liu, A.W. Fan*, Comparison between the cooling performances of micro-jet impingement systems using liquid metal and water as coolants for high power electronics, International Journal of Thermal Sciences, 173:107375, 2022
[2] X. Xiang, Y. Fan, W. Liu, A.W. Fan*, Comparison between thermal resistances of optimized water-based and gallium-based heat sinks using the genetic algorithm, International Journal of Numerical Methods for Heat & Fluid Flow, 30(3):1388-1406, 2020
[3] X. Xiang, J.S. Yang, A.W. Fan*, W. Liu, A comparison between cooling performances of water-based and gallium-based micro-channel heat sinks with the same dimensions, Applied Thermal Engineering, 137: 1-10, 2018
[4] X. Xiang, Y. Fan, A.W. Fan*, W. Liu, Cooling performance optimization of liquid alloys GaIny in microchannel heat sinks based on back-propagation artificial neural network, Applied Thermal Engineering, 127: 1143-1151, 2017
[5] S. Zhong, C. Zhang, A.W. Fan*, Numerical study on heat transfer enhancement of laminar flow in fully wavy wall microchannels, Applied Thermal Engineering, 266: 125782, 2025

三、强化传热
[1] A.W. Fan, J.J. Deng, A. Nakayama, W. Liu*, Parametric study on turbulent heat transfer and flow characteristics in a circular tube fitted with louvered strip inserts, International Journal of Heat and Mass Transfer, 55: 5205-5213, 2012
[2] A.W. Fan, J.J. Deng, J. Guo, W. Liu*, A numerical study on thermo-hydraulic characteristics of turbulent flow in a circular tube fitted with conical strip inserts, Applied Thermal Engineering, 31: 2819-2828, 2011
[3] Y.H. You, A.W. Fan*, W. Liu, S.Y. Huang, Thermo-hydraulic characteristics of laminar flow in an enhanced tube with conical strip inserts, International Journal of Thermal Sciences, 61: 28-37, 2012
[4] Y.H. You, A.W. Fan*, S.Y. Huang, W. Liu, Numerical modeling and experimental validation of heat transfer and flow resistance on the shell side of a shell-and-tube heat exchanger with flower baffles, International Journal of Heat and Mass Transfer, 55: 7561-7569, 2012
[5] Y.H. You, A.W. Fan*, Y.M. Liang, S.P. Jin, W. Liu, F.Q. Dai, Entropy generation analysis for laminar thermal augmentation with conical strip inserts in horizontal circular tubes, International Journal of Thermal Sciences, 88: 201-214, 2015
[6] Y.H. You, A.W. Fan*, X.J. Lai, W. Liu, S.Y. Huang, Experimental and numerical investigations of shell-side thermo-hydraulic performances for shell-and-tube heat exchanger with trefoil-hole baffles, Applied Thermal Engineering, 50: 950-956, 2013
[7] Y.H. You, A.W. Fan*, X.J. Luo, S.P. Jin, W. Liu, S.Y. Huang, A theoretical investigation in the effects of recycles on laminar heat transfer enhancement of parallel-flow heat exchangers, Chemical Engineering and Processing, 70: 27-36, 2013
[8] J. Yang, A.W. Fan*, W. Liu*, A.M. Jacobi, Optimization of shell-and-tube heat exchangers conforming to TEMA standards with designs motivated by constructal theory, Energy Conversion and Management, 78: 468-476, 2014
[9] J. Guo, Y.X. Yan, W. Liu, F.M. Jiang*, A.W. Fan*, Effects of upwind area of tube inserts on heat transfer and flow resistance characteristics of turbulent flow, Experimental Thermal and Fluid Science, 48: 147-155, 2013
[10] J. Guo, Y.X. Yan, W. Liu, F.M. Jiang*, A.W. Fan*, Enhancement of laminar convective heat transfer relying on excitation of transverse secondary swirl flow, International Journal of Thermal Sciences, 87:199-206, 2015

四、储能技术
[1] L.X. Chen, A.W. Fan*, Effects of shell modifications and operational parameters on melting uniformity of a vertical multi-section shell-and-tube latent heat thermal energy storage unit, Journal of Energy Storage, 55: 105593, 2022

发明专利（已授权）：
[1] 范爱武，李佳鑫，王世轩，一种适用于非预混燃烧的多腔回热型燃烧装置，专利号：ZL2021115331384；
[2] 范爱武，王世轩，羊光耀，一种具有多级被动进风功能的微小型燃烧器，专利号：ZL202010051459X；
[3] 范爱武，王世轩，一种适用于热发电的微小型非预混燃烧器，专利号：ZL2019107790687；
[4] 范爱武，袁自力，李林洪，一种具有波纹板的微小型非预混燃烧器，专利号：ZL2019101453675；
[5] 范爱武，王世轩，袁自力，一种微小型尾气再循环式燃烧器，专利号：ZL2019101436133；
[6] 范爱武，杨景珊，刘伟，一种放射状肋片表面有凸起的散热器，专利号：ZL2018115708209；
[7] 范爱武，王飞龙，王特，杨金国，刘伟，一种强化管内对流换热的扰流元件，专利号：ZL2013102678715；
[8] 范爱武，万建龙，张贺，张婧宜，刘伟，一种微燃烧发电装置，专利号：2013103965276；
[9] 范爱武，万建龙，张婧宜，张贺，刘伟，一种分级混合的微小型扩散燃烧器，专利号：2013100624744；
[10] 范爱武，刘思远，张若昀，杨金国，刘伟，一种微小型燃烧器，专利号：2011100571466；

所获荣誉和奖励

1. 教育部科技进步一等奖（2015，7/11）；
2. 入选“全球顶尖2%科学家排行榜”（2022年至今）；
3. 入选“爱思唯尔中国高被引学者”（2021年至今）；
4. 入选ESI高被引论文和热点论文8篇；
5. 中国工程热物理年会“优秀墙报奖”（2024）；
6. Chemical Engineering and Processing杂志封面论文（2019）；
7. Journal of Micromechanics and Microengineering杂志亮点文章（2007）；
8. 华中科技大学“全校最满意课堂”（2023）；
9. 华中科技大学教学质量二等奖4次（2010-2012；2019）；
10. 指导研究生获国家奖学金8人次；
11. 华中科技大学优秀科研工作者（2015）；
12. 华中科技大学高水平论文奖（2014）；
13. 湖北省优秀学士学位论文指导老师2次（2013，2015）；
14. 日本文部省博士后奖学金（2006-2008）；
15. 华中科技大学研究生科技十佳（2003）；
16. 中国工程热物理年会“优秀论文奖”2次（2001，2002）；
17. 岳阳石化总厂机能系统优秀节能手（1997）.