周力行，男，汉族，1952年 6月加入中国共产党。祖先原籍浙江绍兴，后迁居辽宁沈
阳。本人 1932年 12月 4日（后来按照农历登记为 11月 7日）生于北京。清华大学工程力
学系教授，国务院批博士生导师，享受国家特殊津贴的专家，多相流和燃烧学科学术带头
人。1950年毕业于上海洋泾中学，1950—1952年就读于北京大学工学院，1953年毕业于清
华大学动力系本科，1961年毕业于苏联列宁格勒工业大学物理-力学系研究生部，获副博士
学位（相当于西方国家 Ph.D.博士学位）。1961年起为清华大学数学力学系讲师，曾任热物
理教研组主任。1983年起为清华大学工程力学系副教授, 系学术委员会副主任。1985年至
今为清华大学工程力学系教授，曾任清华大学学位委员会热能分会副主席。 1986年至今为
国务院学位办批准的博士生导师。1987—1988年为美国 Catholic University of America访问
教授，1988—1989 年为苏联列宁格勒工业大学访问教授，1989—1990年为美国 University of 
Illinois at Urbana-Champaign和 Brigham Young University访问教授。 1994—2003年任清华大学
煤的清洁燃烧国家重点实验室学术委员会副主任。 1998—2002 年为美国 Ohio State University
访问教授和华中科技大学兼职教授，2010年起为天津大学兼职教授。2001年 9月曾被提名
为中国科学院院士增选候选人，进入第二轮为初步候选人， 2009年 9 月曾被提名为中国科
学院院士增选候选人，进入第二轮为初步候选人。
曾任国际燃烧学会会员和中国分会理事（ 1994—2008），中国力学学会多相流和非牛顿流专业组主任（ 1994—2004），中国工程热物理学会理事（ 1994—1999）和燃烧分会委员（1994—2009），国际多相流会议常设核心组（ governing board）成员（ 2001—2007）和组织
委员及学术委员（ 1998年至今），第 1届和第 2届国际多相流、非牛顿流和反应流会议主席（1997—2004），第 1～3届国际煤燃烧会议执行主席、第 4～7届国际煤燃烧会议学术委员（1987年至今），第 3～11届国际清洁环境燃烧 /能源技术会议国际学术委员(1995年至今)，第 24～31届国际燃烧会议评审委员(1994—2008)，第 2届和第 3届国际湍流和传热传质会议国际学术委员（1997，2000），“力学学报”编委和中国科学院出版基金委员会专家组评审委员。现任《International Journal on Environmental Combustion Technologies》编委，《Journal of Computational Multiphase Flows》编委，《燃烧科学与技术》编委和中国科学院空
间科学专家评审组委员。 
1986年至今曾先后在美、德、加、俄、日、葡、澳大利亚、芬兰等国家和香港、台湾
地区的 60余所大学及研究院所进行合作研究和讲学近 70次。在国内，先后曾应邀到华中
科技大学、天津大学、上海交通大学、西安交通大学、西安理工大学、浙江大学、东南大
学、山东大学、山东科技大学、石油大学（华东）、华东理工大学、内蒙古科技大学和西南
科技大学等高校多次讲学。1999年退休后至今继续工作在科研第一线已经有 12年，持续参
加国内外学术会议，担任学术职务，先后获得学校两次“老有所为”先进个人的表扬。
在教学工作上，先后主讲了“燃烧学”，“湍流两相流动和燃烧的数值模拟”，“电磁流体
力学”，“反应流体力学”等课程，培养了 26名博士生和 17名硕士生，以及 9名博士后。
在科学研究上，曾从事多相流、湍流、燃烧和电弧等离子体研究，承担过国家自然科
学基金重大项目、重点项目和面上项目，国家攀登计划项目和国家“ 973”基础研究项目有关

课题等，发展了“多相湍流反应流体力学”的学术方向，提出了多相湍流和有反应湍流新的理论模型——颗粒湍流动能输运和二阶矩两相湍流模型以及二阶矩燃烧理论模型，发现了颗粒湍流强度及其各向异性大于流体的湍流强度及其各向异性，旋流的增强先减弱后增大总氮氧化物生成等新现象，得到国内外学术界同行的公认。
据 2011年 9月统计，共发表英文专著 1本，中文专著 6本，研究论文 390篇（含国际期刊论文 91篇，国内期刊论文 161篇，国际会议论文 138篇）。被 SCI（美国《科学引文索引》）收录 79篇，EI（美国工程索引）收录 140篇以上。据 2009年 1月统计，SCI他引（他人引用）571次以上，CSCD（“中国科学引文数据库”）收录 159篇，CSCD他引 464次以上。
曾在国际会议上被邀请做大会报告 5次和主题报告 10次。曾获 2007年国家自然科学二等奖（唯一获奖人），1995年国家教委科技进步一等奖（第一获奖人），1995年光华科技一等奖（唯一获奖人），1995年电力部科技进步一等奖（第二获奖人），1992年全国电力科技优秀图书一等奖（唯一获奖人）和部委二等奖多项。周力行教授的传略曾被载入美国 1994年出版的世界 5000名人录。

专著和编著 
[1]	周力行. 燃烧理论和化学流体力学[M].北京：科学出版社，1986. 

[2]	王应时，范维澄，周力行，徐旭常 . 燃烧过程数值计算[M]. 北京：科学出版社， 1986. 

[3]	周力行. 湍流两相流动和燃烧的数值模拟[M].北京：清华大学出版社，1991. 

[4] 	Zhou L X. Theory and Numerical Modeling of Turbulent Gas-particle Flows and Combustion[M]. Science Press (Beijing, PRC) and CRC Press (Florida, USA), 1993. 

[5]	周力行. 湍流气粒两相流动和燃烧的理论与数值模拟[M].北京：科学出版社，1994. 

[6]	周力行. 多相湍流反应流体力学[M]. 北京：国防工业出版社，2002. 

[7]	徐旭常，周力行. 燃烧技术手册[M]. 北京：化工出版社，2008. 

国际期刊论文 

1. 	Zhou L X. Second-order moment modeling of dispersed two-phase turbulence—Part 2–USM-Θ two-phase turbulence model and USM-SGS two-phase stress model[J]. Science in China, Series A, 2011, 54(7):1296–1303. 

2. 	Zhou L X. Second-order moment modeling of dispersed two-phase turbulence—Part 1: USM, k-ε-kp, and non-linear k-ε-kp two-phase turbulence models[J]. Science in China, Series A, 2011, 54 (6): 1098–1107. 

3. 	Wu Y Y, Chan C K, Zhou L X. Large eddy simulation of an ethylene–air turbulent premixed V-flame[J]. Journal of Computational and Applied Mathematics, 2011, 235: 3768–3774. 

4. 	Zhou L X, Liu Y, Xu Y. Measurement and simulation of the two-phase velocity correlation in sudden-expansion gas–particle flows[J]. Acta Mechanica. Sinica, 2011, 27(4):494–501. 

5. 	Liu Y, Liu X, Li G H, Zhou L X. A particle–particle Reynolds stress transportation model of swirling particle-laden-mixtures turbulent flows[J]. Advanced Powder Technology, doi:10.1016/ j.apt.2011.01.010, 2011. 

6. 	Liu Y, Liu X, Kallio S, Zhou L X. Hydrodynamic predictions of dense gas–particle flows using a second-order-moment frictional stress model[J]. Advanced Powder Technology, 2011, 

22: 504–511. 

7. 	Liu Y, Zhou L X, Xu C X. Numerical simulation of instantaneous flow structure of swirling and non-swirling coaxial-jet particle-laden turbulence flows[J]. Physica A, 2010, 389: 5380–5389. 

8. 	Zhou L X. Advances in Studies on Turbulent Dispersed Multiphase Flows[J]. Chinese Journal of Chemical Engineering, 2010, 18(6): 1–10. 

9. 	Liu Y, Zhou L X, Xu C X. Large-eddy simulation of swirling gas-particle flows using a USM two-phase SGS stress model[J]. Powder Technology, 2010, 198: 183–188. 

10. 	Zhou L X. Advances in studies on two-phase turbulence in dispersed multiphase flows[J]. International Journal of Multiphase Flow, 2010, 36: 100–108. 

11. 	
Zeng Zh X, Sun D Ch, Zhou L X. Comparison of gas particle flow prediction from large eddy simulation and Reynolds-averaging Navier-Stokes modeling[J]. J. Shanghai Jiaotong Univ. (Sci.), 2010, 15(5): 622–625. 

12. 	
Zeng Zh X, Pan Y, Zhou L X. Gas turbulence modulation model for gas-solid flows in two-fluid approach[J]. J. Shanghai Jiaotong Univ. (Sci.), 2010, 15(4): 428–433. 

13. 	
Wang F, Zhou L X, Xu C X, Chan C K. DNS-LES Validation of an algebraic second-order moment combustion model[J]. Numerical Heat Transfer, Part B, 2009, 55: 523–532. 

14. 	
Zhou L X. Development of SOM combustion model for Reynolds-averaged and large-eddy simulation of turbulent combustion and its validation by DNS[J]. Science in China, 2008, E-51(8):1073–1086. 

15. 	
Zhou L X, Zeng Zh X. Studies on gas turbulence and particle fluctuation in dense gas-particle flows[J]. Acta Mechanica Sinica, 2008, 24: 251–260. 

16. 	
Wang F, Zhou L X, Xu C X, Goldin G M. Comparison between a composition PDF transport equation model and an ASOM model for simulating a turbulent jet flame[J]. International Journal of Heat and Mass Transfer, 2008, 51: 136–144. 

17. 	
Zhou L X, Hu L Y, Wang F. Large-eddy simulation of turbulent combustion using different combustion models[J]. Fuel, 2008, 87: 3123–3131. 

18. 	
Wang F, Xu Ch X, Zhou L X. Validation of the RANS-SOM combustion model using direct numerical simulation of incompressible turbulent reacting flows[J]. Chinese Journal of Chemical Engineering, 2008, 16(5): 679–685. 

19. 	
Zeng Z X, Zhou L X, Qi H Y. Large eddy simulation of particle wake effect and RANS modeling of turbulence modulation in gas-particle flows[J]. Chinese Journal of Chemical Engineering, 2007, 15(1): 12–16. 

20. 	
Zhang J, Pu Y, Zhou L X. Turbulence characteristics of swirling reacting flow in a combustor with staged air injection[J]. CHINESE JOURNAL OF CHEMICAL ENGINEERING, 2006, 14 (5): 634–641. 

21. 	
Zeng Z X, Zhou L X, Liu Z H. Second-order moment model for dense two-phase turbulent flow of Bingham fluid with particles[J]. APPLIED MATHEMATICS AND MECHANICS-ENGLISH EDITION, 2006, 27 (10): 1373–1381. 

22. 	
Zhou L X, Li R X, Du R X. Numerical simulation of the effect of void fraction and inlet velocity on two-phase turbulence in bubble-liquid flows[J]. ACTA MECHANICA SINICA, 2006, 22 (5): 425–432. 

23. 	
Yu Y, Zhou L X, Wang B G. Modeling of fluid turbulence modification using two-time-scale dissipation models and accounting for the particle wake effect[J]. CHINESE JOURNAL OF CHEMICAL ENGINEERING, 2006, 14 (3): 314–320. 

24. 	
Hu L Y, Zhou L X, Zhang J. Large-eddy simulation of a swirling diffusion flame using a SOM SGS combustion model[J]. NUMERICAL HEAT TRANSFER PART B-FUNDAMENTALS, 2006, 50 (1): 41–58. 

25. 	
Wang F, Zhou L X, Xu C X. Large-eddy simulation of correlation moments in turbulent combustion and validation of the RANS-SOM combustion model[J]. FUEL, 2006, 85 (9): 1242–1247. 

26. 	
Zeng Z X, Zhou L X. A two-scale second-order moment particle turbulence model and simulation of dense gas-particle flows in a riser[J]. POWDER TECHNOLOGY, 2006, 162 (1): 27–32. 

27. 	
Zhang Y, Zhou L X, Wei X L, Sheng H Z. Studies of the effect of a coal concentrator on NO formation in swirling coal combustion[J]. INTERNATIONAL JOURNAL OF HEAT AND MASS TRANSFER, 2006, 49 (1–2): 421–426. 

28. 	
Hu L Y, Zhou L X, Zhang J. Large-eddy structures of turbulent swirling flows and methane-air swirling diffusion combustion[J]. ACTA MECHANICA SINICA, 2005, 21 (5): 419–424. 

29. 	
Zeng Z X, Zhou L X, Zhang J. A two-scale second-order moment two-phase turbulence model for simulating dense gas-particle flows[J]. ACTA MECHANICA SINICA, 2005, 21 (5): 425–429. 

30. 	
Zhang X, Zhou L X. A second-order moment particle-wall collision model accounting for the wall roughness[J]. POWDER TECHNOLOGY, 2005, 159 (2): 111–120. 

31. 	
Zhang J, He J B, Zhou L X, et al. Simulation of swirling turbulent heat transfer in a vortex heat exchanger[J]. NUMERICAL HEAT TRANSFER PART A-APPLICATIONS, 2005, 48 (7): 607–625. 

32. 	
Shang Q, Zhang J, Zhou L X. Effects of gas temperature fluctuation on the instantaneous char reaction of pulverized coal particle[J]. FUEL, 2005, 84 (16): 2071–2079. 

33. 	
Zhang Y, Wei X L, Zhou L X, et al. Simulation of coal combustion by AUSM turbulence- chemistry char combustion model and a full two-fluid model[J]. FUEL, 2005, 84 (14-15): 1798–1804. 

34. 	
Hu L Y, Zhou L X, Zhang J. Comparison between LES and RANS modeling of turbulent swirling flows and swirling diffusion combustion[J]. CHINESE JOURNAL OF CHEMICAL ENGINEERING, 2005, 13 (3): 313–317. 

35. 	
Zhang Y, Zhou L X, Wei X L, et al. Numerical simulation of NOx formation in coal combustion with inlet natural gas burning[J]. CHINESE JOURNAL OF CHEMICAL ENGINEERING, 2005, 13 (3): 318–323. 

36. 	
Yu Y, Zhou L X, Wang B G, et al. A USM-Theta two-phase turbulence model for simulating dense gas-particle flows[J]. ACTA MECHANICA SINICA, 2005, 21 (3): 228–234. 

37. 	
Hu L Y, Zhou L X, Zhang J, et al. Studies on strongly swirling flows in the full space of a volute cyclone separator[J]. AICHE JOURNAL, 2005, 51 (3): 740–749. 

38. 	
Zhou L X. Development of multiphase and reacting turbulence models[J]. NUMERICAL HEAT TRANSFER PART B-FUNDAMENTALS, 2005, 47 (2): 179–197. 

39. 	
Zhou L X, Yang M, Fan L S. A second-order moment three-phase turbulence model for simulating gas-liquid-solid flows[J]. CHEMICAL ENGINEERING SCIENCE, 2005, 60 (3): 647–653. 

40. 	
Zhou L X, Zhang X. Experimental studies of the effect of wall roughness on particle behavior in gas-particle flows[J]. CHINESE JOURNAL OF CHEMICAL ENGINEERING, 2004, 12 (3): 330–334. 

41. 	
Zhou L X, Zhang X. Simulation of sudden-expansion and swirling gas-particle flows using a two-fluid particle-wall collision model with consideration of the wall roughness[J]. ACTA MECHANICA SINICA, 2004, 20(5): 447–454. 

42. 	
Zhou L X, Gu H X. A nonlinear k-ε-kp two-phase turbulence model[J]. Transactions of ASME, Journal of Fluid Engineering, Transactions of ASME, 2003, 125: 191–194. 

43. 	
Yu Y, Zhou L X, Zheng C G, Liu Z H. Simulation of swirling gas-particle flows using different time scales for the closure of two-phase velocity correlation in the second-order moment two-phase turbulence model[J]. Journal of Fluid Engineering, Transactions of ASME, 2003, 

125: 247–250. 

44. 	
Zhou L X, Zhang Y, Zhang J. Simulation of swirling coal combustion using a full two-fluid model and an AUSM turbulence-chemistry model[J]. Fuel, 2003, 82: 1001–1007. 

45. 	
Zhou L X, Chen X L, Zhang J. Studies on the effect of swirl on NO formation in methane-air turbulent combustion[J]. Proceedings of the Combustion Institute, 2003, 29: 2235–2242, Part 2. 

46. 	
Liu Z H, Zheng C G, Zhou L X. A joint PDF model for turbulent spray evaporation/ combustion[J]. Proceedings of the Combustion Institute, 2003, 29: 561–568, Part 1. 

47. 	
Lu Y J, Zhou L X. Numerical simulation of fluid flow and oil-water separation in hydrocyclones[J]. Chinese Journal of Chemical Engineering, 2003, 11: 97–101. 

48. 	
Zhou L X, Wang F, Zhang J. Simulation of swirling combustion and NO formation using a USM turbulence-chemistry model[J]. Fuel, 2003, 82: 1579–1586. 

49. 	
Zhou L X, Qiao L, Zhang J. Simulation of NO formation in turbulent swirling combustion using a USM turbulence-chemistry model[J]. Acta Mechanica Sinica, 2003, 19: 208–212. 

50. 	
Zhou L X. Recent advances in studies on multiphase and reacting flows in China[J]. Acta Mechanica Sinica, 2002, 18: 97–113. 

51. 	
Zhou L X, Li L, Li R X, Zhang J. Simulation of 3-D gas-particle flows and coal combustion in a tangentially fired furnace using a two-fluid-trajectory model[J]. Powder Technology, 2002, 125: 226–233. 

52. 	
Zhou L X, Gu H X. Simulation of swirling gas-particle flows using a nonlinear k-ε-kp two-phase turbulence model[J]. Powder Technology, 2002, 128:47–55. 

53. 	
Zhou L X, Qiao L, Chen X L, Zhang J. A USM turbulence-chemistry model for simulating NO formation in turbulent combustion[J]. Fuel, 2002, 81:1703–1709. 

54. 	
Zhou L X, Yang M, Lian C Y, Fan L S, Lee D J. Comparison of a full second order moment model and an algebraic stress two-phase turbulence model for simulating bubble-liquid flows in a bubble column[J]. Chinese Journal of Chemical Engineering, 2002, 10: 142–148. 

55. 	
Yang M, Zhou L X, Fan L S. Large-eddy simulation of bubble-liquid jets[J]. Chinese Journal of Chemical Engineering, 2002, 10: 381–384. 

56. 	
Zhang H Q, Zhou L X, Chan C K. A double k-epsilon and multi-delta pdf model for turbulent gas-liquid reacting flows[J]. Fuel, 2002, 81: 817–827. 

57. 	
Zhou L X, Yang M, Lian C Y, Fan L S, Lee D J. On the second-order moment turbulence model for simulating a bubble column[J]. Chemical Engineering Science, 2002, 57: 3269–3281. 

58. 	
Liu Z H, Zheng C G, Zhou L X. A second-order-moment-Monte-Carlo (SOM-MC) model for simulating swirling gas-particle flows[J]. Powder Technology, 2001, 120: 218–224. 

59. 	
Zhou L X, Xu Y. Simulation of swirling gas-particle flows using an improved second-order moment two-phase turbulence model[J]. Powder Technology, 2001, 116: 178–189. 

60. 	
Zhang J, Zhou L X. Particle behavior in a coal-fired sudden-expansion combustor with coaxial jets[J]. Fuel, 2001, 80(2): 289–299. 

61. 	
Zhou L X, Chen T. Simulation of strongly swirling flows using USM and k-ε-kp two-phase turbulence models[J]. Powder Technology, 2001, 114 (1–3): 1–11. 

62. 	
Zhou L X, Li Y. Simulation of strongly swirling gas-particle flows using a DSM-PDF two-phase turbulence model[J]. Powder Technology, 2000, 113(2): 70–79. 

63. 	
Zhou L X, Li Y, Chen T, Xu Y. Studies on the effect of swirl numbers on strongly swirling turbulent gas-particle flows using a phase Doppler particle anemometer[J]. Powder Technology, 2000, 112 (1–2): 79–86. 

64. 	
Zhou L X, Guo Y C, Lin W Y. Two-fluid models for simulating reacting gas-particle flows, coal combustion and NOx formation[J]. Combustion Science and Technology, 2000, 150: 161–180.  

65. 	
Zhou L X, Chen X L, Zheng C G, Yin J. Second-order moment turbulence-chemistry models for simulating NOx formation in gas combustion[J]. Fuel, 2000, 79, 1289–1301. 

66. 	
Lu Y J, Zhou L X, Shen X. Numerical simulation of strongly swirling turbulent flows in a liquid-liquid hydrocyclone using the Reynolds stress transport equation model[J]. Science in China, 2000, E43, No.1: 330–337. 

67. 	
Chen X L, Zhou L X, Zhang J. Numerical simulation of methane-air turbulent jet flame using a new second-order moment model[J]. Acta Mechanica Sinica, 2000, 16(1): 41–47. 

68. 	
Zheng C G, Zhou L X, Yin J. Simulation of NO formation in turbulent combustion using an improved second-order moment model[J]. Developments in Chemical Engineering and Mineral Processing, 2001, 9 (3–4): 329–342(EI). 

69. 	
Lei Y, Zhang J, Zhou L X. Simulation of swirling turbulent flows of coaxial jets in a combustor[J]. Numerical Heat Transfer, 2000, 37(2): 189–199. 

70.	
 Luo G, Li R X, Zhou L X. Numerical simulation of gas-particle flows with different swirl numbers in a swirl burner[J]. Tsinghua Science and Technology, 2000, 5(1): 96–99. 

71. 	
Li Zh Q, Li R X, Zhou L X. Cold gas-particle flows in a new swirl pulverized-coal burner by PDPA measurement[J]. Tsinghua Science and Technology, 2000, 5(1): 100–104. 

72. 	
Zhou L X, Li R X, Liao Ch M. Experimental studies on swirling and recirculating two-phase flow field in a cold model of dual-inlet sudden-expansion combustors[J]. Chinese Journal of Aeronautics, 2000, 13(4):193–197. 

73. 	
Zhou L X. two-fluid models for simulating turbulent gas-particle flows and combustion[J], Multiphase Science and Technology, 1999, 11(1): 37–57. 

74. 	
Wang X L, Ma Zh H, Wang D X, Zhou L X. Experimental studies on coal combustion in an improved spouting-cyclone combustor[J]. Tsinghua Science and Technology, 1998, 3(2). 

75. 	
Zhang J, Lu H P, Zhou L X, Nieh S. Simulation of annular swirling turbulent flows with a new algebraic Reynolds stress model[J]. Numerical Heat Transfer, 1997, 31: 235–249 Part B. 

76. 	
Liao C M, Lin W Y, Zhou L X. Simulation of particle-fluid turbulence interaction in sudden-expansion flows[J]. Powder Technology, 1997, 90(1): 29–38. 

77. 	
Zhou L X, Li Y. A new statistical theory and a k-ε-PDF model for simulating turbulent gas-particle flows[J]. Tsinghua Science and Technology, 1997, 2(2): 628–632. 

78. 	
Wang D X, Wang X L, Zhou L X. Experimental studies on gas-particle flows and coal combustion in a new-generation spouting-cyclone combustor[J]. J. Thermal Science, 1996, 5 (2): 132–137. 

79. 	
Li Y, ZhouL X.A k-ε-PDF two-phase turbulence model for simulating sudden-expansion particle-laden flows[J]. ASME FED, 1996, 236(1): 311–316. 

80. 	
Zhou B, Wang X L, Li R X, Zhou L X. Fast ignition and stable combustion of coarse coal particles in a non-slagging cyclone combustor[J]. J. Thermal Science, 1995, 4(2): 136–140. 

81. 	
Zhou L X, Lin W Y, Zhang J, Luo W W, Huang X Q. Gas-particle Flows and Coal Combustion in a burner/combustor with high-velocity jets[J]. Combustion and Flame, 1994, 

99: 669–678. 

82. 	
Zhou L X, Zhou B, Wang X L, Li R X. Experimental studies on swirling gas-particle flows in a spouting-cyclone combustor[J]. J. Thermal Science, 1992, 1(3): 203–207. 

83. 	
Zhang J, Nieh S, Zhou L X. A new version of ASM for simulating strongly swirling flows[J]. Numerical Heat Transfer, 1992, Part B, 22: 49–62.