田瑞峰

田瑞峰，男，1975年生，教授，博士生导师。作为项目负责人先后承担核动力院、原子能科学研究院等多家单位涉及国家各类专项背景的企业委托课题10多项。主持国家自然基金重点项目1项，完成国家自然科学基金2项，国家重大专项和重点实验室基金等纵向课题20项，完成核动力研究设计院、原子能科学研究院、上海核工院、中船集团有关院所等单位企业委托课题多项。获得省部级科技进步奖三等奖5项，发表学术论文50余篇，主编十二五规划教材1部，获得发明和实用新型专利授权10多项。现为某些领域专家组成员，中国能源研究会核能专业专家委员会成员，黑龙江省核动力装置实验室副主任委员，哈尔滨工程大学学报编辑，曾任黑龙江省核学会秘书长。

1993年9月至1997年7月在哈尔滨工程大学热能工程专业就读并取得学士学位；
1999年9月至2002年7月在哈尔滨工程大学热能科学与工程专业就读并取得工学硕士学位；
2002年9月至2005年10月在哈尔滨工程大学热能科学与工程专业就读并取得工学博士学位。

1997年7月至2002年9月    哈尔滨工程大学动力工程系担任助教
2002年9月至2005年9月    哈尔滨工程大学动力与核能工程学院担任讲师
2005年9月至2012年9月    哈尔滨工程大学核科学与技术学院任副教授；
2008年10月至2009年1月  日本九州大学工学院应用量子物理与核能工程系进行访问学术研究
2011年8月至2012年8月   美国德州农工大学（Texas A&M University）核工程系博士后研究
2012年9月至今                哈尔滨工程大学核科学与技术学院任教授

　　核动力装置性能与设备、核反应堆热工水力。

2023-2026，窄流道内液态铅铋合金热工水力行为与颗粒迁移沉积研究，国家自然基金重点项目，主持
2022-2025，反应堆堆内除滴器组件综合性能实验研究，中国核动力研究设计院，主持
2022-2023，铅铋两项力学原理验证试验技术服务，中国广核集团研究院，主持
2020-2021，铅铋合金流致振动特性研究 中国核动力研究设计院，主持
2019-2020，气冷堆堆芯流动传热三维数值模拟研究，中国核动力研究设计院，主持
2019-2020，直流蒸汽发生器精细化数值模拟研究，中国核动力研究设计院，主持
2018，低温供热堆惯性水箱性能试验研究，中国原子能科学研究院，主持
2017-2020，气流横掠作用下竖直异形壁面液膜流动及破裂特性研究，国家自然科学基金委面上项目，主持
2015-2017，干燥器结构参数敏感性试验，上海核工院/重大专项，主持
2014-2016， 回旋式汽水分离技术研究，核动力运行研究所，主持
2012-2016，高效汽水分离技术，能源局/重大专项，主持
2009-2011， 电容法测量流动蒸汽湿度的研究，国家自然科学基金委青年基金，主持

Proceedings of the 28th International Conference on Nuclear Engineering, ICONE 28, 2021, online, 2021.8
Proceedings of the 27th International Conference on Nuclear Engineering, ICONE 27, Tsukuba, Japan, 2019. 5
核反应堆系统设计技术重点实验室2018年学术年会暨第4届核安全和严重事故国际研讨会, 中国 成都，2018.11 

招收硕士及博士研究生，邮箱：tianruifeng@hrbeu.edu.cn

《核动力汽轮机》，《核动力装置泵与阀门》

《数值传热学》

指导本科生《汽轮机课程设计》实践课

[1]谭思超,卢瑞博,刘庆祝,赵富龙,周娅,刘宇光,田瑞峰.一种板状燃料元件出口大空间射流可视化实验装置:黑龙江省,CN113393948B[P].2022-12-13
[2]李小畅,田瑞峰,刘丛林,姜超,王博.一种反应堆堆芯精细化数值求解的虚拟体积力动量源法:黑龙江省,CN110705184B[P].2022-07-15
[3]谭思超,宁可为,王宪礴,赵富龙,何宇豪,刘庆祝,薛满,田瑞峰.一种核动力螺旋桨式航空发动机:黑龙江省,CN113202576B[P].2022-07-12
[4]田瑞峰,毛峰,陈博文,何为.一种用于研究波形板分离器内部机理及选型的可视化实验系统:黑龙江省,CN107884168B[P].2019-12-10
[5]田瑞峰,毛峰,陈怡炫,孙兰昕.一种波形板干燥器可视化实验系统:黑龙江省,CN106442442B[P].2019-06-14
[6]高璞珍,陈涵瀛,王建军,陈先兵,王忠乙,田瑞峰,谭思超.一种基于模拟核反应堆中子反应性反馈过程的热工水力实验装置的模拟核反应堆中子反应性反馈过程的控制方法:黑龙江省,CN105869685B[P].2017-10-03
[7]周豹,高璞珍,田竞达,田瑞峰,谭思超.一种利用局部瞬时空泡份额获得整体瞬时空泡份额的方法:黑龙江省,CN102928026B[P].2015-04-08
[8]高璞珍,田竞达,周豹,谭思超,田瑞峰.用于研究矩形通道内两相脉动流流动特性的实验与测量装置:黑龙江省,CN102928319B[P].2014-11-05
[9]张志俭,田瑞峰,于瑞侠,李兆俊.一种波形板分离元件:黑龙江省,CN101732930B[P].2012-02-01
[10]田瑞峰,张鹏飞,高璞珍,谭思超,李兆俊.一种蒸汽湿度调节装置:黑龙江省,CN101825906B[P].2011-09-14

田瑞峰，刘平安，《传热与流体流动的数值计算》，哈尔滨工程大学出版社，工信部“十二五”规划教材，2015

[1] Chen B, Li J, Mao F, et al. Numerical study on the characteristics of single wetted flat wire with single droplet impact under the disturbance of airflow[J]. Nuclear Engineering and Design, 2019, 345: 74-84.
[2] Chen B, Tian R, Mao F. Analysis of special phenomena of droplet impact on horizontal liquid film at low velocity[J]. Annals of Nuclear Energy, 2020, 136.
[3] Chen B, Wang B, Mao F, et al. Review on separation mechanism of corrugated plate separator[J]. Annals of Nuclear Energy, 2020, 144.
[4] Chen B, Wang B, Mao F, et al. Analysis of liquid droplet impacting on liquid film by CLSVOF[J]. Annals of Nuclear Energy, 2020, 143.
[5] Chen B, Wang B, Mao F, et al. Experimental study of droplet impacting on inclined wetted wall in corrugated plate separator[J]. Annals of Nuclear Energy, 2020, 137.
[6] Du L, Ruifeng T, Xiaoyi L, et al. Numerical simulation and experimental investigation of structural optimization of capacitance sensors for measuring steam wetness with different coaxial cylinders[J]. Nuclear Engineering and Design, 2013, 262: 88-97.
[7] Du L, Tian R, Zhang P, et al. Numerical simulation and experiment investigating the performance of a capacitance sensor measuring the humidity of wet steam[J]. Measurement Science and Technology, 2011, 22(12).
[8] Ke B, Gao P, Wang B, et al. Study on the thermal hydraulic characteristics of a simulated pressurizer during the blowdown process[J]. Annals of Nuclear Energy, 2021, 153.
[9] Ke B, Gao P, Yang W, et al. Study on estimation of break diameter in the small break loss of coolant accident based on NSGA-II[J]. Annals of Nuclear Energy, 2021, 162.
[10] Liu X Y, Tian R F, Gao Y X, et al. A numerical study of wet steam condensation over a corrugated plate separator. 2014: 805-809.
[11] Liu Y, Shi H L, Gui C, et al. Effect of saturated steam carried downward on the flow properties in the downcomer of steam generator[J]. Energies, 2019, 12(19).
[12] Mao F, Lu M, Xie Y, et al. Effects of mixture parameters variation on the performance of corrugated plate dryer[J]. Progress in Nuclear Energy, 2020, 126.
[13] Mao F, Tian R, Chen Y, et al. Re-entrainment in and optimization of a vane mist eliminator[J]. Annals of Nuclear Energy, 2018, 120: 656-665.
[14] Ming Y, Liu K, Zhao F, et al. Dynamic modeling and validation of the 5 MW small modular supercritical CO2 Brayton-Cycle reactor system[J]. Energy Conversion and Management, 2022, 253.
[15] Ru L, Bowen C, Weibing W, et al. Experimental analysis of droplet impacting on inclined wall of the corrugated plate dryer in steam generator of nuclear power plants[J]. Annals of Nuclear Energy, 2022, 172: 109062.
[16] Ru L, Chunyuan Z, Bo W, et al. Experimental study on the influence of drainage tank structure on separation performance of vertical corrugated plate dryer in PWR[J]. Annals of Nuclear Energy, 2022, 177: 109292.
[17] Ru L, Feng M, Bowen C, et al. Influence of the structure of drainage tank on the separation performance of corrugated plate dryer in NPPs: A short communication[J]. Annals of Nuclear Energy, 2022, 169: 108930.
[18] Tian R, Mao X, Gao P, et al. Single-phase computational fluid dynamics applicability for the study of three-dimensional flow in 55 rod bundles with spacer grids[J]. Chinese Journal of Mechanical Engineering (English Edition), 2012, 25(4): 738-744.
[19] Wang B, Chen B, Ke B, et al. Effect of physical property parameters on critical airflow velocity of a corrugated plate dryer[J]. Annals of Nuclear Energy, 2020, 140.
[20] Wang B, Chen B, Ke B, et al. Study on strip-shaped liquid film in the corrugated plate dryer[J]. Annals of Nuclear Energy, 2020, 139.
[21] Wang B, Chen B, Li R, et al. Study on fracture morphology of water film on the wall of vertical corrugated plate under shear of the air flow[J]. Annals of Nuclear Energy, 2020, 136.
[22] Wang B, Chen B, Li R, et al. Analysis of fluctuation and breakdown characteristics of liquid film on corrugated plate wall[J]. Annals of Nuclear Energy, 2020, 135.
[23] Wang B, Chen B, Tian R. Review of research progress on flow and rupture characteristics of liquid film on corrugated plate wall[J]. Annals of Nuclear Energy, 2019, 132: 741-751.
[24] Wang B, Chen B, Wang G, et al. Analysis of influencing factors of rupture phenomenon of liquid film on the wall of corrugated plate dryer[J]. Annals of Nuclear Energy, 2020, 147.
[25] Wang B, Chen B, Wang G, et al. Back propagation (BP) neural network prediction and chaotic characteristics analysis of free falling liquid film fluctuation on corrugated plate wall[J]. Annals of Nuclear Energy, 2020, 148.
[26] Wang B, Chen B, Wen J, et al. Review and Prospect of the Measurement Technology of the Thickness of the Liquid Film on the Wall of the Corrugated Plate Dryer[J]. Frontiers in Energy Research, 2020, 8.
[27] Wang B, Chen B, Wen J, et al. A Mini Review of Research Progress of Nuclear Physics and Thermal Hydraulic Characteristics of Lead-Bismuth Research Reactor in China[J]. Frontiers in Energy Research, 2020, 8.
[28] Wang B, Ke B, Chen B, et al. Study on the size of secondary droplets generated owing to rupture of liquid film on corrugated plate wall[J]. International Journal of Heat and Mass Transfer, 2020, 147.
[29] Wang B, Lu C, Tian R. Characteristics of liquid film rupture at wave plate corner: A short communication[J]. Annals of Nuclear Energy, 2021, 151.
[30] Wang B, Tian R. Study on fluctuation feature and breakdown characteristic of water film on the wall of corrugated plate[J]. International Journal of Heat and Mass Transfer, 2019, 143.
[31] Wang B, Tian R. Judgement of critical state of water film rupture on corrugated plate wall based on SIFT feature selection algorithm and SVM classification method[J]. Nuclear Engineering and Design, 2019, 347: 132-139.
[32] Wang B, Tian R. Investigation on flow and breakdown characteristics of water film on vertical corrugated plate wall[J]. Annals of Nuclear Energy, 2019, 127: 120-129.
[33] Wang B, Tian R. Study on characteristics of water film breakdown on the corrugated plate wall under the horizontal shear of airflow[J]. Nuclear Engineering and Design, 2019, 343: 76-84.
[34] Wang B, Wang G, Chen B, et al. Research on reflux phenomenon of liquid film on the wall of corrugated plate dryer[J]. Annals of Nuclear Energy, 2020, 141.
[35] Wang G, Wang B, Wen J, et al. Investigation on the hydraulic process of inertia tank in the case of pump trips[J]. Nuclear Engineering and Design, 2021, 379.
[36] Wang G, Wang B, Wen J, et al. Scaling analysis for inertia tank based on the cold state of deep pool-type nuclear heating reactor[J]. Annals of Nuclear Energy, 2021, 151.
[37] Wang G, Wang B, Wen J, et al. Experimental study on the hydraulic characteristics of inertia tank after the failure of pump power[J]. Annals of Nuclear Energy, 2021, 151.
[38] Wang G, Yue Z, Sun R, et al. Preliminary study on thermal–hydraulic behavior of loss-of-flow accident in deep pool-type nuclear reactor[J]. Annals of Nuclear Energy, 2022, 170.
[39] Wang W, Zhang M, Cheng K, et al. A coupled model of corrosion of the steam generator heat transfer tube[J]. Nuclear Engineering and Design, 2022, 396.
[40] Wen J, Tian R, Tan S, et al. The weeping characteristic of submerged multi-orifice plate[J]. Chinese Journal of Chemical Engineering, 2020, 28(4): 955-968.
[41] Wen J, Tian R, Tan S, et al. Numerical simulation of gas holdup in nocoalescence media of industrial-scale bubble column[J]. Progress in Nuclear Energy, 2022, 146.
[42] Wu Y, Zhan C, Li D, et al. Multi-objective optimization analysis of corrugated plate dryer[J]. Annals of Nuclear Energy, 2023, 180.
[43] Chen B, Wang B, Mao F, et al. Numerical study on characteristics of single droplet impacting on wetted surface[J]. Experimental and Computational Multiphase Flow, 2021, 3(1): 59-67.
[44] Wang B, Ke B, Chen B, et al. A technical review of research progress on thin liquid film thickness measurement[J]. Experimental and Computational Multiphase Flow, 2020, 2(4): 199-211.

2017 运动条件下核反应堆热工水力机理研究 黑龙江省自然科学类科技二等奖 4
2002 饱和汽轮机监控技术 黑龙江省科技进步三等奖励 4