郑少飞    讲师/硕士生导师, 工程热物理研究中心教师

联系方式：shaofeizheng56@gmail.com

研究方向：

• 冷凝强化换热

• 多组分多相流

• 传热传质

• 强化传热/冷却技术

• 航空发动机热端部件冷却

获得荣誉：

• 郑少飞，第十二届ICCHMT最佳学生论文奖（唯一获得者），2019；

• 郑少飞，Elsevier优秀审稿人，2017；

• 郑少飞，西北工业大学优秀硕士学位论文一等奖，2015；

• 郑少飞，研究生国家奖学金，2014

  
  

学术兼职：

•  Green Energy and Resources国际期刊（Elsevier出版）首届青年编委； 

• 第8届亚洲计算传热大会(The 8th Asian Symposium on Computational Heat Transfer and Fluid Flow, 2021) 分会场主席（Session 26, Chairman）； 

承担的科研项目：

• 航空发动机及燃气轮机基础科学中心重点项目. 项目名称：微纳尺度涡轮叶片高效冷却技术，P2022-B-Ⅱ-029-001，起止日期：2022/10-2024/10（项目负责人）

• 国家自然科学基金青年基金. 项目名称：超滑/亲水复合结构表面滴状冷凝强化换热研究，52006064，起止日期：2021/01-2023/12（项目负责人）

• 北京市自然科学基金面上项目. 项目名称：受限结构空间液滴冷凝和动力学特性及其强化冷凝换热研究，3222043, 起止日期：2022/01-2024/12（项目负责人）

• 国家重点研发计划项目课题. 项目名称：氢基燃料改质、纯化及现场氢源总成，2022YFB4003701, 起止日期：2022/12-2026/11（子课题负责人）

• 广州海洋地质调查局委托项目. 项目名称：天然气水合物储层中多相流动特性测试，CD-1655309023185, 起止日期：2022/08-2022/12（项目负责人）

• 中央高校基础科研业务费面上项目. 项目名称：超滑表面滴状冷凝强化换热研究. 2021MS050, 起止日期：2021/01-2022/12（项目负责人）

  
  

参与的科研项目：

• 国家重点研发计划项目. 项目名称：质子交换膜燃料电池与氢基内燃机混合发电系统技术，2022YFB4003700, 起止日期：2022/12-2026/11（项目联系人、项目骨干）

• 科技部国家高端外国专家项目（文教类）. 项目名称：地质封存条件下超临界二氧化碳微纳尺度润湿动力学与多相流动的基础研究, G2022124002L, 起止日期：2022/01-2023/12（项目联系人）

• 科技部国家高端外国专家项目（文教类）. 项目名称：耐久性界面冷凝换热机理研究, G202124007L, 起止日期：2021/01-2022/12（项目联系人）

• 国家自然科学基金项目重大项目课题. 项目名称：多能互补的协同转化与能势耦合机制, 52090062, 起止日期：2021/01-2025/12（项目骨干）

• 德国国家科学基金（DFG）. 项目名称：湿空气滴状冷凝强化换热的实验和数值研究，Gr.1060/18，起止日期：2016/01-2019/12（主要完成人）

• 国家自然基金. 项目名称：轻质夹芯主动冷却防护结构的热力耦合机理及优化设计研究，11202164，起止日期：2013/01-2015/12（项目骨干）

• 中国燃气涡轮研究院委托项目. 项目名称：涡轮叶片内冷结构的热固耦合优化，APTD-XXXX，中国燃气涡轮研究院，起止日期：2012-2014（主要完成人）

论文及专著：

在国内外学术期刊上发表论文30篇，国内外学术会议上发表论文6篇，其中SCI检索论文27篇，EI检索论文27篇, 第一作者/通讯作者发表SCI检索论文14篇，论文被他引400余次，Web of Science的H因子为12。

期刊论文：(*Corresponding Author)

1. Wang S L, An D, Yang Y R, Zheng S F*, Wang X D, Lee D J. Heat transfer and flow characteristics in symmetric and parallel wavy microchannel heat sinks with porous ribs. International Journal of Thermal Sciences, 2023, 185: 108080. (SCI/EI)

2. Zheng S F, Wu Z Y, Gao Y Y, Yang Y R, Sundén B, Wang X D*. Transient multiphysics coupled model for multiscale droplet condensation out of moist air. Numerical Heat Transfer, Part A: Applications, 2022, Available online. (SCI/EI)

3. Zheng S F, Liu G Q, Lian W K, Yang Y R, Gao S R, Sunden B, Wang X D*. Fluid flow and heat transfer in a rectangular ribbed channel with a hierarchical design for turbine blade internal cooling. Applied Thermal Engineering, 2022, 217: 119183. (SCI/EI)

4. Zheng S F, Wu Z Y, Gao Y Y, Yang Y R, Wang X D*, Gross Ulrich*. Asymmetric condensation characteristics during dropwise condensation in the presence of non-condensable gas: A lattice Boltzmann study. Langmuir, 2022, 38(32): 9760-9776. (SCI/EI)

5. Zheng S F, Wu Z Y, Liu G Q, Yang Y R, Sundén B, Wang X D*. The condensation characteristics of individual droplets during dropwise condensation. International Communications in Heat and Mass Transfer, 2022, 131: 105836. (SCI/EI)

6.  Wang S L, Zhu J F, An D, Zhang B X, Chen L Y, Yang Y R, Zheng S F*, Wang X D*. Heat transfer enhancement of symmetric and parallel wavy microchannel heat sinks with secondary branch design. International Journal of Thermal Sciences, 2022, 171: 107229. (SCI/EI)

7. Zheng S F, Gross U, Wang X D*. Dropwise condensation: From fundamentals of wetting, nucleation, and droplet mobility to performance improvement by advanced functional surfaces. Advances in Colloid and Interface Science, 2021, 295: 102503. (SCI/EI)

8. Zheng S F*, Eimann F, Philipp C, Fieback T, Gross U*, Experimental and modeling investigations of dropwise condensation out of convective humid air flow. International Journal of Heat and Mass Transfer, 2020, 151: 119349. (SCI/EI)

9. Zheng S F*, Eimann F, Philipp C, Fieback T, Gross U*, Dropwise condensation in the presence of non-condensable gas: interactions effect of the droplet array using the distributed point sink method. International Journal of Heat and Mass Transfer, 2019, 141: 34-47. (SCI/EI)

10. Zheng S F*, Eimann F, Philipp C, Fieback T, Gross U*, Single droplet condensation in presence of non-condensable gas by a multi-component multi-phase thermal lattice Boltzmann model. International Journal of Heat and Mass Transfer, 2019, 139: 254-268. (SCI/EI)

11. Zheng S F*, Eimann F, Fieback T, Xie G N, Gross U*, Numerical investigation of convective dropwise condensation flow by a hybrid thermal lattice Boltzmann method. Applied Thermal Engineering, 2018, 145: 590-602. (SCI/EI)

12. Zheng S F*, Eimann F, Philipp C, Fieback T, Gross U*, Modeling of heat and mass transfer for dropwise condensation of moist air and the experimental validation. International Journal of Heat and Mass Transfer, 2018, 120: 879-894. (SCI/EI)

13. Zheng S F, Song Y D, Xie G N, Sunden B*, An assessment of turbulence models for predicting conjugate heat transfer for a turbine vane with internal cooling channels. Heat Transfer Research, 2015, 46(11):1039-1064. (SCI/EI)

14. Zheng S F, Ji T W, Xie G N*, Sunden B, On the improvement of the poor heat transfer lee-side regions of square cross-section ribbed channels. Numerical Heat Transfer-Part A, 2014, 66(9): 963-989. (SCI/EI)

会议论文：

1.  Zheng S F*, Eimann F, Philipp C, Fieback T, Gross U, The interaction effects between droplets condensing from moist air using a distributed point sink method, Proceedings of the 12th International Conference on Computational Heat, Mass and Momentum Transfer, Rome, Italy, 3-6 September, 2019: E3S Web Conferences 128(01005). (SCI, EI, oral presentation)

2. Zheng S F*, Eimann F, Philipp C, Fieback T, Gross U, Single droplet growth model for dropwise condensation considering non-condensable gas, Proceedings of the 16th International Heat Transfer Conference, Beijing, China, 10-15 August, 2018: 2133-2140. (Scopus、poster)

3.  Eimann F*, Zheng S F, Philipp C, Gross U, Convective dropwise condensation from humid air, Proceedings of the 16th International Heat Transfer Conference, Beijing, China, 10-15 August, 2018: 2315-2322. (Scopus, poster)

4. Zheng S F*, Eimann F, Philipp C, Fieback T, Gross U, Numerical study of the effect of forced convective flow on dropwise condensation by thermal LBM simulation, Proceedings of the 11th International Conference on Computational Heat, Mass and Momentum Transfer, Cracow, Poland, 21-24 May, 2018: MATEC Web of Conferences 240 (01040). (SCI, EI, oral presentation)

5. Zheng S F*, Eimann F, Philipp C, Fieback T, Gross U, Numerical simulation of dropwise condensation by a hybrid thermal lattice Boltzmann method, Surface Wettability Effects on Phase Change Phenomena workshop, Brighton, UK, 17-18 May, 2018. (Poster)

6. Zheng S F*, Eimann F, Philipp C, Fieback T, Gross U, Single droplet model for dropwise condensation of moist air and the experimental validation, Thermodynamik-Kolloquium, Dresden, Germany, 27-29 September, 2017. (Poster)