个人信息Personal Information
副教授 硕士生导师
招生学科专业:
机械工程 -- 【招收硕士研究生】 -- 机电学院
航空宇航科学与技术 -- 【招收硕士研究生】 -- 机电学院
机械 -- 【招收硕士研究生】 -- 机电学院
性别:男
毕业院校:南京航空航天大学
学历:南京航空航天大学
学位:工学博士学位
所在单位:机电学院
办公地点:A6203
联系方式:19951655663
电子邮箱:
个人简介Personal Profile
戴庆文,博士,德国洪堡学者(Humboldt Research Fellow,2021),南京航空航天大学副教授,硕士生导师,入选2022年江苏省科协青年人才托举工程,九三学社社员。2017年3月南航机械设计及理论专业博士研究生毕业后直接留校工作。长期从事航空航天领域苛刻工况下高速机械密封、磁性液体润滑与密封设计、油液热驱爬移理论研究,累计发表SCI/EI收录学术论文61篇,其中第一/通讯论文33篇(25篇JCR2区以上,1篇Nature Index索引,1篇封面),授权发明专利10项,SCI他引630余次,H-index 15,直升机传动技术国家级重点实验室固定人员、全国高校黄大年式教师团队“航空航天先进制造教师团队”主要人员。担任SCI收录期刊《Industrial Lubrication and Tribology》编委、《Coatings》 客座主编。担任国家自然科学基金委通讯评审、教育部学位与研究生教育发展中心评审专家,ACS Applied Materials & Interfaces、Journal of Colloid and Interface Science、International Journal of Heat and Mass Transfer、Journal of Physical Chemistry Letters、Applied Surface Science、Langmuir、Tribology International、Journal of Tribology等期刊外审专家。
学习工作经历
2017.04 - 至今 南京航空航天大学,讲师、副教授
2021.10 - 至今 达姆斯塔特工业大学(德国),洪堡研究员
2015.09 - 2016.09 路易斯安娜州立大学(美国),访问学者
2011.09 - 2017.03 南京航空航天大学,机械设计及理论(硕博连读),获得博士学位
2007.09 - 2011.06 南京航空航天大学,机械工程及自动化,获得学士学位
研究方向
[1] 高速机械密封
[2] 表/界面流体调控
[3] 微纳功能表面设计
[4] 磁性液体润滑与密封设计
指导研究生情况
【研究生招生】
每年招生2~3名研究生,欢迎勇于探索未知领域的研究生报考!详情参见课题组网站:http://trib.nuaa.edu.cn/
【毕业研究生】
目前累计毕业5人,学生奖学金获奖率100%。其中国家奖学金3人次(纪亚娟、崇哲均、陈桑秋),南航爱乐达创新奖学金1人次(陈桑秋),苏州工业园区奖学金2人次(陈磊、严谨),详情如下:
2023届,陈桑秋(远景能源,上海)
1. 2022年教育部硕士研究生国家奖学金;
2. 2022年南京航空航天大学爱乐达创新奖学金;
3. 南京航空航天大学科研创新先进个人(2021-2022、2020-2021);
4. 2021-2022南京航空航天大学三好研究生(2021-2022、2020-2021)。
2023届,严谨(中船701所,武汉)
1. 2021苏州工业园区特别奖学金。
2022届,陈磊(海康威视,杭州)
1. 2021年度校群星创新奖提名奖;
2. 2021苏州工业园区特别奖学金。
2021届,崇哲均(东南大学攻读博士学位,南京)
1. 2020年教育部硕士研究生国家奖学金;
2. 2019-2020南京航空航天大学科研创新先进个人。
2020届,纪亚娟(航空工业上电615所,上海)
1. 2019年教育部硕士研究生国家奖学金;
2. 江苏省2019年优秀学生干部;
3. 南京航空航天大学2018年三好研究生标兵。
获奖情况
[8] 2021年,南京航空航天教学优秀二等奖
[7] 2020年,南京航空航天大学科学技术三等奖
[6] 2018年,南京航空航天大学优秀博士论文
[5] 2017年,南京航空航天大学优秀毕业生
[4] 2016年,工信创新创业奖学金之“创新奖学金”一等奖
[3] 2015年,博士研究生国家奖学金
[2] 2015年,南京航空航天大学群星创新提名奖
[1] 2014年,中国国家公派(CSC)奖学金
承担项目
[8] 国家自然科学基金青年基金项目(51805252),主持;
[7] 德国洪堡基金会项目(Alexander von Humboldt Foundation),主持;
[6] 航空科学基金项目(202044052001),主持;
[5] 清华大学摩擦学国家重点实验室开放基金(51805252),主持;
[4] 中国博士后基金面上项目(51805252),主持;
[3] 直升机传动技术国防科技重点实验室基金项目(HTL-A-20G03),主持;
[2] 留学人员科技创新项目资助,主持;
[1] 国家自然科学基金面上项目(52175172),参与;
学术论文 [Researchgate] [Google Scholar]
2023年
[28] Q.W. Dai#, CC Yue, W. Huang, X.L. Wang, Droplets impact on rotating cylinders, Chemical Engineering Science, 2023, 273, 118669(2区TOP期刊)
[27] Q.W. Dai#, J. Yan, A. Sadeghi, W. Huang, X.L. Wang, M.M. Khonsari, Creating Lifting Force in Liquids via Thermal Gradients, Journal of Colloid and Interface Science, 2023, 629, 245–253(1区TOP期刊)
2022年
[26] S.Q Chen, Q.W. Dai*#, X.L. Yang, J.J. Liu, W. Huang, X.L. Wang, Bioinspired Functional Structures for Lubricant Control at Surfaces and Interfaces: Wedged-groove with Oriented Capillary Patterns, ACS Applied Materials & Interfaces, 2022, 14(37), 42635−42644(1区TOP期刊)
[25] Q.W. Dai, S.Q. Chen, W. Huang, X.L. Wang, Steffen Hardt, On the thermocapillary migration between parallel plates, International Journal of Heat and Mass Transfer 2022, 182, 121962.(1区TOP期刊)
[24] L. Chen, G.H. Jin, Q.W. Dai#, W. Huang, X.L. Wang, Droplets Impacting and Migrating on Structured Surfaces With Imposed Thermal Gradients,Journal of Tribology,2022, 14(4), 121962.
2021年
[23] K. Zhuang, X.L. Yang, W. Huang, Q.W. Dai#, X.L. Wang#, Efficient bubble transport on bioinspired topological ultraslippery surfaces, ACS Applied Materials & Interfaces, 2021, 13(51) 61780–61788.(1区TOP期刊)
[22] Q.W. Dai, W. Huang, X.L. Wang, M. M Khonsari, Directional interfacial motion of liquids: Fundamentals, evaluations, and manipulation strategies, Tribology International,154 (2021)106749.(1区TOP期刊,长篇综述邀稿)
2020年
[21] Q.W. Dai, Z.D. Hu, W. Huang, X.L. Wang, Controlled support of a magnetic fluid at a superhydrophobic interface, Applied Physics Letters 116(22) (2020) 221601.(Nature Index索引,TOP期刊)
[20] Q.W. Dai*, Z.J. Chong, W. Huang, X.L. Wang, Migration of liquid bridges at the interface of spheres and plates with an imposed thermal gradient, Langmuir 36(22) (2020) 6268–6276.(TOP期刊)
[19] Z.J. Chong, Q.W. Dai*, W. Huang, X.L. Wang, Investigations on the thermocapillary migration of liquid lubricants at different interfaces, Tribology Letters 68(2) (2020) 59. (美国摩擦与润滑工程师协会期刊亮点报道)
[18] Q.W. Dai, S.J. Qiu, W. Huang, X.L. Wang, Non-sticky and free-forward performances of grubs against soil, Colloids and Surfaces B: Biointerfaces 191 (2020) 111006.(Selected as Cover Art,期刊封面, TOP期刊)
[17] Q.W. Dai, Q. Chang, M. Li, W. Huang, X.L. Wang, Non-sticky and non-slippery biomimetic patterned surfaces, Journal of Bionic Engineering 17(2) (2020) 326-334.
[16] Q.W. Dai*, Z. Qiu, Z.J. Chong, W. Huang, X.L. Wang, Propelling liquids on superhydrophobic surfaces with superhydrophilic diverging grooves, Surface Innovations 8(3) (2020) 158–164.
2019年
[15] Q.W. Dai*, Y.J. Ji, W. Huang, X.L. Wang, On the thermocapillary migration on radially microgrooved surfaces, Langmuir 35(28) (2019) 9169-9176.(TOP期刊)
[14] Q.W. Dai*, Y.J. Ji, Z.J. Chong, W. Huang, X.L. Wang, Manipulating thermocapillary migration via superoleophobic surfaces with wedge shaped superoleophilic grooves, Journal of Colloid and Interface Science 557 (2019) 837-844. (1区TOP期刊)
[13] Y.J. Ji, Q.W. Dai*, W. Huang, X.L. Wang, On the thermocapillary migration at the liquid and solid aspects, Journal of Tribology 141(9) (2019) 091802-091802-7.
[12] Q.W. Dai, M. Li, M.M. Khonsari, W. Huang, X.L. Wang, The thermocapillary migration on rough surfaces, Lubrication Science 31(5) (2019) 163–170.
[11] 戴庆文, 李思远, 王秀英, 黄巍, 王晓雷, 不同密封副材料的表面织构设计及其润滑和密封特性, 中国表面工程 32(3) (2019) 21-29.
2018年
[10] Q.W. Dai, W. Huang, X.L. Wang, M.M. Khonsari, Ringlike migration of a droplet propelled by an omnidirectional thermal gradient, Langmuir 34(13) (2018) 3806-3812.(TOP期刊)
[9] Q.W. Dai, W. Huang, X.L. Wang, Contact angle hysteresis effect on the thermocapillary migration of liquid droplets, Journal of Colloid and Interface Science 515 (2018) 32-38.(1区TOP期刊)
2017年
[8] Q.W. Dai, M.M. Khonsari, C. Shen, W. Huang, X.L. Wang, On the migration of a droplet on an incline, Journal of Colloid and Interface Science 494 (2017) 8-14.(1区TOP期刊)
[7] Q.W. Dai, W. Huang, X.L. Wang, Insights into the influence of additives on the thermal gradient induced migration of lubricant, Lubrication Science 29(1) (2017) 17-29.
[6] Q.W. Dai, W. Huang, X.L. Wang, Micro-grooves design to modify the thermo-capillary migration of paraffin oil, Meccanica 52(1) (2017) 171-181.
[5] Q.W. Dai, W. Huang, J.Q. Wang, X.L. Wang, The thermal capillary migration properties and controlling technique of ferrofluids, Proc IMechE Part J: J Engineering Tribology 231(11) (2017) 1441-1449.
2016年
[4] Q.W. Dai, M.M. Khonsari, C. Shen, W. Huang, X.L. Wang, Thermocapillary migration of liquid droplets induced by a unidirectional thermal gradient, Langmuir 32(30) (2016) 7485-7492.(TOP期刊)
2015年
[3] Q.W. Dai, W. Huang, X.L. Wang, A surface texture design to obstruct the liquid migration induced by omnidirectional thermal gradients, Langmuir 31(37) (2015) 10154-10160. (TOP期刊)
2014年
[2] Q.W. Dai, W. Huang, X.L. Wang, Surface roughness and orientation effects on the thermo-capillary migration of a droplet of paraffin oil, Experimental Thermal and Fluid Science 57 (2014) 200-206.
[1] 戴庆文, 黄巍, 王晓雷. 液体空间润滑剂蠕爬流失机理及应对策略研究进展, 表面技术 2914(6) (2014) 125-130.
非一作、非通讯论文
[19] M.C. Xu, Q.W. Dai, W. Huang, X.L. Wang, Using magnetic fluids to improve the behavior of ball bearings under starved lubrication, Tribology International 141 (2020) 105950.
[18] M. Xu, G. Jin, Q.W. Dai, W. Huang, X.L. Wang, Ferrofluid lubrication for ball bearings to avoid starvation, Industrial Lubrication and Tribology (2020).
[17] A. Sammaiah, Q.W. Dai, W. Huang, X.L. Wang, Synthesis of go-fe3o4-based ferrofluid and its lubrication performances, Proc IMechE Part J: J Engineering Tribology 234(7) (2020) 1160–1167.
[16] Z.D. Hu, Q.W. Dai, W. Huang, X.L. Wang, Liquid–gas support and lubrication based on a ferrofluid seal, Journal of Physics D: Applied Physics 53(2) (2020) 025002.
[15] Y. Hu, Q.W. Dai, W. Huang, X.L. Wang, Accuracy of the pattern transfer from the metal mask to the workpiece surface during multiphase jet machining, The International Journal of Advanced Manufacturing Technology 106(3-4) (2020) 1355-1364.
[14] Y. Hu, Q.W. Dai, W. Huang, X.L. Wang, Tapered mask and its effect on the fluid flow and machining efficiency of a multiphase jet, Journal of Manufacturing Processes 50 (2020) 467-474.
[13] 王秀英, 李思远, 戴庆文, 黄巍, 王晓雷, 织构化机械密封的润滑与泄漏特性协调优化研究进展, 表面技术 48(8) (2019) 1-8.
[12] 何停霞, 戴庆文, 黄巍, 王晓雷, 离子液体基氧化石墨烯胶体分散稳定性研究, 表面技术 48(8) (2019) 129-135.
[11] X. Wang, M. Khonsari, S. Li, Q.W. Dai, X.L. Wang, Experimental verification of textured mechanical seal designed using multi-objective optimization, Industrial Lubrication and Tribology 71(6) (2019) 766-771.
[10] M. Li, Q. Jiao, Q.W. Dai, L. Shi, W. Huang, X.L. Wang, Effects of bulk viscoelasticity and surface wetting on the contact and adhesive properties of a soft material, Polymer Testing 74 (2019) 266-273.
[9] M. Li, Q.W. Dai, Q. Jiao, W. Huang, X.L. Wang, Magnetically stimulating capillary effect for reversible wet adhesions, Soft Matter 15(13) (2019) 2817-2825.
[8] L. Guo, Q.W. Dai, W. Huang, X.L. Wang, Composite ni/uhmwpe coatings and their tribological performances, Applied Surface Science 481 (2019) 414-420.
[7] H. Yin, Q.W. Dai, X. Hao, W. Huang, X.L. Wang, Preparation and tribological properties of graphene oxide doped alumina composite coatings, Surface and Coatings Technology 352 (2018) 411-419.
[6] J. Xie, M. Li, Q.W. Dai, W. Huang, X.L. Wang, Key parameters of biomimetic patterned surface for wet adhesion, International Journal of Adhesion and Adhesives 82 (2018) 72-78.
[5] X.Y. Wang, L.P. Shi, Q.W. Dai, W. Huang, X.L. Wang, Multi-objective optimization on dimple shapes for gas face seals, Tribology International 123 (2018) 216-223.
[4] L. Shi, Y. Fang, Q.W. Dai, W. Huang, X.L. Wang, Surface texturing on sic by multiphase jet machining with microdiamond abrasives, Materials and Manufacturing Processes 33(13) (2018) 1415-1421.
[3] M. Li, J. Xie, Q.W. Dai, W. Huang, X.L. Wang, Effect of wetting case and softness on adhesion of bioinspired micropatterned surfaces, Journal of the Mechanical Behavior of Biomedical Materials 78 (2018) 266-272.
[2] M. Li, Q.W. Dai, W. Huang, X.L. Wang, Pillar versus dimple patterned surfaces for wettability and adhesion with varying scales, Journal of the Royal Society Interface 15(148) (2018) 20180681.
[1] T.X. He, Q.W. Dai, W. Huang, X.L. Wang, Colloidal suspension of graphene oxide in ionic liquid as lubricant, Applied Physics A 124(11) (2018) 777.
发明专利
[6] 戴庆文,胡琳,刘艾灵,胡艺文,张博,李芊芊,邱中华,一种基于温控推进的板式表面张力贮箱,ZL202010608795.X,授权发明专利
[5] 李芊芊,胡艺文,刘艾灵,胡琳,戴庆文,一种仿Laval喷嘴结构的导流板功能表面及其制作方法,ZL202010640271.9,授权发明专利
[4] 戴庆文,徐曼成, 黄巍,王晓雷,崇哲均,胡正东,一种基于极端浸润界面的磁流体可控支撑微型平台,ZL2020104462895,授权发明专利
[3] 戴庆文,邱中华,张博,纪亚娟,崇哲均,黄巍,王晓雷,自推进功能表面的制备方法及基于该表面的表面张力贮箱,ZL201911179756.6,授权发明专利
[2] 戴庆文,纪亚娟,黄巍,王晓雷,具备可控防爬能力的表面织构设计方法,ZL201810909532.5,授权发明专利
[1] 戴庆文,纪亚娟,黄巍,王晓雷,自动调控油膜厚度的智能滑动轴承及其控制方法,ZL201810909815.X,授权发明专利
学术活动
国际会议:
[6] Q.W. Dai, Z. J. Chong, W. Huang, et al., Thermocapillary migration of lubricants at different interfaces & regulation strategy, International Nanotribology Forum, Chiang Rai, Thailand, 2020.1.12–17. [Oral]
[5] Q.W. Dai, W. Huang, X.L. Wang, Effect of surface topography and properties on the migration at the Interface, 3rd International Conference on Applied Surface Science, Pisa, Italy, 2019.6.16–20. [Oral]
[4] Q.W. Dai, W. Huang, X.L. Wang, Insights into the thermocapillary migration: liquid and solid aspects, 6th Asia International Conference On Tribology, Hilton Kuching, Malaysia, 2018.9.17–20. [Oral]
[3] Q.W. Dai, W. Huang, X.L. Wang, Surface texture design to obstruct the migration of liquid lubricants, 1st TU-NUAA Joint Academic Workshop, 2018.1.15–17.[Oral]
[2] Q.W. Dai, W. Huang, X.L. Wang, The thermal capillary migration properties and controlling technique of ferrofluids, 17th Nordic Symposium on Tribology, Hämeenlinna, Finland, 2016.6.14–17. [Poster]
[1] Q.W. Dai, W. Huang, X.L. Wang, The phenomenon of thermocapillary migration effected by surface microgrooves, 2th International Brazilian Conference on Tribology, Iguazu, Brazil, 2014.11.3–5. [Oral]
本科生教学
[2] 主持建设南京航空航天大学精品课程《机械设计基础》。
[1] 承担《机械设计基础》、《机械设计基础I》、《机械设计基础课程设计》、《Innovative Design of Mechanism Kinematic Scheme》课程及《Machinery Design》实验课程的教学工作。