個人簡介
李勇����,教授,博士生導(dǎo)師����,國家級青年人才�。于浙江大學(xué)機械工程學(xué)院獲得本科與碩士學(xué)位��,英國帝國理工學(xué)院獲得博士學(xué)位����,師從金屬材料模擬與成形領(lǐng)域著名學(xué)者��,英國皇家工程院院士林建國(Jianguo Lin) 教授����。擔(dān)任中國機械工程學(xué)會塑性工程分會委員�、中國鍛壓協(xié)會薄壁結(jié)構(gòu)流體成形技術(shù)委員會執(zhí)行委員。主要研究方向為輕質(zhì)材料復(fù)雜構(gòu)件高性能成形制造技術(shù)��。近年來在先進輕質(zhì)材料-成形-應(yīng)用一體化模擬與預(yù)測以及復(fù)雜構(gòu)件高性能成形工藝研發(fā)方面取得了系列成果����,解決了多類航空航天用復(fù)雜薄壁��、空心��、異質(zhì)類構(gòu)件成形過程形性演變精確預(yù)測與控制難題,并實現(xiàn)了其在工業(yè)生產(chǎn)中的應(yīng)用,為巴西航空���、中航工業(yè)集團��、中國航發(fā)��、中國航天科技等提供關(guān)鍵技術(shù)支撐��。近五年主持國自然聯(lián)合重點/專項/面上/青年��、國家重大科技專項課題等國家級縱向課題10余項,承擔(dān)企事業(yè)委托科技攻關(guān)項目20余項��,在輕質(zhì)材料成形制造領(lǐng)域頂級期刊 Int. J. Plasticity, Int. J. Mach. Tool. Manu., Comp. Part A 等發(fā)表 1 作/通訊作者論文50余篇��,申請/授權(quán)專利10余項����。
近年來課題組重點關(guān)注輕質(zhì)新材料(金屬基復(fù)合材料、超混雜復(fù)合材料、熱塑性復(fù)合材料)的熱成形新原理、新工藝���,AI賦能熱成形技術(shù)探索,與國內(nèi)航空航天主要設(shè)計�����、制造院所�,境外相關(guān)科研院所開展了廣泛合作��,課題組誠摯歡迎有志于航空宇航制造工藝技術(shù)研發(fā)及應(yīng)用的學(xué)生及老師加入����,一起成長進步!
基本信息
辦公地點:北京市航空航天大學(xué)沙河校區(qū)科研三號樓916
電子郵件:liyong19@buaa.edu.cn
教育背景
英國帝國理工學(xué)院 機械工程 博士研究生畢業(yè) 2014.11 -- 2018.2
浙江大學(xué) 機械工程 碩士研究生畢業(yè) 2011.9 -- 2014.3
浙江大學(xué) 機械工程 大學(xué)本科畢業(yè) 2007.9 -- 2011.7
工作經(jīng)歷
北京航空航天大學(xué) 機械工程及自動化學(xué)院 教授 2020.12 -- 至今
北京航空航天大學(xué) 機械工程及自動化學(xué)院 副教授 2019.9 -- 2020.12
英國帝國理工學(xué)院 機械工程學(xué)院 研究助理/博士后 2016.11 -- 2019.9
研究方向
1、高性能材料(鋁�����、鈦合金及復(fù)合材料)多場耦合柔性熱成形機理及新工藝
2、輕質(zhì)材料復(fù)雜構(gòu)件成形-連接制造全流程多尺度智能仿真方法及技術(shù)
3、“材料-結(jié)構(gòu)-功能”一體化高溫高壓柔性成形技術(shù)
講授課程
1�、工程熱學(xué) (本科生課程��,中/英文)
2�����、航空發(fā)動機制造工藝學(xué) (本科生課程)
3���、復(fù)合材料結(jié)構(gòu)制造技術(shù) (研究生課程)
4���、工程中的數(shù)學(xué)應(yīng)用 (研究生課程)
5、科技英語 (研究生課程)
代表性科研項目
1����、國家自然科學(xué)基金委�����,聯(lián)合重點項目,2026-2029�����,主持
2、國家自然科學(xué)基金委���,專項項目,2025-2026,主持
3、國家自然科學(xué)基金委,面上項目,2025-2028��,主持
3�����、國家科技重大專項課題����,2024-2027�����,主持
4���、國家重點實驗室基金項目�,2025-2027�����,主持
5�����、中國航空工業(yè)集團����、航發(fā)集團委托攻關(guān)項目
代表性學(xué)術(shù)論文(*為通訊作者)
金屬材料成形方向代表作:
1.Dong, H., Li, X., Zhao, S., Liu, X., Wang, Y., Wu, Y., Yuan, H., Wang, Z. and Li, Y.*, 2025. Accelerated and enhanced artificial ageing of 2195 Al-Li alloy by electric current. Materials Science and Engineering: A, p.149589.
2.Zhao, T., Xiao, Y., Du, H., Wang, C., Li, J. and Li, Y.*, 2025. Bimodal nano-particle enhanced interfacial strength in diffusion bonded joint of Fe/Cu dissimilar alloys. Chinese Journal of Aeronautics, p.103933.
3.Hou, T., Wang, D., Wang, Y., Zheng, K. and Li, Y.*, 2025. Characterization and modelling of non-uniform hot deformation behavior for laser-welding joints. International Journal of Mechanical Sciences, p.110571.
4.Zhang, D., Xiao, Y., Li, C., Zhao, T., Du, H. and Li, Y.*, 2025. Achieving high-quality copper alloy to nickel-based superalloy joint by isostatic high-pressure solid-state diffusion bonding. Journal of Materials Processing Technology, 337, p.118747.
5.Li, Y.*, Chen, H., Du, L., Yang, F., Zhang, Y. and Li, D., 2024. Characterization and unified modelling of creep and viscoplasticity deformation of titanium alloy at elevated temperature. International Journal of Plasticity, 173, p.103892.
6.Li, Y., Gan, W., Huang, X., Zhang, Y., Zhou, W., Li, D. and Zeng, Y., 2023. A quantitative study of machining induced residual stress and its effect on subsequent creep age forming of aluminium alloy panels. Journal of Materials Processing Technology, 321, p.118147.
7.李勇*, 石朱生, 呂鳳工, 榮琦, 李東升 and 林建國, 2022. 基于熱激活變形理論的鋁合金彈塑性應(yīng)力松馳機理與建模. 機械工程學(xué)報, 58(6), pp.42-51.
8.Li, Y., Shi, Z., Rong, Q., Zhou, W. and Lin, J., 2019. Effect of pin arrangement on formed shape with sparse multi-point flexible tool for creep age forming. International Journal of Machine Tools and Manufacture, 140, pp.48-61.
9.Li, Y., Shi, Z., Lin, J., Yang, Y.L., Saillard, P. and Said, R., 2018. Effect of machining-induced residual stress on springback of creep age formed AA2050 plates with asymmetric creep-ageing behaviour. International Journal of Machine Tools and Manufacture, 132, pp.113-122.
10.Li, Y., Shi, Z., Lin, J., Yang, Y.L., Rong, Q., Huang, B.M., Chung, T.F., Tsao, C.S., Yang, J.R. and Balint, D.S., 2017. A unified constitutive model for asymmetric tension and compression creep-ageing behaviour of naturally aged Al-Cu-Li alloy. International Journal of Plasticity, 89, pp.130-149.
復(fù)合材料成形方向代表作:
1.Yuan, D., Li, Y.*, Ma, R., Zhou, W., Li, J. and Gao, L., 2025. Enhanced interfacial and impact properties of Ti/CF/PEEK hybrid laminates via polydopamine-modified carbon nanotubes. Composites Part A: Applied Science and Manufacturing, p.109412.
2.Jiao, Z., Wang, Y., Li, H., Du, L., Mu, Y., Zheng, J. and Li, Y.*, 2025. Wrinkling prediction and controlling for the hot stamping of plain weave CF/PEEK prepreg in the molten state. Composite Structures, p.119817.
3.Zhou, H., Li, X., Shao, C., Li, X., Li, Y.*, Li, D., Feng, J., Ding, X. and Zhu, Y., 2025. Review on the automated fiber placement process for the aero-engine composite fan blade and its feasibility in element level. Composites Part A: Applied Science and Manufacturing, p.108875.
4.Yan, D., Li, Y.*, Zhou, W., Qian, Z. and Wang, L., 2025. A one-step integrated forming and curing process for smart thin-walled fiber metal laminate structures with self-sensing functions. Journal of Materials Processing Technology, 335, p.118648.
5.Zhang, M., Zhang, S., Hu, B., Yan, D., Liu, S., Wang, Y. and Li, Y.*, 2025. Investigation of progressive damage behavior of uncured GLARE: An integrated study using in-situ acoustic emission and multi-scale simulation. Thin-Walled Structures, 213, p.113222.
6.Zhang, M., Cheng, Z.Q., Chen, Y.K., Wang, Y., Zou, Z.P., Mi, Z.L. and Li, Y.*, 2024. A novel dual-stage failure criterion based on forming limit curve for uncured GLARE. Journal of Materials Processing Technology, 332, p.118567.
7.Hu, Y., Li, Y., Yan, D., Jiao, Z., Yuan, D., Qin, C. and Li, Y.*, 2024. Strain transfer of fiber Bragg grating sensors in fiber-reinforced polymer composites with different fiber orientations and temperatures. Measurement, 225, p.114005.
8.Xiao, Y., Li, D., Qian, Z. and Li, Y.*, 2023. An experimental and numerical study of curing deformation considering tool-part interaction for two-step curing tooling composite materials. Journal of Manufacturing Processes, 94, pp.435-453.
9.Li, Y.*, Xiao, Y., Yu, L., Ji, K. and Li, D., 2022. A review on the tooling technologies for composites manufacturing of aerospace structures: materials, structures and processes. Composites Part A: Applied Science and Manufacturing, 154, p.106762.
10.肖遙, 李東升, 吉康 and 李勇*, 2022. 大型復(fù)合材料航空件固化成型模具技術(shù) 研究與應(yīng)用進展. Acta Materiae Compositae Sinica, 39(3).
學(xué)術(shù)與社會服務(wù)
1�����、中國機械工程學(xué)會塑性工程分會委員��;
2�����、中國鍛壓協(xié)會薄壁結(jié)構(gòu)流體成形技術(shù)委員會執(zhí)行委員;
3���、北航沈陽黎明航空發(fā)動機鈑金精密成形及控性聯(lián)合實驗室主任����;
4�����、《Chinese Journal of Aeronautics》��、《航空學(xué)報》、《塑性工程學(xué)報》青年編委���。
Yong Li, Ph.D.
Beihang University
School of Mechanical Engineering and Automation
liyong19@buaa.edu.cn
Flexible Thermoforming Mechanisms and Novel Processes for High-performance Materials
Multi-scale Intelligent Simulation Methods and Technologies for Forming
Integrated "Material-Structure-Function" Flexible Forming Technology
Imperial College London, London, UK
Ph.D., Mechanical Engineering, 02/2018
Zhejiang University, Hangzhou, Zhejiang, China
M.S., Mechanical Engineering, 06/2014
B.S., Mechanical Engineering, 06/2011
Research and Professional Experience |
Professor in the School of Mechanical Engineering and Automation
Beihang University, Beijing, China 2020 - present
Associate Professor in the School of Mechanical Engineering and Automation
Beihang University, Beijing, China 2019 - 2020
Research Associate in Department of Mechanical Engineering
Imperial College London, London, UK 2018 – 2019
Research Assistant in Department of Mechanical Engineering
Imperial College London, London, UK 2016 – 2018
