姓名:邬栋权
职称:副教授
所在学院(系别):中欧航空工程师学院
行政职务:无
导师类型:机械(航空工程)—硕导(专硕)
航空宇航科学与技术—硕导(学硕)
电子信箱:dqwu@cauc.edu.cn
受教育经历:
2014年09月-2019年07月,天津大学,材料加工工程专业,博士(直博),导师:荆洪阳
2010年09月-2014年07月,天津大学,材料成型及控制工程专业,学士
工作与研究经历:
2022年1月-至今,中欧航空工程师学院,副教授;
2020年11月-2021年12月,中欧航空工程师学院,讲师;
2019年9月-2020年9月,新加坡国立大学,博士后研究员;
研究方向:
[1] 结构完整性评估,蠕变、疲劳,寿命评估
[2] 超材料结构设计,3d打印,增材制造
[3] 机器学习,结构设计优化,数据驱动寿命预测
科研项目:
[1] 国家自然科学基金青年项目:增材制造新型板格超材料高温疲劳失效机理及寿命预测研究,2025.01-2027.12,30万元,在研,课题负责人。
[2] 天津市自然科学基金多元投入青年项目:增材制造新型板格超材料蠕变-疲劳失效机理及寿命预测研究,2024.10-2026.09,6万元,在研,课题负责人。
[3] 中央高校基本科研经费项目:基于蠕变孔洞长大理论的蠕变损伤本构模型及蠕变寿命预测研究,2024.01-2026.01,8万元,在研,课题负责人。
[4] 天津市教委科研计划项目:考虑拘束效应的含裂纹高温结构的蠕变-疲劳损伤及寿命评估研究,2021.07-2023.06,8万元,结题,课题负责人。
[5] 中央高校基本科研经费项目:考虑残余应力影响的含裂纹高温结构蠕变-疲劳交互损伤及寿命评估研究,2022.01-2023.12,8万元,结题,课题负责人。
[6] 天津大学优博基金项目:考虑残余应力和拘束效应影响的含裂纹高温结构蠕变裂纹孕育期预测研究,2018.01-2019.05,6万元,结题,课题负责人。
[7] 国家自然科学基金面上项目:含体积缺陷的高温焊接管道寿命评估理论与方法研究,2015.01-2018.12,84万元,结题,第二参与人。
[8] 国家自然科学基金面上项目:双相不锈钢焊接组织多场耦合热动力学调控机理与点蚀寿命预测方法,2026.01-2029.12,50万元,在研,第二参与人。
所获奖励:
[1] 2020年中国民航大学蓝天青年学者
[2] 2023年优秀本科毕业设计指导教师
[3] 2025年中国民航大学优秀教师
学术兼职:
中国机械工程学会会员、《Small》、《INTERNATIONAL JOURNAL OF MECHANICAL SCIENCES》、《European Journal of Mechanics -A/Solids》、《THEORETICAL AND APPLIED FRACTURE MECHANICS》等期刊审稿人
代表性论文:
[1] Wu Dongquan, et al. Machine learning-driven customizable mechanical design of diamond plate lattice metamaterials. INTERNATIONAL JOURNAL OF MECHANICAL SCIENCES 310, 111140. (SCI一区Top)
[2] Wu Dongquan, et al. Machine learning accelerates programmable mechanics in isotropic diamond plate lattices. INTERNATIONAL JOURNAL OF MECHANICAL SCIENCES 302, 110595. (SCI一区Top)
[3] Wu Dongquan, et al. Hierarchical diamond plate-lattice metamaterial: machine-learning co-optimisation of sound absorption and mechanics. VIRTUAL AND PHYSICAL PROTOTYPING 21(1), e2605733. (SCI一区Top)
[4] Wu Dongquan*, et al. Investigation of the Creep Crack Initiation times and the Constraint Effects for Pressurized Pipes with Long Surface Cracks. Thin Walled Structure 2020, 153. (SCI一区Top)
[5] Wu Dongquan, et al. Theoretical and numerical analysis of the creep crack initiation time considering the constraint effects for pressurized pipelines with axial surface cracks. INTERNATIONAL JOURNAL OF MECHANICAL SCIENCES 141, 262-275. (SCI一区Top)
[6] Wu Dongquan, et al. Research on the design and mechanical performance of additively manufactured diamond plate lattice metamaterials. Polymer Composites, DOI: 10.1002/pc.29819. (SCI二区)
[7] Wu Dongquan, et al. Experimental and numerical analysis of in-plane compression properties for hierarchical reentrant honeycomb structures. Mechanics of Advanced Materials and Structures, DOI:10.1080/15376494.2024.2442501. (SCI二区)
[8] Li Dinghe, Li Yupeng, Wu Dongquan*, et al. Investigation on compression properties of perforated face-centered-cubic plate-lattice structures. Mechanics of Advanced Materials and Structures, DOI:10.1080/15376494.2024.2447055. (SCI二区)
[9] Wu Dongquan, et al. Numerical analysis of the creep crack constraint effects and the creep crack initiation for pressurized pipelines with circumferential surface cracks. ADVANCES IN ENGINEERING SOFTWARE 2018, 115, 40-51. (SCI二区)
[10] Wu Dongquan, et al. Analytical approaches of creep crack initiation prediction coupled with the residual stress and constraint effect. European Journal of Mechanics - A/Solids 2018, 71, 1-15. (SCI二区)
[11] Wu Dongquan, et al. Enhanced models of creep crack initiation prediction coupled the stress-regime creep properties and constraint effect. European Journal of Mechanics -A/Solids 2019, 74, 145-159. (SCI二区)
[12] Wu Dongquan *, et al. Engineering application of enhanced C*-Q* two parameter approaches for predicting creep crack initiation times. European Journal of Mechanics -A/Solids 2020, 82. (SCI二区)
[13] Wu Dongquan, et al. Investigation on creep crack initiation prediction considering constraint effect using constraint parameter Q. THEORETICAL AND APPLIED FRACTURE MECHANICS 2018, 96, 631-641. (SCI二区)
[14] Wu Dongquan, et al. Theoretical and numerical analysis of creep crack initiation combined with primary and secondary stresses. THEORETICAL AND APPLIED FRACTURE MECHANICS 95, 143-154. (SCI二区)
[15] Wu Dongquan, et al. Two-parameter approach of creep crack initiation times considering the constraint effect induced by specimen geometry. THEORETICAL AND APPLIED FRACTURE MECHANICS 2018, 96, 31-44. (SCI二区)
[16] Wu Dongquan, et al. Creep crack initiation prediction considering constraint effect for pressurized pipelines with circumferential surface cracks. Fatigue & Fracture of Engineering Materials and Structures 2018, 41(9), 1900-1917. (SCI二区)
[17] Wu Dongquan, et al. Prediction models of creep crack initiation for different specimen geometry. Mechanics of Advanced Materials and Structures. 2020, 27(19): 1639-1652. (SCI二区)
[18] Wu Dongquan, et al. Numerical and theoretical studies about in-plane impact properties of Semi-Reentrant structures. Meccanica. 2022, 57, 313-336. (SCI三区)
[19] Wu Dongquan, et al. Equivalent theories and tension properties of semi-reentrant structures. Meccanica. 2021, 56, 2053-2082. (SCI三区)
[20] Wu Dongquan, et al. Numerical study about tension properties of novel hierarchical reentrant honeycomb structure. JOURNAL OF THEORETICAL AND APPLIED MECHANICS 65(1), 1-12. (SCI四区)
[21] Wu Dongquan, et al. Investigation of out-of-plane compression mechanical property for novel hierarchical reentrant honeycomb structures. JOURNAL OF THEORETICAL AND APPLIED MECHANICS 63(1), 3-15. (SCI四区)
[22] Wu Dongquan, et al. Study on the stress intensity factor of a compact specimen under the pre-compressed load condition. Journal of Theoretical and Applied Mechanics 2023;61(1):37–47. (SCI四区)
[23] Wu Dongquan, et al. Numerical study on compression properties of semi-reentrant filled tubular structures. Journal of Theoretical and Applied Mechanics 2023;61(2):233–244.(IF: 2.538). (SCI四区)
代表性专利:
[1]邬栋权,许桢一,等,一种基于海胆仿生启发的钻石晶胞板格超材料及其增材制造方法。专利号:202511854449.9
[2]邬栋权,许桢一,等,一种钻石基板格超材料及其增材制造方法。专利号:202510999395.9
[3]邬栋权,袁卓,等,一种新型三维雪花板状负泊松比结构。专利号:202510344803.7
[4] 徐连勇,邬栋权,荆洪阳,等,弹性瞬态蠕变条件下含残余应力的蠕变孕育期预测方法。专利号:201710271743.6
[5] 徐连勇,邬栋权,荆洪阳,等,塑性瞬态蠕变条件下考虑拘束效应的蠕变孕育期预测方法。专利号: 201710270920.9.
[6] 徐连勇,邬栋权,荆洪阳,等,高温管道中含椭圆形轴向外表面裂纹的孕育期预测方法。专利号:201710567104.4.
