2021.03——今 南京理工大学 副教授
2019.09——2021.03 新加坡国立大学 机械工程专业 博士后
2016.09——2019.05 美国福特汽车研究院 公派访问学者
担任Polymers期刊(中科院二区)Additive Manufacturing of Fiber/Polymer Composites专刊的客座编辑;
担任Materials期刊(中科院三区)Advances in 3D Printed Reinforced Materials/Electronics: Processes, Properties and Applications专刊的客座编辑;
担任Composites Part B: Engineering、International Journal of Fatigue、International Journal of Mechanical Sciences、Thin-Walled Structures、Advances in Manufacturing、Composites Part C: Open Access、SAE International Journal of Materials and Manufacturing等国际期刊及会议审稿人;
中国力学学会会员、中国机械工程学会会员。
[24]. S. Zhang, H. Tang*, et al. Effect of fabrication process on the microstructure and mechanical performance of carbon fiber reinforced PEEK composites via selective laser sintering. Composites Science and Technology. 2024, 246: 110396.
[23]. D. Tang, S. Xu, K. Yang, T. Gao, H. Tang*. Effects of porosity on effective thermal conductivities of thermal insulation SiC sandwich panels with Schoen-gyroid structure. Ceramics International. 2024; 50 (7), 10618-10625.
[22]. W. Sheng, K. Liang, H. Tang*. Exoskeleton active assistance strategy for human muscle activation reduction during linear and circular walking. Advances in Manufacturing. 2024.
[21]. D. Tang, K. Yang, T. Gao, T. Liu, H. Tang*. Mechanical-electromagnetic integration design of Al2O3/SiO2 ceramic cellular materials fabricated by digital light processing. Thin-Walled Structures. 2023; 183: 110437.
[20]. D. Tang, H. Tang*. Self-healing diamond/geopolymer composites fabricated by extrusion-based additive manufacturing. Additive Manufacturing. 2022. 56: 102898.
[19]. L He, S Wu, A Dong, H. Tang, et al. Selective laser melting of dense and crack-free AlCoCrFeNi2. 1 eutectic high entropy alloy: Synergizing strength and ductility. Journal of Materials Science & Technology 2022; 117: 133-145.
[18]. X Sun, Y Li, C Engler-Pinto, L Huang, S Huang, Z Li, H. Tang, et al. Characterization and modeling of fatigue behavior of chopped glass fiber reinforced sheet molding compound (SMC) composite. International Journal of Fatigue. 2022; 156: 106647.
[17]. H. Tang, et al. Longitudinal compression failure of 3D printed continuous carbon fiber reinforced composites: an experimental and computational study. Composites Part A: Applied Science and Manufacturing. 2021; 146: 106416.
[16]. H. Tang, et al. Experimental and computational analysis of structure-property relationship in carbon fiber reinforced polymer composites fabricated by selective laser sintering. Composites Part B: Engineering. 2021; 204: 108499.
[15]. H. Tang, et al. Multi-scale modelling of structure-property relationship in additively manufactured metallic materials. International Journal of Mechanical Sciences. 2021; 194: 106185.
[14]. H. Tang, et al. Experimental and computational analysis of bending fatigue failure in chopped carbon fiber chip reinforced composites. Composite Structures. 2021; 275: 114402.
[13]. Q. Sun, G. Zhou, H. Tang*, et al. A combined experimental and computational analysis of failure mechanisms in open-hole cross-ply laminates under flexural loading. Composites Part B: Engineering. 2021; 215: 108803.
[12]. Q. Sun, G. Zhou, H. Tang*, et al. In-situ effect in cross-ply laminates under various loading conditions analyzed with hybrid macro/micro-scale computational models. Composite Structures. 2021; 261: 113592.
[11]. G. Zhou, H. Tang, et al. Analysis of the crushing behaviors of woven carbon fiber reinforced plastic component under dynamic bending and axial crushing loading. Thin-Walled Structures. 2021; 161:107426.
[10]. H. Chen, W. Zhu, H. Tang, et al. Oriented structure of short fiber reinforced polymer composites processed by selective laser sintering: the role of powder-spreading process. International Journal of Machine Tools and Manufacture. 2021; 163: 103703.
[9]. H. Huang, L. Qin, H. Tang, et al. Ultrasound cavitation induced nucleation in metal solidification: an analytical model and validation. Ultrasonics Sonochemistry. 2021; 80: 105832.
[8]. H. Tang, et al. Computational micromechanics model based failure criteria for chopped carbon fiber sheet molding compound composites. Composites Science and Technology. 2020; 200: 108400.
[7]. H. Tang, et al. Notch insensitivity in fatigue failure of chopped carbon fiber chip-reinforced composites using experimental and computational analysis. Composite Structures. 2020; 244: 112280.
[6]. H. Tang, et al. Effect of fiber orientation distribution on constant fatigue life diagram of chopped carbon fiber chip-reinforced sheet molding compound (SMC) composite. International Journal of Fatigue. 2019; 125: 394-405.
[5]. Z. Chen, H. Tang, et al. Failure of chopped carbon fiber sheet molding compound (SMC) composites under uniaxial tensile loading: computational prediction and experimental analysis. Composites Part A: Applied Science and Manufacturing. 2019; 118: 117-130.
[4]. H. Tang, et al. Fatigue behavior analysis and multi-scale modelling of chopped carbon fiber chip-reinforced composites under tension-tension loading condition. Composite Structures. 2019; 215: 85-97.
[3]. H. Tang, et al. Correlation between failure and local material property in chopped carbon fiber chip-reinforced sheet molding compound composites under tensile load. Polymer Composites. 2019; 40: E962-E974.
[2]. H. Tang, et al. Low cycle fatigue modeling for nickel-based single crystal superalloy. Materials at High Temperatures. 2018; 35(6): 535-545.
[1]. H. Tang, et al. Effect of grain defects on the mechanical behavior of nickel-based single crystal superalloy. International Journal of Materials Research. 2017; 108: 163-172.
* 本人为通讯作者