研究课题项目
在研课题项目:
Project 1: The Low Velocity Impact Response of Foam-based Sandwich Panels.
Project 2: The Energy-Absorbing Behaviour of Sandwiches Reinforced with Composite Rods and tubes
Project 3: The Mechanical Response of Corrugated Composite Cores Structures
Project 4: The Perforation Resistance of Carbon Fiber Laminates
Project 5: The Impact Resistance of Fiber Metal Laminate
Project 6: Feasibility Study Application – Composite forming limit diagram
Project 7: 3D Printed Composite Structures
已完成课题项目
1. 课题:复合材料夹心结构抗冲击性能及其能量吸收特性(2010-2020)
Project 1: The Low Velocity Impact Response of Foam-based Sandwich Panels.
[1] Zhou J., Hassan M.Z, Guan ZW and Cantwell W.J. The Low Velocity Impact Response of Foam-based Sandwich Panels. Composites Science and Technology. 2012; 72(14):1781-1790.
[2] Zhou J., Guan Z.W., and Cantwell W.J., The Perforation Resistance of Sandwich Structures Subjected to Low Velocity Projectile Impact Loading. Aeronautical Journal. 2012; 116:1247-1262.
[3] Zhou J, Guan Z.W., and Cantwell W.J., The Impact Response of Graded Foam Sandwich Structures. Composite Structures. 2013; 97:370-377.
[4] Zhou J.*, Guan Z.W., and Cantwell W.J., Scaling Effects in the Mechanical Response of Sandwich Structures Based on Corrugated Composite Cores. Composites Part B. 2016; 93: 88-96.
[5] Haldar A. K., Zhou J. and Guan Z.W. Energy absorbing characteristics of the composite contoured-core sandwich panels. Materials Today Communications. 2016; 8: 156-164.
2. 项目课题:金属层合板抗冲击性能及动态响应性能研究 (帝国理工 2012-2019)
Project 2: The High Velocity Impact on Carbon Fiber Laminates (Imperial College)
[6] Zhou J., Guan Z.W., and Cantwell W.J., The Influence of Strain-rate on The Perforation Resistance of Fiber Metal Laminates. Composite Structures. 2015; 125:247–255.
[7] Kaboglu C., Mohagheghian I., Zhou J, Guan ZW, Cantwell WJ, John Sabu, Blackman Bamber, Kinloch Anthony, Dear John. High-velocity impact deformation and perforation of fibre-metal laminates. Journal of Materials Science 2018;53(6), 4209-4228.
[8] Liu, H., Liu, J., Ding, Y., Zhou, J., Kong, X., Harper, L. T., Bamber R. K. Blackman, Brian G. Falzon, Dear, J. P. (2020). Modelling damage in fibre-reinforced thermoplastic composite laminates subjected to three-point bend loading. Composite Structures, 236, 111889. doi:10.1016/j.compstruct.2020.111889
[9] Liu H., Zhou J. and Dear J., Effects of a coupling agent on the crush behaviour of flax fibre reinforced composite laminates: an experimental study, 1st European Conference on Crashworthiness of Composite Structures (ECCC-1), Belfast, UK, November 2019.
[10] Liu, H., Liu, J., Ding, Y., Zheng, J., Kong, X., Zhou, J., . . . Dear, J. P. (2020). The behaviour of thermoplastic and thermoset carbon fibre composites subjected to low-velocity and high-velocity impact. Journal of Materials Science, 55(33), 15741-15768. doi:10.1007/s10853-020-05133-0
[11] Liu, H., Liu, J., Ding, Y., Zhou, J., Kong, X., Blackman, B. R. K., . . . Dear, J. P. (2020). Effects of Impactor Geometry on the Low-Velocity Impact Behaviour of Fibre-Reinforced Composites: An Experimental and Theoretical Investigation. Applied Composite Materials, 27(5), 533-553. doi:10.1007/s10443-020-09812-8
[12] Liu, H., Liu, J., Kaboglu, C., Zhou, J., Kong, X., Blackman, B. R. K., . . . Dear, J. P. (2020). The behaviour of fibre-reinforced composites subjected to a soft impact-loading: An experimental and numerical study. Engineering Failure Analysis, 111, 104448. doi:10.1016/j.engfailanal.2020.104448
[13] Liu, H., Liu, J., Ding, Y., Zhou, J., Kong, X., Harper, L. T., . . . Dear, J. P. (2020). Modelling damage in fibre-reinforced thermoplastic composite laminates subjected to three-point bend loading. Composite Structures, 236, 111889. doi:10.1016/j.compstruct.2020.111889
3. 项目课题:复合材料碳纤维杆及碳纤维管抗冲击增强特性及能量吸收性能(2013-2020)
Projects 3: The Energy-Absorbing Behaviour of Sandwiches Reinforced with Composite
[14] Zhou J., Guan Z.W., Cantwell W.J. and Liao Y., The Energy-Absorbing Behaviour of Foam Cores Reinforced with Composite Rods. Composite Structures. 2014; 116: 346–356.
[15] Zhou J., Guan Z.W., and Cantwell W.J., Modelling of the Compression Behavior of Foam Cores Reinforced with Composite Rods. Polymer Composites. 2015.DOI: 10.1002/pc.23812.
[16] Al Antali A., Umer R., Zhou J.* and Cantwell W.J. The Energy-absorbing Properties of Composite Tube-Reinforced Aluminum Honeycomb. Composite Structures. 2017; 176:630-639.
[17] Zhou J. *, Guan Z.W., and Cantwell W.J. The Energy-Absorbing Behaviour of Composite Tube-reinforced Foams. Composites Part B. 2018;139, 227-237. doi:10.1016/j.compositesb.2017.11.066
[18] Alia, R. A., Rao, S., Umer, R., Zhou, J., Zheng, C., Guan, Z., & Cantwell, W. J. The crushing characteristics of reinforced Nomex honeycomb. Journal of Reinforced Plastics and Composites, 2018; 37(20), 1267-1276.
[19] Xin, Z., Duan, Y., Zhou, J. & Xiao, H. Effect of tailored plies on the energy absorption capability of square CFRP tubes with discontinuous fibers. Composite Structures; 2019; 209,150-159.
[20] Alia, R. A., Zhou, J. *, Guan, Z., Duan Y, Qin Q. & Cantwell, W. J. (2020). The effect of loading rate on the compression properties of carbon fibre-reinforced epoxy honeycomb structures. Journal of Composite Materials. 2020. 236, 111889. doi:10.1016/j.compstruct.111889
[21] Liu H., Zhou J. and Dear J.P., Effects of a coupling agent on the crush behaviour of flax fibre reinforced composite laminates: an experimental study, 1st European Conference on Crashworthiness of Composite Structures (ECCC-1), Belfast, UK, November 2019.
[22] Alia, R. A., Zhou, J., Guan, Z. W., Qin, Q., Duan, Y., & Cantwell, W. J. (2020). The effect of loading rate on the compression properties of carbon fibre-reinforced epoxy honeycomb structures. JOURNAL OF COMPOSITE MATERIALS, 54(19), 2565-2576. doi:10.1177/0021998319900364
[23] Xin, Z., Duan, Y., & Zhou, J. (2020). Energy absorption properties of CFRP composites tube with discontinuous plies. In ECCM 2018 - 18th European Conference on Composite Materials.
4. 课题:碳纤维三维编织层合板抗冲击性能研究(2015-2018)
Project 4: The Perforation Resistance of Carbon Fiber Laminates (The University of Liverpool)
[24] Umer R., Rao S., Zhou J., Guan Z. and Cantwell W.J. The Low Velocity Impact Response of Graphene Modified Composites Manufactured using Automated Dry Fiber Placement. Polymers and Polymer Composites, 2016; 24.4: 233-240.
[25] Umer R., Rao S., Zhou J., Guan Z. and Cantwell W.J. The Mechanical Properties of 3D Woven Composites. Journal of Composite Materials. 2017;5(12):1703-1716.
5. 可行性研究:复合材料成型缺陷控制可行性研究 (剑桥大学2018-2019)
Project 5: Composite forming limit diagram-University of Cambridge - EPSRC Feasibility Study Application
[26] Viisainen V., Zhou J. and Sutcliffe M. Wrinkle Formation Characterisation During the Forming of Non-Crimp Fabric. The 11th International Conference on Manufacturing Advanced Composites, Nottingham, UK 2018; 10-12th July.
[27] Viisainen Verner, Zhou Jin and Sutcliffe Michael. Development of a Composite Forming Limit Diagram: A Feasibility Study. The 22nd International Conference on Composite Materials Melbourne (ICCM22), Australia, August 2019.
6. 课题:复合材料连接与修复(利物浦大学2016-2020)
Project 6: Composite joint and repairing
[28] Sun, C., Zhao, W., Zhou, J., Altenaiji, M., Cantwell, W. J., Wang, Q. Y., & Guan, Z. W. (2021). Mechanical behaviour of composite laminates repaired with a stitched scarf patch. Composite Structures, 255, 112928. doi:10.1016/j.compstruct.2020.112928.
[29] Chen, C., Sun, C., Han, X., Hu, D., Zhou, J., & Guan, Z. (2020) The structural response of the thermoplastic composite joint subjected to out-of-plane loading. International Journal of Impact Engineering, 103691. doi:10.1016/j.ijimpeng.2020.103691
[30] Ji, F., Liu, C., Hu, Y., Xu, S., He, Y., Zhou, J., & Zhang, Y. (2020). Chemically Grafting Carbon Nanotubes onto Carbon Fibers for Enhancing Interfacial Properties of Fiber Metal Laminate. Materials, 13(17), 3813. doi:10.3390/ma13173813
