Vibration characteristics of carbon-fiber reinforced composite drive shafts fabricated using filament winding technology

被引:32
作者
Sun, Zeyu [1 ,2 ]
Xiao, Jie [3 ]
Yu, Xuduo [4 ]
Tusiime, Rogers [1 ]
Gao, Hongping [4 ]
Min, Wei [1 ]
Tao, Lei [1 ]
Qi, Liangliang [1 ]
Zhang, Hui [1 ,2 ]
Yu, Muhuo [1 ,2 ]
机构
[1] Donghua Univ, Coll Mat Sci & Engn, State Key Lab Modificat Chem Fibers & Polymer Mat, Shanghai 201620, Peoples R China
[2] Donghua Univ, Shanghai Key Lab Lightweight Struct Composites, Shanghai 201620, Peoples R China
[3] Donghua Univ, Res Ctr Anal & Measurement, Shanghai 201620, Peoples R China
[4] Shanghai Fishman New Mat Technol Co, Shanghai 201620, Peoples R China
来源
COMPOSITE STRUCTURES | 2020年 / 241卷
关键词
CFRP drive shaft; Metal flange; Filament winding; Natural frequency; Damping; FINITE-ELEMENT-METHOD; DYNAMIC-ANALYSIS; HYBRID; BEHAVIOR; PERFORMANCE; DESIGN; MANUFACTURE; STRENGTH;
D O I
10.1016/j.compstruct.2019.111725
中图分类号
O3 [力学];
学科分类号
08 ; 0801 ;
摘要
The metal connector and tube of the composite drive shaft were bonded together generally. However, the glued shafts showed numerous risks due to the instability of chemical glues. To avoid potential risks, filament winding with integrated flanges was proposed to prepare carbon fiber-reinforced composite (CFRP) drive shafts in this study. The natural frequency and damping of CFRP shafts were investigated by FEA and experiment. Results revealed that the natural frequency of CFRP shafts embedded in metal flanges is slightly lower than that of the glued CFRP shafts. The metal flanges did not affect the changing trend of the natural frequency with various fiber ply angles or thicknesses, and the damping had little effect on the natural frequency. The natural frequency of CFRP tubes and drive shafts was predicted using FEA and agreed well with the experimental results. The results of this study will be of great significance in the design and application of CFRP drive shafts.
引用
收藏
页数:12
相关论文
共 40 条
[1]   Developing a hybrid, carbon/glass fiber-reinforced, epoxy composite automotive drive shaft [J].
Abu Talib, A. R. ;
Ali, Aidy ;
Badie, Mohamed A. ;
Lah, Nur Azida Che ;
Golestaneh, A. F. .
MATERIALS & DESIGN, 2010, 31 (01) :514-521
[2]  
[Anonymous], 2009, STRESS ANAL FIBER RE
[3]   An investigation into hybrid carbon/glass fiber reinforced epoxy composite automotive drive shaft [J].
Badie, M. A. ;
Mahdi, E. ;
Hamouda, A. M. S. .
MATERIALS & DESIGN, 2011, 32 (03) :1485-1500
[4]   Two cases of failure in the power transmission system on vehicles: A universal joint yoke and a drive shaft [J].
Bayrakceken, H. ;
Tasgetiren, S. ;
Yavuz, I. .
ENGINEERING FAILURE ANALYSIS, 2007, 14 (04) :716-724
[5]   Mechanical characterization of glass/vinylester ±55° filament wound pipes by acoustic emission under axial monotonic loading [J].
Ben Khalifa, Ated ;
Zidi, Mondher ;
Abdelwahed, Laksimi .
COMPTES RENDUS MECANIQUE, 2012, 340 (06) :453-460
[6]   Vibration analysis of rotating composite shafts containing randomly oriented reinforcements [J].
Chang, CY ;
Chang, MY ;
Huang, JH .
COMPOSITE STRUCTURES, 2004, 63 (01) :21-32
[7]   Multistep Optimization of Composite Drive Shaft Subject to Strength, Buckling, Vibration and Manufacturing Constraints [J].
Cherniaev, Aleksandr ;
Komarov, Valeriy .
APPLIED COMPOSITE MATERIALS, 2015, 22 (05) :475-487
[8]   The dynamic analysis of rotors mounted on composite shafts with internal damping [J].
De Paula Mendonca, Willy Roger ;
De Medeiros, Everton Coelho ;
Rezende Pereira, Artur Luiz ;
Mathias, Mauro Hugo .
COMPOSITE STRUCTURES, 2017, 167 :50-62
[9]   Modal analysis based on finite element method and experimental validation on carbon fibre composite drive shaft considering steel joints [J].
Ding, G. ;
Xie, C. ;
Zhang, J. ;
Zhang, G. ;
Song, C. ;
Zhou, Z. .
MATERIALS RESEARCH INNOVATIONS, 2015, 19 :748-753
[10]   4D rods: 3D structures via programmable 1D composite rods [J].
Ding, Zhen ;
Weeger, Oliver ;
Qi, H. Jerry ;
Dunn, Martin L. .
MATERIALS & DESIGN, 2018, 137 :256-265
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