通过定向纤维增强提高汽车塑料齿轮的强度

Q3 Engineering

International Journal of Powertrains Pub Date : 2019-03-05 DOI:10.1504/IJPT.2019.10019429

V. Spitas

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引用次数: 0

摘要

本文介绍了一种碳纤维增强塑料齿轮的新拓扑结构。在齿角处的临界截面切向放置钢筋以提高抗弯强度。纤维增强材料的力学建模是使用各向异性材料刚度矩阵进行的，该矩阵来源于使用商业应力分析软件对具有代表性的体积单元的分析。对传统塑料齿轮的基准测试表明，最大的圆角应力，这是负责在超载条件下的齿失效大大减少，因此，使这些齿轮适合考虑其在高负载应用，如在汽车工业中使用。此外，研究了钢筋厚度对根部最大发展拉应力的影响。结果表明，根圆角处的弯曲应力显著降低，使这种设计成为加强塑料齿轮的另一种方法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Improving strength for automotive plastic gears through directional fibre reinforcement

In this paper, a new topology of reinforcing plastic gears with carbon fibres is introduced. The reinforcement is placed tangentially to the critical cross section at the tooth fillet to improve bending strength. The mechanical modelling of the fibrous reinforcement is performed using an anisotropic material stiffness matrix derived from the analysis of a representative volume element using commercial stress analysis software. Benchmarking against conventional plastic gears illustrates that the maximum fillet stress, which is responsible for tooth failure in overloading conditions is greatly reduced, therefore rendering these gears suitable for considering their use in high load applications such as in the automotive industry. Also, the effect of the thickness of the reinforcement on the maximum developed tensile stress at the root is examined. The results show significant decrease of the bending stress at the root fillet rendering this design an alternative way in reinforcing plastic gears.

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来源期刊

International Journal of Powertrains Engineering-Automotive Engineering

CiteScore

1.20

自引率

0.00%

发文量

期刊介绍： IJPT addresses novel scientific/technological results contributing to advancing powertrain technology, from components/subsystems to system integration/controls. Focus is primarily but not exclusively on ground vehicle applications. IJPT''s perspective is largely inspired by the fact that many innovations in powertrain advancement are only possible due to synergies between mechanical design, mechanisms, mechatronics, controls, networking system integration, etc. The science behind these is characterised by physical phenomena across the range of physics (multiphysics) and scale of motion (multiscale) governing the behaviour of components/subsystems.