Design and transmission performance analysis of planthopper hip joint gear

Shengping Fu, Zenghuang He, Weixiong Ye, Xudong Li, Rui Wang, Bin Sheng
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Abstract

To enhance the efficiency and load-carrying capacity of the jumping robot’s transmission system, the transmission characteristics of the planthopper hip gear were analyzed. The analysis revealed that the gear pair exhibited low transmission errors, high transmission efficiency, and significant torque capacity, making it suitable for high-speed, high-precision, and high-power density transmissions. A bionic design study of the jumping robot’s gear was conducted, drawing inspiration from the planthopper hip gear’s tooth shape and profile. A logarithmic spiral was assumed as the tooth profile based on its consistent pitch angle and curvature gradient characteristics. Parameters of the tooth profile of the bionic gear were calculated, and equations for the tooth surface were derived. A three-dimensional model of the bionic gear was constructed, and both its transmission efficiency and error were calculated. Using the finite element method, theoretical formulas for contact stress and bending stress in the bionic gear were deduced. The distribution characteristics of both bending and contact stress were analyzed, demonstrating that the bionic gear used in high-performance jumping robots possesses low transmission error, high transmission efficiency, and excellent contact strength, providing a theoretical foundation for enhancing their jumping capabilities.
平面髋关节齿轮的设计与传动性能分析
为了提高跳跃机器人传动系统的效率和承载能力,我们分析了平面跳跃髋齿轮的传动特性。分析结果表明,该齿轮副的传动误差小、传动效率高、扭矩容量大,适合高速、高精度和高功率密度的传动。从刨齿髋关节齿轮的齿形和轮廓中汲取灵感,对跳跃机器人的齿轮进行了仿生设计研究。根据其一致的节距角和曲率梯度特征,假定齿形为对数螺旋形。计算了仿生齿轮齿廓的参数,并得出了齿面方程。建立了仿生齿轮的三维模型,并计算了其传动效率和误差。利用有限元法,推导出了仿生齿轮接触应力和弯曲应力的理论公式。分析了弯曲应力和接触应力的分布特征,证明高性能跳跃机器人使用的仿生齿轮具有较低的传动误差、较高的传动效率和出色的接触强度,为增强机器人的跳跃能力提供了理论依据。
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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