材料科学
复合数
复合材料
刚度
分层(地质)
有限元法
比模量
弯曲
抗弯刚度
结构工程
情态动词
体积分数
比强度
纤维
模态分析
上下界
纤维增强复合材料
碳纤维
固有频率
制作
可加工性
先进复合材料
机械臂
作者
Rongtao Zhang,Zhuo Meng,Gaowei Cai,Zhijun Sun,Yujing Zhang
摘要
ABSTRACT This study proposes a hat‐stiffened carbon fiber composite industrial robot upper arm (hereafter referred to as the composite upper arm) to address the excessive weight, insufficient stiffness and limited modal performance of conventional metal robot upper arms. By integrating the good machinability of metallic materials with the high specific stiffness of carbon fiber composites, an integrated forming method for a metal‐composite hybrid structure is proposed. Three‐dimensional carbon fiber braiding is introduced into the fabrication of the composite upper arm. A braiding‐layering‐winding composite preforming process is employed to enhance the delamination resistance, bending performance, and fiber volume fraction of the composite upper arm. A braided model of the composite upper arm is established. The braiding trajectories are determined by numerical calculation and mapped into the composite finite element model to analyze the stiffness and modal characteristics of the composite upper arm. Experimental results show that, compared to the metal upper arm, the composite upper arm achieves a weight reduction of 31% and an increase of 13% in the first natural frequency. After adopting the composite upper arm, the overall stiffness of the robot is improved by 13%.
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