Rigid-flexible coupling dynamic modelling and dynamic accuracy analysis of planar cam four-bar mechanism with multiple clearance joints

Zhan Wei, Zanyong Wang, Dandan Li, Dong Liang
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Abstract

Combination mechanism of conjugate cam and four-bar is a complex type of multi-body system, in which the coupling problems such as cam profile law, flexible deformation of connecting rods, and multiple joint clearance collision make it difficult to model and optimise its dynamics. Just as the beating-up mechanism of high-speed rapier looms for multi-layer weaving is a representative conjugate cam four-bar mechanism. In response to the current development of textile machinery in the direction of high-speed and precision, and in order to improve the work efficiency and operational accuracy of the conjugate cam four-bar beating-up mechanism, the following work is done for the purpose of taking into account the multi-joint clearance and the flexible rod based on the mechanism. Firstly, based on Kane's equation, a multi-body dynamic model with multiple clearances is established combined with clearance collision theory. Secondly, a dynamic model of a rigid-flexible coupling system with multiple revolute clearances is established using finite element method combined with modal synthesis technology. Subsequently, the variables separation method and mode superposition method are used to solve the dynamic equations of the coupled system. Finally, numerical examples are used to analyse the effects of clearance quantity, clearance size, mode truncation order, cam speed, and component material properties on the dynamic response and accuracy of the system. The results show that, in the rotational speed range of 600–800 rpm, the dynamic performance of the system is little affected by the speed; Through comparative analysis of multiple materials, it is found that selecting carbon fibre composite materials has the smallest impact on the motion accuracy of the system. In this paper, the clearance collision model, finite element model and rigid-flexible coupling dynamic model are integrated, which are applied to the cam-linkage combined multi-body mechanism, and the dynamic problems of the actual machine are analysed and solved.
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带多个间隙接头的平面凸轮四杆机构的刚柔耦合动态建模和动态精度分析
共轭凸轮和四杆的组合机构是一种复杂的多体系统,其中凸轮轮廓规律、连杆柔性变形、多关节间隙碰撞等耦合问题使其动力学建模和优化变得困难。正如用于多层织造的高速剑杆织机的打纬机构就是一个具有代表性的共轭凸轮四杆机构。针对当前纺织机械向高速化、精密化方向发展的现状,为了提高共轭凸轮四杆打纬机构的工作效率和运行精度,在考虑多关节间隙和弹性杆的基础上,对该机构进行了以下工作。首先,根据凯恩方程,结合间隙碰撞理论,建立了具有多重间隙的多体动力学模型。其次,利用有限元法结合模态合成技术,建立了具有多重转轴间隙的刚柔耦合系统动态模型。随后,采用变量分离法和模态叠加法求解耦合系统的动态方程。最后,利用数值实例分析了间隙数量、间隙大小、模态截断阶数、凸轮速度和部件材料特性对系统动态响应和精度的影响。结果表明,在 600-800 rpm 的转速范围内,系统的动态性能受转速的影响很小;通过多种材料的对比分析,发现选择碳纤维复合材料对系统运动精度的影响最小。本文集成了间隙碰撞模型、有限元模型和刚柔耦合动力学模型,并将其应用于凸轮连杆组合多体机构,对实际机器的动力学问题进行了分析和求解。
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来源期刊
CiteScore
4.10
自引率
11.10%
发文量
38
审稿时长
>12 weeks
期刊介绍: The Journal of Multi-body Dynamics is a multi-disciplinary forum covering all aspects of mechanical design and dynamic analysis of multi-body systems. It is essential reading for academic and industrial research and development departments active in the mechanical design, monitoring and dynamic analysis of multi-body systems.
期刊最新文献
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