Dynamic Modeling of an Origami Prismatic Joint

2023 IEEE International Conference on Soft Robotics (RoboSoft) Pub Date : 2023-04-03 DOI:10.1109/RoboSoft55895.2023.10122040

M. Mete, Jian-Lin Huang, J. Paik

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Abstract

Dynamic modeling of folding joints is critical for predicting dynamic behavior, optimizing design parameters, and developing control strategies for origami robots and machines. Although kinematics of the folded joints exists, little research describes their dynamics. Currently, prevailing models neglect the stiffness of the hinges by making zero-thickness assumption or ignore physical factors such as gravity and friction. In this work, we focus on the dynamic modeling of an origami prismatic joint with rotary-to-translational transmission by using the Newton-Euler method and pseudo-rigid-body-approximation. We provide a comprehensive dynamic model by including gravity, friction, and hinge parameters. We validate the model in an all-inclusive experimental setup addressing static, quasi-static, and dynamic conditions. Our proposed model successfully predicts the dynamics and structural stiffness of the joint. This novel model can be combined with other origami-joint models, such as pin and spherical joint models, to allow model-based design and control strategies for desired output performance of origami robots.

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折纸移动关节的动力学建模

折叠关节的动力学建模对于预测折纸机器人和机械的动态行为、优化设计参数和制定控制策略至关重要。虽然存在折叠关节的运动学，但很少有研究描述其动力学。目前，主流模型通过零厚度假设或忽略重力、摩擦等物理因素而忽略铰链刚度。本文采用牛顿-欧拉方法和拟刚体近似对具有旋转平移传动的折纸移动关节进行了动力学建模。我们提供了一个综合的动力学模型，包括重力，摩擦和铰链参数。我们在解决静态、准静态和动态条件的全面实验设置中验证了该模型。我们提出的模型成功地预测了关节的动力学和结构刚度。该模型可与其他折纸关节模型(如针脚和球面关节模型)相结合，实现折纸机器人输出性能的基于模型的设计和控制策略。

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2023 IEEE International Conference on Soft Robotics (RoboSoft)

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