Toward Tradeoff Between Impact Force Reduction and Maximum Safe Speed: Dynamic Parameter Optimization of Variable Stiffness Robots

Song, Siyang; She, Yu; Wang, Junmin; Su, Hai‐Jun

doi:10.1115/1.4046839

Cited by 13 publications

(2 citation statements)

References 34 publications

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“…The potential impact force is determined by impact velocity, robot stiffness, and mass involved in the impact (including robot effective mass and object effective mass). 54 Given a particular manipulation task, the mass of the objects is generally fixed, and we do not have control over it. Here, we consider the effect of the impact velocity v(t) and robot stiffness k(t) on the impact force F(t).…”

Section: Problem Statementmentioning

confidence: 99%

A Parametric Study of Compliant Link Design for Safe Physical Human–Robot Interaction

She

Song

et al. 2021

Robotica

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SUMMARY Robots of next-generation physically interact with the world rather than be caged in a controlled area, and they need to make contact with the open-ended environment to perform their task. Compliant robot links offer intrinsic mechanical compliance for addressing the safety issue for physical human–robot interactions (pHRI). However, many important research questions are yet to be answered. For instance, how do system parameters, for example, mechanical compliance, motor torque, impact velocities, and so on, affect the impact force? how to formulate system impact dynamics of compliant robots, and how to size their geometric dimensions to maximize impact force reduction. In this paper, we present a parametric study of compliant link (CL) design for safe pHRI. We first present a theoretical model of the pHRI system that is comprised of robot dynamics, an impact contact model, and dummy head dynamics. After experimentally validating the theoretical model, we then systematically study the effects of CL parameters on the impact force in more detail. Specifically, we explore how the design and actuation parameters affect the impact force of pHRI system. Based on the parametric studies of the CL design, we propose a step-by-step process and a list of concrete guidelines for designing CL with safety constraints in pHRI. We further conduct a simulation case study to validate this design process and design guidelines.

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Section: Problem Statementmentioning

confidence: 99%

A Parametric Study of Compliant Link Design for Safe Physical Human–Robot Interaction

She

Song

et al. 2021

Robotica

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“…A compliant mechanism is suitable for applications where small size, low power consumption, and simple control algorithms are required 17 . However, size and weight of tunable stiffness compliant mechanisms limit their implementation in many applications such as robotics and wearable systems 18 .…”

Section: Introductionmentioning

confidence: 99%

A Bioinspired Compliant 3D-Printed Soft Gripper

et al. 2022

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A compliant 3D-printed soft gripper is designed based on the bio-inspired spiral spring in this study. The soft gripper is then 3D-printed using a suitable thermoplastic filament material to deliver the desired performance. The sensorless mechanism introduced here provides adequate compliance with a single linear actuator for interacting with delicate objects, such as manipulation of human biological materials and fruit picking. The kinematic and dynamic models of the monolithic gripper are derived analytically as well as by means of finite element analysis to synthesize its functionality. The fabricated gripper module is installed on a robot arm to demonstrate the efficacy of design for picking and placing fruits without damaging them. The presented mechanism could be customized and used in the medical and agricultural sectors with diverse geometry objects.

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Trust‐Triggered Robot–Human Handovers Using Kinematic Redundancy for Collaborative Assembly in Flexible Manufacturing

Rahman

Sadrfaridpour

Walker

et al. 2023

Cyber–Physical–Human Systems

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Toward Tradeoff Between Impact Force Reduction and Maximum Safe Speed: Dynamic Parameter Optimization of Variable Stiffness Robots

Cited by 13 publications

References 34 publications

A Parametric Study of Compliant Link Design for Safe Physical Human–Robot Interaction

A Parametric Study of Compliant Link Design for Safe Physical Human–Robot Interaction

A Bioinspired Compliant 3D-Printed Soft Gripper

Trust‐Triggered Robot–Human Handovers Using Kinematic Redundancy for Collaborative Assembly in Flexible Manufacturing

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