D3-ARM: High-Dynamic, Dexterous and Fully Decoupled Cable-driven Robotic Arm

TL;DR

This paper introduces D3-Arm, a lightweight, fully decoupled cable-driven robotic arm with high precision and stability, achieved through novel low-friction decoupling mechanisms and cable pretensioning, suitable for various environments.

Contribution

The paper presents a novel low-friction decoupling mechanism and cable pretension system that significantly improve control precision and stability in cable-driven robotic arms.

Findings

Average positioning error of 1.29 mm

Payload capacity of 2.0 kg

Effective decoupling and cable tension management

Abstract

Cable transmission enables motors of robotic arm to operate lightweight and low-inertia joints remotely in various environments, but it also creates issues with motion coupling and cable routing that can reduce arm's control precision and performance. In this paper, we present a novel motion decoupling mechanism with low-friction to align the cables and efficiently transmit the motor's power. By arranging these mechanisms at the joints, we fabricate a fully decoupled and lightweight cable-driven robotic arm called D3-Arm with all the electrical components be placed at the base. Its 776 mm length moving part boasts six degrees of freedom (DOF) and only 1.6 kg weights. To address the issue of cable slack, a cable-pretension mechanism is integrated to enhance the stability of long-distance cable transmission. Through a series of comprehensive tests, D3-Arm demonstrated 1.29 mm average positioning error and 2.0 kg payload capacity, proving the practicality of the proposed decoupling mechanisms in cable-driven robotic arm.