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arxiv_robotics 85% Match Research Paper Robotics Engineers,Mechanical Designers,Product Developers,CAD Engineers 3 weeks ago

COMPAct: Computational Optimization and Automated Modular design of Planetary Actuators

robotics › manipulation
📄 Abstract

Abstract: The optimal design of robotic actuators is a critical area of research, yet limited attention has been given to optimizing gearbox parameters and automating actuator CAD. This paper introduces COMPAct: Computational Optimization and Automated Modular Design of Planetary Actuators, a framework that systematically identifies optimal gearbox parameters for a given motor across four gearbox types, single-stage planetary gearbox (SSPG), compound planetary gearbox (CPG), Wolfrom planetary gearbox (WPG), and double-stage planetary gearbox (DSPG). The framework minimizes mass and actuator width while maximizing efficiency, and further automates actuator CAD generation to enable direct 3D printing without manual redesign. Using this framework, optimal gearbox designs are explored over a wide range of gear ratios, providing insights into the suitability of different gearbox types across various gear ratio ranges. In addition, the framework is used to generate CAD models of all four gearbox types with varying gear ratios and motors. Two actuator types are fabricated and experimentally evaluated through power efficiency, no-load backlash, and transmission stiffness tests. Experimental results indicate that the SSPG actuator achieves a mechanical efficiency of 60-80 %, a no-load backlash of 0.59 deg, and a transmission stiffness of 242.7 Nm/rad, while the CPG actuator demonstrates 60 % efficiency, 2.6 deg backlash, and a stiffness of 201.6 Nm/rad. Code available at: https://anonymous.4open.science/r/COMPAct-SubNum-3408 Video: https://youtu.be/99zOKgxsDho

Key Contributions

This paper introduces COMPAct, a framework for computational optimization and automated modular design of planetary actuators. It systematically identifies optimal gearbox parameters across four types of gearboxes to minimize mass and actuator width while maximizing efficiency, and automates CAD generation for direct 3D printing, enabling efficient and rapid design of robotic actuators.

Business Value

Accelerates the design and manufacturing of custom robotic actuators, leading to lighter, more efficient, and cost-effective robotic systems for various industries.

Paper Metadata

Innovation Type

Framework & Automation

Deployment Feasibility

High for design and prototyping, moderate for mass production depending on manufacturing capabilities.

Limitations Addressed

Limited attention to optimizing gearbox parameters and automating actuator CAD; manual redesign required for 3D printing.

Performance Gains

Provides insights into optimal gearbox designs across various gear ratios and automates CAD generation, reducing design time and effort.

Technical Tags

planetary gearboxesactuator designcomputational optimizationautomated CADgear ratio optimizationmass minimizationefficiency maximization3D printingmodular design

Research Topics

RoboticsMechanical DesignOptimizationAutomationActuator Technology

Methods & Architectures

Computational OptimizationAutomated CAD GenerationParameter SweepingDesign Exploration

Applications & Tasks

Robotics Mechanical Engineering Product Design Manufacturing Optimizing Gearbox ParametersAutomating Actuator DesignMinimizing Mass and WidthMaximizing Efficiency Planetary Gearbox DesignActuator CAD GenerationRobotic Component Optimization

Related Fields

Mechanical EngineeringRoboticsComputer-Aided Design (CAD)OptimizationManufacturing

Keywords

planetary gearboxactuator designcomputational optimizationautomated CADgear ratiomass reductionefficiency3D printingroboticsmechanical designmodular designWolfrom gearbox

Academic Context

#Robotics#Mechanical Design#Optimization#Automation#Actuator Technology

Commercial Potential

Potential Products
Custom robotic actuatorsDesign automation software for actuators3D printable robotic components
Target Industries
RoboticsAutomotiveAerospaceManufacturingConsumer Electronics
Use Case Examples
Designing lightweight actuators for dronesOptimizing gearboxes for industrial robotsCreating custom actuators for space applications
Competitive Edge
Provides a systematic and automated approach to planetary actuator design, surpassing traditional manual design methods in terms of optimization and speed.

Resource Requirements

Compute Needs
Moderate compute for optimization simulations.
Data Requirements
Motor specifications, performance requirements.
Deployment Constraints
Requires access to advanced manufacturing (e.g., 3D printing) for realized designs.
Scalability
The framework is scalable to different motor types and design requirements.

Production Readiness

Maturity Level

Research

Patent Potential

Moderate

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