Interpolation optimization for robotic grinding with velocity constraints

Interpolation optimization for robotic grinding with velocity constraints

Low rigidity of industrial robot can easily result in deformations during grinding process and finally lead to a deviation between planned path and actual path. In order to reduce impact of the deviation, with an analysis of the relationship among feed velocity, deformation, and trajectory planning,...

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Bibliographic Details
Main Authors: Shouyan Chen, Tie Zhang, Ming Shao
Format: Article
Language:English
Published: SAGE Publishing 2017-12-01
Series:Advances in Mechanical Engineering
Online Access:https://doi.org/10.1177/1687814017708709
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spelling doaj-d5cd60726f1b44cd804ff0648c6c0a952020-11-25T03:51:58ZengSAGE PublishingAdvances in Mechanical Engineering1687-81402017-12-01910.1177/1687814017708709Interpolation optimization for robotic grinding with velocity constraintsShouyan ChenTie ZhangMing ShaoLow rigidity of industrial robot can easily result in deformations during grinding process and finally lead to a deviation between planned path and actual path. In order to reduce impact of the deviation, with an analysis of the relationship among feed velocity, deformation, and trajectory planning, a deformation-based trajectory optimization approach is proposed in this article. The relationship among grinding angle, feed velocity, deformation, and interpolation point planning is first studied and two velocity constraints are proposed. The positions of interpolation points are then adjusted in accordance with the velocity constraints to optimize trajectory. Experiment results indicate that the proposed trajectory optimization approach can significantly reduce the deformation and vibration occurring in robotic grinding process.https://doi.org/10.1177/1687814017708709
collection DOAJ
language English
format Article
sources DOAJ
author Shouyan Chen
Tie Zhang
Ming Shao
spellingShingle Shouyan Chen
Tie Zhang
Ming Shao
Interpolation optimization for robotic grinding with velocity constraints
Advances in Mechanical Engineering
author_facet Shouyan Chen
Tie Zhang
Ming Shao
author_sort Shouyan Chen
title Interpolation optimization for robotic grinding with velocity constraints
title_short Interpolation optimization for robotic grinding with velocity constraints
title_full Interpolation optimization for robotic grinding with velocity constraints
title_fullStr Interpolation optimization for robotic grinding with velocity constraints
title_full_unstemmed Interpolation optimization for robotic grinding with velocity constraints
title_sort interpolation optimization for robotic grinding with velocity constraints
publisher SAGE Publishing
series Advances in Mechanical Engineering
issn 1687-8140
publishDate 2017-12-01
description Low rigidity of industrial robot can easily result in deformations during grinding process and finally lead to a deviation between planned path and actual path. In order to reduce impact of the deviation, with an analysis of the relationship among feed velocity, deformation, and trajectory planning, a deformation-based trajectory optimization approach is proposed in this article. The relationship among grinding angle, feed velocity, deformation, and interpolation point planning is first studied and two velocity constraints are proposed. The positions of interpolation points are then adjusted in accordance with the velocity constraints to optimize trajectory. Experiment results indicate that the proposed trajectory optimization approach can significantly reduce the deformation and vibration occurring in robotic grinding process.
url https://doi.org/10.1177/1687814017708709
work_keys_str_mv AT shouyanchen interpolationoptimizationforroboticgrindingwithvelocityconstraints
AT tiezhang interpolationoptimizationforroboticgrindingwithvelocityconstraints
AT mingshao interpolationoptimizationforroboticgrindingwithvelocityconstraints
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