An Alternative Method for Shaking Force Balancing of the 3RRR PPM through Acceleration Control of the Center of Mass

An Alternative Method for Shaking Force Balancing of the 3RRR PPM through Acceleration Control of the Center of Mass

The problem of shaking force balancing of robotic manipulators, which allows the elimination or substantial reduction of the variable force transmitted to the fixed frame, has been traditionally solved by optimal mass redistribution of the moving links. The resulting configurations have been achieve...

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Main Authors: Mario Acevedo, María T. Orvañanos-Guerrero, Ramiro Velázquez, Vigen Arakelian
Format: Article
Language:English
Published: MDPI AG 2020-02-01
Series:Applied Sciences
Subjects:
dynamic balancing
shaking force balancing
acceleration control of the center of mass
fully cartesian coordinates
natural coordinates
parallel manipulators
Online Access:https://www.mdpi.com/2076-3417/10/4/1351
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spelling doaj-3bf16fa4ca874dddba85da1c30d7c7112020-11-25T02:03:23ZengMDPI AGApplied Sciences2076-34172020-02-01104135110.3390/app10041351app10041351An Alternative Method for Shaking Force Balancing of the 3RRR PPM through Acceleration Control of the Center of MassMario Acevedo0María T. Orvañanos-Guerrero1Ramiro Velázquez2Vigen Arakelian3Facultad de Ingeniería, Universidad Panamericana, Álvaro del Portillo 49, Zapopan, Jalisco 45010, MexicoFacultad de Ingeniería, Universidad Panamericana, Josemaría Escrivá de Balaguer 101, Aguascalientes 20290, MexicoFacultad de Ingeniería, Universidad Panamericana, Josemaría Escrivá de Balaguer 101, Aguascalientes 20290, MexicoLS2N-ECN UMR 6004, 1 rue de la Noë, BP 92101, F-44321 Nantes, FranceThe problem of shaking force balancing of robotic manipulators, which allows the elimination or substantial reduction of the variable force transmitted to the fixed frame, has been traditionally solved by optimal mass redistribution of the moving links. The resulting configurations have been achieved by adding counterweights, by adding auxiliary structures or, by modifying the form of the links from the early design phase. This leads to an increase in the mass of the elements of the mechanism, which in turn leads to an increment of the torque transmitted to the base (the shaking moment) and of the driving torque. Thus, a balancing method that avoids the increment in mass is very desirable. In this article, the reduction of the shaking force of robotic manipulators is proposed by the optimal trajectory planning of the common center of mass of the system, which is carried out by “bang-bang” profile. This allows a considerable reduction in shaking forces without requiring counterweights, additional structures, or changes in form. The method, already presented in the literature, is resumed in this case using a direct and easy to automate modeling technique based on fully Cartesian coordinates. This permits to express the common center of mass, the shaking force, and the shaking moment of the manipulator as simple analytic expressions. The suggested modeling procedure and balancing technique are illustrated through the balancing of the 3RRR planar parallel manipulator (PPM). Results from computer simulations are reported.https://www.mdpi.com/2076-3417/10/4/1351dynamic balancingshaking force balancingacceleration control of the center of massfully cartesian coordinatesnatural coordinatesparallel manipulators
collection DOAJ
language English
format Article
sources DOAJ
author Mario Acevedo
María T. Orvañanos-Guerrero
Ramiro Velázquez
Vigen Arakelian
spellingShingle Mario Acevedo
María T. Orvañanos-Guerrero
Ramiro Velázquez
Vigen Arakelian
An Alternative Method for Shaking Force Balancing of the 3RRR PPM through Acceleration Control of the Center of Mass
Applied Sciences
dynamic balancing
shaking force balancing
acceleration control of the center of mass
fully cartesian coordinates
natural coordinates
parallel manipulators
author_facet Mario Acevedo
María T. Orvañanos-Guerrero
Ramiro Velázquez
Vigen Arakelian
author_sort Mario Acevedo
title An Alternative Method for Shaking Force Balancing of the 3RRR PPM through Acceleration Control of the Center of Mass
title_short An Alternative Method for Shaking Force Balancing of the 3RRR PPM through Acceleration Control of the Center of Mass
title_full An Alternative Method for Shaking Force Balancing of the 3RRR PPM through Acceleration Control of the Center of Mass
title_fullStr An Alternative Method for Shaking Force Balancing of the 3RRR PPM through Acceleration Control of the Center of Mass
title_full_unstemmed An Alternative Method for Shaking Force Balancing of the 3RRR PPM through Acceleration Control of the Center of Mass
title_sort alternative method for shaking force balancing of the 3rrr ppm through acceleration control of the center of mass
publisher MDPI AG
series Applied Sciences
issn 2076-3417
publishDate 2020-02-01
description The problem of shaking force balancing of robotic manipulators, which allows the elimination or substantial reduction of the variable force transmitted to the fixed frame, has been traditionally solved by optimal mass redistribution of the moving links. The resulting configurations have been achieved by adding counterweights, by adding auxiliary structures or, by modifying the form of the links from the early design phase. This leads to an increase in the mass of the elements of the mechanism, which in turn leads to an increment of the torque transmitted to the base (the shaking moment) and of the driving torque. Thus, a balancing method that avoids the increment in mass is very desirable. In this article, the reduction of the shaking force of robotic manipulators is proposed by the optimal trajectory planning of the common center of mass of the system, which is carried out by “bang-bang” profile. This allows a considerable reduction in shaking forces without requiring counterweights, additional structures, or changes in form. The method, already presented in the literature, is resumed in this case using a direct and easy to automate modeling technique based on fully Cartesian coordinates. This permits to express the common center of mass, the shaking force, and the shaking moment of the manipulator as simple analytic expressions. The suggested modeling procedure and balancing technique are illustrated through the balancing of the 3RRR planar parallel manipulator (PPM). Results from computer simulations are reported.
topic dynamic balancing
shaking force balancing
acceleration control of the center of mass
fully cartesian coordinates
natural coordinates
parallel manipulators
url https://www.mdpi.com/2076-3417/10/4/1351
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