TY - JOUR
T1 - Topological and lattice-based AM optimization for improving the structural efficiency of robotic arms
AU - Batista, Rafael Cavicchioli
AU - Agarwal, Abhishek
AU - Gurung, Adash
AU - Kumar, Ajay
AU - Altarazi, Faisal
AU - Dogra, Namrata
AU - H. M, Vishwanatha
AU - Chiniwar, Dundesh S.
AU - Agrawal, Ashish
N1 - Publisher Copyright:
Copyright © 2024 Batista, Agarwal, Gurung, Kumar, Altarazi, Dogra, H. M., Chiniwar and Agrawal.
PY - 2024
Y1 - 2024
N2 - The robotic arm is one of the vital components of robot assembly. The purpose of the robotic arm is to transmit power and conduct the desired motion, i.e., translation or rotation. Robotic limbs are designed and constructed to execute certain tasks with a high degree of speed, accuracy, and efficiency. This research focuses on to enhancing the strength-to-weight ratio of robotic arm using certain techniques of additive manufacturing, i.e., topology optimization and lattice structure. Employing the finite element analysis, the impact of weight reduction optimization on structural parameters such as stress and deformation in the current design is assessed using ANSYS R18.1 for FE analysis and Creo parametric 7.0 design software for computer-aided design modeling. Observations reveal that the 0.5 and.4 scale lattice structure designs have deformation of 0.01453mm and 0.01453 mm respectively though the generic design has 0.01043 mm deformation. Notably, the 0.5 scale lattice of the robotic arm exhibits a 31.08% higher equivalent stress than the generic design with 29.3%. reduction in mass of the robotic arm. These findings highlight the efficacy of lattice structures for optimizing the robotic arm’s performance, contributing to advancements in power-efficient robot assembly processes.
AB - The robotic arm is one of the vital components of robot assembly. The purpose of the robotic arm is to transmit power and conduct the desired motion, i.e., translation or rotation. Robotic limbs are designed and constructed to execute certain tasks with a high degree of speed, accuracy, and efficiency. This research focuses on to enhancing the strength-to-weight ratio of robotic arm using certain techniques of additive manufacturing, i.e., topology optimization and lattice structure. Employing the finite element analysis, the impact of weight reduction optimization on structural parameters such as stress and deformation in the current design is assessed using ANSYS R18.1 for FE analysis and Creo parametric 7.0 design software for computer-aided design modeling. Observations reveal that the 0.5 and.4 scale lattice structure designs have deformation of 0.01453mm and 0.01453 mm respectively though the generic design has 0.01043 mm deformation. Notably, the 0.5 scale lattice of the robotic arm exhibits a 31.08% higher equivalent stress than the generic design with 29.3%. reduction in mass of the robotic arm. These findings highlight the efficacy of lattice structures for optimizing the robotic arm’s performance, contributing to advancements in power-efficient robot assembly processes.
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U2 - 10.3389/fmech.2024.1422539
DO - 10.3389/fmech.2024.1422539
M3 - Article
AN - SCOPUS:85196427276
SN - 2297-3079
VL - 10
JO - Frontiers in Mechanical Engineering
JF - Frontiers in Mechanical Engineering
M1 - 1422539
ER -