Conceitos essenciais
A fast, end-to-end approach to automatically customize rigid gripper fingerpads that can achieve precise and stable grasping for different 3D-printed objects at multiple grasp points.
Resumo
The paper introduces Fingerpad Customization with Set Operators (FCSO), a fast and automated approach to design gripper fingerpads for grasping customized 3D-printed parts.
The key components of FCSO are:
- A method using set Boolean operations (intersections, unions, subtractions) to extract object features and synthesize gripper surfaces that conform to different local shapes to form caging grasps.
- A grasp quality evaluation method to assess the geometric quality of the synthesized gripper surfaces.
The pipeline consists of five modules:
- Stable pose generator: Identifies stable resting poses of the objects on a planar surface.
- Grasp sampler: Samples valid grasp locations by sliding rectangular samples along the object surfaces.
- Fingerpad customization: Extracts object features using set Boolean operations and synthesizes the optimal fingerpad geometry.
- Grasp quality evaluation: Assesses the geometric quality of the synthesized fingerpads based on contact normal variations and contact area.
- Finger design: Fuses the optimal fingerpad geometry onto a flat finger base.
The authors demonstrate that the customized fingerpads can achieve precise and stable grasping of complex 3D-printed objects at multiple poses, outperforming flat fingerpads in terms of precision and stability.
Estatísticas
The paper does not contain any key metrics or figures to support the author's main arguments.
Citações
"The rise in additive manufacturing comes with unique opportunities and challenges. Massive part customization and rapid design changes are made possible with additive manufacturing, however, manufacturing industries that desire the implementation of robotics automation to improve production efficiency could face challenges in the gripper design and grasp planning due to highly complex geometrical shapes resulting from massive part customization."
"Current gripper design methods for 3D-Print (3DP) parts are often manual that rely on ad-hoc design intuition rather than rigorous principles. It would also be difficult for a single manually designed gripper to be able to grasp different complex objects or multiple grasp points of one object."