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Hybrid Gripper Finger Enabling In-Grasp Friction Modulation Using Inflatable Silicone Pockets

Hoang Hiep Ly, Cong-Nhat Nguyen, Doan-Quang Tran, Quoc-Khanh Dang, Ngoc Duy Tran, Thi Thoa Mac, Anh Nguyen, Xuan-Thuan Nguyen, Tung D. Ta

Abstract

Grasping objects with diverse mechanical properties, such as heavy, slippery, or fragile items, remains a significant challenge in robotics. Conventional grippers often rely on applying high normal forces, which can cause damage to objects. To address this limitation, we present a hybrid gripper finger that combines a rigid structural shell with a soft, inflatable silicone pocket. The gripper finger can actively modulate its surface friction by controlling the internal air pressure of the silicone pocket. Results from fundamental experiments indicate that increasing the internal pressure results in a proportional increase in the effective coefficient of friction. This enables the gripper to stably lift heavy and slippery objects without increasing the gripping force and to handle fragile or deformable objects, such as eggs, fruits, and paper cups, with minimal damage by increasing friction rather than applying excessive force. The experimental results demonstrate that the hybrid gripper finger with adaptable friction provides a robust and safer alternative to relying solely on high normal forces, thereby enhancing the gripper flexibility in handling delicate, fragile, and diverse objects.

Hybrid Gripper Finger Enabling In-Grasp Friction Modulation Using Inflatable Silicone Pockets

Abstract

Grasping objects with diverse mechanical properties, such as heavy, slippery, or fragile items, remains a significant challenge in robotics. Conventional grippers often rely on applying high normal forces, which can cause damage to objects. To address this limitation, we present a hybrid gripper finger that combines a rigid structural shell with a soft, inflatable silicone pocket. The gripper finger can actively modulate its surface friction by controlling the internal air pressure of the silicone pocket. Results from fundamental experiments indicate that increasing the internal pressure results in a proportional increase in the effective coefficient of friction. This enables the gripper to stably lift heavy and slippery objects without increasing the gripping force and to handle fragile or deformable objects, such as eggs, fruits, and paper cups, with minimal damage by increasing friction rather than applying excessive force. The experimental results demonstrate that the hybrid gripper finger with adaptable friction provides a robust and safer alternative to relying solely on high normal forces, thereby enhancing the gripper flexibility in handling delicate, fragile, and diverse objects.

Paper Structure

This paper contains 21 sections, 14 equations, 12 figures.

Table of Contents

  1. Introduction
  2. Methods and Materials
  3. Hybrid gripper finger in the context of contact theory
  4. Hybrid Gripper Finger
  5. Outer Shell
  6. Silicone Air Pocket
  7. Gripper Prototype
  8. Experiments
  9. Fundamental Experiment
  10. Gripping Objects Experiments
  11. Grasping Heavy and Slippery Objects Experiments
  12. Grasping Deformable Objects Experiments
  13. Grasping Different Objects Experiments
  14. Experiment Results
  15. Fundamental Experiment Results
  16. ...and 6 more sections

Figures (12)

  • Figure 1: Hybrid robotic gripper for adaptive grasping using inflatable silicone pockets to grasp heavy and slippery objects, deformable objects, and various types of objects. (a) Gripper finger, (b) hybrid gripper system, (c-f) grasping various objects.
  • Figure 2: Modeling the contact mechanisms between a hybrid gripper finger and a target object.
  • Figure 3: Inflation stages of the silicone air pocket at different pressure levels. (a) Total deflated, (b) slightly inflated, (c) inflated, (d) fully inflated.
  • Figure 4: Design model of the outer shell. (a) Assembled view. (b) Front part with three grooves. (c) Back part with load-cell mount. Dimensions is in mm.
  • Figure 5: Fabrication of the silicone air pocket. (a) Female mold. (b) Male mold. (c) The three stages of fabrication. (d) The final product is assembled with a load cell mount.
  • ...and 7 more figures