A group of scientists and innovators over at the Japan Advanced Institute of Technology have devised a high-tech robotic gripper that is designed to offer the positioning and sensitivity required in robot-based gripping tools whilst addressing many of the standing disadvantages.
Specifically, existing robotic grippers designed to be able to handle delicate and fragile objects tend to be expensive. The Japanese team have taken steps to address this by developing a soft robotic gripper that uses a funnel-like component that is linked to a circular foundation, with the funnel element placed over objects to pick them up without causing damage.
Dubbed the 'rotation-based squeezing gripper' or 'ROSE' for short, this particular robotic gripper is inspired by the fragility of nature and flowers, and is positioned as an innovation that will make robotic grippers designed for softer and more delicate items less expensive to produce and deploy.
Flower-Inspired Robotic Grippers
This Gripping Tool is Designed to Gently Grasp Delicate Objects
Trend Themes
1. Soft Robotic Grippers - Development of soft robotic grippers inspired by nature and flowers offers cost-effective solutions for handling delicate objects.
2. Rotation-based Squeezing Gripper - Innovation in gripper technology with a rotation-based squeezing gripper improves the positioning and sensitivity required for delicate object manipulation.
3. Fragility-inspired Robotics - Exploring robotics inspired by the fragility of nature allows for the creation of gentle and damage-free gripping tools.
Industry Implications
1. Robotics - The robotics industry can utilize soft robotic grippers for delicate object handling, improving efficiency and reducing costs.
2. Manufacturing - The manufacturing industry can benefit from the use of rotation-based squeezing grippers to improve automation processes and handle fragile components more effectively.
3. Logistics - Incorporation of fragility-inspired robotics in the logistics industry can enhance the safe handling of delicate items during transportation and storage.