Highly sensitive robot gripper eliminates need for pneumatics

Being able to transport, sort and pack fragile food automatically is no mean feat. The robot must handle the products quickly and dynamically, be it eggs, meringues, meatballs, cookies, pralines, donuts or anything else, without damaging them with pressure marks or other blemishes. As part of a project funded by the federal state of North Rhine-Westphalia, researchers at Fraunhofer IEM in Paderborn have developed a robot gripper, designed for use in the food industry.

The gripper system can be set up with two, three or four fingers and adapted for a range of tasks and purposes — meaning that it could also be used for the automated handling of other fragile products such as glassware.

“The fingers have a plastic-based, soft and flexible coating, which enables them to keep a delicate grip on fragile materials and avoid damaging them” said Dr Christian Henke, head of the Scientific Automation department at Fraunhofer IEM. “The robot gripper is also extremely dynamic and can easily be incorporated into production processes. It maintains the required balance between speed and sensitivity at all times.”

Precise and dynamic control technology enables targeted finger movement and complex product control. Sensors integrated into the fingers determine the amount of pressure required.

Saving resources with electric power

A special advantage of the system is that the gripper is not operated pneumatically, but electrically. In this way, it works energy-efficiently and uses existing power connections.

“Until now, gripper systems have been powered pneumatically, which uses a lot of energy. Generating pressurised air is less efficient — even less so due to frequent leakages in the lines,” Henke explained.

Safety barriers not required for production

The system’s spatial radius of action can be expanded with a linear axis, ie, a horizontal track. To do this, the robot gripper is mounted on a vertical lifting column, which is attached to the linear axis. The gripper is suitable for safe human–robot collaboration due to its sensor-based environment recognition system. This is not the case for the axes (both the linear axis and the lifting column), however. To render the entire workspace collaborative, the researchers have developed a 360-degree environment recognition system that monitors the full length and height of the axes and can be integrated into the base of the linear axis.

“With this multi-sensor system, which includes distance and thermographic sensors, the entire cobot and axis structure can work collaboratively. This means that businesses don’t need to install safety barriers,” Henke said. “The gripper can either be combined with the linear axis and multi-sensor system or used on its own.”

Initial tests have been successful, and the Fraunhofer IEM team is now looking for partners to manage bringing the robot gripper to market.

Image caption: Fraunhofer IEM is researching intelligent gripping systems. Image credit: © Fraunhofer IEM/Wolfgang Schroll.

Originally published here.