The researchers present a method to design and fabricate a soft, sensorized skin for a dexterous robotic hand, the Faive hand. They use multi-material 3D printing to rapidly prototype and optimize the skin design, which features an origami-inspired structure to preserve the hand's range of motion and speed. The final skin is cast in silicone and embedded with piezoresistive pressure sensors.
The dynamic tests show that the skin has minimal impact on the hand's latency and range of motion, even at high frequencies. Static pull tests reveal that the soft skin enables the hand to grasp smooth objects with up to 4 times more force compared to the bare hand. The tactile sensors embedded in the skin can distinguish different grasped objects and hand states, demonstrating the potential for enhanced proprioception.
The researchers discuss the trade-offs between 3D printing and casting for skin fabrication, with casting providing higher structural integrity but taking longer. They also highlight the challenges in reliably integrating custom-made tactile sensors into the soft skin. Overall, the work demonstrates that a sensorized soft skin can augment the capabilities of dexterous robotic hands without compromising their dynamic performance.
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by Jana Egli (1... kl. arxiv.org 05-01-2024
https://arxiv.org/pdf/2404.19448.pdfDybere Forespørgsler