Mechanical design, modeling, and identification for a novel antagonistic variable stiffness dexterous finger

Abstract: This study traces the development of dexterous hand research and proposes a novel antagonistic variable stiffness dexterous finger mechanism to improve the safety of dexterous hand in unpredictable environments, such as unstructured or man-made operational errors through comprehensive consideration of cost, accuracy, manufacturing, and application. Based on the concept of mechanical passive compliance, which is widely implemented in robots for interactions, a finger is dedicated to improving mechanical robustn… Show more

“…For example, they are suitable for manipulation of Background of variable stiffness for robotics: (a) different variable stiffness devices. Reproduced from [21]. CC BY 4.0.…”

“…As shown in figure 1(a), to improve the robots' compliance and safety when they interact with complicated and unstructured environments, many methods based on the concept of stiffness modulation, have been developed. For example, the rigid robotic finger can manipulate different objects based on variable stiffness mechanism [21]; the wearable exoskeletons of rigid robotic arm with variable stiffness can be used for increasing safe physical human-robot interaction or improving the dynamical adaptability with environment, as well as enhancing the energy efficiency [22]; artificial spine can increase its stiffness to support the body's weight and provide load-bearing capabilities, while it also can adaptively decrease stiffness to enable adaptive motion and provide flexibility when necessary [23]; variation in leg stiffness can not only allow the robots to alter their stride frequency, but also can be beneficial to running and hopping systems, allowing energy to be stored and reused as the leg shortens and extends [24,25]; stiffness tunable ankle exoskeletons can adjust output force based on the external load and joint angle, which can provide scientifically motivated, quantifiable, and automated exercises, help control the complex's position during ambulation, and to then recover a normal walking gait for patients [26]. As shown in figure 1(b), some animals and soft organ, such as octopus, snake and elephant trunk show highly flexible and deformable structures in low stiffness, which enable them entrance into small apertures for shelter.…”

Variable stiffness methods for robots: a review

“…For example, they are suitable for manipulation of Background of variable stiffness for robotics: (a) different variable stiffness devices. Reproduced from [21]. CC BY 4.0.…”

“…As shown in figure 1(a), to improve the robots' compliance and safety when they interact with complicated and unstructured environments, many methods based on the concept of stiffness modulation, have been developed. For example, the rigid robotic finger can manipulate different objects based on variable stiffness mechanism [21]; the wearable exoskeletons of rigid robotic arm with variable stiffness can be used for increasing safe physical human-robot interaction or improving the dynamical adaptability with environment, as well as enhancing the energy efficiency [22]; artificial spine can increase its stiffness to support the body's weight and provide load-bearing capabilities, while it also can adaptively decrease stiffness to enable adaptive motion and provide flexibility when necessary [23]; variation in leg stiffness can not only allow the robots to alter their stride frequency, but also can be beneficial to running and hopping systems, allowing energy to be stored and reused as the leg shortens and extends [24,25]; stiffness tunable ankle exoskeletons can adjust output force based on the external load and joint angle, which can provide scientifically motivated, quantifiable, and automated exercises, help control the complex's position during ambulation, and to then recover a normal walking gait for patients [26]. As shown in figure 1(b), some animals and soft organ, such as octopus, snake and elephant trunk show highly flexible and deformable structures in low stiffness, which enable them entrance into small apertures for shelter.…”

Variable stiffness methods for robots: a review

Ensemble Approach for Optimizing Variable Rigidity Joints in Robotic Manipulators Using MOALO-MODA

Kinematic Modeling and Experimental Verification of Underdriven Rigid-Flex Integrated Manipulator^*