Reconfigurable soft robotic actuators with hard components are described. Magnetic attraction is used to couple flexible molded bodies capable of actuation upon pressurization with other flexible molded bodies and/or with hard components (e.g., frames and connectors) to form a seal for fluidic communication and cooperative actuation. Pneumatic de-coupling chambers built into the hard components to de-couple the hard components from the magnetically-coupled soft molded bodies are described. The use of magnetic self-alignment coupling and pneumatic de-coupling allows for the remote assembly and disassembly of complex structures involving hard and soft components. The magnetic coupling allows for rapid, reversible reconfiguration of hybrid soft-hard robots for repair, testing new designs, and carrying out new tasks.

The present disclosure provides a robot gripper, comprising a bottom plate (101), a side plate A (102), an intermediate plate (103), a side plate B (104), guide rods (105), sliding blocks (106), cylinders (107), spherical joints (108), pneumatic quick plug connectors, a connecting plate (114), racks (115), a gear (116), a gear shaft (117), a horn type switch support (120), detection switches (121) and a detection head (122). By adopting the robot gripper, the bottom plate (101) can be connected with six-shaft flanges of a robot together by connectors; a gripper arm can be designed to connect the connecting plate (114) to grip a hub according to different demands; and the opening and closing state of the gripper can be detected by the detection switches (121). The robot gripper has the advantages of low price, compact overall structure, large clamping force, strong stability and the like.

Exemplary embodiments relate to soft robotic gripper systems suited to grasping target objects in cluttered environments. Some embodiments provide extension rods, hinges, and/or rails that allow a soft robotic actuator to be extended towards or away from a robotic base and/or other actuators. Accordingly, a gripper including the actuator may be reconfigured into a size and/or shape that allows for improved access to the cluttered environment. Further embodiments relate to soft robotic gripper systems for supporting grasped objects during high acceleration movements using vacuum, gripper, and/or bellows devices. Still further embodiments relate to specialized grippers for manipulating food items.

A robotic finger is provided. The robotic finger includes a first member that has a plurality of rigid sections that are rotatably connected end-to-end through respective first joints. The robotic finger also includes a second member that has a plurality of flexible sections that are connected end-to-end at respective second joints. The robotic finger also includes a plurality of linkages connecting the first member and the second member so as to align the plurality of flexible sections with the plurality of rigid sections side-by-side, and a respective linkage connects a respective first joint of the first member to a respective second joint of the second member. The robotic finger further includes a fingertip section that connects a distal end the first member to a distal end of the second member.

The gripper assembly includes a base, a guide situated on the base, and first and second jaws members. First and second ball bearing slides are associated with the jaw members for mounting the jaw members for movement along a guide track between proximate and remote positions. First and second low friction pneumatic actuators are provided. A mechanical linkage connects the actuators to at least one of the jaw members. A pulley and wire rope assembly connects the first and second jaw members for simultaneous movement in opposite directions. Valves are provided for actuating one actuator at a time. Actuation of the first actuator causes simultaneous movement of the jaw members in one direction. Actuation of the second actuator causes simultaneous movement of the jaw members in opposite directions.

A robotic finger is provided. The robotic finger includes a first member that has a plurality of rigid sections that are rotatably connected end-to-end through respective first joints. The robotic finger also includes a second member that has a plurality of flexible sections that are connected end-to-end at respective second joints. The robotic finger also includes a plurality of linkages connecting the first member and the second member so as to align the plurality of flexible sections with the plurality of rigid sections side-by-side, and a respective linkage connects a respective first joint of the first member to a respective second joint of the second member. The robotic finger further includes a fingertip section that connects a distal end the first member to a distal end of the second member.

Exemplary embodiments relate to user-assisted robotic control systems, user interfaces for remote control of robotic systems, vision systems in robotic control systems, and modular grippers for use by robotic systems. The systems, methods, apparatuses and computer-readable media instructions described interact with and control robotic systems, in particular pick and place systems using soft robotic actuators to grasp, move and release target objects.

Exemplary embodiments relate to user-assisted robotic control systems, user interfaces for remote control of robotic systems, vision systems in robotic control systems, and modular grippers for use by robotic systems. The systems, methods, apparatuses and computer-readable media instructions described interact with and control robotic systems, in particular pick and place systems using soft robotic actuators to grasp, move and release target objects.