Systems and methods are provided for shape controlled gripping of a workpiece. A layer jamming structure includes a membrane defining an internal cavity containing a number of overlapping material layers. A pressure system includes a pump coupled with the internal cavity. A shape conforming tool includes at least one part configured to move to apply a force to the layer jamming structure. The shape conforming tool, by operation of the part, conforms the layer jamming structure to the workpiece. The pressure system, with operation of the pump, changes a pressure in the internal cavity to impart rigidity to the layer jamming structure.

Systems and methods are provided for shape controlled gripping of a workpiece. A layer jamming structure includes a membrane defining an internal cavity containing a number of overlapping material layers. A pressure system includes a pump coupled with the internal cavity. A shape conforming tool includes at least one part configured to move to apply a force to the layer jamming structure. The shape conforming tool, by operation of the part, conforms the layer jamming structure to the workpiece. The pressure system, with operation of the pump, changes a pressure in the internal cavity to impart rigidity to the layer jamming structure.

An artificial muscle includes a housing having an electrode region, an expandable fluid region, and a pass through region formed between the electrode region and the expandable fluid region. The artificial muscle further includes an electrode pair having a first electrode and a second electrode, at least one of the first electrode and the second electrode including a central opening coaxial with the pass through region and the expandable fluid region, and a dielectric fluid is disposed in the housing. The electrode pair is actuatable between a non-actuated state and an actuated state such that actuation from the non-actuated state to the actuated state directs the dielectric fluid into the expandable fluid region.

A structural load cell case for a pick and place robotic system that prevents torsion, bending, and overloading from damaging sensors is disclosed. The structural load cell case includes a base, an inner tube that houses the load cell, and a roller sleeve outside the inner tube. The base is adapted to connect to a load and includes a compression spring interfaced with a first part of the load cell. The roller sleeve includes a plurality of roller bearings in contact with the inner tube. The inner tube is free to slide along an axis of the roller sleeve up to pre-determined limits, but is constrained from rotating or translating in directions other than the axis of the roller sleeve.

A structural load cell case for a pick and place robotic system that prevents torsion, bending, and overloading from damaging sensors is disclosed. The structural load cell case includes a base, an inner tube that houses the load cell, and a roller sleeve outside the inner tube. The base is adapted to connect to a load and includes a compression spring interfaced with a first part of the load cell. The roller sleeve includes a plurality of roller bearings in contact with the inner tube. The inner tube is free to slide along an axis of the roller sleeve up to pre-determined limits, but is constrained from rotating or translating in directions other than the axis of the roller sleeve.

The present disclosure is directed to systems and methods for simultaneously and concentrically handling cylindrical objects of different diameters. Also, the present disclosure is directed to a handler having a clamp that includes pairs of outer and inner tongs spaced apart on separate sides of the central plane that is orthogonal to a central longitudinal axis of the cylindrical object. Some embodiments may include a clamp having a mounting plate and a piston assembly coupled to the mounting plate where the central plane is parallel to the mounting plate. Some embodiments include a plurality of linkage bars pivotally coupled between the piston assembly and the plurality of outer tongs and inner tongs. In some embodiments, in response to a movement of the piston assembly, the inner and outer tongs pivot between an open position and a closed position to secure the cylindrical object between the inner and outer tongs.

A hub assembly for coupling different grasper assemblies including a soft actuator in various configurations to a mechanical robotic components are described. Further described are soft actuators having various reinforcement. Further described are and soft actuators having electroadhesive pads for improved grip, and/or embedded electromagnets for interacting with complementary surfaces on the object being gripped. Still further described are soft actuators having reinforcement mechanisms for reducing or eliminating bowing in a strain limiting layer, or for reinforcing accordion troughs in the soft actuator body.

A soft actuator includes an inflation chamber. The inflation chamber has a first end and a second end opposite the first end. The inflation chamber is inflatable during an inflation stage, in which the second end rotates toward the first end about a folding axis, and is operable to be loaded during an inflated stage, in which the inflation chamber is inflated. The soft actuator also includes a variable-stiffness hinge located between the first end and the second end along the folding axis. The variable-stiffness hinge has a decreased stiffness in the inflation stage and an increased stiffness in the inflated stage.

Provided is a soft growing robot which may be precisely controlled by reducing the effect of a tail tension applied to its inner periphery. The soft growing robot includes a case having one open side; and a vine including an outer periphery having one end fixed to one side surface of the case, the inner periphery disposed inside the outer periphery while being spaced apart from the outer periphery and extended into the case, a tip connecting the other end of the outer periphery and one end of the inner periphery to each other, and a tip space formed by the outer periphery, the tip and the inner periphery, and a tip space formed by the outer periphery, the tip and the inner periphery. A diameter of the tip is smaller than a diameter of the outer periphery to a bent portion between the tip and the outer periphery.

An arm module has a housing with a first connection side and a second connection side. The first connection side is embodied to be controllably rotatable about an axis of rotation relative to the second connection side. The first connection side has a rotatable first connection device and the second connection side has a second connection device fixed to the housing. A multifunctional rotation transfer system is provided for rotational transmission of data signals, electrical energy and fluid. A drive device is provided comprising a shaft assembly having an output shaft, which is connected to the rotatable first connection device of the first connection side in a torque-proof manner, wherein the shaft assembly forms a section of the multifunctional rotation transfer system.