A self-contained robotic arm system includes: an operating platform; a robotic arm subsystem coupled to the operating platform; a control subsystem coupled to the operating platform and configured to effectuate movement of the robotic arm assembly; and a power subsystem including an internal battery system that is configured to provide electrical power to the robotic arm subsystem and the control subsystem.

A self-contained robotic arm system includes: an operating platform; a robotic arm subsystem coupled to the operating platform; a control subsystem coupled to the operating platform and configured to effectuate movement of the robotic arm assembly; and a power subsystem including an internal battery system that is configured to provide electrical power to the robotic arm subsystem and the control subsystem.

A robotic surgical system includes a fluid drive system and a surgical instrument removably positioned in operative engagement with the drive system. A sterile barrier covers non-sterile portions of the surgical system. Features of the sterile barrier are used to transfer motion output from the fluid drive system to the instrument for actuation of the instrument.

A robotic surgical system includes a fluid drive system and a surgical instrument removably positioned in operative engagement with the drive system. A sterile barrier covers non-sterile portions of the surgical system. Features of the sterile barrier are used to transfer motion output from the fluid drive system to the instrument for actuation of the instrument.

A method of facilitating switching of a quasi-passive elastic actuator of a tunable actuator joint module of a robotic system between an inelastic state and an elastic state comprising configuring a quasi-passive elastic actuator to be operable with a primary actuator of the tunable actuator joint module to selectively apply an augmented torque to assist the primary actuator in rotation of a joint of the tunable actuator joint module. The method further comprises configuring an elastic component of the quasi-passive actuator to comprise a first vane device and second vane device rotatable relative to each other within a housing, supporting a valve assembly about the axis of rotation of the joint through the first vane device, and configuring a shunt circuit to facilitate fluid flow between compression and expansion chambers through the valve assembly. The method can further comprise configuring the valve assembly with a valve device disposed in an opening of a shaft of the first vane device, the valve device being actuatable between an open position to open the shunt circuit and a closed position to close the shunt circuit.

A robot end effector for dispensing an extrudable substance comprises a chassis and cartridge bays, attached to the chassis and each shaped to receive a corresponding one of two-part cartridges. Robot end effector also comprises a dispensing valve, attached to the chassis and comprising a valve inlet and a valve outlet in selective fluidic communication with the valve inlet. Robot end effector further comprises a manifold, comprising a manifold outlet and manifold inlets. The manifold outlet is in fluidic communication with the valve inlet. Robot end effector additionally comprises a plunger assembly, comprising pairs of plungers. Plunger assembly is arranged to concurrently extrude contents of the two-part cartridges through the cartridge outlets when the two-part cartridges are received by the cartridge bays. Robot end effector also comprises a non-rotating linear pneumatic actuator, configured to selectively move the plunger assembly relative to the chassis.

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.

The invention relates to a device for positioning in the proximity of a joint between two portions, the device comprising a first interface (11) carried by a first of the two portions and a second interface (12) carried by a second of the two portions, the device including at least one connection between the first interface and the second interface, the connection comprising a double cylinder having two chambers that are connected together by a floating piston, the first of the two chambers being connected to the first interface and a second of the two chambers being connected to a drive rather of the double cylinder, said rod being connected to the second interface.

The invention also relates to a system including such a device.

A soft robot includes a main body configured as a tube inverted back inside itself to define a pressure channel, such that when the channel is pressurized, the main body everts, and inverted material everts and passes out of a tip at a distal end of the main body. A fluidization tube for passing air or other fluid through a core of the main body in the fluidization tube, wherein the fluidization tube engages the main body such that the fluidization tube is ejected as the distal end as the main body everts and joins part of the side of the main body as the main body everts and extends its distal tip.

The invention disclosure a remotely operated pneumatic manipulator based on Kinect, comprising Kinect sensor, computer, D/A embedded board, PWM piezoelectric pneumatic ratio valve, pneumatic triad, air compressor, artificial muscle, spring and finger joint, wherein the Kinect sensor is provided on one side of the finger joint, a camera module of the Kinect sensor is faced to the finger joint. The pneumatic humanoid manipulator of the invention has basically the same dimensions as human hands, can achieve human-computer interaction and remotely operation, the transmission structure thereof is novel, simple and compact, the fingers thereon are convenient to control and flexible to move, the finger movement range is large for wide application, moreover, the PWM piezoelectric pneumatic ratio valve is with advantages of fast dynamic response, low cost, strong resistance to noise, and high detection accuracy of Kinect sensor.