A parallel type integrated actuator is proposed. The actuator includes: a driving unit composed of a plurality of motors, each motor being stacked successively in a longitudinal direction of the driving unit, each motor having a stator fixed to a position outside the driving unit and a rotor positioned inside thereof, each motor rotating relative to each other; a plurality of shafts; a heat sink housing having a cylindrical shape formed around the outer surface of the driving unit, and having an inner circumferential surface thereof thermally connected with the plurality of stators and a plurality of flow paths formed on the outer circumferential surface thereof; and a blower fan installed on one end side of the driving unit, provided with a wing part disposed to be adjacent to one end side of the heat sink housing, wherein rotation generates convection for heat exchange.

There is provided a spherical mechanism robot assembly for accessing a confined space in a vehicle, to perform confined space operation(s) in the vehicle. The assembly includes a base structure configured for attachment to the vehicle. The assembly includes a spherical mechanism structure having a first end attached to the base structure, and having a second end. The spherical mechanism structure includes a plurality of mechanical links, joints coupling the plurality of mechanical links together, and a plurality of actuators having one or more actuators coupled at each joint of the plurality of joints. The assembly includes an end effector attached to the second end of the spherical mechanism structure. The assembly is configured such that a majority portion remains outside of the confined space, while a remaining portion of the assembly accesses and occupies the confined space in the vehicle, to perform the confined space operation(s) in the vehicle.

A robot arm comprising a number N of actuator-drivable joint connections GV.sub.n, which are connected in series via arm links GL.sub.i, where n=1, 2, . . . , N, and i=1, 2, . . . , N1, and N6, wherein the robot arm is configured in such a way that the axes of rotation R.sub.GV,N-2 and R.sub.GV,N-1 of each of joint connections GV.sub.N-1, GV.sub.N-2 intersect at an angle in the range from 50 to 130, an axis of rotation R.sub.GV,N of joint connection GV.sub.N, is arranged radially at a constant distance D1 from the axis of rotation R.sub.GV,N-1, and a sensor is present in the joint connection GV.sub.N-1 to detect a force or a torque about the axis of rotation R.sub.GV,N-1.

A robotic arm according to various implementations includes: a tool driver configured to hold a surgical tool; a first section comprising a first end coupled to a base, a second end distal from first end; a first link that includes a motor configured to rotate at least a portion of the first section around a pitch axis; a second link coupled to the first link, the second link including a motor configured to rotate at least a portion of the first section around a roll axis; and a second section comprising: a first end coupled to the second end of the first section, a second end distal from the first end, a first link that includes a motor configured to rotate at least a portion of the second section around a roll axis, a second link coupled to the first link.

A computing device comprises a memory and a control unit coupled to the memory. The control unit is configured to receive a patient model and identify a plurality of port locations on the patient model for accessing a workspace using a plurality of instruments controlled by a computer-assisted device. For each of the port locations, the control unit determines a collision volume for portions of the computer-assisted device proximal to the port location, a reachability metric, and an anthropomorphic metric. For each combination of the plurality of port locations, the control unit determines a collision metric based on overlaps of the collision volumes for the port locations in the combination, and an aggregate metric for the combination. The control unit is also configured to display one or more of the combinations of the plurality of port locations to a user along with a corresponding aggregate metric.

A robot arm with a robot-hand drive device, which has at least three electric motors arranged in an arm boom of the robot arm for driving a multi-axis robot hand of the arm boom, each electric motor having an electric rotor, each of which has a motor shaft. The at least three electric motors are arranged in the interior of a common housing cylinder block, in such a way that each rotor lies in a separate cylinder sector of the housing cylinder block, more specifically with its respective motor shaft running parallel to the center axis of the housing cylinder block, said axis running longitudinally along the arm boom.

Provided is a robot wrist structure provided with a first wrist element, a second wrist element, and a third wrist element. The first wrist element is provided with a casing having a hollow structure, two driving motors that drive the second wrist element and the third wrist element, and a conduit member that allows wiring to pass therethrough from an arm-side to a second-wrist-element-side in a direction along a first axis. A first opening and a second opening are provided in a first side wall and a second side wall that are positioned on either side of a reference plane. The first opening is large enough to allow the driving motors to pass therethrough. Centers of rotation shafts of the two driving motors are disposed between the first side wall and the reference plane. The conduit member is disposed between the second side wall. The wiring bypasses the driving motors.

A linear extension and retraction mechanism includes a plurality of flat-plate shaped first pieces that are connected to each other, and a plurality of second pieces having a cross-sectional U-shaped groove frame shape that are connected to each other. A leading first piece of the plurality of first pieces and a leading second piece of the plurality of second pieces are joined by a head section. The first and second pieces become linearly rigid when the first pieces are joined to an upper part of the second pieces, and the first and second pieces return to a bent state when separated from each other. Protrusion sections that protrude inward are extended in the width direction in a bottom plate of each second piece. Corners of edge parts of the protrusion sections are chamfered.

A robot comprising an arm extending between a base and an attachment for an end effector, the arm comprising: a first arm part; a second arm part distal of the first arm part; and a joint whereby the first and second arm parts are coupled together, the joint permitting the first and second arm parts to rotate relative to each other about at least two mutually offset axes; a control rod attached to the second part of the arm at a location spaced from the first and second axes, the control rod extending distally of that location along the first arm part; and a drive mechanism for driving the control rod to move relative to the first arm part and thereby alter the attitude of the second arm part relative to the first arm part.

A portable work module includes a combination of prismatic and revolute joints for positioning and orienting a robotic end effector for performing a task within confined space. For example, the portable work module may include telescoping arm integrated with wrist having a plurality of degrees of freedom with respect to telescoping arm. The portable work module includes an insert that is secured with respect to an access port of confined space, said access port serving as a reference location for calculating the position of the robotic end effector within confined space. The portable work module is configured to have a compacted configuration for insertion into confined space, and an extended configuration for performing tasks within confined space. In some examples, the portable work module is modular, such that the robotic end effector or other components may be selectively removed and replaced.