A sterile interface module for coupling an electromechanical robotic surgical instrument to a robotic surgical assembly is provided. The surgical instrument includes an end effector and is configured to be actuated by the robotic surgical assembly. The sterile interface module includes a body member and a drive assembly. The body member is configured to selectively couple the surgical instrument to the robotic surgical assembly. The body member is formed of a dielectric material. The drive assembly is supported within the body member and is configured to transmit rotational forces from the robotic surgical assembly to the surgical instrument to actuate the surgical instrument to enable the surgical instrument to perform a function.

A horizontal articulated robot is provided, which includes a first connecting part disposed between two of the arms and rotatably connecting the other arm to one arm, a second connecting part disposed between a pedestal and the arm and rotatably connecting the arm to the pedestal, and a ring member disposed between the first connecting part and the arm and formed so that, as compared with one of end part sides in an extending direction of the arms, a height dimension thereof becomes larger at the other end part side.

Various embodiments of the present technology generally relate to robotics. More specifically, some embodiments of the present technology relate to an integrated system design for a mobile manipulation robot with socially expressive abilities. Some embodiments provide for a robot comprising a socially expressive head unit. The head can have at least two degrees of freedom created by a motor with a planetary gear box and a servo. The motor can be connected to a shell via a support that allows the shell to tilt up and down upon activation of the motor. The shell can include a camera housing configured to receive a camera which can be attached to the support. The motor can be mounted on a rotatable shaft controlled by a servo causing the head unit to pan.

A gear device includes an internal gear, an external gear having flexibility configured to partially mesh with the internal gear and relatively rotate around a rotation axis with respect to the internal gear, a bearing disposed at an inner side of the external gear, and a cam section having an elliptical shape disposed at an inner side of the bearing and configured to move a meshing position of the internal gear and the external gear in a circumferential direction around the rotation axis. The bearing is deformed in an elliptical shape by the cam section and includes a plurality of balls disposed side by side in the circumferential direction and a holder including a plurality of partition walls disposed alternately with the balls in the circumferential direction and holding the balls. A gap is provided between the ball located on a major axis of the bearing and the partition wall adjacent to the ball in the circumferential direction. The ball located on a minor axis of the bearing is in contact with each of the partition walls adjacent to the ball at both sides in the circumferential direction.

A programmable motion system is disclosed that includes a dynamic end effector system. The dynamic end effector system includes an end effector that is coupled via a dynamic coupling to the programmable motion system, wherein the dynamic coupling provides that at least a portion of the end effector may spin with respect to an other portion of the end effector.

A system for use in surgery includes a central body, a visualization system operably connected to the central body, a video rendering system, a head-mounted display for displaying images from the video rendering system, a sensor system, and a robotic device operably connected to the central body. The visualization system includes at least one camera and a pan system and/or a tilt system. The sensor system tracks the position and/or orientation in space of the head-mounted display relative to a reference point. The pan system and/or the tilt system are configured to adjust the field of view of the camera in response to information from the sensor system about changes in at least one of position and orientation in space of the head-mounted display relative to the reference point.

A speed reducer and a robot are disclosed. The speed reducer includes a rigid wheel, a flexible wheel and a flexible bearing; the rigid wheel is provided with a first fitting position and an inner wheel tooth set; the outer peripheral surface of a peripheral wall of the flexible wheel is provided with an outer wheel tooth set; in the axial direction of the rigid wheel, the tooth top of the outer wheel tooth set is provided with a first length, and the tooth root of the outer wheel tooth set is provided with a second length; the tooth top of the inner wheel tooth set is provided with a third length; the flexible bearing is provided with a fourth length; the second length and the third length are both greater than the first length, and the fourth length is greater than the second length.

A rotatable cushioning pick-and-place device primarily comprises a motor, a body, a cushioning module and a pick-and-place module. The cushioning module is disposed in a first chamber of the body and comprises a rotary bearing which is connected to a drive shaft of the motor, and coupled to a driven shaft sleeve through a rotary follower. The rotary follower is driven by the rotary bearing to drive the driven shaft sleeve to rotate, thereby allowing the rotary bearing to displace relative to the driven shaft sleeve axially. The cushioning spring is arranged between the rotary bearing and the driven shaft sleeve. A first sealing ring and a second sealing ring of the pick-and-place module are fixed on the body to cooperatively and air-tightly seal the second chamber.

An articulated structure includes first and second members, and an actuator relatively rotating the first and second members about a first axis and including a motor fixed in the first member, a reducer transmitting rotation of the motor to the second member, and a mechanism transmitting power of the motor to the reducer, the reducer includes a hole extending therethrough along the first axis, and an input member supported rotatably about the first axis to receive the power. The mechanism includes a first section including an output member supported rotatably about a second axis parallel to the first axis to transmit power to the input member, a second section transmitting power between a shaft of the motor and the output member, and a housing that houses the second section to support the motor and being detachably attached to the first member at a position offset radially outward from the hole.

A high-performance four-axis robot (1) with horizontal joints includes a robot body (11), a first arm assembly (12) connected to the robot body 11, a second arm assembly (13) that one end thereof is connected to the first arm assembly, and a R-axis rotation assembly arranged at the other side of the second arm assembly opposite to the first arm assembly. Assembly of the robot body includes a linear assembly unit (115) arranged in a vertical direction, a fixed seat (111) capable of moving up and down along the linear assembly unit, and a drive assembly (14) configured to drive the fixed seat to move and arranged at a lower portion of the linear assembly unit. The drive assembly includes a first drive motor (141) arranged at the lower portion of the linear assembly unit and a coupling (142) connected to an output shaft of the first drive motor.