A robot includes a spin body, and a drive motor, a spin motor, and a PCB connected electrically to the spin motor and the drive motor mounted on the spin body. Accordingly, the spin motor, the driving motor, and the PCB are rotated together with the spin body, so that relative movement does not occur between the PCB and the respective motors, and tangling or twisting of the connection member electrically connecting the respective motors and the PCB does not occur.

A compact robotic device for driving movement of two or more elongate surgical tools configured for a telescopic arrangement when said two or more elongate surgical tools are at least partially received within said device, the device comprising: a housing comprising walls which define an inner volume including at least two inner pathways for accommodating the two or more elongate surgical tools; the housing encasing: a plurality of motors, and two or more tool actuation assemblies configured at a position of each of the two or more inner pathways; the actuation assemblies driven by the plurality of motors and configured to operably contact an elongate surgical tool at least partially received in the inner pathway to at least one of advance, retract and/or roll said elongate surgical tool.

An assembly for driving linear movement and roll movement of an elongate surgical tool, comprising: an elongate shaft comprising a central lumen extending along the shaft long axis; the elongate shaft comprising a plurality of apertures extending across walls of the elongate shaft and into the central lumen; a set of wheels positioned opposing each other and aligned on two sides of the central lumen, the set of wheels at least partially extending through the apertures beyond the walls of the elongate shaft and into the central lumen to contact an elongate surgical tool received therein; the set of wheels being coupled to the elongate shaft and configured to rotate with the elongate shaft as a single unit when the elongate shaft is rotated about the shaft long axis.

A surgical implant planning computer for intra-operative CT workflow, pre-operative CT imaging workflow, and fluoroscopic imaging workflow. A network interface is connectable to a CT image scanner and a robot surgical platform having a robot base coupled to a robot arm that is movable by motors. A CT image of a bone is received from the CT image scanner and displayed. A user's selection is received of a surgical screw from among a set of defined surgical screws. A graphical screw representing the selected surgical screw is displayed as an overlay on the CT image of the bone. Angular orientation and location of the displayed graphical screw relative to the bone in the CT image is controlled responsive to receipt of user inputs. An indication of the selected surgical screw and an angular orientation and a location of the displayed graphical screw are stored in a surgical plan data structure.

A robotic surgical system includes a robotic arm, a carriage coupled to the robotic arm, a drive belt, and a motor supported by the carriage. The carriage rotatably supports an instrument rotation pulley and a motor axis pulley. The drive belt is coupled to the instrument rotation pulley and the motor axis pulley. The motor includes a coupling that is driven by the motor upon an actuation of the motor. The coupling is engaged with the motor axis pulley such that rotation of the motor axis pulley rotates the drive belt to rotate the instrument rotation pulley.

A robotic surgical system includes a robotic arm, a carriage coupled to the robotic arm, a drive belt, and a motor supported by the carriage. The carriage rotatably supports an instrument rotation pulley and a motor axis pulley. The drive belt is coupled to the instrument rotation pulley and the motor axis pulley. The motor includes a coupling that is driven by the motor upon an actuation of the motor. The coupling is engaged with the motor axis pulley such that rotation of the motor axis pulley rotates the drive belt to rotate the instrument rotation pulley.

Provided is a robot system that can accurately sense contact between an arm of a robot or an instrument attached to the arm and another object. The robot system includes: a robot main body 22 and a robot control unit 21, the robot main body 22 including: a motor 8; a deceleration device 19 connected to a motor shaft 17 of the motor 8; an arm 15 connected to an output shaft 16 of the deceleration device 19; a motor shaft-side angular sensor 1 capable of detecting an angle of rotation of the motor shaft 17 of the motor 8; and an output shaft-side angular sensor 2 capable of detecting an angle of rotation of the output shaft 16 of the deceleration device 19, and the robot control unit 21 being configured to detect a contact state between the arm 15 or an instrument attached to the arm 15 and another object, based on a motor shaft-side rotation angle detected by the motor shaft-side angular sensor 1, an output shaft-side rotation angle detected by the output-side angular sensor 2, and an angular sensor misalignment correction value for the motor shaft-side angular sensor 1 and the output shaft-side angular sensor 2.

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 semi-automatic precision positioning robot apparatus and method for use of the same to hold, position, orient and/or move a workpiece are provided. The positioning apparatus utilizes an actuator system of a given configuration to manipulate a workpiece holding unit with multiple degrees of freedom to achieve various positions and orientations. An associated took may further be provided to interact with the workpiece in various positions and orientations. The positioning apparatus enables an operator to obtain high degrees of maneuverability while maintaining precision and consistency in the manufacture and production of various products and components.

A compact robotic device for driving movement of two or more elongate surgical tools configured for a telescopic arrangement when said two or more elongate surgical tools are at least partially received within said device, the device comprising: a housing comprising walls which define an inner volume including at least two inner pathways for accommodating the two or more elongate surgical tools; the housing encasing: a plurality of motors, and two or more tool actuation assemblies configured at a position of each of the two or more inner pathways; the actuation assemblies driven by the plurality of motors and configured to operably contact an elongate surgical tool at least partially received in the inner pathway to at least one of advance, retract and/or roll said elongate surgical tool.