Abstract: A medical manipulator system includes a manipulator, an operating unit for entering operation commands, motors for actuating a working unit, and a controller for energizing the motors based on operation commands supplied from the operating unit. When an activation resetting switch and a resetting switch are operated according to a predetermined procedure, the controller performs a resetting process to return the motors to an origin. The controller is capable of controlling three manipulators. The activation resetting switch is shared by the three manipulators, and there are three resetting switches corresponding to the three manipulators.

Abstract: A medical manipulator system has an operating unit including a grip handle and a composite input unit, a working unit detachably mounted on the operating unit and including an end effector, and a controller for controlling the operating unit. The controller judges starting and ending of a surgical case and increments the usage count of the working unit based on a manner in which the working unit is mounted and dismounted, and the times at which the working unit is mounted and dismounted, and disables the working unit if the usage count of the working unit exceeds a preset count.

Abstract: A manipulator has a working unit including an end effector and a posture axis for changing the orientation of the manipulator, a compound mechanism provided on the working unit, and a controller for actuating a gripper axis, a yaw axis, and a roll axis by respectively controlling movement positions of three motors. The controller includes a torque generation detector for detecting a timing at which torque is generated on the gripper axis. When the controller detects the timing at which a torque ?g? is generated on the gripper axis under operation of a given motor, the movement positions of the plural motors are shifted and set, corresponding to the directions at which interference torques are generated with respect to the yaw axis and the roll axis, and to predetermined positions of the same directions.

Abstract: In a manipulator, an actuator block contains motors and rotary shafts extending from the motors. A working unit of the manipulator contains a connecting portion, attachable to and detachable from the actuator block. The connecting portion has pulleys connectable to ends of the rotary shafts, and has a locking plate movable by alignment pins. The locking plate has slits, which are engaged with plate-shaped portions formed on the upper ends of the pulleys. A coil spring is placed between the locking plate and a top plate.

Abstract: A working unit includes a gear body disposed forwardly of a tubular member around which a wire is wound and having a rotational axis disposed substantially parallel to the tubular member, and a first gear and a second gear for transmitting rotation of a gear body to another gear body. The numbers of turns of wires, the size of a main shaft, and the size of a gear body, which are positioned forwardly of the tubular member, have no adverse effect on the manner in which a wire is wound around the tubular member. The wire can be wound around the tubular member over a wide region thereof for increasing the angular displacement of the gear body. The increased angular displacement of the gear body makes it possible to increase the angular displacement and rotational torque of the gear body.

Abstract: A robot has a flexible power transmission member, an input rotation axis rotated by a power generation source, a driving link connected at both ends of the flexible power transmission member, which transmits a rotation torque of the input rotation axis to the flexible power transmission member, and a driven pulley around which the flexible power transmission member is hung.

Abstract: A medical robot system includes a forceps arm provided with a forceps manipulator and a camera arm provided with an endoscope. The forceps manipulator and the endoscope are inserted into a living body through a common insertion implement. The system further includes an operating unit that generates a control signal to control the forceps manipulator and the forceps arm, a forceps motion control unit that controls motions of the forceps manipulator and the forceps arm according to the control signal from the operating unit, an endoscope motion control unit that controls motions of the endoscope and the camera arm, and an interference avoiding unit that controls an interference avoiding motion of the camera arm to avoid interference between the camera arm and the forceps arm while a visual point of the endoscope is kept constant.

Abstract: A medical manipulator system includes a manipulator including a working unit having a distal end at which an end effector for carrying out working is provided and an operating unit including an operating input unit for being operated for an input and a driving source for operating in response to contents of an operation of the operating input unit to drive the end effector, the working unit being removably attached to the operating unit. A controller to which the operating unit can be connected controls at least the driving source. A use history retaining unit is adapted to retain use history data for each working unit.

Abstract: A manipulator has a working unit in which when at least a first end effector finger and a second end effector finger are maximally closed on each other, at least the distance between a third joint axis and a first joint axis is greater than the distance between the first joint axis and a distal end of the second end effector finger, or the distance between the third joint axis and the first joint axis is greater than the distance between third joint axis and a second joint axis, or the angle formed between a direction from the third joint axis to the first joint axis and a direction from the third joint axis to the second joint axis is not ?.

Abstract: A working unit comprises a gear body rotatable in a direction perpendicular to a reference axis, a gear ring including a proximal end surface held in contact with the gear body and rotatable about the reference axis to change the direction of rotation of the gear body, a first end effector body held in contact with an axially distal end surface of the gear ring at an upper portion thereof, and rotatable about a rotational axis perpendicular to the reference axis to change the direction of rotation of the gear ring, and a second end effector body held in contact with the axially distal end surface of the gear ring at a lower portion thereof, and rotatable in a direction opposite to the direction in which the first end effector body rotates, about the rotational axis. The first end effector body and the second end effector body are openable and closable symmetrically with respect to the reference axis.

Abstract: A medical manipulator comprises a working unit (10) that performs operations, an operating unit (20) that generates instructions, a drive unit (50) that drives the working unit on the basis of instructions given thereto by the operating unit, a power transmission mechanism (60) for transmitting driving force of the drive unit to the working unit, and a control unit (40) for controlling the power transmission mechanism on the basis of instructions given thereto by the operating unit. The power transmission mechanism includes a first power transmission unit (61) interlocked with the drive unit, and a second power transmission unit (63) interlocked with the working unit and capable of being detachably connected to the first power transmission unit. A back drive torque of the first power transmission unit is larger than a back drive torque of the second power transmission unit.

Abstract: A power transmission mechanism comprising: a flexible power transmission element; a pair of a drive pulley and a driven pulley on which the flexible power transmission element is wound, each the pulley having a pin-embedding hole formed to extend from the outer circumferential thereof toward the center thereof, and a slit elongated in the circumferential direction of the pulley to extend to opposite sides of the embedding hole and communicating with the embedding hole; and a pair of columnar or tapered anchor pins each having a path hole penetrating the anchor pin across the lengthwise direction thereof to receive the flexible power transmission element inserted therein, wherein each the anchor pin receiving the flexible power transmission element in the path hole thereof is embedded in the embedding hole of the associated pulley under pressure, and the flexible power transmission element is thereby held on the pulley.

Abstract: Scissors on the distal end of a medical instrument are assembled highly accurately for cutting an object with ease. A scissors mechanism is assembled as a unit. The scissors mechanism has a pair of end effector members openably and closably fastened at proximal ends thereof by a bolt and nuts, while being held in a predetermined sliding state. The bolt has a central hole defined axially therethrough. The scissors mechanism is inserted into a tubular structure of a cover, which is coupled to the distal end of a joint shaft, and the end effector members are connected to a driven plate by links. A spacer is placed in a gap between the scissors mechanism and an inner surface of the cover. A pin is inserted, from an outer surface of the cover, into a hole of the cover and the central hole of the bolt.

Abstract: A medical manipulator is provided. The medical manipulator includes an end effector that is configured to perform motions with respect to at least two different axes, and that is inserted in a body cavity during operation of the medical manipulator. The medical manipulator also includes at least two cylindrical motors that each include a longitudinal axis and that drive at least a part of the end effector. The motors remain outside a living body during operation of the medical manipulator and the motors are mounted on at least one bracket. A shaft interconnects the bracket and the end effector. A longitudinal axis of the shaft extends substantially parallel to each of the longitudinal axes of the motors.

Abstract: A medical manipulator includes a wire movable in opposite directions, a driven wire having both ends thereof connected to the wire, an end effector of a distal-end working unit, a transmitting member, a crescent driven member integral with the transmitting member, and a return pulley. The transmitting member, the crescent driven member, and the return pulley are successively arranged in this order from the proximal end of the medical manipulator. When the driven wire is moved in opposite directions, the transmitting member also moves in opposite directions. At this time, the crescent driven member moves toward the return pulley, and the proximal-end portion of the return pulley enters a cavity of the crescent driven member.

Abstract: A blood treatment method using high-degree-of-freedom forceps. The forceps main body includes a joint portion and a tip working portion provided on a distal end portion, a handle provided on a proximal end, which is held and manipulated, and an input portion provided on the handle. The controller drives the joint portion and the tip working portion with at least 2 degrees of freedom and in response to an input to the input portion. In the blood vessel treatment method, a membranous tissue covering a blood vessel is incised, the blood vessel is detached from the tissue, a branch is cut off from the blood vessel, or a peripheral side of the blood vessel is cut off, by respective inputs to the input portion, in the state where a distal side of the forceps main body is inserted into the body cavity.

Abstract: A power transmission mechanism comprising: a flexible power transmission element; a pair of a drive pulley and a driven pulley on which the flexible power transmission element is wound, each the pulley having a pin-embedding hole formed to extend from the outer circumferential thereof toward the center thereof, and a slit elongated in the circumferential direction of the pulley to extend to opposite sides of the embedding hole and communicating with the embedding hole; and a pair of columnar or tapered anchor pins each having a path hole penetrating the anchor pin across the lengthwise direction thereof to receive the flexible power transmission element inserted therein, wherein each the anchor pin receiving the flexible power transmission element in the path hole thereof is embedded in the embedding hole of the associated pulley under pressure, and the flexible power transmission element is thereby held on the pulley.

Abstract: A manipulator has a treating portion, a driving portion which are connected by a connecting portion, a first pulley on which a first wire which passes through inside of the connecting portion and is driven by the driving portion is hung for rotation, and a main shaft portion which rotatably supports the treating portion around a main shaft along a direction different from a first rotor axis that the first pulley rotates, one end portion of which is fixed to the first pulley.

Abstract: A medical manipulator system includes a manipulator including a working unit having a distal-end working unit, the attitude of which can be changed by a motor, and a controller for controlling the manipulator. When the controller performs an origin return process for moving a gripper of the distal-end working unit to an origin position at an end of an operating range thereof, the controller issues a first control target value to the motor indicative of a virtual position beyond the origin. Thereafter, the controller issues a second control target value to the motor indicative of the origin. The first control target value represents a position, which is over from the origin P0 by a distance greater than a value corresponding to an error ? between a control target position for the gripper and the actual position thereof.

Abstract: A manipulator has a treating portion, a driving portion which are connected by a connecting portion, a first pulley on which a first wire which passes through inside of the connecting portion and is driven by the driving portion is hung for rotation, and a main shaft portion which rotatably supports the treating portion around a main shaft along a direction different from a first rotor axis that the first pulley rotates, one end portion of which is fixed to the first pulley.