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 sw
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.
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1. A medical manipulator system comprising: a manipulator;a controller connected to the manipulator; anda first resetting switch and a second resetting switch;the manipulator comprising:an operating unit having an actuator, a grip handle for being gripped by a human hand, and an input unit for input
1. A medical manipulator system comprising: a manipulator;a controller connected to the manipulator; anda first resetting switch and a second resetting switch;the manipulator comprising:an operating unit having an actuator, a grip handle for being gripped by a human hand, and an input unit for inputting an operation command;a working unit removably mounted on the actuator and having a shaft and a distal-end working unit mounted on a distal end of the shaft, the distal-end working unit being angularly movable about a pivot axis not parallel to an axis of the shaft in response to operation of the actuator; anda working unit detecting unit for supplying the controller with a signal indicating whether the working unit is present on the operating unit or not;wherein when the working unit is removed from the operating unit and when the actuator is not at an origin, the controller produces a warning, and performs a resetting process to return the actuator to the origin if both of the first resetting switch and the second resetting switch are operated according to a predetermined procedure. 2. A medical manipulator system comprising: a manipulator;a controller connected to the manipulator; anda first resetting switch and a second resetting switch;the manipulator comprising:an operating unit having an actuator, a grip handle for being gripped by a human hand, and an input unit for inputting an operation command, the operating unit being connected to the controller by a connector; anda working unit removably mounted on the actuator and having a shaft and a distal-end working unit mounted on a distal end of the shaft, the distal-end working unit being angularly movable about a pivot axis not parallel to an axis of the shaft in response to operation of the actuator;wherein the controller detects whether the connector is connected or disconnected based on a change in the operation command, and when the connector is disconnected and when the actuator is not at an origin, the controller produces a warning, and performs a resetting process to return an internal signal representing an angle of the actuator to the origin if both of the first resetting switch and the second resetting switch are operated according to a predetermined procedure. 3. A medical manipulator system according to claim 1, wherein the controller is capable of controlling N manipulators, the first resetting switch comprises a single resetting switch shared by the N manipulators, and the second resetting switch comprises N resetting switches corresponding respectively to the N manipulators. 4. A medical manipulator system according to claim 1, wherein the first resetting switch and the second resetting switch are provided in the controller. 5. A medical manipulator system according to claim 1, wherein the second resetting switch has a light-emitting element, and the controller has a function to detect whether the working unit is mounted or removed individually with respect to the N manipulators and to detect an angle of the actuator, and wherein when the first resetting switch is pressed, the controller emits light from the light-emitting element of the second resetting switch corresponding to the manipulator with the working unit removed when the actuator is not at the origin, and the controller resets the manipulator after the second resetting switch whose light-emitting element is emitting light is pressed. 6. A medical manipulator system according to claim 2, wherein the second resetting switch has a light-emitting element, and the controller has a function to detect whether the connector is connected or disconnected individually with respect to the N manipulators and to detect an angle of the actuator, and wherein when the first resetting switch is pressed, the controller emits light from the light-emitting element of the second resetting switch corresponding to the manipulator with the connector disconnected when the actuator is not at the origin, and the controller resets the manipulator after the second resetting switch whose light-emitting element is emitting light is pressed. 7. A medical manipulator system comprising: a manipulator;a controller connected to the manipulator; anda first resetting switch and a second resetting switch;the manipulator comprising:an actuator block including an actuator;a working unit removably mounted on the actuator block and having a shaft and a distal-end working unit mounted on a distal end of the shaft, the distal-end working unit being angularly movable about a pivot axis not parallel to an axis of the shaft in response to operation of the actuator; anda working unit detecting unit for supplying the controller with a signal indicating whether the working unit is present on the operating unit or not;wherein when the working unit is removed from the actuator block and when the actuator is not at an origin, the controller produces a warning, and performs a resetting process to return the actuator to the origin if both of the first resetting switch and the second resetting switch are operated according to a predetermined procedure.
Tierney Michael J. ; Cooper Thomas G. ; Julian Chris A. ; Blumenkranz Stephen J. ; Guthart Gary S. ; Younge Robert G., Surgical robotic tools, data architecture, and use.
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Kerr, Wendy A.; Lytle, IV, Thomas W.; Overmyer, Mark D.; Swensgard, Brett E.; Sackett, Kevin D.; Leimbach, Richard L.; Houser, Kevin L.; Morgan, Jerome R.; Shelton, IV, Frederick E., Surgical instrument system comprising lockable systems.
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