1460718899-4e69bf23-720f-447a-a92b-1c4f524388f9

1. A medical device delivery system comprising:
a manifold having a rack and pinion, the rack slidable in a proximal direction;
an inner tube having a proximal end and a distal end, the inner tube extending distally from the manifold;
a retractable sheath disposed about the distal end of the inner tube; and
a pull-wire extending proximally from the retractable sheath to the manifold, the pull wire attached to the pinion.
2. The medical device delivery system of claim 1 wherein the rack is movable in a distal direction.
3. The medical device delivery system of claim 1 wherein the retractable sheath is retracted by moving the rack in the proximal direction.
4. The medical device delivery system of claim 1 wherein the retractable sheath is retracted by moving the rack in the distal direction.
5. The medical device delivery system of claim 1 wherein the manifold comprises a first part and a second part, the first part movably received in the second part, the pinion disposed in the first part and the rack disposed in the second part.
6. The medical device delivery system of claim 1 further comprising a stent disposed about the inner tube and covered by the retractable sheath.
7. The medical device delivery system of claim 1 wherein the pinion comprises a gear portion and a spool portion for taking up the pull wire.
8. The medical device delivery system of claim 7 wherein the pull wire is wound around the spool portion when the rack is moved in a proximal direction.
9. The medical device delivery system of claim 1 wherein the pinion is movable in a proximal direction.
10. The medical device delivery system of claim 1 wherein the retractable sheath is retracted by moving the pinion in the proximal direction.
11. The medical device delivery system of claim 1, the pinion comprising a gear portion and a shaft portion in rotational cooperation with the gear portion, wherein the pull-wire is attached to the shaft portion.
12. The medical device delivery system of claim 11, wherein the shaft portion is spool-like and takes up the pull-wire when the gear portion rotates.

The claims below are in addition to those above.
All refrences to claim(s) which appear below refer to the numbering after this setence.

1. A robot teaching apparatus for moving a robot so as to obtain desired position and orientation and teaching the position and orientation of said robot after the movement, said robot teaching apparatus comprising:
a copying control means for detecting or estimating an external force applied to said robot and moving said robot based on the detected or estimated external force;
an enabling region setting means for setting an enabling region in which movement of said robot by said copying control means is enabled; and
a means for enabling the copying control by said copying control means when said robot is located in the set enabling region.
2. The robot teaching apparatus according to claim 1, wherein said robot teaching apparatus further comprises a copying control setting means for setting a restriction that the copying control be carried out in the enabling region for only one or both of movement in a predetermined direction and a change in orientation around a predetermined axis, and said copying control means executes the copying control according to the set restriction.
3. The robot teaching apparatus according to claim 1, wherein said enabling region setting means sets the enabling region based on positions of teaching points defined in a previously prepared model teaching program or positions of previously designated teaching points and an index representing the size of the region.
4. The robot teaching apparatus according to claim 3, wherein said copying control means executes the copying control only in a direction of a line segment connecting adjoining teaching points defined in said model teaching program when a control point of said robot is located at any teaching point defined in said model teaching program or on said line segment connecting said adjoining teaching points, so that said copying control means guides the movement of said robot between said adjoining teaching points along said line segment.
5. The robot teaching apparatus according to claim 4, further comprising a means for making the operator recognize that said robot has approached one of said teaching points by once stopping the copying control when said robot approaches within a predetermined distance of said one of said teaching points while executing the copying control in only the direction of said line segment connecting adjoining teaching points, and by then automatically restarting the copying control.
6. The robot teaching apparatus according to claim 4, further comprising a means for displaying a block in said model teaching program corresponding to one of said teaching points which said robot is heading toward or one of said teaching points approached within a predetermined distance, while executing the copying control in only the direction of said line segment connecting adjoining teaching points.
7. The robot teaching apparatus according to claim 3, wherein the positions of said teaching points defined in said model teaching program is corrected to prepare a corrected teaching program which is used as a new model teaching program.
8. The robot teaching apparatus according to claim 1, wherein said copying control means estimates an external force based on one or both of torques and speeds of motors for driving axes of said robot and automatically move said robot in a direction where the estimated external force becomes smaller.
9. The robot teaching apparatus according to claim 1, wherein said copying control means detects an external force by a force sensor attached to said robot and automatically moves said robot in a direction where the detected external force becomes smaller.
10. The robot teaching apparatus according to claim 1, wherein said copying control means measures an acceleration by an acceleration sensor attached to said robot, estimates an external force applied to said robot based on the measured acceleration and dynamic parameters including a mass and inertia moment, and automatically moves said robot in a direction where the estimated external force becomes smaller.
11. The robot teaching apparatus according to claim 1, wherein a teaching handle having a deadman’s switch and a position teaching key is attached to said robot, and the operator applies an external force to said teaching handle.