Climbing robot with compliant pinion drive

We claim: 1. A mobile robot configured to travel in a vertical or inclined passage within an automated retrieval and storage system, the passage comprising a linear drive mount, the mobile robot comprising: a compliant drive assembly for moving the mobile robot in the passage, the compliant drive assembly comprising: a hub comprising at least one set of recirculating balls; a shaft comprising a grooved portion including at least one race portion configured to mate with the at least one set of recirculating balls of the hub, the shaft configured to be rotated about an axis of rotation and the hub configured to engage the shaft by the at least one set of recirculating balls of the hub engaging the at least one pair of race portions of the shaft, the shaft further configured to be extended axially along the axis of rotation; a drive gear mounted on an end of the shaft, the drive gear configured to move into engagement with the linear drive mount; wherein the at least one set of recirculating balls is configured to engage the at least one pair of race portions of the shaft such that rotational play between the hub and the shaft is permitted, the rotational play allowing a degree of free rotation of the drive gear relative to the linear drive mount to prevent jamming of the drive gear against the linear drive mount when the drive gear moves into engagement with the linear drive mount upon extension of the shaft. 2. The mobile robot of claim 1 , the at least one set of the recirculating balls comprises a pair of diametrically opposed sets of the recirculating balls. 3. The mobile robot of claim 1 , wherein the hub is configured to mount to a wheel of the mobile robot, wherein the wheel is configured to support the mobile robot as the mobile robot moves horizontally. 4. The mobile robot of claim 1 , wherein the hub is configured to move axially on the shaft. 5. The mobile robot of claim 1 , wherein a portion of each one of the race portions includes a portion that is wider than other portions of the race portions to allow the degree of free rotation of the drive gear relative to the linear drive mount. 6. The mobile robot of claim 1 , wherein each race portion of the race portions includes a lead-in to facilitate a smooth transition between the hub and the race portion. 7. The mobile robot of claim 1 , wherein the shaft further includes a pinion mounting portion. 8. The mobile robot of claim 7 , the drive gear comprises a pinion and the linear drive mount comprises a rack comprising teeth configured to mesh with gear teeth of the pinion. 9. The mobile robot of claim 8 , wherein the mobile robot further comprises a counter wheel mounted on the shaft adjacent the pinion, wherein the rack includes at least grooved counter wheel support surfaces complementary to the counter wheel to center the counter wheel upon the axial extension of the shaft, and wherein the counter wheel includes lead-in chamfered portions that mate with complementary portions of the grooved counter wheel support surfaces of the rack. 10. The mobile robot of claim 1 , wherein the mobile robot is configured to move up or down within the passage by the rotation of the drive gear against the linear drive mount. 11. A mobile robot configured to travel in a vertical or inclined passage within an automated retrieval and storage system, the passage comprising a linear drive mount, the mobile robot comprising: a compliant drive assembly for moving the mobile robot in the passage, the compliant drive assembly comprising: a hub comprising at least one pair of recirculating ball sets, each pair of the recirculating ball sets comprising two diametrically opposed recirculating ball sets; a shaft comprising at least one pair of race portions, each pair of the race portions comprising two diametrically opposed race portions, the shaft configured to be rotated about an axis of rotation, the shaft further configured to be extended axially along the axis of rotation; a drive gear mounted on an end of the shaft, the drive gear configured to move into engagement with the linear drive mount; wherein the shaft is configured to exert torque on the hub by engagement between the at least one pair of recirculating ball sets of the hub and the at least one pair of race portions of the shaft, there being rotational play between the at least one pair of recirculating ball sets of the hub and the at least one pair of race portions of the shaft, the rotational play allowing a degree of free rotation of the drive gear relative to the linear drive mount to prevent jamming of the drive gear against the linear drive mount when the drive gear moves into engagement with the linear drive mount upon extension of the shaft. 12. The mobile robot of claim 11 , the at least one set of the recirculating balls comprises a pair of diametrically opposed sets of the recirculating balls. 13. The mobile robot of claim 11 , wherein the hub is configured to mount to a wheel of the mobile robot, wherein the wheel is configured to support the mobile robot as the mobile robot moves horizontally. 14. The mobile robot of claim 11 , wherein the hub is configured to move axially on the shaft. 15. The mobile robot of claim 11 , wherein a portion of each one of the race portions includes a portion that is wider than other portions of the race portions to allow the degree of free rotation of the drive gear relative to the linear drive mount. 16. The mobile robot of claim 11 , wherein each race portion of the race portions includes a lead-in to facilitate a smooth transition between the hub and the race portion. 17. The mobile robot of claim 11 , wherein the shaft further includes a pinion mounting portion. 18. The mobile robot of claim 17 , the drive gear comprises a pinion and the linear drive mount comprises a rack comprising teeth configured to mesh with gear teeth of the pinion. 19. The mobile robot of claim 18 , wherein the mobile robot further comprises a counter wheel mounted on the shaft adjacent the pinion, wherein the rack includes at least grooved counter wheel support surfaces complementary to the counter wheel to center the counter wheel upon the axial extension of the shaft, and wherein the counter wheel includes lead-in chamfered portions that mate with complementary portions of the grooved counter wheel support surfaces of the rack. 20. The mobile robot of claim 11 , wherein the mobile robot is configured to move up or down within the passage by the rotation of the drive gear against the linear drive mount.