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 rack having gear teeth, the mobile robot comprising: a pinion gear having gear teeth and configured to rotate on a shaft about an axis of rotation, the shaft configured to extend axially along the axis of rotation to position the pinion gear in meshing engagement with the rack when the mobile robot is to travel in the passage, wherein both the gear teeth of the rack and the gear teeth of the pinion gear comprise complementary chamfered lead in portions configured to facilitate a meshing engagement of the gear teeth of the pinion gear with the gear teeth of the rack without the gear teeth of the pinion gear jamming against the gear teeth of the rack upon axial extension of the shaft. 2 . The mobile robot of claim 1 , wherein the mobile robot is configured to move up or down within the passage by rotation of the drive gear against the gear teeth of the rack. 3 . The mobile robot of claim 1 , wherein the mobile robot further comprises a counter wheel mounted on the shaft adjacent the pinion gear, and wherein the rack includes grooved counter wheel support surface complementary to the counter wheel to center the counter wheel upon the axial extension of the shaft. 4 . The mobile robot of claim 3 , wherein the counter wheel includes lead-in chamfered portions that mate with complementary portions of the grooved counter wheel support surfaces of the rack. 5 . The mobile robot of claim 4 , wherein the complementary portions of the grooved counter wheel support surfaces of the rack include cutouts positioned at locations where the lead-in chamfered portions of the counter wheel engage the rack. 6 . The mobile robot of claim 4 , wherein the grooved counter wheel support surfaces of the rack include a vee portion that mates with the lead-in chamfered portions of the counter wheel to center the counter wheel in the grooved counter wheel support surfaces of the rack. 7 . The mobile robot of claim 1 , wherein the rack further includes a backer bar surface to restrict the pinion gear from jumping or skipping the gear teeth of the rack. 8 . The mobile robot of claim 1 , wherein the rack further includes cutouts positioned at locations of the rack, the cutouts defining access zones of the rack wherein the pinion gear can extend with the shaft to the rack for the meshing engagement with the rack. 9 . The mobile robot of claim 1 , wherein the rack further includes a pair of cutouts positioned at two locations of the rack, the pair of cutouts defining an access zone of the rack wherein the pinion gear can extend with the shaft to the rack for the meshing engagement with the rack. 10 . 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 drive assembly for moving the mobile robot in the passage, the drive assembly having: a shaft configured to be rotated about an axis of rotation by a motor and 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 upon extension of the shaft; a hub for supporting a wheel and mounted on the shaft; wherein: the hub is permitted to move axially along the shaft between a first position and a second position; wherein in the first position, rotational play between the hub and the shaft is restricted, and wherein in the second position, 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. 11 . The mobile robot of claim 10 , wherein the mobile robot is configured to move up or down within the passage by rotation of the drive gear against the linear drive mount. 12 . The mobile robot of claim 11 , wherein the drive gear comprises a pinion gear and the linear drive mount comprises a rack comprising teeth configured to mesh with the gears of the pinion. 13 . The mobile robot of claim 12 , wherein the pinion gear comprises gear teeth having chamfered lead in portions configured to facilitate meshing engagement of the pinion gear with the rack without jamming upon axial extension of the shaft. 14 . The mobile robot of claim 13 , wherein the mobile robot further comprises a counter wheel mounted on the shaft adjacent the pinion gear, and wherein the linear drive mount includes grooved counter wheel support surface complementary to the counter wheel to center the counter wheel upon the axial extension of the shaft. 15 . The mobile robot of claim 14 , wherein the counter wheel includes lead-in chamfered portions that mate with complementary portions of the grooved counter wheel support surfaces of the linear drive mount. 16 . The mobile robot of claim 15 , wherein the complementary portions of the grooved counter wheel support surfaces of the linear drive mount include cutouts positioned at locations where the lead-in chamfered portions of the counter wheel engage the linear drive mount. 17 . The mobile robot of claim 15 , wherein the grooved counter wheel support surfaces of the linear drive mount include a vee portion that mates with the lead-in chamfered portions of the counter wheel to center the counter wheel in the grooved counter wheel support surfaces of the linear drive mount. 18 . The mobile robot of claim 12 , wherein the rack further includes a backer bar surface to restrict the pinion gear from jumping or skipping the gear teeth of the rack. 19 . The mobile robot of claim 12 , wherein the rack further includes cutouts positioned at locations of the rack, the cutouts defining access zones of the rack wherein the pinion gear can extend with the shaft to the rack for the meshing engagement with the rack. 20 . The mobile robot of claim 12 , wherein the rack further includes a pair of cutouts positioned at two locations of the rack, the pair of cutouts defining an access zone of the rack wherein the pinion gear can extend with the shaft to the rack for the meshing engagement with the rack.