A vehicle transfer robot (10) of the present invention, disposed vertically on the ground, is formed to have four vertical frames (110) disposed at a predetermined distance apart from each other and formed to have a quadrangular frame, and a quadrangle by connecting the upper end parts of the four vertical frames (110), respectively, wherein the vehicle transfer robot (10) includes: a frame part (100) including an upper frame (120); a driving part (200) installed at each of the lower end parts of the vertical frames (110) for moving the frame part (100); and a carriage (300) installed in the frame part (100) for loading a vehicle.

A vehicle transfer robot (10) of the present invention, disposed vertically on the ground, is formed to have four vertical frames (110) disposed at a predetermined distance apart from each other and formed to have a quadrangular frame, and a quadrangle by connecting the upper end parts of the four vertical frames (110), respectively, wherein the vehicle transfer robot (10) includes: a frame part (100) including an upper frame (120); a driving part (200) installed at each of the lower end parts of the vertical frames (110) for moving the frame part (100); and a carriage (300) installed in the frame part (100) for loading a vehicle.

A transportation arrangement for transportation of an object on a surface comprises at least one transportation unit. The transportation unit comprises a housing comprising a vertical front surface, two arms movably connected to the housing at each side of the vertical front surface, at least one rolling element arranged at a lower portion of the housing, and a power source connected to the rolling elements and the movable arms. The rolling element are configured to roll in any horizontal direction on the surface.

A sliding platform system for moving a vehicle parked on a platform, the sliding platform system including at least one rail and at least one vehicle platform slidably movable upon the at least one rail, a chain drive assembly comprising a chain, motor and sprockets, a chain guide channel positioned adjacent the at least one rail, and at least one latching mechanism mounted to the platform and slidably engaged in the chain guide channel, wherein the chain drive assembly is operably coupled to the latching mechanism and wherein a portion of the chain is positioned in the chain guide channel, wherein the chain guide channel includes at least one detent operable to engage the latching mechanism when the latching mechanism is positioned in alignment with the detent and to disengage the chain from a chain engagement element in the latching mechanism. The chain drive assembly is operable to move one or more platforms along the rail to pre-selected positions. The system may include a latch set device operable to move the latch mechanism to an engaged state with the chain.

In some embodiments, a mobile robot unit for engaging a wheel of parked target vehicle is provided, the mobile robot unit comprising: a frame adjustable from a first configuration to a second configuration and vice versa, wherein in the second configuration the frame engages the vehicle wheel to apply a sufficient counterforce onto the vehicle wheel to lift the vehicle wheel and the vehicle weight supported by the vehicle wheel from the ground; and at least two wheel assemblies supporting the frame above the ground, each wheel assembly comprising at least one steerable wheel, the steerable wheel contacting the ground.

In some embodiments, a mobile robot unit for engaging a wheel of parked target vehicle is provided, the mobile robot unit comprising: a frame adjustable from a first configuration to a second configuration and vice versa, wherein in the second configuration the frame engages the vehicle wheel to apply a sufficient counterforce onto the vehicle wheel to lift the vehicle wheel and the vehicle weight supported by the vehicle wheel from the ground; and at least two wheel assemblies supporting the frame above the ground, each wheel assembly comprising at least one steerable wheel, the steerable wheel contacting the ground.

The present invention relates to a vehicle left and right alignment device for a parking facility. Provided is a vehicle left and right alignment device for a parking facility which is installed at an entrance of a parking facility to align wheels of an incoming vehicle, the device comprising: a front wheel alignment unit (2, 2′) and a rear wheel alignment unit (3) respectively provided on both sides of a central passage part (11) of a frame (1) installed at the entrance of the parking facility. The rear wheel alignment unit (3) comprises: a plurality of rollers (31) extending in the longitudinal direction of the vehicle body and arranged in the vehicle width direction to be rotatable; and a driving unit (30) for rotating the rollers (31) to adjust and align the position of a rear wheel of the vehicle positioned on the rollers (31). The present invention solves conventional problems in which durability is decreased due to occurrence of uneven wear caused by uneven loads applied to a moving means or the body of a vehicle is damaged as a vehicle is moved by a moving means in a non-aligned state. As such, the present invention has an effect of safely performing vehicle transfer by means of a moving means and an effect of reducing manufacturing costs by simplifying a structure.

A parking robot for a transportation vehicle having at least two wheel axles and a method for operating a parking robot. The parking robot includes a main robot part and a secondary robot part which each have a pair of wheel support arms on two opposite sides. The two-part parking robot then moves under the transportation vehicle with respective folded-in wheel support arms and disconnects the secondary robot part from the main robot part to position the main robot part and the secondary robot part each in a region of one of the wheel axles beneath the transportation vehicle and to lift up respective wheels of the respective wheel axle of the transportation vehicle by folding out the respective pairs of wheel support arms.

The present invention can provide an intelligent vehicle transport robot for a single-level parking lot, wherein: parking lines for indicating parking locations of respective vehicles are marked on a parking lot formed at a single level; the parking lines are marked in a checkerboard pattern so as to exclude drive aisles for vehicle movements and thus increase the number of vehicles that can be accommodated in parking spaces; and a vehicle transport robot (10) is provided in the parking lot, which performs vehicle parking and retrieval by moving a vehicle above parked vehicles, whereby due to exclusion of drive aisles, the number of vehicles that can be accommodated in parking spaces is increased as compared to a conventional parking lot having the same area, and thus the parking efficiency of the parking lot can be improved.

A vehicle transfer robot (10) of the present invention, disposed vertically on the ground, is formed to have four vertical frames (110) disposed at a predetermined distance apart from each other and formed to have a quadrangular frame, and a quadrangle by connecting the upper end parts of the four vertical frames (110), respectively, wherein the vehicle transfer robot (10) includes: a frame part (100) including an upper frame (120); a driving part (200) installed at each of the lower end parts of the vertical frames (110) for moving the frame part (100); and a carriage (300) installed in the frame part (100) for loading a vehicle.