Transferring carriage (100) of vehicles for automatic mechanic parking systems comprising at least a frame (1); means of handling of said carriage (100); and at least a device (13) of centering, raising and keeping up of the wheel (32) of a vehicle, said device (13) comprising at least a couple of clamp elements (17) and at least a movable support (14); each couple of clamp elements (17) being supported by said movable support (14); said movable support (14) being transversally translatable for positioning said clamp elements (17) of a same couple in proximity of a wheel (32) of an axle of a vehicle such that the centering, raising and keeping up of the two wheels (32) of an axle of a vehicle is achieved by means of a single transversal movement towards outside of the carriage of said at least one movable support (14) and of the couple of clamp elements (17) integral therewith.

A cluster transfer robot includes a body, two clamping arms arranged at the bottom of the body, and a first driving mechanism arranged at the bottom of the body. The first driving mechanism includes a driving wheel configured for driving the transfer robot to move. The clamping arm includes a second driving mechanism and a rotating assembly connected to the second driving mechanism, the rotating assembly includes a rotating arm rotatably connected to the body and a supporting wheel arranged on the rotating arm for supporting the transfer robot, the rotating arm is provided with a clamping portion for clamping automobile tire, and two clamping portions of two rotating arms are arranged facing to each other to define a clamping space for the automobile tire when the two clamping portions are close to each other. The cluster transfer robot can greatly reduce the construction cost of intelligent parking lots.

A carriage for handling a vehicle in an automatic parking system includes a frame axially movable along a first longitudinal axis, rotating clamps, each including a pair of counter-rotating arms rotating with respect to a vertical axis orthogonal to both the longitudinal axis and the transverse axis. The carriage includes a transverse-centering unit with transverse pushers, transversely extensible, moving along an axis parallel to the transverse axis and independent of the rotating clamps. In a first retracted position they do not interact with the vehicle wheels. When extended, they come into contact with at least one vehicle wheel. The extensible transverse pushers are on left and right sides of the carriage, and simultaneously move in a symmetrical extension, being operated by a respective motor positioned laterally of the longitudinal axis of the carriage. The extensible transverse pushers include a pantograph for longitudinally aligning the vehicle along the longitudinal axis.

The disclosure relates to a conveyor for moving four-wheel vehicles. The conveyor includes a chassis having stowable extensions movable between a position in which the extensions make it possible to move the chassis under the vehicle and a position in which the extensions make contact with the treads of the wheels. The chassis is telescopic and includes two segments that each have a pair of arms. At least one of the arm pairs is hinged so as to enable movement between a position perpendicular to the longitudinal axis of the chassis with an extension at least equal to the track width of the vehicle and a folded-up position that is to occupy a width less than the distance between the inner flanks of the wheels of the vehicle. The segments are movable between a position where the arms are not in contact with the wheels and a position where each arm makes contact with the tread of one of the wheels so as to raise or lower the vehicle.

Device for storing an automotive vehicle transversely relative to its longitudinal axis on a parking space of a storage facility, having a surface-manoeuvrable, driverless vehicle transporter which is disposed parallel to the longitudinal axis of the automotive vehicle when receiving the automotive vehicle and has horizontally extending pairs of forks which are disposed thereon at one side and perpendicularly, the forks of the pairs of forks being displaceable individually horizontally along the vehicle transporter and the pairs of forks moving under wheels respectively of a vehicle axle from one side of the automotive vehicle in order to grip the wheels by displacing the individual forks horizontally towards each other, whereupon the automotive vehicle is lifted for transporting, surface-manoeuvrable supports (4) being disposed on the vehicle transporter (1) respectively at the end-side, which supports extend horizontally and parallel to the pairs of forks (3) and, when the pairs of forks (3) move under the wheels (8), move past the automotive vehicle (7) at the front- and rear-side at a small spacing, the spacing between the supports (4) being adjustable, a measuring device (6), before the automotive vehicle (7) is received, determining its length, axle positions and the position of the automotive vehicle (7) in space, the surface-manoeuvrable, driverless transporting means (1) adapting, with the data transmitted from the measuring device (6), its length determined by the spacing of the supports (4) and the position of the pairs of forks (3) automatically to the dimensions of the automotive vehicle (7) to be received, and the load absorbed upon lifting the automotive vehicle (7) being transmitted, on the one hand, by the vehicle transporter (1) and, on the other hand, by the surface-manoeuvrable supports (4) to the travel surface.

Transferring carriage (100) of vehicles for automatic mechanic parking systems comprising at least a frame (1); means of handling of said carriage (100); and at least a device (13) of centering, raising and keeping up of the wheel (32) of a vehicle, said device (13) comprising at least a couple of clamp elements (17) and at least a movable support (14); each couple of clamp elements (17) being supported by said movable support (14); said movable support (14) being transversally translatable for positioning said clamp elements (17) of a same couple in proximity of a wheel (32) of an axle of a vehicle such that the centering, raising and keeping up of the two wheels (32) of an axle of a vehicle is achieved by means of a single transversal movement towards outside of the carriage of said at least one movable support (14) and of the couple of clamp elements (17) integral therewith.

A vehicle shuttle car operable to travel in linear and lateral directions includes a low profile cart including a steerable front section and a rear section, the front section operable to turn left and right relative to the rear section. The rear section is operable to raise and support at least one tire of a vehicle off the ground.

Disclosed are an automatic battery replacement system of a transfer robot which includes a transfer robot which autonomously moves and includes a lifting module which supports and lifts a cargo, a battery which is detachably mounted on the transfer robot and is provided as a power source to supply a power required for an operation of the transfer robot, and a battery replacement robot which sucks and handles the battery and performs an operation of sucking the battery previously mounted on the transfer robot to be removed or mounting a new fully-charged battery on the transfer robot and an automatic battery replacement method of a transfer robot using the same.