Systems, methods, and apparatuses for controlling objects being loaded or unloaded from a storage structure or vehicle, such as a trailer. In example embodiments, a plurality of parcels may be stored in or on a trailer that is attached to a cab of a delivery vehicle. Upon arrival at a deposit location, the trailer loaded with the one or more parcels may be removably secured to a an adjustable platform designed to be raised to a predetermined angle for unloading of the one or more parcels. Once the adjustable platform is raised to the predetermined angle, a plurality of adjustable dividing mechanisms may be configured to pivot, allowing for the movement of a controlled volume of the one or more parcels onto the receiving platform.

Systems, methods, and apparatuses for controlling objects being loaded or unloaded from a storage structure or vehicle, such as a trailer. In example embodiments, a plurality of parcels may be stored in or on a trailer that is attached to a cab of a delivery vehicle. Upon arrival at a deposit location, the trailer loaded with the one or more parcels may be removably secured to a an adjustable platform designed to be raised to a predetermined angle for unloading of the one or more parcels. Once the adjustable platform is raised to the predetermined angle, a plurality of adjustable dividing mechanisms may be configured to pivot, allowing for the movement of a controlled volume of the one or more parcels onto the receiving platform.

Example vehicle restraints with a barrier having rotational and translational motion are described. An example vehicle restraint includes a carriage frame movable vertically relative to the dock. A drive shaft is supported by the carriage frame. A drive unit is to rotate the drive shaft about a shaft axis and relative to the carriage frame. A hub is connected to rotate with the drive shaft about the shaft axis, the hub having an outer diameter surface that is radially off center relative to the shaft axis. A barrier defines a bore that encircles the outer diameter surface of the hub. The barrier is movable selectively to an extended position and a retracted position. The barrier being connected to move selectively to the extended position and the retracted position in response to relative rotation between the outer diameter surface of the hub and the bore of the barrier.

Example vehicle restraints with a barrier having rotational and translational motion are described. An example vehicle restraint includes a carriage frame movable vertically relative to the dock. A drive shaft is supported by the carriage frame. A drive unit is to rotate the drive shaft about a shaft axis and relative to the carriage frame. A hub is connected to rotate with the drive shaft about the shaft axis, the hub having an outer diameter surface that is radially off center relative to the shaft axis. A barrier defines a bore that encircles the outer diameter surface of the hub. The barrier is movable selectively to an extended position and a retracted position. The barrier being connected to move selectively to the extended position and the retracted position in response to relative rotation between the outer diameter surface of the hub and the bore of the barrier.

Example vehicle restraints with a barrier having rotational and translational motion are described. An example vehicle restraint includes a carriage frame movable vertically relative to the dock. A drive shaft is supported by the carriage frame. A drive unit is to rotate the drive shaft about a shaft axis and relative to the carriage frame. A hub is connected to rotate with the drive shaft about the shaft axis, the hub having an outer diameter surface that is radially off center relative to the shaft axis. A barrier defines a bore that encircles the outer diameter surface of the hub. The barrier is movable selectively to an extended position and a retracted position. The barrier being connected to move selectively to the extended position and the retracted position in response to relative rotation between the outer diameter surface of the hub and the bore of the barrier.

Example vehicle restraints with a barrier having rotational and translational motion are described. An example vehicle restraint includes a carriage frame movable vertically relative to the dock. A drive shaft is supported by the carriage frame. A drive unit is to rotate the drive shaft about a shaft axis and relative to the carriage frame. A hub is connected to rotate with the drive shaft about the shaft axis, the hub having an outer diameter surface that is radially off center relative to the shaft axis. A barrier defines a bore that encircles the outer diameter surface of the hub. The barrier is movable selectively to an extended position and a retracted position. The barrier being connected to move selectively to the extended position and the retracted position in response to relative rotation between the outer diameter surface of the hub and the bore of the barrier.

The present invention discloses an apparatus for freight transportation. The apparatus comprising an electrified rail network, and a freight carrier mounted on the electrified rail network. The freight carrier is adjustable in length and comprises locking pins at opposing sides of the freight carrier. The freight carrier adjusts a location of the locking pins to match a length of the container. An attachment device receives and raises the container towards the carrier so that a connection holes at a top of the container connects to the locking pins under the freight carrier. A drive wheel assembly disposed at the freight carrier provides drive required to facilitate movement of the freight carrier along the rail network. A computing device in communication with the freight carrier is configured to send signal to the freight carrier to navigate the freight carrier to a destination point, thereby automatically delivering containers to the destination point.

The present invention discloses an apparatus for freight transportation. The apparatus comprising an electrified rail network, and a freight carrier mounted on the electrified rail network. The freight carrier is adjustable in length and comprises locking pins at opposing sides of the freight carrier. The freight carrier adjusts a location of the locking pins to match a length of the container. An attachment device receives and raises the container towards the carrier so that a connection holes at a top of the container connects to the locking pins under the freight carrier. A drive wheel assembly disposed at the freight carrier provides drive required to facilitate movement of the freight carrier along the rail network. A computing device in communication with the freight carrier is configured to send signal to the freight carrier to navigate the freight carrier to a destination point, thereby automatically delivering containers to the destination point.

An unloading apparatus for unloading a load contained in a tray of a load carrying vehicle having a transporter adapted to releasably receive the tray, the unloading apparatus comprising a rotator having a support surface for parking of the load carrying vehicle according to the second aspect of the invention, and a plurality of frames arranged in a spaced apart relationship with respect to each other along the support surface, the frames being adapted to secure the tray to the rotator and lifting the tray from the transporter, and means for rotating the rotator about the longitudinal axis of the tray for unloading of the load. There is also provide a load carrying vehicle including a transporter and a tray releasably attached to the transporter as well as a system and method from loading load from a first location into the tray and unloading the load at a second location using the unloading apparatus.