A microtransporter system includes a plurality of microtransporters and a housing. The microtransporters each include a rigid base structure, three wheels rotatably mounted in the base structure, an electric motor drivingly connected to one of the wheels, and a load support surface connected to the base structure. The housing includes a storage chamber sized to store a plurality of microtransporters, and a passageway connecting the chamber to an outside of the housing.

An apparatus for supporting a two-wheeled vehicle on a structural part has the following features: a fork receiving element having recesses for receiving a fork of the two-wheeled vehicle, an axle support element for supporting on an axle of the two-wheeled vehicle, at least two connecting elements for connecting the fork receiving element to the axle support element, which have respective recesses for receiving the axle support element, and at least two means which are arranged at a distance from the recesses for receiving the axle support element for attaching lashing elements by means of which the apparatus can be connected to the structural part.

An apparatus for supporting a two-wheeled vehicle on a structural part has the following features: a fork receiving element having recesses for receiving a fork of the two-wheeled vehicle, an axle support element for supporting on an axle of the two-wheeled vehicle, at least two connecting elements for connecting the fork receiving element to the axle support element, which have respective recesses for receiving the axle support element, and at least two means which are arranged at a distance from the recesses for receiving the axle support element for attaching lashing elements by means of which the apparatus can be connected to the structural part.

An automatic guided vehicles (AGV) can include: motors, wheels, motor controllers, and batteries coupled to an elongated frame. The two wheels can be mounted on opposite sides of the elongated frame. The wheels can be coupled to motors which can be controlled by motor controllers. The motors and motor controllers can be attached to the frame. The center of gravity can be lower than the axis of rotation of the wheels so that the AGV will passively rotated into an upright position. A connector flange can be mounted on top of a payload holder column mounted to a center portion of the AGV frame. Objects can be mounted on or towed by the connector flange.

An automatic guided vehicles (AGV) can include: motors, wheels, motor controllers, and batteries coupled to an elongated frame. The two wheels can be mounted on opposite sides of the elongated frame. The wheels can be coupled to motors which can be controlled by motor controllers. The motors and motor controllers can be attached to the frame. The center of gravity can be lower than the axis of rotation of the wheels so that the AGV will passively rotated into an upright position. A connector flange can be mounted on top of a payload holder column mounted to a center portion of the AGV frame. Objects can be mounted on or towed by the connector flange.

A system and method for transporting a detachable vehicle is provided. In one embodiment of the present invention, a track is affixed to a first vehicle, such as a van, and used to transport (e.g., load, secure, unload, etc.) a detachable vehicle, such as a motorized scooter. The track may be a single track, or a plurality of track portions (e.g., a ramp portion, a floor portion, a seat portion, etc.). In one embodiment of the present invention, the first vehicle includes a first connector and the detachable vehicle includes a second connector, where said first connector and said second connector can be mated, either manually or automatically in response to moving the detachable vehicle along the track (e.g., to a final location). Once an electrical connection is made, said electrical connection can be used to share information between the vehicles and/or to charge a battery on the detachable vehicle.

A system and method for transporting a detachable vehicle is provided. In one embodiment of the present invention, a track is affixed to a first vehicle, such as a van, and used to transport (e.g., load, secure, unload, etc.) a detachable vehicle, such as a motorized scooter. The track may be a single track, or a plurality of track portions (e.g., a ramp portion, a floor portion, a seat portion, etc.). In one embodiment of the present invention, the first vehicle includes a first connector and the detachable vehicle includes a second connector, where said first connector and said second connector can be mated, either manually or automatically in response to moving the detachable vehicle along the track (e.g., to a final location). Once an electrical connection is made, said electrical connection can be used to share information between the vehicles and/or to charge a battery on the detachable vehicle.

Methods, apparatus, systems, and articles of manufacture are disclosed for high-traffic density air transportation. An example system includes a land vehicle having a first location and a transit carrier having a movement system, first stacking couplers, a first and second magnetic coupler, and a transit pod having second stacking couplers configured to couple to the first stacking couplers, a UAV having UAV couplers and a second location, and a controller to, in response to obtaining a request to direct the land vehicle to move from the first location to a third location, invoke the UAV to move to the third location, and in response to the land vehicle and the UAV arriving at the third location, invoke the UAV to couple to the transit pod to facilitate transport of the transit pod from the third location to a fourth location by coupling the UAV couplers to the second stacking couplers.

Methods, apparatus, systems, and articles of manufacture are disclosed for high-traffic density air transportation. An example system includes a land vehicle having a first location and a transit carrier having a movement system, first stacking couplers, a first and second magnetic coupler, and a transit pod having second stacking couplers configured to couple to the first stacking couplers, a UAV having UAV couplers and a second location, and a controller to, in response to obtaining a request to direct the land vehicle to move from the first location to a third location, invoke the UAV to move to the third location, and in response to the land vehicle and the UAV arriving at the third location, invoke the UAV to couple to the transit pod to facilitate transport of the transit pod from the third location to a fourth location by coupling the UAV couplers to the second stacking couplers.

A transport trailer includes a chassis, a deck, a lifting assembly, and a stabilizer assembly. The lifting assembly is mechanically coupled to the deck and the chassis and selectively raises and lowers the deck relative to the chassis. The stabilizer assembly includes a support post and a slide member. The support post is laterally disposed between first and second edges of the deck and extends from the chassis to a top end of the support post. The slide member is coupled to the deck and translates along a length of the support post as the deck is raised and lowered to stabilize the deck. An upper surface of the deck is above the top end of the support post when the deck is in a raised position and is below the top end of the support post when the deck is in a lowered position.