A detachable body securing mechanism having first and second clamp arms that rotate toward the inside of longitudinal support members of a detachable body to clamp down on the longitudinal support members is disclosed. The first and second clamp arms are rotatably coupled to respective first and second ends of an elongated frame of the securing mechanism. The securing mechanism further includes an actuable piston with a piston body coupled to the first clamp arm and a piston coupled to the second clamp arm. In certain implementations, extension of the piston rotates the first and second clamp arms away from each other and the elongated frame into a clamping configuration for securing the detachable body. Retraction of the piston rotates the first and second clamp arms toward each other and the elongated frame into a retracted configuration for releasing the detachable body.

A U-shaped support frame has a base beam and parallel side beams extending rearward from the base beam and defining an open implement area, which can be made adjustable. A hitch is attached to the front end of the support frame and frame wheels support the side beams, and rotate about a horizontal frame wheel axis that is fixed in an orientation perpendicular to the operating travel direction. Implements are configured to perform an implement operation and to rest on the ground surface when in an idle position. The support frame is moved rearward to a loading position where each implement is movable to an operating position supported by the support frame. Each implement provides a beam lock connection between the side beams that resists twisting movement of the side beams to maintain the frame wheels and the side beams in a substantially fixed relationship with respect to each other.

A lashing system is usable on cargo ships that are transporting shipping containers, optionally as a supplement to standard lashing bridges provided on cargo ships. The lashing system includes a support that can interface with the pre-existing interlocking system provided on the shipping containers. The support can be lifted and placed on a stack of shipping containers using the same cranes used for loading and unloading shipping containers. The lashing system includes lashings that are attached to the support and are releasably connectable to another shipping container or to a structure of the cargo ship. The tension in the lashings is preferably monitored during the trips of the cargo ships.

A lashing system is usable on cargo ships that are transporting shipping containers, optionally as a supplement to standard lashing bridges provided on cargo ships. The lashing system includes a support that can interface with the pre-existing interlocking system provided on the shipping containers. The support can be lifted and placed on a stack of shipping containers using the same cranes used for loading and unloading shipping containers. The lashing system includes lashings that are attached to the support and are releasably connectable to another shipping container or to a structure of the cargo ship. The tension in the lashings is preferably monitored during the trips of the cargo ships.

The present invention relates to self-propelled airside dollies (100), and particularly but not exclusively to airside baggage dollies and airside cargo dollies, and autonomous airside dollies. The self-propelled airside dolly comprises a cargo portion (104) configured to hold baggage or cargo, a drive system (108) for driving the self-propelled airside dolly (100), a controller (114) configured to control the drive system (108) in response to control signals and a processor (116) configured to provide the control signals to the controller (114).

A clamping device secures an equipment rack during shipping. The clamping device includes a gripping portion having first and second surfaces positionable along opposing sides of a respective one of a front and rear lateral logistic bar. The clamping device also includes a clamp mechanism attached to the gripping portion for movement between a disengaged position and an engaged position to selectively engage the first and second surfaces to the opposing sides of the respective one of the front and rear lateral logistic bars positioned adjacent to an equipment rack within a carrier shipping enclosure. A mounting feature is attached to the gripping portion to hold one end of a longitudinal logistic bar positioned along a lateral side of the equipment rack.

A clamping device secures an equipment rack during shipping. The clamping device includes a gripping portion having first and second surfaces positionable along opposing sides of a respective one of a front and rear lateral logistic bar. The clamping device also includes a clamp mechanism attached to the gripping portion for movement between a disengaged position and an engaged position to selectively engage the first and second surfaces to the opposing sides of the respective one of the front and rear lateral logistic bars positioned adjacent to an equipment rack within a carrier shipping enclosure. A mounting feature is attached to the gripping portion to hold one end of a longitudinal logistic bar positioned along a lateral side of the equipment rack.

A method for operating a vehicle comprising at least one functional module, two or more drive modules, which are: autonomously operated, individually associated with a set of energy parameters, a pair of wheels, an electrical motor operating the wheels, and an interface releasably connected to an interface on the functional module, and wherein one drive module has a gear ratio different from any gear ratio of any other drive module. The method comprises: obtaining route information describing a planned route of the vehicle; determining a distribution of a requested driving torque between the respective at least one electrical motors of the two or more drive modules for operating the vehicle along the route based on the route information and the individual sets of energy parameters in order to meet energy criteria; and controlling the two or more drive modules to produce the requested driving torque, in accordance with the determined distribution.

A cargo restraint system comprises a plurality of cargo restraint assemblies. Each cargo restraint assembly in the plurality of cargo restraint assemblies may be removably coupled to a cargo deck in various configurations. The plurality of cargo restraint assemblies may be reconfigurable based on a size of a plurality of unit load devices (ULDs) to be loaded and restrained. Each cargo restraint assembly may restrain four or fewer corners of respective ULDs simultaneously.

A cargo restraint system comprises a plurality of cargo restraint assemblies. Each cargo restraint assembly in the plurality of cargo restraint assemblies may be removably coupled to a cargo deck in various configurations. The plurality of cargo restraint assemblies may be reconfigurable based on a size of a plurality of unit load devices (ULDs) to be loaded and restrained. Each cargo restraint assembly may restrain four or fewer corners of respective ULDs simultaneously.