A dunnage assembly that is quickly and easily installed within a shipping container and is easily reworked while remaining secure and adjustable during use is provided. The dunnage assembly of the present disclosure may also include a locking mechanism to keep the sling assembly securely positioned during shipping. Finally, according to one aspect the dunnage assembly of the present disclosure may collapse into the base of the shipping container, allowing it to remain mounted within the shipping container when the shipping container is collapsed for the return shipment back to be reused.

An expandable and collapsible grain bin is provided, comprising: two telescoping cylindrical sections, an upper bin section and a lower bin section, the two telescoping cylindrical sections adapted to automatically interlock with one another when the grain bin is in an expanded position; a first lifting system for lifting the upper bin section until the upper bin section automatically interlocks with the lower bin section and lowering the upper bin section when collapsing the grain bin for storage or transport; and a bin cover attached at or near the top of the upper bin section for enclosing the grain bin.

An expandable and collapsible grain bin is provided, comprising: two telescoping cylindrical sections, an upper bin section and a lower bin section, the two telescoping cylindrical sections adapted to automatically interlock with one another when the grain bin is in an expanded position; a first lifting system for lifting the upper bin section until the upper bin section automatically interlocks with the lower bin section and lowering the upper bin section when collapsing the grain bin for storage or transport; and a bin cover attached at or near the top of the upper bin section for enclosing the grain bin.

A container including first, second, and third side walls and an open end; a bottom wall coupled with the first, second, and third side walls; and a door pivotably coupled to the container and movable between a first position at which the door is spaced apart from the at least one open end and a second position at which the door closes the at least one open end. The container defines an interior volume of at least ten (10) cubic yards. At least one of the first, second, and third side walls includes a plurality of rectangular side panels releasably fastened together by mechanical fasteners. Each of the plurality of side panels defines a longitudinal axis. The longitudinal axes of each of the plurality of rectangular side panels are parallel with the bottom wall.

A hollow container or box formed from a roof, a first side (i.e., or first upper and lower sides), a second side (i.e., for second upper and lower sides), a rear side (i.e., or rear upper and lower sides), a door (i.e., or upper and lower door), and a base placing the container or box in a fully assembled position. Unique side and end access doors are provided. Each of the sides are releaseably coupled or hingedly connected to one another and the adjacent sides are hingedly coupled to the base. Upon releasing the sides from one another and rotating each relative to one another in a particular order along various axis rotation, the container or box is transitioned from a fully assembled position into a flat, parallel orientation, fully collapsed position.

A collapsible frame for a liquid holding tank is provided. The frame has orthogonal upper and lower rails spaced by vertical struts. The upper and lower rails have hinges at each corner thereof and orthogonally aligned hinges at midpoints and quarterpoints of two opposed sides thereof. The frame can be expanded or collapsed between a fully expanded and a fully collapsed condition by operation of the midpoint hinges and corner hinges. The frame can be expanded or collapsed between a fully expanded and a semi-expanded condition by operation of either the quarterpoint and corner hinges or the midpoint, quarterpoint, and corner hinges. The fully collapsed condition is primarily designed for storage, the semi-expanded condition allows the size of the tank to be reduced to accommodate site constraints, and the fully expanded condition maximizes the tank's liquid storage capacity.

A holding container includes a plurality of pre-formed, releasably interlocking, load-bearing panels configured to form an at least partially curved, load-bearing wall extending around the perimeter of at least one storage area capable of containing at least 100,000 gallons of liquids, solids or a combination thereof. At least one among the width and length of each panel is less than 102 inches in a non-load-bearing state.

A modular autonomous bot apparatus assembly is described for transporting an item being shipped. The assembly includes a modular mobility base having propulsion, steering, sensors for collision avoidance, and suspension actuators; a modular auxiliary power module with a power source and cargo door; a modular cargo storage system with folding structural walls and a latching system; and a modular mobile autonomy module that covers the cargo storage system and provides human interaction interfaces, externals sensors, a wireless interface, and an autonomous controller with interfacing circuitry coupled to the human interaction interfaces and sensors on the mobile autonomy module. The assembly has a power and data transport bus that provides a communication and power conduit across the different modular components. A method for on-demand assembly of such a bot apparatus is further described with steps for authenticating the different modular components during assembly.

An apparatus and method for lifting and collapsing a collapsible cargo container includes a frame, and vertical guides for aligning the actuator with the cargo container. First and second pusher assemblies engage the end walls of the container to pivot the end walls against the ceiling of the container, where uplocks retain the end walls in a stowed away position. Foldable side walls are then buckled by the weight of the ceiling with assistance from the actuator, until the side walls occupy a predominantly horizontal position between the ceiling/end wall combination and a floor of the cargo container, resulting in a compact configuration. The actuator unfolds the container using steps discussed above in a reverse order.

An apparatus and method for lifting and collapsing a collapsible cargo container includes a frame, and vertical guides for aligning the actuator with the cargo container. First and second pusher assemblies engage the end walls of the container to pivot the end walls against the ceiling of the container, where uplocks retain the end walls in a stowed away position. Foldable side walls are then buckled by the weight of the ceiling with assistance from the actuator, until the side walls occupy a predominantly horizontal position between the ceiling/end wall combination and a floor of the cargo container, resulting in a compact configuration. The actuator unfolds the container using steps discussed above in a reverse order.