A system for transporting fluid cargo within a shipping container, the system comprising an open topped box having side walls and end walls and a flexible membrane which either independently or in combination with the box contains the fluid cargo. The box supports the portion of the cargo within the box and is designed to flex and absorb at least part of the horizontal forces generated within the cargo during its transportation thus preventing overloading of the walls of the surrounding container. The membrane may be a bladder which completely encloses the cargo and is disposed partially within the box to contain the cargo independently of the box. The box may have a floor pan which can seal the box against leakage of any cargo.

A modular facility formation system includes any number of modules that may be coupled to one another to create a facility. Walls of the facility may be provided by one or more removeable walls, the walls of a shipping container, or a combination thereof. When installed within a shipping container, upper and lower braces are pressure fit into the shipping container without penetrating the container. The lower braces are configured to engage guidance mechanisms of the modules to guide the modules into a stowage position within the shipping container and to secure the modules in place. The modules may be configured with a pre-determined internal configuration corresponding to a defined function of the room within the facility.

A modular shipping container apparatus having a base with two support portions each of having two substantially open top rectangular shaped spaces each having a bottom side, a left side and a right side and at least one set of base holes; at least one wheel assembly between the two substantially open top rectangular shaped spaces, the at least one wheel assembly having a substantially open bottom rectangular piece with at least one set of wheel assembly holes and at least one wheel with a center opening, the wheel assembly is retained between the two substantially open top rectangular shaped spaces by at least one bar through the at least one set of base holes, the at least one set of wheel assembly holes and the wheels; at least two tracks attached to the bottom interior of a shipping container for slidably receiving the at least one wheel assemblies.

A cargo rack for transferring loads between a marine vessel and an offshore marine platform (for example, oil and gas well drilling or production platform) provides a frame having a front, a rear, and upper and lower end portions. The lower end of the frame has a perimeter beam base, a raised floor and a pair of open-ended parallel fork tine tubes or sockets that communicate with the perimeter beam at the front and rear of the frame, preferably being structurally connected (e.g., welded) thereto. Openings in the perimeter beam base align with the forklift tine tubes or sockets. The frame includes a plurality of fixed side walls extending upwardly from the perimeter beam that include at least left and right side walls. A plurality of gates are movably mounted on the frame including a gate at least at the front and at least at the rear of the frame, each gate being movable between open and closed positions, the gates enabling a forklift to place loads on the floor by accessing either the front of the frame or the rear of the frame. Each gate can be pivotally attached to a fixed side wall. The frame has vertically extending positioning beams or lugs that segment the raised floor into a plurality of load-holding positions. Each load holding position has a plurality of positioning beams or lugs that laterally hold a load module (e.g., palletized load) in position once a load is placed on the raised floor.

A modular subsea fluid storage unit comprises a variable-volume inner tank having a rigid top panel and a peripheral wall that is flexible by virtue of concertina formations. The peripheral wall is extensible and retractable vertically while the horizontal width of the tank remains substantially unchanged. A side wall of a lower housing part surrounds and is spaced horizontally from the peripheral wall of the inner tank to define a floodable gap between the peripheral wall and the side wall that surrounds the tank. An upper housing part extends over and is vertically spaced from the top panel of the inner tank and overlaps the side wall to enclose the inner tank. The floodable gap and the upper housing part enhance thermal insulation and trap any fluids that may leak from the inner tank.

A modular facility formation system includes any number of modules that may be coupled to one another to create a facility. Walls of the facility may be provided by one or more removeable walls, the walls of a shipping container, or a combination thereof. When installed within a shipping container, upper and lower braces are pressure fit into the shipping container without penetrating the container. The lower braces are configured to engage guidance mechanisms of the modules to guide the modules into a stowage position within the shipping container and to secure the modules in place. The modules may be configured with a pre-determined internal configuration corresponding to a defined function of the room within the facility.

Container adapted for cargo or personnel transport, the container being substantially prismatic, cylindrical or cubic in shape, wherein the container comprises: an internal surface and an external surface, a rigid frame, which defines a plurality of container faces, wherein the confluence of two or more of said container faces define edge portions being substantially chamfered, and one or more shock absorbing corner protectors adapted for being mounted on the edge portions, characterized in that the edge portions of the rigid frame comprise one or more beams arranged substantially in parallel to the direction of the confluence of two container faces, and the inner face of the corner protectors comprise at least a flange adapted for fitting in the one or more beams of the edge portions, such that the corner protectors substantially protrude from the external surface.

In accordance with embodiments disclosed herein, there are provided herein systems and methods for implementing aggregable, environment-controlled mini-containers for the efficient logistics of perishable products. For example, there is a system for providing efficient transportation logistics of dissimilar perishable products within a transportation unit, in which the system includes: multiple mini-containers, each being configurable to stack and aggregate to consume at least a portion of volume within the transportation unit; a Central Driving Unit (CDU) operable to provide services to each of the mini-containers to maintain the contents of each mini-container; a Central Control Unit (CCU) to receive sensor information from each of the mini-containers and further to issue control parameters for maintaining a specified atmosphere composition within each connected mini-container via the CDU, in which the CCU executes the control parameters for maintaining the specified atmosphere composition within each connected mini-container by activating actuators, in which the actuators manipulate valves at each mini-container, allowing for inflow and egress of atmospheric elements; and in which each of the multiple mini-containers constitute individual modular units configurable to form a single inter-connected and aggregated stack having a size which fits within the available volume of the transportation unit. In related embodiments, the CCU is further configured to transmit data on the status of the mini-containers to the outside world, such as transmitting status information to a remote storage location, or to the cloud, or directly to a centrally located data hub. Other related embodiments are disclosed.

A modular facility formation system includes any number of modules that may be coupled to one another to create a facility. Walls of the facility may be provided by one or more removeable walls, the walls of a shipping container, or a combination thereof. When installed within a shipping container, upper and lower braces are pressure fit into the shipping container without penetrating the container. The lower braces are configured to engage guidance mechanisms of the modules to guide the modules into a stowage position within the shipping container and to secure the modules in place. The modules may be configured with a pre-determined internal configuration corresponding to a defined function of the room within the facility.

An apparatus, system and method for securing wheeled shipping carts within a shipping container. The apparatus, system and method for securing wheeled shipping carts within a shipping container secures the shipping racks across the width of the container and vertically, and then end-to-end inside the length of the container from the fixed end of the container to the doors as the container is loaded. In addition, the system and method secures wheeled shipping carts within a shipping container using a securing apparatus installed within the shipping container to constrain the wheeled shipping carts both vertically and horizontally in location during transport.