A bulk fluid storage container includes a frame assembly having a lower rectangular frame, first and second wheel assemblies extending from opposite ends of the lower rectangular frame, and an upper rectangular frame member arranged in spaced relation to the lower rectangular frame member by a plurality of vertically extending posts. The bulk fluid storage container also includes a fluid storage vessel having first and second end walls held in spaced relation by first and second side walls, a top wall and a bottom wall, which defines a fluid storage volume. A baffle assembly having a plurality of baffle plates is disposed in a space relationship in the fluid storage volume. The frame assembly provides an exoskeletal structure which surrounds the fluid storage vessel and is configured to support a second bulk fluid storage container in a vertically stacked relationship.

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.

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.

The invention is based on using existing approved tanks and shipping containers for transportation of liquids. It is a combination rotomolded plastic tanks customized for industrial, petrochemical and agricultural applications placed in a secured standard shipping container (20′/40′/53′). As well as custom outfitted with inlets and outlet for top and side filling and extraction from the bottom side. The tanks are equipped to be bolted on the floor or braced from the sides of the container. Each tank is elliptically shaped outfitted with four legs for stability. The top center of the tank has an inlet which also functions as ventilation for the tank. The inlets are custom made to ensure easy access for top loading and side loading purposes. The extraction will be from the bottom of the tank and run to the exit access doors to the side of the container.

A heavy duty container includes a plastic base having a plurality of vertical corrugations. A separate plastic liner is placed inside the base. The liner is smooth to allow materials to fall out easy and not catch or build up in corners. The container can be moved with a fork lift and serviced with a front loader truck.

Corrugated fluid-tight membrane fluid-tight wall (1) including two series of parallel corrugations forming a plurality of nodes (5) at the crossings of said series of corrugations, wave reinforcements (11) being arranged under the corrugations (3) of the first series of corrugations (3), two successive wave reinforcements (11) in a corrugation (3) each including a hollow sole (15) and a reinforcement portion (16) disposed above the sole (15), the two wave reinforcements (11) being developed in the corrugation (3) on either side of a node (5), a connecting member (13) at the level of the node (5) being nested in the soles (15) of said two wave reinforcements (11) in such a manner as to assemble the two wave reinforcements (11) in an aligned position.

Shipping system for temperature-sensitive materials. In one embodiment, the shipping system may include a frame defining an enclosure. The frame may include a bottom, a top, a front, a rear, a left side, a right side, a left corner gusset, and a right corner gusset. The front may serve as a door. Thermal breaks may be provided in one or more of the bottom, the front, the left corner gusset, and the right corner gusset. Vacuum insulated panels may be positioned along all sides of the frame. Many of the vacuum insulated panels may be encapsulated between the frame and an outer shell. A plurality of phase-change material assemblies may be positioned within the frame along all sides. Heat-spreaders may be positioned interior to the phase-change material assemblies. The shipping system may be dimensioned so that four such shipping systems may be seated on a prorate manual cargo sheet.

A molded container assembly includes a pallet, a molded container, and a plurality of connection systems. The pallet supports the molded container thereon and includes stacking alignment structure for stacking the pallet on another molded container assembly. The molded container includes a tank portion, several leg supports, several buttresses, and several horizontally extending ribs. The tank portion includes several curved sidewalls and a fill opening. The leg supports include lower and upper sections that extend above the fill opening for spacing a pallet stacked on top of the molded container above the fill opening. The upper sections include pallet engaging structure for engaging pallets of at least two different types. The horizontally extending ribs minimize outward deflection due to hydrostatic loading and/or pressurization. The connection systems include washers that allow for shrinkage and expansion between the molded container and the pallet in a number of directions.

A lightweight shipping container includes two parallel side walls each having a top rail and secured on the opposite side to bottom rails of a floor frame, coupled to one another by a floor, secured to a multiplicity of cross-beam members. A front end assembly is secured to one end of the top and bottom side rails and a door end assembly opposite the front end assembly is secured to an opposite end of the top and bottom side rails. The container further includes a roof secured to respective ones of the top rails of each of the two side walls. The floor includes a metallic cellular panel including a metallic cellular core of multiple polygonal cells, each including opposing horizontal walls coupled to one another at each distal end by at least one perpendicularly intersecting wall of half thickness as that of the opposing horizontal walls.

A bulk fluid storage container has a top wall structure and a bottom wall structure held in spaced relation by a side wall structure. An internal baffle assembly is disposed in the fluid storage volume between the side wall structure for reducing fluid sloshing. A fill port formed in the top wall structure has a fill flange for coupling with a source of the fluid. A vent port formed in the top wall structure has a pressure vacuum value. A drain port formed in the side wall structure in a lower region adjacent the gutter region has a drain valve assembly is coupled to the drain port. A frame assembly includes an upper rectangular frame member and a lower rectangular frame member arranged in spaced relation by a plurality of post; wherein the frame assembly surrounds and supports the fluid storage vessel.