A method of creating a stand-off between insulation and chime on a storage tank is provided. A plurality of tank chime spacers are positioned in space relation to each other such that the bottom of the tank chime spacer is positioned on the tank chime and one of the peripheral side walls of the tank chime spacer is positioned adjacent to the sidewalls of the storage tank to create a gap between the tank chime and the sidewalls of the storage tank. Each of the tank chime spacers has a body with a top, a bottom and peripheral side walls.

An improved shelving unit for a shipping container is disclosed herein. The improved shelving unit can comprise one or more shelf assemblies and an RFID reader. Each of the one or more shelf assemblies can comprise a bottom platform and a top platform. The RFID reader can be mounted between the bottom platform and the top platform. The top platform can be capable of supporting items.

An improved wall panel for an automated inventory module is disclosed herein. The improved wall panel can comprise a wall panel. The wall panel can be capable of being mounted at a corrugated interior surface of an automated inventory module (AIM). The wall panel can comprise a substantially flat first exterior layer comprising a first side and a second side. The first exterior layer first side can face the interior of the AIM when the wall panel is mounted at the interior surface, and the first exterior layer second side can face the interior surface when the wall panel is mounted at the interior surface. The first exterior layer can comprise a ferromagnetic material.

The invention refers to an equipment (1) including a container (19) for the storage of a liquid (2) as well as thermal insulation panels (12,13), wherein none of the thermal insulation panels (12,13) is mounted directly on or even in contact with an outer surface of the container (19), wherein a chamber (5) housing the container (19) is delimited by an enclosure (6) consisting of walls (7), a floor (8) and a ceiling (9), and which is accessible through an access opening, either in the form of an entrance opening in one of the walls (7) closeable by a door or in the form of a manhole (11) eccentric to the center of the ceiling (9) and closeable by a lid (10), wherein the lid (10) or the door is thermally insulated at the inner side and is provided with an air-tight sealing all around, and wherein an inner surface of the chamber (5) except the access opening is entirely covered with the thermal insulation panels (12,13) in such a way that a volume of space occupied by the container (19) is smaller than a volume of space delimited by the inner sides of the thermal insulation panels (12,13) at the inner side of the walls (7), the ceiling (9) and the floor (8), leaving a space for maintenance between the outer surface of the container (19) and the thermal insulation panels (12,13) mounted to the inner surface of the chamber (5), which is only filled with air and is free of any liquid or bulk material in order to keep the container and the bottom of the chamber visible for inspection, and wherein the only way for heat to leave the air-filled space for maintenance between the outer surface of the container (19) and the thermal insulation panels (12,13) is through these thermal insulation panels (12,13) and neither besides such thermal insulation panels (12,13) nor through any kind of air duct or acitve or passive venting.

A container for storing liquids includes an inner layer including a storage space for storing liquids; an outer layer; and multiple spacers fastened between the inner layer and the outer layer to form multiple compartments. The spacer includes a first surface and a second surface. The first surface is secured to an adhesive layer of the inner layer. The first surface has many cavities. The second surface is secured to the outer layer and having projections complimentarily secured to the cavities. A manufacturing method of the container is also provided. Therefore, it can solve the problem permeation and adhesive failure caused by leaking. It can generate an early alarm by detecting any leaking or permeation of the container.

A tank for the storage of liquid or gaseous substances with a fiber-reinforced plastic sheathing, which limits at least one interior space for holding the materials to be stored. At least one circumferential section of the fiber-reinforced plastic sheathing comprises an evacuable sandwich structure, which completely encloses the circumferential section. As a result, the tank has a low weight with a high thermal insulation capacity. Furthermore, a reliable explosion protection of the tank is provided. Furthermore, a method for manufacturing a tank for the storage of liquid or gaseous substances is provided.

An apparatus for distillation at cryogenic temperatures can include a cold box module comprising framing and having an upper module section and a lower module section, wherein the upper module comprises a roof; an upper column section disposed within the upper module section; a lower column section disposed within the lower module section; a plurality of support saddles attached to the upper and lower module sections that are configured to provide structural support for the upper and lower column sections when the upper and lower column sections are in a horizontal position during transportation; and means for limiting longitudinal movement of the lower column section when the lower module section is in a horizontal position during transport, wherein the means for limiting longitudinal movement are connected to the lower column section and the lower module section.

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 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 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.