Provided is a container-use surface treated steel sheet which is manufactured without using chromium and exhibits excellent working adhesion with a coated organic resin, a method of manufacturing the container-use surface treated steel sheet, an organic resin coated surface treated steel sheet. The container-use surface treated steel sheet is a surface treated steel sheet where nickel plating is applied to at least one-side surface of surfaces of a steel sheet by coating, wherein nickel plating has a fine particle shape formed by fine particles which has particle density of 2 to 500 pieces/m.sup.2 and having an average particle size of 0.05 to 0.7 m. The container-use surface treated steel sheet is also characterized in that a coating weight of the nickel plating of the container-use surface treated steel sheet is 0.1 to 12 g/m.sup.2, metal tin is contained in coating of the nickel plating, and an amount of metal tin is 0.05 to 0.1 g/m.sup.2. The organic-resin-coated surface treated steel sheet of the present invention is characterized in that an organic resin layer is formed on at least one surface of the container-use surface treated steel sheet. The metal can is formed by working the organic-resin-coated surface steel sheet.

A food container includes a body having a first and second receptacle. A first food product is contained in the first receptacle. A second food product is contained in the second receptacle. A lid includes two portions coupable to the body, a first portion configured to enclose the first receptacle and a second portion configured to enclose the second receptacle. Each portion has a permeability, and the first portion has a permeability different than the second portion.

A method of incremental autofrettage is taught herein, whereby the cycle life of a metal liner in a pressure vessel is increased. This method serves to increase the yield strength of the metal liner through sequential work hardening due to repeated autofrettage at increasing pressures. By incrementally increasing the internal pressure used in the autofrettage process, the compressive stresses at an inner surface of the metal liner may be controlled so that post-pressurization buckling does not occur, yet the yield strength of the metal liner is substantially increased. The higher compressive stresses in the metal liner mean that higher Maximum Expected Operating Pressures (MEOPs) may be used without detracting from the cycle life of the metal liner, or alternatively, for lower pressures, a longer metal liner cycle life may be obtained. Either internal or external pressures may be used, generated by a pressure source, or a suitable die.

Disclosed is an apparatus of housing component which includes a case which accommodates a component, a cover which covers the case, and a sealant applied on a joining surface at which the case and the cover join together, wherein a step is formed at the joining surface.

The present disclosure relates to a foldable container which includes a pair of side walls disposed side-by-side; a guide rail disposed in a direction transverse-crossing between lower ends of the one pair of side walls to guide movement of at least one of the side walls; an upper plate and a lower plate, wherein each of the upper plate and the lower plate is divided into at least two unit plates that are rotatably connected to each other so as to be folded by the movement of the side wall, and wherein each of the upper plate and the lower plate connects upper ends of the pair of side walls to each other and connects lower ends of the one pair of side walls to each other; and a door rotatably connected to each of a front end and a rear end of the side wall.

A system for elevating polymeric crates with mounted sidewall assembly is described; a respective method of elevating polymeric crates with sidewall mountable assemblies and a kit-of-parts implementable for elevating polymeric crates with sidewall mountable assemblies are further described; the system comprises: a polymeric crate comprising a pair of longitudinal sidewalls and a pair of flanking sidewalls, at least one sidewall mountable elevating assembly comprising a pair of longitudinal members and a pair of flanking members; the method comprises: providing polymeric crate, providing pair of longitudinal members, providing pair of flanking members, mounting flanking members on polymeric crate, mounting longitudinal members on polymeric crate, assembling flanking members to longitudinal members; the kit-of-parts comprises: at least a pair of longitudinal members and at least a pair of flanking members.

Foldable plant pot with removable hooking for the configuration of vertical gardens that is manufactured from a foldable flat square structure manipulated by folds and cuts to obtain a conical reservoir with angular shapes. It has a hooking system that allows them to be suspended in vertical structures, preferably of the mesh type, thanks to the pressure generated by the folds of the material and which also allow it to come off when this pressure is reduced so that it can be placed elsewhere. When the plant is moved, it is not affected as its root remains intact in the conical reservoir and the stem is secured by a support ring which prevents it from dropping in the event of sudden movements. In the same way, it has containment flaps that partially close the conical reservoir and prevent the substrate from being extracted by external agents such as sudden movements, winds, birds, etc. As a whole, it is possible to work with vertical garden designs considering the plants as pixel units in order to create figures, letters, logos, etc. It is a very clean system that does not require prepared soil (clay, sand, etc.) and uses little water. The irrigation system only requires a hose with drippers at the top that distribute the water to vertical rows of the plant pot.

A method for joining shipping containers together to create a modular structure includes providing a first shipping container and a second shipping container; removing a wall of the side of the first shipper container to create a first opening; removing a wall of the side of the second shipping container to create a second opening; positioning the first opening adjacent and opposite to the second opening; aligning the first opening with the second opening; after the aligning, securing the first shipping container to the second shipping container to create the modular structure; and securing an inner flashing around an inner periphery of the first opening.

A container assembly includes a first component, a second component, and a third component. Each component has an outer wall, a side wall extending upward from the outer wall, and a lip extending outward around a perimeter of the side wall. Each of the lips of the components are releasably lockable with another lip to form a modular container assembly.

A rollingly conveyable transport unit (1) comprises a container shell (10) and an internal space (28), provided within the container shell, for accommodating a product (90) to be packaged. The container shell comprises two or more shell parts (11, 12) that are reversibly connected to one another in a force-fit manner by a closing element.