A liquid cooler device. The liquid cooler device having an interior cavity with a ledge, the ledge segregating the interior cavity into a lower portion for the placement of liquid and an upper portion for the receipt of an upper tray portion. The upper tray portion including a gasket for engagement with the ledge and designed for the dry storage of bulk items within the interior cavity. In use, the device acts as a combination cooler for both liquids and dry items.

Tissue-processing containers are disclosed for facilitating multistep processing of tissue. Also disclosed are systems incorporating the tissue-processing containers that include shakers, incubators, controllers, and pumps. Multistep methods are disclosed for processing tissues using the tissue-processing containers. The tissue-processing containers are specially designed to achieve efficiencies in automated tissue processing, exposure of tissues to processing media, and multistep tissue processing protocols. The described tissue-processing containers comprise a cup-like cavity comprising a middle hole covered by a mesh screen, troughs for separate processing steps, and are stackable in a substantially airtight and substantially watertight manner. Tissues for processing using the described tissue-processing containers include nerve tissue. Also described herein is a transport housing for the transport of stacks of tissue-processing containers, and which may directly incubate those containers, or which may be placed inside a separate incubator for incubating the containers.

Tissue-processing containers are disclosed for facilitating multistep processing of tissue. Also disclosed are systems incorporating the tissue-processing containers that include shakers, incubators, controllers, and pumps. Multistep methods are disclosed for processing tissues using the tissue-processing containers. The tissue-processing containers are specially designed to achieve efficiencies in automated tissue processing, exposure of tissues to processing media, and multistep tissue processing protocols. The described tissue-processing containers comprise a cup-like cavity comprising a middle hole covered by a mesh screen, troughs for separate processing steps, and are stackable in a substantially airtight and substantially watertight manner. Tissues for processing using the described tissue-processing containers include nerve tissue. Also described herein is a transport housing for the transport of stacks of tissue-processing containers, and which may directly incubate those containers, or which may be placed inside a separate incubator for incubating the containers.

A stackable bulk bin container having shock absorbing elements is provided. The bulk bin container includes a base portion and four collapsible sidewalls. The base includes feet extending downward. The feet are connected by stringers forming four corner portions. Shock absorbing elements are positioned proximate the corner portions in the base of the container. The shock absorbing elements absorb energy from impacts when the container is stacked on like containers.

A stackable storage box includes an upper box body and at least one modular storage unit. The upper box body includes a box bottom having a rotary portion and a positioning portion. The modular storage unit includes a lower base, an upper base and a drawer. The lower base includes a lower rotary portion and a lower positioning portion. The upper base includes an upper rotary portion and an upper positioning portion. The upper rotary portion is rotatably coupled with the rotary portion of the upper box body. The upper positioning portion is coupled with the positioning portion of the upper box body for positioning when the modular storage unit relative to the upper box body is rotated by a specific angle. A plurality of modular storage units can be rotatably stacked relative to one another and positioned with the upper and lower positioning portions combined.

In accordance with an embodiment, a hybrid modular furniture and container unit includes a base shell, a base core layer, and a set of base inner panels. The base shell has a shell bottom, a first shell wall, a second shell wall, a third shell wall, a fourth shell wall, and upper flaps associated with each of the respective walls. The base core layer has a core bottom, a first core wall, a second core wall, a third core wall, and a fourth core wall. The core layer is disposed within the base shell. The base inner panels include a first inner panel wall, a second inner panel wall, a third inner panel wall, and a fourth inner panel wall. The inner panel walls disposed within the shell and each upper flap is folded over a respective core wall and inner panel wall.

In accordance with an embodiment, a hybrid modular furniture and container unit includes a base shell, a base core layer, and a set of base inner panels. The base shell has a shell bottom, a first shell wall, a second shell wall, a third shell wall, a fourth shell wall, and upper flaps associated with each of the respective walls. The base core layer has a core bottom, a first core wall, a second core wall, a third core wall, and a fourth core wall. The core layer is disposed within the base shell. The base inner panels include a first inner panel wall, a second inner panel wall, a third inner panel wall, and a fourth inner panel wall. The inner panel walls disposed within the shell and each upper flap is folded over a respective core wall and inner panel wall.

A beverage brewing package includes a cup and a filter bag. The filter bag is supported in an interior region formed in the cup.

Polygonal sliding packaging having an inner hollow body (3) which slides telescopically within an outer hollow body (2) to form a variable length container which uses a twist-and-push or pull movement for closing and opening. The two hollow bodies are latched using assigned latchways (13-2 to 13-3), which are at least a first row of notches (6, 7) with at least one latch notch (5) disposed on one hollow body (3) and at least a second row of notches (9 through 12) with at least one latch notch (8) disposed on the other hollow body (2). Latchways are disengaged by twisting the two hollow bodies counter to one another about their longitudinal axes so that the latch notches of one latchway (13-3) reside within at least one slideway (14-2, 15-2), which is disposed on one hollow body (2) in a circumferential direction at a distance from the at least one latchway (13-2).

Polygonal sliding packaging having an inner hollow body (3) which slides telescopically within an outer hollow body (2) to form a variable length container which uses a twist-and-push or pull movement for closing and opening. The two hollow bodies are latched using assigned latchways (13-2 to 13-3), which are at least a first row of notches (6, 7) with at least one latch notch (5) disposed on one hollow body (3) and at least a second row of notches (9 through 12) with at least one latch notch (8) disposed on the other hollow body (2). Latchways are disengaged by twisting the two hollow bodies counter to one another about their longitudinal axes so that the latch notches of one latchway (13-3) reside within at least one slideway (14-2, 15-2), which is disposed on one hollow body (2) in a circumferential direction at a distance from the at least one latchway (13-2).