A portable insulated storage container includes a first divider and an insulated body. The first divider includes a first projection defining a length having a first dimension and a width having a second dimension. The insulated body has an internal cavity adapted for storing items and at least partially bounded by a bottom, a first wall, and a second wall opposite the first wall. The first wall includes a first groove adapted to receive the first projection in a first orientation. One of the first wall and the second wall includes a second groove adapted to receive the first projection in a second orientation. The first groove has a width adapted to receive the width of the first projection and the second groove has a width adapted to receive the length of the first projection.

The present invention provides a thermally insulated shipping container comprising a thermally insulating layer defining a first void, a main layer containing phase change material (main PCM layer) within the first void and defining a second void within the first void, a barrier layer containing phase change material (barrier PCM layer) within the second void and distinct from the main PCM layer, the barrier PCM layer defining a third void within the second void, the container being arranged to receive a product for transportation inside of the third void, wherein the main PCM layer has an average thickness greater than the average thickness of the barrier PCM layer, the barrier PCM layer comprises of an envelope in which the phase change material of the barrier PCM layer is contained and the barrier PCM layer is configured to maintain the phase change material with a relatively even distribution within the envelope.

The present invention relates to a shipping container for mitigating external fire risks. The shipping container is configured for shipping lithium ion batteries with a cargo cavity proximate and interior to a second inner flame-retardant corrugated layer. The second inner flame-retardant corrugated layer is proximate and interior to an inner thermal paste panel. The inner thermal paste panel is proximate and interior to a dead air space panel. The dead air space panel is proximate and interior to a first inner flame-retardant corrugated layer. The first inner flame-retardant corrugated layer is proximate and interior to an outer thermal paste panel. The outer thermal paste panel is proximate and interior to a flame-retardant corrugated carton. The thermal paste panels preferably comprise aluminum flashing containing a mesh matrix for holding flowable thermal paste. The shipping container is lidded by a fitted cap above an air cap above a vacuum plenum cap.

A chest insert for a freezer is disclosed. The chest insert is placed inside a freezer and food is placed inside the chest insert. Several sides of the chest insert comprise a gap which is partially filled with a refrigerant gel. These gaps are slanted such that the gel can expand into a wider gap as it expands while freezing, lessening the risk of uneven freezing causing the refrigerant gel to press agains the walls of the chest insert. The use of the disclosed subject matter reduces freezer burn by stabilizing humidity. Further, the chest insert maintains the temperature inside the chest insert for extended periods if the freezer fails or the power to the freezer is interrupted.