An insulated packaging assembly can include a box including a top side wall, a bottom side wall, a first lateral side wall, a second lateral side wall, a third lateral side wall, and a fourth lateral side wall the box defining a cavity; a first thermal liner positioned in the cavity, a first portion of the first thermal liner positioned in contact with the top side wall, a second portion of the first thermal liner positioned in contact with the first lateral side wall, a third portion of the first thermal liner positioned in contact with the bottom side wall; and a second thermal liner defining a first end and a second end disposed opposite from the first end, the second thermal liner defining an inner surface and an outer surface disposed opposite from the inner surface.

A packaging assembly includes first insulation blocks, second insulation blocks, and third insulation blocks, each insulation block arranged in contact with at least one other insulation block to define a void, the packaging assembly including at least one enclosure, the insulation blocks at least partially surrounded by the at least one enclosure.

Insert container for a shipment carrier, which insert container comprises at least one side wall and a bottom, which enclose a receiving space which can be closed with a lid, the at least one side wall and/or the bottom having a multilayer wall structure comprising at least one layer of at least one vacuum insulation panel and at least one layer of a particle foam, such as in particular expanded polypropylene (EPP), and wherein the at least one layer of particle foam is formed at each point with a thickness in the range from 2 mm to 12 mm.

To improve the moldability and keeping cold performance of a vacuum heat insulating container. A constant temperature container includes a heat insulating container formed by disposing a core material between an outer cover material and an inner cover material and sealing the core material in a reduced-pressure state. The core material includes a first core material, the first core material being an organic substance made of open-cell foam, and a second core material having a lower thermal conductivity than the first core material at a vacuum degree of 100 Pa or less.

The present invention provides a thermally insulated shipping container 1 comprising a thermally insulating layer 5 defining a first void, a main layer 9, 10, 11 containing phase change material (main PCM layer) within the first void and defining a second void within the first void, a barrier layer 12 containing phase change material (barrier PCM layer) within the second void and distinct from the main PCM layer, the barrier PCM layer 12 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 9, 10, 11 has an average thickness greater than the average thickness of the barrier PCM layer 12, the barrier PCM layer 12 comprises of an envelope in which the phase change material of the barrier PCM layer 12 is contained and the barrier PCM layer 12 is configured to maintain the phase change material with a relatively even distribution within the envelope.

Insulating assemblies having improved thermal seals are provided. The insulating assemblies have an interface between a base portion and a lid that has an angled transitional portion and at least one elevation change. The angled transitional portion advantageously improves lid removability, assembly reusability, and resistance to thermal energy transfer.

The present disclosure relates to a containment system comprising hard and soft containers. More specifically, but without limitation, present disclosure relates to a containment system which provides soft containers sized to fit within the hard container and provide an organized arrangement of soft containers within the hard container, as well of differing levels of insulation to provide at least some level of food safe storage, as well as some level of damage protection for the items stored therein.

Provided is a thermostatic container that improves both the communication radio wave transmissivity and keeping cold performance of a thermostatic container. A thermostatic container includes: a vacuum heat insulating container; a vacuum heat insulating lid configured to close the vacuum heat insulating container; a box body housed inside the vacuum heat insulating container; a box lid configured to close the box body; and a phase change material provided on a bottom portion and a wall portion of the box body and the box lid. An area made of a radio wave transmissive organic substance is provided on a path leading from inside of the box body to outside of the heat insulating container.

A cold storage box is provided that allows individual confirmation that stored objects such as medicine, food, and beverages have been managed at an appropriate temperature. The cold storage box 1 includes: a storage part which can house stored objects; a lid part which covers an opening part of the storage part; and a cooling device which cools the storage part, and the cold storage box includes an RF tag provided for each of the stored objects and equipped with a temperature sensor and a control part which communicates with the RF tag at appropriate time intervals via an antenna part provided inside the storage part and stores ID information of the RF tag and temperature information sensed by the temperature sensor of the RF tag.

The present invention provides a thinner, movable load bearing structure having indentations, grooves, valleys, channels or other similar depressions on its underside. These depressions are mated with corresponding features for improved loading bearing capabilities. The load bearing structures also includes roughened side edges for improving the strength of the edges. The load bearing structure may be a dunnage platform or a container for storing and/or shipping cargo.