A vacuum insulated appliance structure, comprising: a first layer of a first polymer material. A second layer of a second polymer material is molded to (e.g. over) at least a portion of the first layer, and a third layer of a third polymer material is molded to (e.g. over) at least a portion of the second layer to form a first component. At least one of the layers is impervious to one or more gasses. One or more additional components are secured to the first component to form a vacuum cavity. The vacuum cavity is filled with a porous material, and the vacuum cavity is evacuated to form a vacuum.

The disclosed technology includes a passive temperature controlled container for passively maintaining a specified temperature range in a storage chamber of the container for a predetermined amount of time. The passive temperature controlled container may be configured to have an inner PCM layer and an outer PCM layer, with an air chamber layer between the two PCM layers to allow for the free movement of air around all six sides of the container.

A container assembly having an expandable insulated container and an expandable insert. The insert includes an open upper rigid portion having side panels and a lower rigid portion having side panels a bottom panel, and the upper and lower rigid portions are joined by a flexible medial portion.

A hard-sided cooler box may include a channel or cylindrical-shaped hole that extends from the outside of the cooler box to the inside of the cooler box. This cylindrical-shaped hole or channel may be covered/sealed by one or more latches of the cooler box when the cooler box is closed, and the latches are secured. However, when the latches of the cooler box are released, the cylindrical-shaped hole or channel may be unblocked, and the air from the interior of the cooler box can escape to the outside of the cooler box before the lid is lifted from the body. This allows the lid to be opened with no struggle.

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.

Example aspects of an insulated box assembly and a method of assembling an insulated box assembly are disclosed. The insulated box assembly can comprise a plurality of outer lateral sidewalls, the outer lateral sidewalls defining an inner surface, the inner surface defining an inner cavity; a plurality of inner lateral sidewalls received in the inner cavity, the inner lateral sidewalls defining an outer surface; and a monolithic sidewall liner received in the inner cavity between the outer lateral sidewalls and the inner lateral sidewalls, the sidewall liner defining a liner outer surface and a continuous, uninterrupted liner inner surface opposite the liner outer surface, the liner outer surface facing the inner surface of the outer lateral sidewalls, and the liner inner surface facing the outer surface of the inner lateral sidewalls.

A vacuum-insulated container (1) comprises a container body (2) and a container lid (3). The container body (2) is formed from an inner body shell (8) and an outer body shell (6), which are both made of a metal material. A core (7) is provided between the inner body (shell 8) and the outer body shell (6), and a seal (11) connects to (flanges 12) of the inner body shell (8) and the outer body shell (6), so as to define an intermediate vacuum space (10) surrounding the core (7). A compressible gasket (17) is provided to protect the seal (11). The lid (103) has two pair of fasteners (122) hingedly connected to opposing sides of the lid (103). Each of the fasteners (122) is releasably connectable to the body (102) whilst the lid is in a closed position with respect to the body.

A temperature insulated packaging system includes a container having interior surface bounding an interior volume and a liner disposed within the interior volume and at least partially bounding a compartment configured to receive an item for temperature insulated shipping. The liner includes a first sleeve made of cellulose material and at least partially bounds a channel. The first sleeve has an outside wall disposed adjacent to the container and an opposing inside wall disposed adjacent to the compartment configured to receive the item for shipping, the channel being disposed between the inside wall and the outside wall. At least one insulation sheet is disposed within the channel of the first sleeve, the at least one insulation sheet being made of a cellulose material and having a plurality of recesses formed thereon.

Thermally insulated shipping system for use in transporting a pallet-sized payload. In one embodiment, the system includes a plurality of thermally insulating walls arranged to define an interior volume suitable for receiving a pallet-sized payload. The thermally insulating walls include a top wall, a bottom wall, a front wall, a rear wall, a left wall, and a right wall, of which all but the bottom wall include at least two slots facing towards the interior volume. One of the slots is an inner slot that is more proximal to the interior volume, and one of the slots is an outer slot that is more distal to the interior volume. The system also includes a plurality of inner cassettes disposed in at least some of the inner slots and a plurality of outer cassettes disposed in at least some of the outer slots. The inner and outer cassettes include phase-change materials.

Provided is a constant temperature container capable of largely improving the heat insulating property. A constant temperature container includes: a heat insulating container; a heat insulating lid configured to close the heat insulating container; a box body housed inside the heat insulating container; a box lid configured to close the box body; a phase change material provided on a bottom portion and a wall portion of the box body and the box lid; and a support member provided between the bottom portion of the box body and a bottom portion of the heat insulating container, the support member supporting the box body in such a manner that the wall portion of the box body is separated from a wall portion of the heat insulating container.