A method of making a vacuum insulated refrigerator structure includes positioning a core of overlapping stacked sheets of fiberglass mat in an envelope of impermeable barrier material. The core is pressed into a predefined three dimensional shape by pressing first and second mold parts together. The core is evacuated, and the envelope is sealed to form a three dimensional core having an airtight envelope around the core. The three dimensional vacuum core is positioned between a wrapper and a liner, and the wrapper and the liner are interconnected to form a vacuum insulated refrigerator structure.

A vacuum insulated cabinet structure includes first and second cover members having pre-deformed portions and perimeter portions. The perimeter portions of the first and second cover members are disposed along first and second planar levels and the pre-deformed portions of the first and second cover members include portions thereof extending outwardly relative to the first and second planar levels. A thermal bridge interconnects the first cover member and the second cover member at the perimeter portions thereof to define an insulating cavity therebetween. The insulating cavity is a sealed cavity having a vacuum drawn therefrom. The pre-deformed portions of the first and second cover members move inwardly towards the first and second planar levels under a force of the vacuum within the insulating cavity.

A refrigerator includes a vacuum adiabatic body having a storage space to store a product and a door to open or close the storage space. The main body includes a first plate and perforation plate. A cool air supply gap through which cool air flows is formed between the first plate and the perforation plate. At least two holes through which cool air is discharged to the storage space are formed in the perforation plate. The first plate may be a wall of the main body.

A vacuum insulated structure includes a trim breaker having a wrapper channel and a liner channel that extend perimetrically about the trim breaker. An inner liner is attached to the trim breaker at the liner channel. An outer wrapper is attached to the trim breaker at the wrapper channel. A metallic plate is disposed within the trim breaker and extends from a first area proximate the liner channel to a second area proximate the wrapper channel. The metallic plate defines an internal barrier to gas permeation through the trim breaker.

A refrigerator includes: an inner case including a plurality of plates formed by injection-molding; an outer case couplable with an exterior of the inner case; and an insulation between the inner case and the outer case. A first plate of the plurality of plates includes a first coupling portion formed along an edge of the first plate, and a second plate of the plurality of plates includes a second coupling portion formed along an edge of the second plate and couplable with the first coupling portion. The first coupling portion includes an insertion protrusion. The second coupling portion includes: an accommodating portion forming an accommodating groove in which the insertion protrusion is inserted; and a catching portion configured to prevent the insertion protrusion from departing from the accommodating groove; and an inner rib protruding from an inner surface of the accommodating portion to be inserted in the insertion groove.

A refrigerator includes a first inner case, a second inner case to be coupled to the first inner case, an outer case coupled to the first inner case and the second inner case, and an insulating material between the outer case, and the first inner case and the second inner case and the outer case. One of the first lower plate and the second upper plate includes an extension extending from the one of the first lower plate and the second upper plate, and a first coupler provided in the extension. An other one of the first lower plate and the second upper plate includes a second coupler to be coupled to the first coupler, and the first lower plate is coupled to the second upper plate by coupling the first coupler to the second coupler to prevent the insulating material from leaking between the first and second couplers.

A thermoplastic molding composition comprising (A) 15 to 45 wt.-% graft copolymer (A) obtained by emulsion polymerization of styrene and acrylonitrile in presence of an agglomerated butadiene rubber latex (A1) with D50 of 150 to 800 nm; (B) 40 to 75 wt.-% copolymer (B) of styrene and acrylonitrile having a weight ratio of 80:20 to 65:35 and Mw of 150,000 to 300,000 g/mol, (C) 2.0 to 5.0 wt.-% elastomeric block copolymer (C) made from 15 to 65 wt.-% diene, and 35 to 85% by weight vinylaromatic monomer; (D) 2.0 to 5.0 wt.-% titanium dioxide pigment D comprising at least 95 wt.-% titanium dioxide and 1.7 to 3.3 wt.-% alumina; and (E) 0 to 7.0 wt.-% of at least one additive/processing aid (E) different from (D); having a high chemical resistance, high color and thermal stability and low tendency to delamination. This can be used for sheet extrusion and thermoforming, in particular as inner liner for a cooling apparatus.

A refrigerator which comprises a housing, a refrigerating inner liner, a freezing inner liner and a foaming layer formed between the housing, the refrigerating inner liner and the freezing inner liner; the housing comprises a back plate and two side plates, and the foaming layer comprises a first foaming zone disposed close to the back plate, a second foaming zone disposed close to the side plates and a third foaming zone disposed in an interior of the middle beam, and the third foaming zone is connected to the second foaming zone; the refrigerator further comprises a sealing device that at least partially spaces the first foaming zone apart from the third foaming zone. After the foaming material reaches the first foaming zone, a lot of foaming material may be limited from entering the interior of the middle beam, so that the filling uniformity can be further improved effectively.

Product transport containers are disclosed. Such containers can provide one or more advantages compared to existing containers. For example, product transport containers described herein can maintain a product at a desired temperature for an extended period of time, including without the use of an active heating or cooling component. Such product transport containers described herein may also provide improved breathability, thermal insulation, and/or mechanical strength or dimensional stability. Such containers can include a plurality of walls defining an interior volume and a selectively openable side permitting movement of the product into and out of the interior volume of the container. The walls can be formed from a thermoformed non-woven fabric.

A refrigerator includes a cabinet with a plurality of walls and a compartment area for storing food within the cabinet. A door is configured to seal the compartment area. A refrigeration component is disposed within the cabinet. A wall panel is positioned within the cabinet and includes a three-dimensional molded surface with non-uniformly spaced peaks and valleys and a lighting structure. The wall panel extends from a lower end of the compartment area to an upper end of the compartment area. The wall panel separates the compartment area from the refrigeration component and is coextensive with one of the plurality of walls of the cabinet.