A cooler can comprise a shell that defines a cavity, a container disposed in the cavity, and one or more thermoelectric coolers (TECs). Each of the TEC(s) can have opposing first and second surfaces and be configured to transfer heat from the first surface to the second surface when an electric current flows through the TEC. Each of the TEC(s) can also be movable between a first position in which the first surface does not contact the container and a second position in which the first surface contacts the container.

A refrigerator includes a main body defining a storage space, a cryogenic freezing compartment having an insulation space that is independent with respect to the storage space, an evaporator disposed inside the storage space to cool the storage space, and a thermoelectric module assembly disposed at one side of the cryogenic freezing compartment so that the cryogenic freezing compartment is cooled to a temperature less than that of the storage space. The thermoelectric module assembly includes a thermoelectric module, a cold sink coming into contact with a heat absorption surface of the thermoelectric module and disposed in the cryogenic freezing compartment, and a heat sink coming into contact with a heat generation surface of the thermoelectric module. The heat sink is cooled by introducing a refrigerant supplied to the evaporator.

A refrigerator according to an embodiment of the present disclosure includes a cabinet, a door configured to open/close the cabinet, an outer plate defining a front surface of the door and having an opening formed therein to pass through the door, a door liner defining a rear surface of the door, lighting members configured to illuminate storage spaces of the door and the cabinet, a transparent panel assembly mounted to shield the opening and allowing the storage spaces to be selectively seen according to an ON/OFF state of the lighting members, an insulator filled between the outer plate and the door liner, and a blocking part arranged inside the door along a periphery of the transparent panel assembly and detachably coupled to a peripheral surface of the transparent panel assembly to fix the transparent panel assembly.

A vacuum insulated refrigerator structure includes an outer wrapper having a first opening and a first edge extending around the first opening. A liner has a second opening and second edge extending around the second opening. The liner is disposed inside the wrapper with the first and second edges being spaced apart to form a gap therebetween. An insulating thermal bridge extends across the gap, and an airtight vacuum cavity is formed between the wrapper and the liner. The thermal bridge includes elongated first and second channels having sealant disposed therein, and the first and second edges are disposed in the first and second channels, respectively. Porous core material may be disposed in the vacuum cavity.

A modular box assembly includes a box defining a box cavity within the box, the box further defining a top end and a bottom end, the top end defining a box opening connected to the box cavity, the box including a side panel extending from the top end to the bottom end; a shoulder attached to the side panel, the shoulder extending inward from the side panel and into the box cavity, the shoulder including a first sub-shoulder and a second sub-shoulder, the first sub-shoulder, the second sub-shoulder, and the side panel defining a shoulder channel; and an inner box disposed in the box cavity, the inner box including a channel tab, the channel tab frictionally engaging the shoulder channel to secure and suspend the inner box within the box cavity between the top end and the bottom end.

A refrigeration cabinet assembly for a refrigeration appliance (1) comprises an insulated cabinet (20) having five closed faces and an open front face providing access to an interior of the cabinet. A torsionally stiff structure fixed to one of the five closed faces (23) or a structure (31) is added to one of the five closed faces (23) so that together with that closed face a torsionally stiff structure results. The torsional stiffness of the assembly is thereby increased beyond that of the cabinet alone so that the insulated cabinet has an improved ability to resist twisting.

A vacuum adiabatic body and a refrigerator are provided. The vacuum adiabatic body includes a support that maintains a vacuum space between a first plate and a second plate, and a heat resistance unit comprising at least one radiation resistance sheet that blocks radiation heat transfer in the vacuum space so as to reduce heat transfer between the first plate and the second plate. The support includes two support plates, and the at least one radiation resistance sheet is supported by at least one support protrusion provided on a bar, which couples the two support plates to each other, to maintain an interval between the first plate and the second plate.

The endothermic syringe sleeve is an insulating storage structure. The endothermic syringe sleeve is configured to store a burette that contains an arterial blood samples. The endothermic syringe sleeve is configured to cool the arterial blood sample. The endothermic syringe sleeve is configured to store the arterial blood sample in the cooled state. The endothermic syringe sleeve comprises an endothermic sleeve and the burette. The endothermic sleeve forms a cooled environment within which the burette is stored.

A home appliance device, in particular a home refrigeration appliance device, has improved energy efficiency. The home appliance device has at least one inner liner defining at least one storage space and at least one functional unit which in an assembled state is connected to the inner liner and located in the storage space. The inner liner contains at least one accommodation element which in the assembled state at least partly accommodates the at least one functional unit.

A vacuum insulated refrigerator structure includes an outer wrapper having a first opening and a first edge extending around the first opening. A liner has a second opening and second edge extending around the second opening. The liner is disposed inside the wrapper with the first and second edges being spaced apart to form a gap therebetween. An insulating thermal bridge extends across the gap, and an airtight vacuum cavity is formed between the wrapper and the liner. The thermal bridge includes elongated first and second channels having sealant disposed therein, and the first and second edges are disposed in the first and second channels, respectively. Porous core material may be disposed in the vacuum cavity.