A drawer assembly contains a drawer, a cap, and a sealing member. The drawer has an upward opening. The cap being capable of sliding forward and backward relative to the drawer to open or close the opening. The sealing member is disposed between the cap and the drawer and has a sealing surface between the sealing member and the drawer or the cap, and the sealing surface has a rough feature. More specifically, the sealing surface has the rough feature. Therefore, when the cap closes the opening, a contact area between the sealing member and the drawer or the cap is relatively reduced, binding is relatively weakened, and suction is relatively reduced. The cap can be easily pushed away by merely applying relatively little thrust to open the opening when the opening of the drawer needs to be opened, greatly facilitating use by a user.

A vacuum adiabatic body includes a conductive resistance sheet which blocks heat conduction between plate members, and a sealing frame which covers the conductive resistance sheet. The sealing frame includes a side surface part, an outer surface part which is bent and extends from a side of the side surface part, and an inner surface part which is bent and extends from the other side of the side surface part. The sealing frame is provided as a configuration of a concave groove in which the width between the outer surface part and the inner surface part is smaller than the width of the side surface part. According to the present invention, a peripheral portion of the vacuum adiabatic body can be stably maintained.

A sealing structure and a refrigerated container having same. The sealing structure comprises a base, a protruding portion, a deforming portion, and connections through holes. The base is a bar having a predetermined thickness. The protruding portion and the deforming portion are on a sealing surface of the base, and are configured to protrude outwards relative to the sealing surface and extend lengthwise along the base. The deforming portion extends by the same length as but higher than the protruding portion. When the deforming portion is subjected to a force toward the sealing surface, the height decreases. The holes are between the protruding portion and the deforming portion along the base. The holes are spaced apart from each other in the lengthwise direction of the base. The performance of the sealing structure improves hermeticity of products, reduces quality risks, and ensures pressure-resistance installation and anti-weathering performance that extends service life.

A vacuum adiabatic body includes a conductive resistance sheet which blocks heat conduction between plate members, and a sealing frame which covers the conductive resistance sheet. The sealing frame includes a side surface part, an outer surface part which is bent and extends from a side of the side surface part, and an inner surface part which is bent and extends from the other side of the side surface part. The sealing frame is provided as a configuration of a concave groove in which the width between the outer surface part and the inner surface part is smaller than the width of the side surface part. According to the present invention, a peripheral portion of the vacuum adiabatic body can be stably maintained.

A home appliance device, in particular a home refrigeration appliance device, has improved energy efficiency. The home appliance device has at least one functional unit, which is embodied as a partitioning unit for partitioning at least one storage space into at least two subspaces in an assembled state. The partitioning unit contains at least one thermal insulation inlay element and at least one protective foil. The at least one thermal insulation inlay element is encased by the protective foil.

A refrigerating unit including a compartment, a glass door, and a heating arrangement installed in a base profile of the compartment. The refrigerating unit including an elongated gasket profile having a proximal part and a distal part, wherein the proximal part includes a flexible element configured to allow the distal part to be displaced towards the base profile upon closing the glass door. The distal part includes a hollow part with a first side of the hollow part connected to the proximal part and a second side of the hollow part directed towards the glass door. The heating arrangement further includes a heat-conducting material enclosed by the hollow part and arranged with an outer side surface of the heat-conducting material abutting the second side of the hollow part, and a heating element enclosed by the hollow part and arranged for conductive heating of the heat-conducting material.

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 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 vacuum adiabatic body includes a heat exchange pipeline and a sealing plug. The heat exchange pipeline includes at least two pipelines which pass through a first plate and a second plate to allow a refrigerant to move between inner and outer spaces. The sealing plug allows the heat exchange pipeline to pass through a first point of the first plate and a second point of the second plate without contacting a third space.

A method including forming a housing configured to house a number of first magnets; fixing the number of first magnets to the housing to form a magnetic sub-assembly; and attaching the magnetic sub-assembly to at least one of the closure or the body. The magnetic sub-assembly being configured to cooperate with a number of second magnets disposed on either the closure or the body, so that when the closure is in the closed position, a magnetic force between the magnetic sub-assembly and the number of second magnets biases the closure towards the body.