A refrigerating appliance comprises a cabinet, at least one door, and at least one hinge allowing the door to rotate about an axis for opening and closing, and further comprising at least one bracket configured to support the hinge, and at least one flexible tubular element inserted on one side in the cabinet and on the other side in the door. The flexible tubular element is configured to exit through a top wall of the cabinet, and is further configured to enter a cavity of the door by passing through a slot formed in the top wall of the door. The slot partially surrounds the hinge, and the slot is partially under the bracket when the door is closed.

A vacuum adiabatic body includes: a first plate member defining at least one portion of a wall for a first space; a second plate member defining at least one portion of a wall for a second space having a different temperature from the first space; a sealing part sealing the first plate member and the second plate member to provide a third space that has a temperature between the temperature of the first space and the temperature of the second space and is in a vacuum state; a supporting unit maintaining the third space; a heat resistance unit for decreasing a heat transfer amount between the first plate member and the second plate member; an exhaust port through which a gas in the third space is exhausted; a side frame provided at an edge portion of the third space, the side frame having at least one portion defining a wall for the third space; and a peripheral frame fixed to the side frame to have a part mounted thereto. Accordingly, each part of the vacuum adiabatic body can be mounted without any interference, and an adiabatic effect can be improved.

A refrigerator includes a cabinet including a refrigerating compartment and an evaporation chamber, a first door, a housing in the first door, an ice making room defining a cool air inflow hole and a cool air discharge hole, a chiller room defining a cool air discharge hole, a second door connected to the first door, a partition wall defining the ice making room, the chiller room, and a communication hole, a damper opening and closing the communication hole, a cool air supply duct connecting an outlet of the evaporation chamber and the cool air inflow hole to supply cool air of the evaporation chamber to the ice making room, and a cool air return duct having a first inlet connected to the cool air discharge hole of the ice making chamber and a second inlet connected to the cool air discharge hole of the chiller room.

A mobile cooling box having a box main body and at least one lid for opening the box and providing access to the inside of the box. The at least one lid is pivotally attached to the box main body by at least two hinge modules. Each hinge module comprises a pin module having a hinge pin with a front end, a rear end, a longitudinal axis about which the lid is pivotable and predominantly a smooth outer surface of a cylindrical shape. Each hinge module further comprises a bearing module having a hinge bearing accommodating the hinge pin. The hinge pin laterally extends with its front end into the hinge bearing. A bolt portion extends from the rear end of the hinge pin so that so that the pin module is mountable by the bolt portion.

A system and method for a cooler with a barrier. The cooler has an internal void and a barrier located within said void. The barrier has at least one covered opening. The barrier acts as a physical barrier which prevents air from exiting the cooler. A user can retrieve contents through the covered opening. In this manner, the temperature within the cooler is maintained.

A refrigerator includes a cabinet, a door, and a hinge connecting the door to an upper surface of the cabinet. The hinge includes a mounting part mounted on the cabinet and a hinge pin inserted into the door. The door includes a door body that has a hinge mounting part and is filled with an insulating material, and a panel assembly mounted on a front surface of the door body. The hinge mounting part is recessed into the door body and receives the hinge inserted at a position spaced apart from the upper end of the door body. A pin mounting hole into which the hinge pin is inserted is formed on a lower surface of the hinge mounting part, and an upper opening through which an electric wire directed into the door passes is formed on an upper surface of the hinge mounting part.

A refrigerator includes a cabinet having a storage space, a hinge bracket configured to be installed on an upper wall of the cabinet and having a hinge shaft, a door configured to be connected to the hinge shaft and to open and close the storage space while rotating, and a hinge cover configured to be installed on the upper wall of the cabinet and to cover the hinge bracket, in which the hinge cover includes a first mounting part and a second mounting part disposed to be spaced apart in a horizontal direction, a bracket cover detachably mounted on one mounting part of the first mounting part and the second mounting part disposed at a position corresponding to the hinge bracket and configured to cover the hinge bracket, and a shielding member detachably mounted on another mounting part of the first mounting part and the second mounting part.

A refrigerator box body includes mounting bases (1) used to mount hinges, a box housing (2) provided with an upward opening, and an opening frame (3) connected to the opening of the box housing (2), a side plate of the box housing (2) being provided with mounting ports (4) penetrating the side plate of the box housing (2) along the thickness direction, the mounting bases (1) being arranged within the mounting ports (4), the mounting bases (1) being provided with depressions (11) with concave sides toward an inside of the box housing (2), the hinges being mounted within the depressions (11), the mounting bases (1) being provided with guide grooves (12), side edges of the mounting ports (4) being inserted into the guide grooves (12) so as to connect the mounting bases (1) and the box housing (2), an edge of the opening frame (3) abutting against upper sides of the mounting bases (1).

Provided is a wireless power transmission system for a rotating connector. A wireless power transmission system for a rotating connector according to an embodiment of the present invention comprises: a wireless power transmission module comprising a first magnetic core and a first coil, provided on a fixed first connector, and using the power thereof to generate a magnetic field and transmit wireless power; and a wireless power receiving module comprising a second magnetic core and a second coil, and provided on a second connector, which is rotatably connected to the first connector, to receive the transmitted wireless power and supply same to the second connector. The first and second magnetic cores are positioned in a straight line along the rotational axis of the second connector.

The present invention provides a refrigerator, comprising a refrigerator body and a door body. A hinge body is disposed on the refrigerator body. A first hinge shaft and a second hinge shaft are disposed on the hinge body. A first guide groove and a second guide groove are formed in the door body. The first hinge shaft is located in the first guide groove and the second hinge shaft is located in the second guide groove. During opening of the door body, the first guide groove moves relative to the first hinge shaft and the second guide groove moves relative to the second hinge shaft, the first hinge shaft applies an acting force to the first guide groove to drive the end, away from the first guide groove, of the second guide groove to approach the second hinge shaft, so that the door body is displaced in a horizontal direction.