A cooling device including a liner defining a freezer compartment, a shelf positioned within the freezer compartment, and an ice maker assembly secured to the shelf. The ice maker assembly including an ice maker configured to produce ice pieces, and an ice maker support frame that supports the ice maker. The ice maker support frame includes a fill cup and an air plenum, the air plenum defining a channel therein and extends between first and second walls of the ice maker support frame. A fan is disposed adjacent the ice maker frame at a location corresponding to the air plenum. The fill cup is configured to receive water from a water fill tube and direct the water to an ice tray of the ice maker.

The storage cell includes ventilation means suitable for creating a rear-to-front air flow or a front-to-rear air flow, an inflatable sealing device, and inflation means which allow the inflatable sealing device to be inflated. The inflatable sealing device includes an upper inflatable sealing element and at least one side inflatable sealing element which directly or indirectly allow, in the inflated state, a seal between the upper wall of the cell and at least one part of the top face of a set of products positioned in the cell and a seal between at least one side wall of the cell and at least one part of one of the side faces of this set of products. The upper inflatable sealing element and the side inflatable sealing element delimit a single inflatable chamber, and the inflation means allow the upper inflatable sealing element and the side inflatable sealing element to be inflated by blowing air into this single inflatable chamber.

A refrigeration appliance including a compartment for storing food items. A partition divides the compartment into a first and a second compartments. The first compartment is disposed horizontally adjacent the second compartment and has a user-selectable target freezer temperature. An evaporator is disposed in the first compartment. An evaporator fan is disposed in the first compartment for conveying cooling air from the evaporator to the first and the second compartments. A temperature control module positioned in the second compartment. The temperature control module includes a body having front and rear surfaces. An air passage is formed in the body and extends between a side inlet opening of the body to at least one outlet opening on the front surface of the body. A heater assembly is disposed between the front and the rear surfaces of the body for heating air in the air passage.

A refrigerator according to an embodiment includes: a duct dividing the inside of a storage compartment body into a storage compartment and an air channel and having a main discharge port and a sub-discharge port; an air guide dividing the air channel into a first channel communicating with the main discharge port and a second channel guiding air in the first channel to the sub-discharge port; a heat exchanger provided in the first channel; and a fan suctioning air in the storage compartment and sending the air to the first channel. According to the refrigerator, it is possible to maximize the volume of the storage compartment and separately discharge air to the main discharge port and the sub-discharge port, using a simple structure.

The present invention discloses an air duct shielding device and an air-cooled refrigerator; the air duct shielding device includes: a fan base having a plurality of air outlets; a first adjusting part having a rotary disc portion and a plurality of first shielding sheets arranged at intervals, the first adjusting part being configured to controllably rotate around an axis of the rotary disc portion; and a second adjusting part provided between the first adjusting part and the fan base, the second adjusting part having a plurality of second shielding sheets arranged at intervals; wherein when the first adjusting part rotates around the axis of the rotary disc portion, the second adjusting part is driven to rotate, such that the first shielding sheet and/or the second shielding sheet completely shield(s), partially shield(s) or completely expose(s) each air outlet, thereby adjusting an air outlet area of each of the plural air outlets.

A refrigerator includes an inner case defining a storage chamber, a door disposed at a front portion of the inner case and defining a storage space therein, a cool air distribution device disposed inside the inner case and defining a box inlet portion configured to receive cool air, a multi-duct disposed in the inner case and defining discharge holes configured to discharge a first portion of cool air in the cool air distribution device to the storage chamber, and a duct assembly that extends from the cool air distribution device toward the door and that is configured to carry a second portion of cool air in the cool air distribution device. The inner case defines a case inlet at the front portion of the inner case, and the case inlet is configured to communicate with the duct assembly and supply the second portion of cool air to the storage chamber.

The present disclosure relates to a refrigerator. The refrigerator is configured to supply cool air to a refrigerating compartment, a freezing compartment, and an ice-making compartment by a single evaporator. A cool air passage for the ice-making compartment for supplying cool air to the ice-making compartment is configured to supply the cool air to an upper space in a cool air passage for the freezing compartment, which. supplies cool air to the refrigerating compartment and the freezing compartment, through an upper supply passage. Accordingly, since additional cool air is supplied to the cool air passage for the freezing compartment by using the upper supply passage, sufficient cool air is supplied to the refrigerating compartment and the freezing compartment by the single evaporator.

The present disclosure relates to a refrigerator. Wherein a cool air passage for a freezing compartment, the cool air passage guiding the flow of cool air to the freezing compartment, and a cool air passage for an ice-making compartment, the cool air passage guiding the flow of cool air to the ice-making compartment, partially share the cool air thereof. Through the sharing of cool air, the amount of cool air supplied to the freezing compartment is increased and sufficient cool air is supplied to the refrigerating compartment. Accordingly, sufficient cool air is supplied to the refrigerating compartment, the freezing compartment, and the ice-making compartment even with a single evaporator.

Provide is a refrigerator provided with a defrosting device capable of enhancing the defrosting efficiency. The refrigerator includes main body, storage compartment provided inside the main body, an evaporator provided in the storage compartment and configured to generate cold air, a first flow path allowing air to be guided in a first direction for the air to be supplied to the storage compartment during a cooling operation, a defrosting heater configured to generate heat for defrost, a second flow path allowing air to be guided in a second direction opposite to the first direction for the air to be circulated around the evaporator during a defrosting operation, a fan allowing air having received heat from the defrosting heater to be circuited around the evaporator through the second flow path, and a flow path resistance portion provided on the second flow path to increase a flow path resistance in the first direction.

An ice maker (126) including an ice maker frame having an air inlet provided at a first end thereof. An ice tray (144) is rotatably secured to the ice maker frame and configured to form ice pieces therein. An air handler (142) includes an outlet diffuser having a central body defined by a first wall—and a radially spaced apart second wall, wherein a plurality of radially extending fins are disposed between the first and second walls. Each of the fins is spaced apart, one from the other, along an outer peripheral surface of the first wall. In an installed position, the outlet diffuser is disposed directly adjacent the air inlet at the first end of the ice maker frame. A method is provided for synchronizing an ice making cycle of an ice making unit and a defrost cycle of an evaporator.