A device for dispensing items includes a cabinet, and a drawer within the cabinet. The drawer includes one or more compartments for storing items and a cooling system within the drawer. The cooling system is configured to maintain the one or more compartments in the drawer at a temperature below the temperature of the environment surrounding the cabinet. The drawer further includes thermal insulation at sides of the drawer and thermal insulation beneath the one or more compartments. The refrigeration system may be a thermoelectric cooling system.

A refrigerator includes a refrigerator cabinet, a fresh food compartment disposed within the cabinet, a freezer compartment disposed within the cabinet, an ice compartment disposed within the cabinet, and an electronic control system associated with the refrigerator and adapted to monitor and control the fresh food compartment, the freezer compartment and the ice compartment. The control system provides for energy efficient control and operation through various means, including by monitoring state of an ice maker associated with the ice compartment and controlling temperature within compartments of the refrigerator based on the ice maker state. A damper controls air flow between the fresh food and freezer compartments. The control system can direct heat to the damper if the damper becomes frozen.

A refrigerator has a refrigeration compartment, a drawer located inside the refrigeration compartment, and a lid adapted to open or close the drawer. The refrigeration compartment includes: a support module, mounted on an inner side wall of the refrigeration compartment, where the support module includes an elastic member; and a motor module, including a motor, a cam, and a connection portion connected to the lid and the cam. The motor drives the cam to generate a first rotation to push the connection portion to move upward, to cause the lid to compress upward the elastic member, so that the lid ascends to a first position. The motor further drives the cam to generate a second rotation to push the connection portion to move downward, to cause the connection portion and the elastic member to push downward the lid, so that the lid descends to a second position.

An artificial intelligent refrigerator is disclosed. The artificial intelligent refrigerator includes: one or more first temperature sensor that senses refrigerating compartment-internal temperature in a refrigerating compartment of the refrigerator; one or more second temperature sensor that senses freezing compartment-internal temperature in a freezing compartment of the refrigerator; and a refrigerator processor that calculates a load accumulation amount for food put in the refrigerator on the basis of the refrigerating compartment-internal temperature or the freezing compartment-internal temperature, and performs a load correspondence operation using the calculated load accumulation amount. According to the artificial intelligent refrigerator of the present disclosure, one or more of a user terminal, and a server of the present disclosure may be associated with an artificial intelligence module, a drone ((Unmanned Aerial Vehicle, UAV), a robot, an AR (Augmented Reality) device, a VR (Virtual Reality) device, a device associated with 5G services, etc.

A refrigerator including a refrigerator compartment, a dairy product maker inside the refrigerator compartment, a control panel configured to receive a control command, and a controller configured to control the dairy product maker based on the control command, the dairy product maker includes a container to store milk or a dairy product, a heater configured to heat the milk stored in the container, a fan configured to supply cool air inside the refrigerator compartment to the container, and a temperature sensor configured to measure a temperature inside of the dairy product maker, and the controller operates the heater for a preset fermentation period in response to the control command, turns off the heater and turns on the fan to cool down inside of the container after a lapse of the preset fermentation period, and turns off the fan in response to completing of the cooling down inside of the container.

A refrigerator includes a body including an inner case, a first storage compartment, a second storage compartment, a third storage compartment, a first partition between the second storage and the third storage compartments, a second partition between the first and the second storage compartments, a cold air supplier in the third storage compartment to generate cold air, a first communication hole, a second communication hole to face the first communication hole, a first guide duct formed in the first partition to guide the cold air from the first communication hole to the second communication hole, and a second guide duct formed in the second partition to guide the cold air which has flown to the first guide duct, to the second storage compartment, the second guide duct connected to the first guide duct through the second communication hole.

An example transport refrigeration system includes first and second refrigeration circuits configured to cool first and second transport compartments, respectively. An electric machine powers the first and second refrigeration circuits. A controller is configured to monitor a temperature of the electric machine, and reduce a cooling capacity of a selected one of the first and second refrigeration circuits based on the temperature exceeding a first threshold.

A refrigerator appliance includes a cabinet with at least one food storage chamber defined in the cabinet. The refrigerator appliance also includes a sealed cooling system in fluid communication with the at least one food storage chamber via a multi-flow system. A plurality of independently cooled zones are defined within the at least one food storage chamber. The refrigerator appliance also includes a temperature control module selectively positionable in one of the plurality of zones. Methods of operating the refrigerator appliance may include and/or a controller of the refrigerator appliance may be configured for locating the temperature control module, receiving a temperature setting from the temperature control module, and adjusting operation of at least one of the sealed cooling system and the multi-flow system in response to the received temperature setting from the temperature control module.

A control method for a refrigerator and a refrigerator are provided. The refrigerator includes a compartment, an evaporator, and a heating module. The method includes: acquiring a current temperature of the compartment; and adjusting an operating power of the heating module according to the current temperature, so that the heating module heats the compartment to a target temperature according to the operating power, where different temperature ranges correspond to different operating powers.

The present disclosure relates to a refrigerator. The refrigerator includes an evaporator, a defrost heater, a temperature sensor to detect an ambient temperature of the evaporator, and controller to control the defrost heater, wherein, in response to a defrosting operation start time point arriving, the controller is configured to perform a defrost operation mode including a pre-defrost cooling mode, a heater operation mode, and post-defrost cooling mode, perform a pulse operation mode in which the defrost heater is repeatedly turned on and off based on the heater operation mode, and change a magnitude of cooling power supplied in the post-defrost cooling mode based on an ON period of the defrost heater or a temperature of a cooling compartment in the pulse operation mode. Accordingly, defrosting efficiency and power consumption may be improved, and cooling power after defrosting may be efficiently supplied.