A refrigeration device includes a blow-out temperature detector that detects the blow-out temperature of air blown out into the interior of the device, a cargo temperature detector that detects the temperature of a cargo, an operation controller that performs cooling control of the interior on the basis of the detection temperature from the blow-out temperature detector and the detection temperature from the cargo temperature detector, a storage unit that stores a first set temperature as a control target value for the blow-out temperature and a cargo target temperature as a target value for the temperature of the cargo, and a time measurement unit that measures a treatment time elapsed for low-temperature treatment of the cargo. The operation controller is configured to control the refrigerant circuit so that the blow-out temperature approaches the first set temperature. The time measurement unit is configured to start measuring the treatment time when the temperature of the cargo is lower than the cargo target temperature.

A refrigeration device with a refrigerant circuit for cooling at least two cooling chambers. The device has a condenser of the refrigerant circuit configured to liquidize refrigerant, a compressor of the refrigerant circuit compresses refrigerant, a first evaporator of the refrigerant circuit cools a first cooling chamber of the refrigeration device, a second evaporator of the refrigerant circuit cools a second cooling chamber of the refrigeration device, and a multi suction line of the refrigerant circuit connects the condenser with the compressor. The first and second evaporators are positioned on the multi suction line in a consecutive order. The multi suction line has a first capillary tube, a second capillary tube, and a suction pipe. The first capillary tube connects the condenser with the first evaporator, the second capillary tube connects the condenser with the second evaporator, and the suction pipe connects the first and second evaporator with the compressor.

A refrigerator including a refrigerator compartment; a freezer compartment; an ice compartment disposed in the refrigerator compartment; an ice maker assembly disposed in the ice compartment, the ice maker assembly including an ice maker tray/evaporator having an evaporator cooling tube which is in direct contact with the ice maker tray portion; an ice bucket for storing ice disposed in the ice compartment; and an air handler/auger motor assembly disposed at a rear portion of the ice compartment behind the ice bucket. The air handler/auger motor assembly includes an air passage having a fan disposed therein. An inlet of the fan communicates with an airflow passage under the ice maker tray/evaporator, such that the fan creates a suction and draws cool air from the ice maker tray/evaporator and discharges the cool air through the air passage and to the ice bucket to prevent any ice in the ice bucket from melting.

Disclosed herein is a refrigerator. The refrigerator includes a storage compartment, an evaporator configured to cool the air in the storage compartment, a first heater provided in the vicinity of the evaporator, a tray provided to accommodate water, a refrigerant pipe provided in contact with the tray and configured to cool the tray, a second heater provided in the vicinity of the refrigerant pipe, a compressor configured to supply a compressed refrigerant to at least one of the evaporator or the refrigerant pipe, and a processor configured to start an operation of the second heater after starting an operation of the first heater, and configured to start an operation of the compressor after stopping the operation of the first heater and the second heater. Accordingly, it is possible to prevent ice from being agglomerated caused by the defrosting operation.

A method for controlling a refrigerator includes operating a heater of the refrigerator in a first mode to increase a temperature of an evaporator of the refrigerator to a predetermined temperature, the first mode comprising a continuous operation of the heater, determining a period of time taken to increase the temperature of the evaporator to the predetermined temperature, determining whether the period of time is within a reference period of time, maintaining operation of the heater in the first mode based on a determination that the period of time is outside of the reference period of time, and operating the heater in a second mode that is different from the first mode based on a determination that the period of time is within the reference period of time.

A method for controlling a refrigerator includes providing an initial input value to a heater configured to supply heat to an evaporator, performing a continuous operation of the heater based on the initial input value to increase a temperature of the evaporator to a predetermined temperature, determining a period of time taken to increase the temperature of the evaporator to the predetermined temperature, determining whether the period of time is within a reference period of time, operating the heater based on a first input value that is equal to the initial input value based on a determination that the period of time is outside of the reference period of time, and operating the heater based on a second input value that is less than the initial input value based on a determination that the period of time is within the reference period of time.

A method of controlling the temperature in cavities of a refrigerator (10) cooled by a refrigeration circuit having a compressor (18) and an evaporator (32) includes the steps of: monitoring the duty cycle of the compressor (18); determining whether the duty cycle is below a threshold; determining whether the temperature of the evaporator (32) is above a threshold; and if the duty cycle is below the threshold and if the evaporator temperature is above a threshold, activating the refrigeration circuit to start cooling of at least one of the refrigerator cavities. A refrigeration appliance (10) with a controller that activates the refrigeration circuit based on the monitored duty cycle of the compressor (18) and the evaporator temperature is also provided.

A refrigerator a duct arranged to partition an inner space of a storage chamber body into a storage chamber and an air flow channel, wherein the duct has an ejection hole defined therein; a roll-bond evaporator disposed in the air flow channel, wherein the roll-bond evaporator has a top and a bottom, a left end and a right end; a blowing fan configured to draw air from the storage chamber to blow the air into the air flow channel; and a defrost sensor closer to one of the top and bottom than the other of the top and the bottom, wherein said one is closer to the blowing fan than the other, wherein the sensor is closer to one of the left end and the right end than the other of the left end and the right end.

Standalone and self-contained cooling systems using compressed liquid and/or gas CO.sub.2 containers positioned in an insulated or non-insulated vessel and consisting of a specially designed unit where the containers are vertically positioned in an upright or upside-down position.

The liquid and/or gas CO.sub.2 coolant is then released into capillary tube(s) embedded into a heat transfer plate or heat exchanger thus leveraging the CO.sub.2 coolant properties.

The temperature is controlled by a metering CO.sub.2 releasing system encompassing an electronic control device which can be operated remotely and/or via a touch screen and which sends alerts when pre-defined thresholds are exceeded.

The invention's metering CO.sub.2 releasing system may be triggered by an electronic or a thermostatic valve or may be triggered manually or by an electronic solenoid. The invention's cooling system also encompasses check valves, which avoid liquid and/or gas CO.sub.2 from escaping when removing or replacing CO.sub.2 containers individually.

Standalone and self-contained cooling systems using compressed liquid and/or gas CO.sub.2 containers positioned in an insulated or non-insulated vessel and consisting of a specially designed unit where the containers are vertically positioned in an upright or upside-down position.

The liquid and/or gas CO.sub.2 coolant is then released into capillary tube(s) embedded into a heat transfer plate or heat exchanger thus leveraging the CO.sub.2 coolant properties.

The temperature is controlled by a metering CO.sub.2 releasing system encompassing an electronic control device which can be operated remotely and/or via a touch screen and which sends alerts when pre-defined thresholds are exceeded.

The invention's metering CO.sub.2 releasing system may be triggered by an electronic or a thermostatic valve or may be triggered manually or by an electronic solenoid. The invention's cooling system also encompasses check valves, which avoid liquid and/or gas CO.sub.2 from escaping when removing or replacing CO.sub.2 containers individually.