KR100471063B1 - Refrigerator and method of controlling the same - Google Patents

Abstract

The present invention provides at least one storage compartment, an evaporator for supplying cold air to the storage compartment, a compressor, a compressor driving unit for supplying driving power to the compressor, and a driving power supply from the compressor driving unit when the compressor is overloaded. It relates to a refrigerator including an overload blocking unit for blocking the provision and a control method thereof. The refrigerator includes a heater for heating a predetermined portion; A heater driver supplying driving power to the heater; A temperature sensing unit sensing an indoor temperature of the storage room; When it is determined that the indoor temperature of the storage chamber sensed by the temperature sensing unit is rising while the compressor driving unit drives the compressor to supply cold air to the storage chamber through the evaporator, And a controller to block driving power from being provided to the heater. Accordingly, when the driving of the compressor is stopped due to overload, a refrigerator and a control method thereof are provided, which minimizes the increase in the internal temperature of the compressor and ensures stability when the compressor is restarted.

Description

Refrigerator and its control method {REFRIGERATOR AND METHOD OF CONTROLLING THE SAME}

The present invention relates to a refrigerator, and more particularly, to a refrigerator in which stability of a compressor is restarted while minimizing an increase in internal temperature when the compressor is stopped due to an overload.

In general, a cooling system circulates a refrigerant through a compressor to supply cold air to each of the storage compartments by the circulating refrigerant so that food can be stored for a long time.

As shown in FIG. 1, the refrigeration cycle of the refrigerator is compressed into a gaseous refrigerant at a high temperature and high pressure in the compressor 24, and then flows into the condenser 130 through a connecting pipe to liquefy the refrigerant at room temperature and high pressure through a heat radiation process. And is selectively sent to the evaporators 151a and 151b provided in the respective storage chambers through the solenoid valves 114a and 114b. The refrigerant vaporizes in the evaporators 151a and 151b to take away the latent heat of the surroundings to cool the storage compartment. The refrigerant evaporated in the evaporators 151a and 151b is collected by the condenser 130 and returned to the compressor 24 to complete one refrigeration cycle. Such a refrigeration cycle senses the temperature in the storage room through the temperature sensors 112a and 112b for sensing the temperature of each storage room, and controls the solenoid valves 114a and 114b to maintain the storage temperature set by the user. The temperature of the plurality of storage compartments can be adjusted by adjusting the cold air supplied to the storage chambers.

An overload protector (OLP) is added to the compressor 24 of the refrigeration cycle to stop the operation by stopping the power supplied to the compressor 24 when the load on the compressor 24 is heavy. . Therefore, during the operation of the refrigeration cycle, if a load is applied to the compressor 24, the OLP is operated to stop the operation of the compressor 24. When the driving of the compressor 24 is stopped, the circulation of the refrigerant is also stopped so that no cool air is supplied to the storage compartment.

On the other hand, such a refrigerator is provided with a defrost heater to remove the defrost of the evaporator 151 during the operation of the refrigeration cycle, or a heater for removing the dew caused by the temperature difference between the inside and the outside of the storage compartment in the portion adjacent to the door. In particular, kimchi refrigerators may have a heater to perform the function of ripening food by supplying warmth to the storage compartment.In the case of a kimchi refrigerator made of a drawer type, frost does not occur in the door sliding bearing that guides the sliding of the drawer. The heater is running to prevent it.

However, when the OLP is operated due to an overload during operation of the refrigeration cycle, the compressor is stopped and the supply of cold air is stopped, but the heater devices are operated as before, causing the temperature rise of the storage compartment. Due to the elevated temperature in the room, not only the stored food can be deteriorated, but also the heat load when the compressor is restarted.

Accordingly, an object of the present invention is to provide a refrigerator in which stability of the compressor is restarted while minimizing an increase in internal temperature when driving of the compressor is stopped due to overload during operation of the refrigeration cycle.

According to the present invention, the object is at least one storage compartment, an evaporator for cooling the storage compartment, a compressor, a compressor driver for supplying drive power to the compressor, and a drive power from the compressor driver when the compressor is overloaded. A refrigerator comprising an overload cut-off unit for blocking a supply to the compressor, the refrigerator comprising: a heater for heating a predetermined portion; A heater part driving part supplying driving power to the heater; A temperature sensing unit sensing an indoor temperature of the storage room; When it is determined that the indoor temperature of the storage compartment sensed by the temperature sensing unit is rising while the compressor driving unit is supplying driving power to the compressor, driving power from the heater unit driving unit is provided to the heater. It is achieved by a refrigerator, characterized in that it comprises a control unit for blocking that.

Here, the heater may include at least one of a reheater for reheating the evaporator, a heater for heating the door sliding bearing, and a ripening heater for ripening food stored in the storage compartment.

In addition, further comprising a valve for adjusting the amount of refrigerant flowing into the evaporator; The control unit, when the driving power is supplied to the compressor by the compressor driving unit, and when the valve is open, it is determined that the room temperature of the storage chamber detected by the temperature sensing unit is rising, the heater unit It is possible to include a control unit for blocking the driving power from the drive unit is provided to the heater.

On the other hand, according to another field of the present invention, the object is at least one storage compartment, an evaporator for cooling the storage compartment, a valve for adjusting the amount of refrigerant flowing into the evaporator, a compressor, and supplying driving power to the compressor In the control method of the refrigerator comprising a compressor driving unit, an overload blocking unit for blocking the driving power from the compressor driving unit is provided to the compressor when the compressor is overloaded, and the heater for heat dissipation, the compressor driving unit Determining whether driving power is supplied to the compressor; Determining whether the valve is open; Detecting whether an indoor temperature of the storage compartment is rising; When it is detected that the indoor temperature of the storage compartment is rising, the control method of the refrigerator is also achieved, comprising the step of stopping the operation of the heater.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

2 is a control block diagram of a refrigerator according to the present invention. As shown in the figure, the refrigerator according to the present invention has a temperature sensing unit 12 for sensing the temperature in the storage compartment, and a valve sensing unit 14 for sensing the on-off state of the valve for controlling the amount of cold air supplied to the storage compartment. And a heater unit driving unit 16 for driving a plurality of heaters 18 for performing functions such as defrosting and aging, a compressor 24, and a compressor driving unit 20 for supplying driving power to the compressor 24. And the OLP 22 which cuts off the power provided to the compressor 24 from the compressor driver 20 when the compressor 24 is overloaded, and is sensed by the temperature sensing unit 12 and the valve sensing unit 14. The control unit 10 for controlling the heater driving unit 16, the compressor driving unit 20 according to the results.

The temperature detector 12 detects a temperature in the storage compartment and provides a sensed value to the controller 10.

The valve detecting unit 14 detects whether a valve for controlling an amount of cold air supplied to each storage chamber of the refrigerator having a plurality of storage chambers is provided, and provides a detection result to the controller 10. The valve is opened and closed under the control of the controller 10 to selectively supply the refrigerant to the evaporator. Accordingly, the controller 10 may control the opening and closing of the valve according to the temperature value of the storage compartment detected by the temperature sensing unit 12 to adjust the temperature of the storage compartment.

The heater 18 includes a defrost heater for removing defrost of the evaporator, a heater for removing dew caused by a temperature difference between the inside and the outside of the storage compartment, or a heater for ripening food. In addition, in the case of a kimchi refrigerator of the drawer type, a heater is installed so that frost does not occur in the door sliding bearing for guiding the sliding of the drawer. The technique of the present invention can be applied to all kinds of heaters applied to the refrigerator.

The compressor driver 20 drives the compressor 24 by supplying driving power to the compressor 24 under the control of the controller 10. When the compressor 24 is driven, a cooling cycle is started to supply cool air to the storage compartment.

The OLP 22 cuts off the power supplied from the compressor driver 20 to the compressor 24 when the compressor 24 is overloaded. A bimetal or the like is used as the OLP 22, and operates separately from the control of the controller 10, and is turned on when the compressor 24 is overloaded. When the OLP 22 is turned on, the driving power provided to the compressor 24 is cut off, and the driving of the compressor 24 is stopped. When the overload is released after a predetermined time, the OLP 22 is automatically turned off and the compressor is turned off. The driving power from the driving unit 20 is supplied to the compressor 24. As described above, since the OLP 22 operates independently of the controller 10 according to the load state of the compressor 24, the controller 10 may not directly detect the state of the OLP 22.

Therefore, the controller 10 detects the on / off state of the compressor 24 based on whether the compressor driver 20 supplies the driving power to the compressor 24, and the valve detector 14 detects the on / off state of the valve. While checking the state to determine whether cold air is supplied into the storage compartment, the temperature in the storage compartment is continuously monitored through the temperature sensing unit 12.

Here, in the normal state, if it is determined that the compressor driving unit 20 is supplying driving power to the compressor 24, and the valve is opened and cold air is supplied into the storage compartment, the compressor driving unit 20 detects the temperature through the temperature sensing unit 12. The temperature in the reservoir will remain cold.

However, when the OLP 22 is operating due to the overload of the compressor 24, the compressor driving unit 20 supplies driving power to the compressor 24, but the driving power provided from the compressor driving unit 20. Is blocked by the OLP 22 so that the compressor 24 is not driven.

Therefore, the control unit 10 is a state in which the compressor driving unit 20 is supplying driving power to the compressor 24, and although the valve is opened and it is determined that cold air is supplied into the storage chamber, the temperature sensing unit 12 When the temperature in the storage compartment sensed through the temperature rises above a predetermined reference temperature, the compressor 24 is determined to be stopped due to overload, and the heater 18 is not driven through the heater part driving unit 16.

As such, the operation sequence of the refrigerator according to the present invention is as shown in FIG. 3. When power is supplied to the refrigerator, the refrigeration cycle is started to operate the refrigerator (S10). If the door is opened or the heat dissipation is poor while the refrigerator is being driven, the load on the compressor 24 is increased (S12). When the compressor 24 is overloaded, the driving power supplied to the compressor 24 from the compressor driver 20 is cut off by turning on the OLP 22 (S14). Thereby, the drive of the compressor 24 is stopped (S16), and supply of cold air is stopped. When the cold air supply is stopped, the heater 18 is also stopped (S18).

As described above, the refrigerator according to the present invention prevents the temperature in the storage room from rising sharply by turning off various heaters 18 when the compressor 24 stops operating due to an overload.

This series of processes is performed by the control of the control unit 10, wherein the control flow of the control unit 10 is as shown in FIG. When driving of the refrigeration cycle is started (S40), the control unit 10 determines whether the compressor driving unit 20 is supplying driving power to the compressor (24) (S42). When the compressor driving unit 20 is supplying driving power to the compressor 24, the control unit 10 determines whether the valve is opened through the valve detecting unit 14 (S44). When the compressor driving unit 20 is supplying driving power to the compressor 24 and the valve is also open, the control unit 10 monitors a sensing value input through the temperature sensing unit 12 so that the storage room temperature is predetermined. It is determined whether or not the reference temperature of (S46). When it is determined that the temperature in the storage compartment is equal to or higher than the predetermined reference temperature, the controller 10 controls the heater part driving unit 16 to stop the operations of all the heaters 18 (S48). That is, when the temperature in the storage compartment rises even when the compressor 24 is being driven and the valve is open, the controller 10 determines that the operation of the compressor 24 is stopped due to the operation of the OLP 22, and thus, the storage compartment is in the storage compartment. The heater 18 is stopped to maintain the temperature.

As described above, in the present invention, although the compressor driving unit is determined to supply driving power to the compressor and the valve is opened to determine that the cool air is supplied to the storage chamber, the temperature in the storage chamber sensed by the temperature sensing unit is When the temperature rises above the predetermined reference temperature, the compressor is stopped due to overload, and the driving of the heater is stopped. When the compressor is stopped due to the overload during the operation of the refrigeration cycle, the rise of the internal temperature is minimized while the compressor is stopped. Provide a refrigerator that ensures stability upon restart.

As described above, according to the present invention, when the driving of the compressor is stopped due to the overload during the operation of the refrigeration cycle, while minimizing the rise of the internal temperature, there is provided a refrigerator that ensures stability when the compressor is restarted.

1 shows a cooling cycle of the refrigerator,

2 is a control block diagram of a refrigerator according to the present invention;

3 is an operation flowchart of a refrigerator according to the present invention;

4 is a control flowchart of a refrigerator according to the present invention.

* Explanation of symbols for the main parts of the drawings

10: control unit 12: temperature detection unit

14 valve detection unit 16 heater driving unit

18: heater 20: compressor drive unit

22: OLP 24: compressor

Claims (4)

At least one storage compartment, an evaporator for cooling the storage compartment, a compressor, a compressor driver for supplying drive power to the compressor, and a block of driving power from the compressor driver when the compressor is overloaded. In the refrigerator comprising an overload blocking unit, A heater for heating a predetermined portion; A heater part driving part supplying driving power to the heater; A temperature sensing unit sensing an indoor temperature of the storage room; When it is determined that the indoor temperature of the storage compartment sensed by the temperature sensing unit is rising while the compressor driving unit is supplying driving power to the compressor, the driving power from the heater unit driving unit is provided to the heater. Refrigerator comprising a control unit for blocking that. The method of claim 1, wherein the heater, And at least one of a reheater for reheating the evaporator, a heater for heating a door sliding bearing, and a ripening heater for ripening food stored in the storage compartment. The method of claim 1, A valve for controlling the amount of refrigerant flowing into the evaporator; The control unit, when the driving power is supplied to the compressor by the compressor driving unit, when the valve is open, it is determined that the room temperature of the storage chamber detected by the temperature sensing unit is rising, the heater unit driving unit And a control unit for blocking driving power from being provided to the heater. At least one storage compartment, an evaporator for cooling the storage compartment, a valve for controlling the amount of refrigerant flowing into the evaporator, a compressor, a compressor driver for supplying driving power to the compressor, and a compressor driver for overloading the compressor. In the control method of the refrigerator comprising an overload blocking unit for blocking the driving power of the provided to the compressor, and a heater for heat dissipation, Determining whether the compressor driver is supplying driving power to the compressor; Determining whether the valve is open; Detecting whether an indoor temperature of the storage compartment is rising; And if the indoor temperature of the storage compartment is detected to increase, stopping the operation of the heater.