KR20130004678A - Operating system and method of refrigerator with inverter compressor - Google Patents

Abstract

The present invention includes a first reservoir having a first temperature sensor and a first evaporator therein; A second reservoir including a second temperature sensor and a second evaporator therein; An inverter compressor for compressing the refrigerant into a high pressure gas state; A condenser for cooling the refrigerant compressed by the inverter compressor in a liquid state; A valve for opening and closing the refrigerant cooled in the condenser to be supplied to the first reservoir or the second reservoir; And the size of the first reservoir and the size of the second reservoir are stored and receive temperature measurement data from the first temperature sensor and the second temperature sensor, and the temperature measurement data based on the size of the first reservoir and the size of the second reservoir is an upper limit value. In this case, the inverter compressor is driven at a high RPM higher than the normal RPM, and controls the opening and closing of the valve; when the temperature of the reservoir provided in the refrigerator is the upper limit, the inverter compressor responsible for the compression of the refrigerant supplied to the reservoir By driving Revolution Per Minute (RPM) at a higher RPM than the normal RPM, the temperature of the storage can be lowered below the upper limit for a short time. As a result, the amount of power supplied to the inverter compressor can be reduced.

Description

Operating system and method of refrigerator with inverter compressor {Operating system and method of Refrigerator with inverter compressor}

The present invention relates to a system and method for operating a refrigerator having an inverter compressor, and more particularly, to a rotational speed per minute of an inverter compressor responsible for compressing a refrigerant supplied to a storage when the temperature of the storage provided in the refrigerator is an upper limit ( Revolution Per Minute (RPM) is operated with a high RPM higher than the normal RPM to lower the temperature of the reservoir below the upper limit for a short time, thereby reducing the amount of power supplied to the inverter compressor. And to a method.

In general, when the temperature of the storage provided in the refrigerator increases, the RPM of the inverter compressor is raised to lower the temperature. As such, the RPM of the refrigerator is set separately from the RPM operating when the temperature of the storage is normal and the RPM operating when the temperature of the storage increases.

However, the RPM setpoint, which operates when the temperature of the reservoir rises, is set to run for a long time until the temperature of the reservoir lowers below the upper limit instead of supplying low power to the inverter compressor, so that the temperature of the reservoir eventually becomes If it is not lowered quickly, a problem occurs that the power supplied to the inverter compressor is used more than necessary.

In this regard, referring to Korean Patent No. 10-0213793, a feature of measuring a load amount according to the temperature of the inlet and the outlet of the evaporator and thus controlling the driving of the compressor is described. However, Korean Patent No. 10-0213793 has a problem in that it does not describe specific criteria for driving the compressor according to the temperature change amount only to control the driving of the compressor.

The present invention has been made to solve the above problems, and when the temperature of the storage unit provided in the refrigerator is the upper limit, the revolution per minute (RPM) of the inverter compressor that is responsible for the compression of the refrigerant supplied to the storage is always available. It is an object of the present invention to provide a driving system of a refrigerator having an inverter compressor that can reduce the amount of power supplied to the inverter compressor by driving the high RPM higher than the RPM and lowering the temperature of the reservoir below the upper limit for a short time.

An object of the present invention as described above is a first reservoir including a first temperature sensor and a first evaporator therein; A second reservoir including a second temperature sensor and a second evaporator therein; An inverter compressor for compressing the refrigerant into a high pressure gas state; A condenser for cooling the refrigerant compressed by the inverter compressor in a liquid state; A valve for opening and closing the refrigerant cooled in the condenser to be supplied to the first reservoir or the second reservoir; And the size of the first reservoir and the size of the second reservoir are stored and receive temperature measurement data from the first temperature sensor and the second temperature sensor, and the temperature measurement data based on the size of the first reservoir and the size of the second reservoir is an upper limit value. And a controller for driving the inverter compressor at a high RPM higher than the normal RPM and controlling opening and closing of the valve.

In another category, an object of the present invention is a temperature checking step of transmitting temperature measurement data measured from a first temperature sensor of a first reservoir and a second temperature sensor of a second reservoir; A temperature upper limit value determining step of determining whether the temperature measurement data is an upper limit by the control unit; A high RPM driving step of varying and driving the inverter compressor driving RPM from the normal RPM to the high RPM when the temperature measurement data based on the size of the first and second reservoirs is an upper limit value; And a normal RPM driving step of maintaining and driving the inverter compressor driving RPM at a constant RPM when the temperature measurement data is not the upper limit.

According to the present invention, when the temperature of the reservoir provided in the refrigerator is the upper limit, the revolution per minute (RPM) of the inverter compressor that is responsible for the compression of the refrigerant supplied to the reservoir is driven by a high RPM higher than the normal RPM. By lowering the temperature of the reservoir below the upper limit during the time, the amount of power supplied to the inverter compressor can be reduced.

1 is a block diagram of an operating system of a refrigerator having an inverter compressor according to an embodiment of the present invention.
2 is a flowchart illustrating a method of operating a refrigerator equipped with an inverter compressor according to an exemplary embodiment of the present invention.

Hereinafter, the configuration and operation of a preferred embodiment of a driving system of a refrigerator having an inverter compressor according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of an operating system of a refrigerator having an inverter compressor according to an embodiment of the present invention.

An operating system of a refrigerator having an inverter compressor includes a first reservoir 110, a second reservoir 120, an inverter compressor 130, a condenser 140, a valve 150, and a controller 160.

The first reservoir 110 is a place where food is refrigerated and includes a first temperature sensor 111 and a first evaporator 112. Here, the first temperature sensor 111 measures the temperature inside the first reservoir 110, and thus, the temperature inside the first reservoir 110 measured by the first temperature sensor 111 will be described later. It is transmitted to the controller 160.

In addition, the first evaporator 112 evaporates the liquid refrigerant supplied from the condenser 140, which will be described later, to cool the inside of the first reservoir 110 by heat exchange.

The second reservoir 120 is a place where food is refrigerated and includes a second temperature sensor 121 and a second evaporator 122. Here, the functions of the second temperature sensor 121 and the second evaporator 122 are the same as the first temperature sensor 111 and the first evaporator 112 described in the first reservoir 110, and thus, detailed description thereof will be omitted.

The inverter compressor 130 compresses the refrigerant into a high pressure gas state, and thus, the compressed gas refrigerant is supplied to the condenser 140 to be described later. In addition, the RPM of the inverter compressor 130 is varied by the control of the controller 160 to be described later.

The condenser 140 cools the gaseous refrigerant supplied from the inverter compressor 130 in the liquid state. As such, the refrigerant cooled in the liquid state in the condenser 140 may be the first reservoir 110 and the second reservoir. Supplied to 120. Here, the amount of the refrigerant supplied to the first reservoir 110 and the second reservoir 120 is controlled by the valve 150 to be described later.

The valve 150 is opened and closed so that the coolant cooled in the condenser 140 is supplied to the first reservoir 110 and the second reservoir 120. As such, the valve 150 controls the interval at which the refrigerant is opened and closed. In 140, the amount of the refrigerant supplied to the first reservoir 110 and the second reservoir 120 is adjusted.

The controller 160 stores the size of the first reservoir 110 and the size of the second reservoir 120, receives temperature measurement data from the first temperature sensor 111 and the second temperature sensor 121, and When the temperature measurement data based on the size of the first reservoir 110 and the size of the second reservoir 120 is the upper limit, the inverter compressor 130 is driven at a higher RPM than the usual RPM, and the opening and closing of the valve 150 is controlled. Here, the temperature measurement data is the upper limit value when the temperature of the first reservoir 110 and the second reservoir 120 is higher than the reference temperature.

In addition, when the controller 160 changes the constant RPM of the inverter compressor 130 to a high RPM, the RPM of the inverter compressor 130 is increased by increasing the amount of power supplied to the inverter compressor 130 by 30%. . As such, the refrigerant compression ratio of the inverter compressor 130 is increased due to the increased RPM, and the amount of the refrigerant supplied to the first reservoir 110 or the second reservoir 120 increases, thereby increasing the first reservoir for a short time. The temperature of the 110 or the second reservoir 120 may be lowered, and thus, the power used in the inverter compressor 130 to lower the temperature of the first reservoir 110 or the second reservoir 120 may be saved. have.

Hereinafter, a configuration and an operation of a preferred embodiment of a method of operating a refrigerator having an inverter compressor according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a flowchart illustrating a method of operating a refrigerator equipped with an inverter compressor according to an exemplary embodiment of the present invention.

A method of operating a refrigerator having an inverter compressor includes a temperature check step (S110), a temperature upper limit value determination step (S120), a high RPM drive step (S130), and a constant RPM drive step (S140).

In the temperature checking step S110, temperature measurement data measured from the first temperature sensor 111 of the first storage 110 and the second temperature sensor 121 of the second storage 120 is transmitted to the controller 160. Here, the first temperature sensor 111 is located inside the first reservoir 110 to measure the temperature inside the first reservoir 110, and the second temperature sensor 121 is the second reservoir 120 Located in the interior of the second reservoir 120 measures the temperature.

The temperature upper limit value determining step (S120) is performed by the controller 160 to determine whether the temperature measurement data is an upper limit value. Here, the temperature measurement data is an upper limit value, wherein the temperatures of the first storage unit 110 and the second storage unit 120 are reference temperatures. It means a higher case.

High RPM drive step (S130) is a high RPM RPM from the inverter compressor 130 at all times in the control unit 160 when the temperature measurement data based on the size of the first reservoir 110 and the second reservoir 120 is the upper limit value. By varying the driving speed, the variable from the constant RPM to high RPM is changed to high RPM by increasing the amount of power supplied to the inverter compressor 130 from the controller 160 by 30% than usual.

The constant RPM driving step (S140) maintains the drive RPM of the inverter compressor 130 at all times and drives the controller 160 when the temperature measurement data is not the upper limit.

After the above-described high RPM driving step S130 and the normal RPM driving step S140 are performed, the temperature check step S110 is performed again to determine whether the temperature of the first reservoir 110 or the second reservoir 120 is the upper limit. Determine whether or not.

In the present specification, a preferred embodiment of a driving system and method of a refrigerator having an inverter compressor according to the present invention has been described, but the present invention is not limited thereto. The invention may be practiced in various ways within the scope of the claims and the accompanying drawings, which also belong to the scope of the invention.

110: first storage 111: first temperature sensor
112: first evaporator 120: second storage
121: second temperature sensor 122: second evaporator
130: inverter compressor 140: condenser
150: valve 160: control unit
S110: temperature check step S120: temperature upper limit value determination step
S130: High RPM drive step S140: Always RPM drive step

Claims (2)

A first reservoir 110 including a first temperature sensor 111 and a first evaporator 112;
A second reservoir 120 including a second temperature sensor 121 and a second evaporator 122;
An inverter compressor 130 for compressing the refrigerant into a high-pressure gas state;
A condenser 140 for cooling the refrigerant compressed by the inverter compressor 130 to a liquid state;
A valve 150 that opens and closes so that the refrigerant cooled in the condenser 140 is supplied to the first reservoir 110 or the second reservoir 120; And
The size of the first storage 110 and the size of the second storage 120 is stored, and receives the temperature measurement data from the first temperature sensor 111 and the second temperature sensor 121, When the temperature measurement data based on the size of the first reservoir 110 and the size of the second reservoir 120 is the upper limit, the inverter compressor 130 is driven at a high RPM higher than the normal RPM, and the valve 150 is opened and closed. The control unit 160 for controlling the operation system of the refrigerator with an inverter compressor comprising a.
A temperature check step (S110) in which temperature measurement data measured from the first temperature sensor 111 of the first reservoir 110 and the second temperature sensor 121 of the second reservoir 120 are transmitted to the controller 160;
A temperature upper limit value determining step (S120) determining whether the temperature measurement data is an upper limit value by the control unit 160;
When the temperature measurement data based on the sizes of the first reservoir 110 and the second reservoir 120 is the upper limit, the controller 160 drives the inverter compressor 130 by changing the driving RPM from the normal RPM to the high RPM. High RPM drive step (S130); And
When the temperature measurement data is not the upper limit value, the inverter RPM driving step (S140) for maintaining and driving the drive RPM of the inverter compressor 130 at all times in the control unit 160; How to drive a refrigerator.

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