KR100366449B1 - Control Device and Control Method of 3 way valve - Google Patents

Abstract

The present invention relates to a refrigeration system, and more particularly to a three-way valve switching control device and control method for facilitating valve switching of the three-way valve in the refrigeration system using the three-way valve.

According to the present invention, in the refrigeration system having a plurality of evaporators for evaporating the refrigerant compressed by one compressor 270, the compressor 270 is driven for a predetermined time. After that, the compressor 270 is turned off, and the three-way valve 250 is switched in a state in which the compressor 270 is not driven for a predetermined time.

Therefore, even in the initial stage of the refrigerator in which an overload condition occurs in the three-way valve, the valve switching of the three-way valve is easy and the three-way valve can be operated normally.

Description

Control Device and Control Method of 3 Way Valve

The present invention relates to a refrigeration system, and more particularly to a three-way valve switching control device and control method for facilitating valve switching of the three-way valve in the refrigeration system using the three-way valve.

Refrigerating equipment using a refrigeration system includes a refrigerator, a kimchi refrigerator, an air conditioner, etc. Here, the refrigerator will be described as an example.

A refrigerator is a freezer that supplies cold air into a storage space and maintains food in the storage space at a constant temperature.

The cold air of the refrigerator is generated by the operation of the refrigeration cycle, the refrigeration cycle comprises a compressor, a condenser, a capillary tube, an evaporator. As the refrigerant flows along the components, the phase changes and heat exchanges with the air circulating in the storage space of the refrigerator to generate cold air.

1 is a configuration diagram showing a refrigeration cycle of a refrigerator using a three-way valve.

As shown in FIG. 1, the refrigerating cycle includes a compressor 100 that compresses a low pressure refrigerant. In addition, a condenser 105 for condensing and liquefying the refrigerant passing through the compressor 100 is connected to the compressor 100 through the refrigerant pipe 130.

A plurality of evaporators 115a and 115b are connected to the condenser 105. The evaporators 115a and 115b generate cold air to take heat contained in food in the storage space.

Capillary tubes 110a and 110b for reducing the liquid refrigerant flowing into the evaporators 115a and 115b to facilitate evaporation of the refrigerant in the evaporators 115a and 115b are provided between the condenser 105 and the evaporators 115a and 115b. Is installed.

In addition, a three-way valve 120 for opening and closing the refrigerant passage flowing through the one compressor 100 to the plurality of evaporators 115a and 115b is installed between the condenser 105 and the capillary tubes 110a and 110b. .

And the refrigerant pipe connected to the rear end of the evaporator (115a, 115b) is connected to the compressor 100, the compressor 100 → condenser 105 → capillary (110a, 110b) → evaporator (115a, 115b) → compressor A refrigeration cycle connected to 100 is formed.

Therefore, as shown in FIG. 1, in the case of a refrigerator having a plurality of evaporators 115a and 115b, the compressor 100 → condenser 105 is operated according to the open control operation of the three-way valve 120. → a refrigerating cycle consisting of a capillary tube 110a → an evaporator 115a → a compressor 100, or the compressor 100 → a condenser 105 → a capillary tube 110b → an evaporator 115b → a compressor 100 Or a refrigeration cycle connected to the compressor 100, or a refrigeration cycle connected to the compressor 100 → condenser 105 → capillaries 110a and 110b → evaporators 115a and 115b → compressor 100.

Next, in the refrigeration system using the three-way valve having the configuration as described above, the control method of the three-way valve according to the prior art will be described.

When cold air is required in the storage space, the microcomputer (not shown) drives the compressor 100 to operate the refrigeration cycle.

The refrigeration cycle is configured by a refrigerating cycle connected to the compressor 100 → condenser 105 → capillary 110a → evaporator 115a → compressor 100 according to the switching mode of the three-way valve 120, or The compressor 100 → condenser 105 → capillary 110b → evaporator 115b → a refrigeration cycle connected to the compressor 100 is configured, or the compressor 100 → condenser 105 → capillary 110a, 110b) → evaporator (115a, 115b) → the refrigeration cycle is connected to the compressor (100).

When changing to another refrigeration cycle during one refrigeration cycle operation, the microcomputer instructs the valve switching driver (not shown) to switch the valve, and the three-way valve 120 is valve-changed by driving the valve switching driver.

However, the valve switching control method of the three-way valve according to the prior art as described above poses the following problems.

The three-way valve 120 has an input port (not shown) for supplying refrigerant from the outside and first and second output ports (not shown) for discharging the refrigerant introduced into the input port to the outside. The input port is connected to the coolant pipe line 130, and the first and second output ports are connected to the coolant pipe lines 130a and 130b, respectively. The opening or closing of the first and second output ports is performed by the rotation of the valve body (not shown).

When the high pressure refrigerant passing through the condenser 105 flows into the input port of the three-way valve, the pressure of the input port increases, and the pressure difference between the input port and the first and second output ports becomes high pressure. In particular, when the refrigeration cycle is operating at high temperatures or during the initial operation of the refrigerator, the pressure of the refrigerant flowing into the three-way valve 120 becomes higher. Therefore, the operating pressure difference for the switching of the three-way valve 120 becomes larger. Here, the valve operating pressure difference or the operating pressure difference for switching the valve represents a load received when the valve is switched, and is a pressure difference between the input port and the output port.

When the refrigerant flowing into the three-way valve as described above becomes high, the high pressure liquid refrigerant acts as a load with respect to the rotation of the valve body which is the opening or closing means of the first and second output ports. Therefore, when high-pressure liquid refrigerant flows into the valve body, braking is applied to the rotation of the valve body. As a result, difficulty in switching valves between the first and second output ports occurs. That is, the valve switching becomes difficult because the operating pressure difference between the valve switching becomes large.

As described above, when the high-pressure refrigerant flows into the three-way valve 120, a problem arises in that the valve switching for driving a desired refrigeration cycle occurs.

SUMMARY OF THE INVENTION An object of the present invention is to provide a switching control device and control method for a three-way valve to facilitate the switching of the three-way valve during the initial operation of the refrigerator by solving the problems of the conventional three-way valve switching as described above.

1 is a configuration diagram of a refrigeration cycle using a three-way valve.

Figure 2 is a block diagram for a three-way valve control according to the present invention.

3 is a characteristic diagram of a three-way valve operating pressure difference according to the present invention;

4 is an operation flowchart for the three-way valve control according to the present invention.

Explanation of symbols on the main parts of the drawings

100 .............. Compressor 105 ......... Condenser

110a, 110b ........ capillary 115a, 115b .... evaporator

120 .......... 3 way valve 130,130a, 130b ..

210 ...... Refrigerator temperature sensor 220 ... Freezer temperature sensor

230 ......... Microcomputers 240 .... Three-way valve actuator

250 ........... Three-way valve 260 ... Compressor drive

270 .............. Compressor

The three-way valve switching control apparatus according to the present invention is a refrigeration system having a plurality of evaporators for evaporating the refrigerant compressed by one compressor, to selectively open and close the flow of the refrigerant passing through the compressor to the plurality of evaporators And a control unit for controlling switching of the three-way valve in a state in which the compressor is turned off when the compressor driving time passes a predetermined time.

In the three-way valve switching control method, the refrigeration system having a plurality of evaporators for evaporating the refrigerant compressed by one compressor, the step of commanding the switching of the three-way valve, and whether the drive time of the compressor has passed a predetermined time Determining the step, and if the drive time of the compressor has passed a predetermined time, the step of turning off the compressor for a predetermined time, characterized in that it comprises a step of performing a valve switching in the compressor off state.

According to the configuration as described above it is easy to switch the three-way valve can operate the desired refrigeration cycle normally.

Next, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Since the configuration of the refrigeration cycle of the refrigeration system according to the present invention is as described above on the basis of FIG.

2 is a block diagram showing a configuration for controlling a three-way valve according to the present invention.

A refrigerator compartment temperature sensor 210 for detecting a refrigerator compartment temperature is installed at one side of the refrigerator compartment, and a freezer compartment temperature sensor 220 for detecting the freezer compartment temperature is installed at one side of the freezer compartment. In addition, the microcomputer 230 that receives the temperature of the refrigerating compartment and the freezing compartment sensed by the refrigerating compartment temperature sensor 210 and the freezing compartment temperature sensor 220 and controls the refrigerating cycle is connected to the temperature sensors 210 and 220.

A compressor driver 260 for driving a compressor for driving a refrigeration cycle under the control of the microcomputer 230 is connected to the microcomputer 230. The compressor 270 is connected to the compressor driver 260.

In addition, a three-way valve 120 for opening and closing the refrigerant pipes 130a and 130b flowing through the compressor 100 to the plurality of evaporators 115a and 115b is connected to the microcomputer 230. The three-way valve 120 opens and closes the refrigerant lines 130a and 130b under the control of the microcomputer 230. A three-way valve driver 240 for driving the three-way valve 120 is connected between the microcomputer 230 and the three-way valve 250.

Next, a switching control method of the three-way valve according to the present invention having the configuration as described above will be described.

Figure 3 is a characteristic diagram of the operating pressure difference of the three-way valve during the initial operation of the refrigerator, Figure 4 is a flow chart for the three-way valve switching control.

When the temperature of the storage space is input to the microcomputer 230 by the refrigerating compartment temperature sensor 210 or the freezer compartment temperature sensor 220, the microcomputer 230 sets a reference set temperature of each storage space set in the microcomputer 230. And compare the temperature of the input storage space.

If the temperature detected by the temperature sensors 210 and 220 is higher than the reference set temperature set in the microcomputer 230, the microcomputer 230 drives the compressor 270 through the compressor driver 260 (step 400). .

When the compressor 270 is driven, the operating pressure difference of the three-way valve 250 rapidly rises as shown in FIG. 3. When the refrigeration cycle is driven by the operation of the compressor 270 and wants to operate another refrigeration cycle, the user inputs the switching of the refrigeration cycle. The microcomputer 230 that recognizes the user's refrigeration cycle switching command commands the valve switching unit to the three-way valve driving unit 240 (step 402).

After the compressor 270 is driven for a predetermined time (60 minutes in the present embodiment), the compressor 270 is turned off (step 404 and step 406). As shown in FIG. 3, when the compressor 270 is turned off, the operating pressure difference of the three-way valve 250 decreases rapidly.

When the compressor 270 is not driven, the valve operation pressure difference is very small, so that the valve switching of the three-way valve is very easy.

Therefore, the off time of the compressor 270 is maintained for a predetermined time (7 to 10 minutes in this embodiment) (step 408) so that the valve switching of the three-way valve 250 can be performed, and the compressor 270 is not driven. During the idle period, the three-way valve 250 is switched over (step 410).

After the valve switching, the compressor 270 is driven again to drive a desired refrigeration cycle (412). The control operation of the three-way valve 250 as described above is continued during the initial operation of the refrigerator. That is, each refrigeration cycle constituted by the switching of the three-way valve 250 is operated until it reaches the normal orbit so that the temperature of each storage space becomes the reference set temperature set in the microcomputer 230.

The above embodiments of the present invention are merely one embodiment of the technical idea of the present invention, and of course, other modifications are possible within the technical idea of the present invention.

The present invention having the configuration as described above has the following effects.

When the three-way valve operating pressure difference is large during the initial operation of the refrigerator, the valve switching is facilitated by switching the valve of the three-way valve while the compressor is turned off after driving the compressor for a predetermined time.

In addition, there is an effect of allowing the three-way valve to operate normally by reducing the leakage of the refrigerant generated by the suction of the high-pressure refrigerant to the three-way valve.

Claims (2)

In a refrigeration system having a plurality of evaporators for evaporating refrigerant compressed by one compressor: A three-way valve for selectively opening and closing the refrigerant passing through the compressor to a plurality of evaporators; A control unit for controlling the switching of the three-way valve in a state in which the compressor is turned off when the compressor driving time has elapsed; Three-way valve switching control device comprising a. In a refrigeration system having a plurality of evaporators for evaporating refrigerant compressed by one compressor: Instructing switching of the three-way valve; Determining whether a driving time of the compressor has passed a predetermined time; Turning off the compressor for a predetermined time when the driving time of the compressor has passed a predetermined time; Performing valve switching in the compressor off state; Three-way valve switching control method characterized in that it comprises a.