KR19990015411A - Cooling cycle of the refrigerator with two evaporators - Google Patents

Abstract

The present invention relates to a cooling cycle of a refrigerator having two evaporators. When the liquid refrigerant separated by the phase separator becomes excessive compared to the gas phase refrigerant, the separated liquid refrigerant flows more rapidly toward the freezer evaporator. As the liquid refrigerant does not pass directly into the compressor without passing through the freezer evaporator, the operation of the compressor is always smooth and the power consumption is not increased and the cooling efficiency is not reduced.

To this end, in the present invention, the refrigerant compressed in the compressor and condensed in the condenser passes through a capillary tube, and then separated into a gas phase and a liquid phase by a phase separator through a refrigerating chamber evaporator, and the separated gas phase refrigerant enters the compressor and is compressed again. When the liquid refrigerant enters the compressor through the freezer evaporator and is compressed again, it is installed between the phase separator and the freezer evaporator and operates according to the control signal of the controller to adjust the amount of liquid refrigerant flowing to the compressor corresponding to the temperature of the freezer compartment. A first freezing chamber temperature sensor and a second freezing chamber temperature sensor installed at an inlet and an outlet of the freezing chamber evaporator to sense an inlet and an outlet temperature of the freezing chamber evaporator and to send the detected value to a controller; Is installed at the inlet of the refrigerator evaporator, the inlet of the refrigerator evaporator A refrigerator phase temperature sensor that detects the degree and sends this detection value to the controller, and a first phase separator installed at the upper and lower ends of the phase separator, respectively, to sense the upper and lower temperatures of the phase separator and send the detected value to the controller. If the temperature values detected by the first and second phase separator temperature sensors, including the temperature sensor and the second phase separator temperature sensor, are different from each other, the controller may be configured according to the difference between the temperature values detected by the first and second freezer temperature sensors. Normal operation is performed while controlling the opening time of the expansion valve, and when the temperature value detected by the first and second phase separator temperature sensors is the same, the controller detects the temperature and the refrigerator compartment detected by the first and second phase separator temperature sensors. According to whether the temperature detected by the temperature sensor is the same or wrong, the opening time of the expansion valve is controlled differently from the normal operation so that abnormal operation is performed. .

Description

Cooling cycle of the refrigerator with two evaporators

The present invention relates to a cooling cycle of a refrigerator having two evaporators. When the liquid refrigerant separated by a phase separator is higher than the refrigerant in the gas phase, the separated liquid refrigerant flows rapidly toward the freezer evaporator. In any case, the liquid refrigerant will not enter the compressor.

In general, a refrigerator is a device that keeps food fresh for a long time. The refrigerator includes a device body, a refrigerating chamber integrated with the device body to store food, a freezing chamber integrated with the device body, and freezing and storing food, and a refrigerating chamber and a freezing chamber. The refrigerator consists of a cooling cycle for cooling the refrigerator, which is a refrigerator having two evaporators, each having a refrigerator compartment evaporator for cooling the refrigerator compartment and a freezer compartment evaporator for cooling the freezer compartment.

The conventional cooling cycle of the refrigerator having two evaporators includes a compressor (1) for compressing a refrigerant, a condenser (2) for condensing the refrigerant compressed by the compressor, and the condenser, as shown in FIG. A capillary tube (3) for changing the temperature and pressure of the refrigerant corresponding to the appropriate temperature of the refrigerating chamber, a refrigerating chamber evaporator (4) for cooling the refrigerating chamber while evaporating by the refrigerant passing through the capillary tube, and for the refrigerating chamber A phase separator 5 separating the refrigerant passing through the evaporator into a liquid phase and a gas phase, a pressure sensor 6 and a pressure sensor 6 connected in parallel between the phase separator and the compressor 1 to sense the pressure of the gaseous refrigerant flowing toward the compressor; The solenoid valve 7, which is turned on and off according to the sensing value of the sensor, is connected in parallel between the phase separator 5 and the compressor 1 to freeze the temperature and pressure of the liquid refrigerant flowing toward the compressor. It consists of an auxiliary capillary tube 8 which changes according to the appropriate temperature of the chamber, and a freezer compartment evaporator 9 which cools the freezing chamber while evaporating by the refrigerant passing through the auxiliary capillary tube.

Therefore, when the power is applied, the compressed refrigerant is condensed in the condenser 2 and then passes through the capillary tube 3 according to the operation of the compressor 1, and the temperature and pressure are changed to correspond to the proper temperature of the refrigerating chamber. Since the refrigerating chamber evaporator 4 is subsequently passed, the refrigerating chamber is cooled to an appropriate temperature range (3 ° C.) as the refrigerating chamber evaporator causes an evaporation action.

In this way, the refrigerant passing through the refrigerating chamber evaporator 4 is separated into a liquid phase refrigerant and a gaseous phase refrigerant in the phase separator 5. Since the separated liquid phase refrigerant is heavy, the refrigerant in the gas phase is light and is light. Therefore, it is located at the top.

Meanwhile, the liquid refrigerant separated from the phase separator (5) passes through the auxiliary capillary tube (8) connected in parallel between the phase separator (5) and the compressor (1), and the temperature and pressure change to correspond to the appropriate temperature of the freezer compartment. As the freezer compartment evaporator 9 evaporates, the freezer compartment is cooled to an appropriate temperature range (−18 ° C.), and the refrigerant passing through the freezer compartment evaporator 9 becomes a gaseous state because it passes through the practical evaporator 9. After entering (1), it is compressed again according to the continuous operation of the compressor.

While the above operation is performed, a pressure sensor 6 connected in parallel between the phase separator 5 and the compressor 1 senses the pressure of the gaseous refrigerant flowing from the phase separator 5 toward the compressor 1. When the amount of refrigerant in the liquid phase separated by the phase separator 5 increases, the pressure increases, so that the sensing pressure of the pressure sensor 6 becomes greater than or equal to a predetermined pressure (3 bar) at some point, so that the solenoid valve 7 On (open), from this time, the refrigerant in the gas phase passes through the solenoid valve, enters the compressor 1, and is compressed again by the compressor.

Meanwhile, when the refrigerant in the gas phase separated by the phase separator 5 enters the compressor 1, the sensing pressure of the pressure sensor 6 begins to drop, and the sensing pressure of the pressure sensor is a constant pressure (2.5). bar), the solenoid valve 7 is turned off (closed) so that the gaseous refrigerant does not enter the compressor 1 anymore. As described above, the liquid refrigerant is again used for the auxiliary capillary tube 8 and the freezer compartment. It passes continuously through the evaporator 9 and enters the compressor 1 to be compressed again.

However, in the refrigerator having such a conventional cooling cycle, the solenoid valve 7 is operated by the pressure sensor 7 only when the pressure of the gaseous phase refrigerant separated from the phase separator 5 and flowing toward the compressor 1 is 3 bar or more. In consideration of the fact that the temperature of the installation place decreases rapidly or when the load fluctuates due to external conditions caused by frequent openings of the refrigerating and freezing doors during use, the pressure sensor 6 should be opened. In this case, the liquid refrigerant separated in the phase separator 5 is saturated, but when the pressure sensor 6 is opened, the refrigerant in the liquid phase is not changed to the gaseous phase. 1) the compressor causes liquid compression, the operation state is not smooth, the power consumption is increased and cooling efficiency There was also a problem falling.

The present invention has been made to solve the above problems, when the liquid refrigerant separated by the phase separator is excessive compared to the refrigerant in the gas phase to flow the refrigerant of the separated liquid toward the freezer evaporator more quickly to the liquid Since the refrigerant does not enter the compressor immediately without passing through the freezer evaporator, the operation of the compressor is always smooth and the power consumption is not increased and the cooling efficiency is also not reduced.

According to the present invention for achieving the above object, the refrigerant compressed in the compressor and condensed in the condenser is passed through a capillary and then separated into a gaseous phase and a liquid phase by a phase separator through a refrigerating chamber evaporator. As the liquid refrigerant enters the compressor and is compressed again, the liquid refrigerant passes through the freezer compartment evaporator and is compressed again. The liquid refrigerant is installed between the phase separator and the freezer compartment evaporator to operate according to the control signal of the controller and correspond to the temperature of the freezer compartment. An expansion valve for controlling the amount of refrigerant flowing into the freezer, and a first freezer temperature sensor installed at an inlet and an outlet of the freezer evaporator to sense an inlet and an outlet temperature of the freezer evaporator and send the detected value to the controller. And a second freezer temperature sensor and an inlet portion of the refrigerating chamber evaporator. Air temperature sensor that senses the inlet temperature of the refrigerator's evaporator and sends this detected value to the controller, and is installed at the top and bottom of the phase separator, respectively, and detects the upper and lower temperatures of the phase separator to control this detected value. If the temperature values detected by the first and second phase separator temperature sensors, including the first phase separator temperature sensor and the second phase separator temperature sensor, are different from each other, the controller detects them by the first and second freezer temperature sensors. Normal operation is performed while controlling the opening time of the expansion valve according to the difference of the set temperature value. When the temperature value detected by the first and second phase separator temperature sensors is the same, the controller sets the first and second phase separator temperature sensors. The opening time of the expansion valve is controlled differently than in normal operation depending on whether the temperature detected by The driving, there is provided a refrigeration cycle of a refrigerator having one or two of the evaporator to be made.

1 is a block diagram showing a cooling cycle of a conventional refrigerator having two evaporators

Figure 2 is a block diagram showing a cooling cycle of the refrigerator having two evaporators of the present invention

Explanation of symbols for main parts of the drawings

1. compressor 2. condenser

3. Capillary tube 4. Refrigerator evaporator

5. Phase separator 6. Pressure sensor

7. Solenoid valve 8. Auxiliary capillary

9. Freezer Evaporator 10. Controller

11. Expansion valve 12. First freezer temperature sensor

13. Second Freezer Temperature Sensor 14. Refrigerator Temperature Sensor

15. First Phase Separator Temperature Sensor 16. Second Phase Separator Temperature Sensor

Hereinafter, the present invention will be described in more detail with reference to the accompanying FIG. 2 as an embodiment.

2 is a block diagram illustrating a cooling cycle of a refrigerator having two evaporators of the present invention. The present invention provides a compressor (1) for compressing a refrigerant, a condenser (2) for condensing the refrigerant compressed by the compressor, and And a capillary tube (3) for changing the temperature and pressure of the refrigerant passing through the condenser to correspond to a proper temperature of the refrigerating chamber, and a refrigerating chamber evaporator for cooling the refrigerating chamber while evaporating by the refrigerant passing through the capillary tube (4). And a phase separator 5 for separating the refrigerant passing through the refrigerating chamber evaporator into a liquid phase and a gas phase, and a pressure sensor connected in parallel between the phase separator and the compressor 1 to sense the pressure of the gas phase refrigerant flowing toward the compressor. 6 and the liquid-cooled liquid flowing toward the compressor 1 connected in parallel between the solenoid valve 7 on and off according to the sensing value of the pressure sensor, and the phase separator 5 and the compressor 1 in parallel. It consists of a freezer compartment evaporator (9) for cooling the freezing chamber while evaporating by the operation, provided between the phase separator (5) and the freezer compartment evaporator (9) while operating in accordance with the control signal of the controller (10) Expansion valve 11 for adjusting the amount of refrigerant in the liquid flowing toward the compressor 1 to correspond to the temperature of the freezer compartment, and the inlet and outlet temperatures of the freezer compartment evaporator are respectively installed at the inlet and outlet of the freezer compartment evaporator 9. And a first freezing chamber temperature sensor 12 and a second freezing chamber temperature sensor 13 for sensing the detected value and sending the detected value to the controller 10, and are installed at an inlet of the refrigerating chamber evaporator 4. The refrigerating chamber temperature sensor 14 which senses the inlet temperature and sends this detected value to the controller 10 and the upper and lower ends of the phase separator 5 respectively detect the upper and lower temperatures of the phase separator. Detect value to controller (10 When the temperature values detected by the first and second phase separator temperature sensors 15 and 16, including the first phase separator temperature sensor 15 and the second phase separator temperature sensor 16, are different from each other. The controller 10 controls the opening time of the expansion valve 11 according to the difference in the temperature value detected by the first and second freezing chamber temperature sensors 12 and 13 to allow normal operation to be performed. When the temperature values detected by the phase separator temperature sensors 15 and 16 are the same, the temperature detected by the first and second phase separator temperature sensors 15 and 16 and the refrigerator compartment temperature sensor ( According to whether the temperature sensed by 14) is the same or different, the abnormal operation is performed while controlling the opening time of the expansion valve 11 differently from the normal operation.

In the present invention configured as described above, when the refrigerant is compressed in the compressor (1) and condensed in the condenser (2) and then passes through the refrigerating chamber evaporator (4) through the capillary tube (3), the refrigerating chamber evaporator causes an evaporation action. The action of cooling to the appropriate temperature range (3 ° C.) and passing through the refrigerating chamber evaporator 4 to separate the liquid phase refrigerant from the phase separator 5 into the refrigerant in the gas phase is described in the related art. Is the same as

Meanwhile, when the refrigerant is separated from the liquid phase and the gas phase in the phase separator 5, the first phase separator temperature sensor 15 and the second phase separator temperature sensor 16 installed in the phase separator are upper and lower parts of the phase separator 5. The sensor senses the temperature and sends the detected value to the controller 10. At this time, if any one of the liquid refrigerant and the gas phase refrigerant separated in the phase separator 5 is saturated, the first and second phase separators Since the temperature values detected by the temperature sensors 12 and 13 are different from each other, the controller 10 normally controls the expansion valve 11 to allow the cycle to operate normally.

That is, the liquid refrigerant separated in the phase separator 5 passes through an expansion valve 11 connected in parallel between the phase separator and the compressor 1, and then passes through the freezer compartment evaporator 9, thereby allowing the freezer compartment evaporator. As the evaporation effect occurs, the freezer compartment is cooled to an appropriate temperature range (-18 ° C.), and the refrigerant passing through the freezer compartment evaporator 9 enters the compressor 1 while being in a gaseous state, and performs normal operation. At this time, the first freezer compartment temperature sensor 12 installed at the inlet side of the freezer compartment evaporator 9 and the second freezer compartment temperature sensor 13 installed at the outlet side of the freezer compartment evaporator 4 are provided. Senses the temperature of each and sends it to the controller 10, which compares the sensed values sensed by the first and second freezer temperature sensors 12 and 13 with each other and expands the expansion valve 11 according to this comparison value. It controls the opening time of) The liquid refrigerant flowing toward the operation when the compressor 1 is controlled.

The controller 10 controls the opening time of the expansion valve 11 to adjust the amount of the refrigerant in the liquid flowing toward the compressor 1, when the temperature of the freezing compartment drops below an appropriate temperature, the amount of refrigerant is reduced to reduce the flow of the refrigerant. This is to prevent the temperature of the freezer compartment from increasing more than necessary, and increasing the flow rate of the refrigerant when the temperature of the freezer compartment rises above an appropriate temperature.

While the above operation is performed, a pressure sensor 6 connected in parallel between the phase separator 5 and the compressor 1 senses the pressure of the gaseous refrigerant flowing from the phase separator 5 toward the compressor 1. In consideration of the increase in pressure as the amount of the liquid refrigerant separated in the phase separator 5 increases, the solenoid valve 7 is turned on because the sensing pressure of the pressure sensor 6 becomes greater than or equal to a predetermined pressure (3 bar). (Open), and from this time, the refrigerant in the gas phase passes through the solenoid valve 7 to enter the compressor 1 and is compressed again by the compressor.

On the other hand, when the refrigerant in the gas phase separated by the phase separator 5 enters the compressor 1, the sensing pressure of the pressure sensor 6 begins to drop from this time, and at some point, the sensing pressure of the pressure sensor is constant pressure. If it falls below (2.5 bar), the solenoid valve 7 is turned off (closed) so that the gaseous refrigerant does not enter the compressor 1 any more, and as described above, the liquid refrigerant again opens the expansion valve 11. It passes through the freezer compartment evaporator 9 and enters the compressor 1 by an amount proportional to time and is compressed again.

The above-described action is a state in which the cycle is normally operated. In this case, the first phase separator temperature sensor 15 and the second phase separator temperature sensor 16 respectively installed on the upper and lower portions of the phase separator 5 are the phase separators. The upper and lower temperature of (5) is sensed and the detected value is sent to the controller 10, and the refrigerating compartment temperature sensor 14 installed at the inlet of the refrigerating compartment evaporator 4 adjusts the inlet temperature of the refrigerating compartment evaporator. The sensing value is sent to the controller 10. In the process, when the pressure sensor 6 causes a pressure sensing error due to a change in external conditions, the liquid phase separated by the phase separator 5 As the refrigerant is saturated and filled to the maximum value, the sensing temperature of the first phase separator temperature sensor 15 and the second phase separator temperature sensor 16 installed in the phase separator 5 and the inlet portion of the evaporator 4 for the refrigerating compartment. Of the refrigerator compartment temperature sensor (14) installed in the When the temperature is the same and the sensing temperature of the first and second phase separator temperature sensors 15 and 16 and the refrigerating chamber temperature sensor 14 are the same, the controller 10 is a liquid refrigerant separated from the phase separator 5. Is determined to be saturated, and as a result of controlling the expansion valve to further increase the opening time of the expansion valve 11, a larger amount of liquid refrigerant is released from the phase separator 5, so that the sensing pressure of the pressure sensor 6 is Even if the solenoid valve 7 is turned on according to the value, liquid refrigerant does not enter the compressor 1 through the solenoid valve.

In addition, when the refrigerant in the gas phase separated by the phase separator 5 is saturated and filled to the maximum value, the first phase separator temperature sensor 15 and the second phase separator temperature sensor 16 installed in the phase separator 5 are filled. Although the sensing temperature of the same is the same, but the sensing temperature of the refrigerator compartment temperature sensor 14 installed in the inlet of the refrigerator evaporator (4) is not the same as the first and second phase separator temperature sensor (15) (16) controller 10 ) Determines that the refrigerant in the gas phase separated by the phase separator 5 is saturated and controls the expansion valve so that the opening time of the expansion valve 11 is further reduced, so that a small amount of liquid refrigerant is removed from the phase separator 5. Therefore, when the normal operation of the cycle is performed later, the liquid refrigerant separated in the phase separator 5 is smoothly introduced into the freezer compartment evaporator 9 through the expansion valve 11.

As described above, according to the present invention, when the liquid phase refrigerant separated by the phase separator becomes excessive compared to the refrigerant in the gas phase, the liquid phase refrigerant flows more rapidly toward the freezer compartment evaporator, so that the liquid phase refrigerant flows into the freezer compartment evaporator. There is no effect of entering the compressor immediately without passing through the compressor, so that the operation of the compressor is always smooth, and thus the power consumption is not increased and the cooling efficiency is not reduced.

Claims (1)

The refrigerant compressed in the compressor and condensed in the condenser passes through a capillary tube and then passes through a refrigerating chamber evaporator to be separated into a gaseous phase and a liquid phase by a phase separator. The separated vapor phase refrigerant enters the compressor and is compressed again, while the liquid refrigerant is frozen. In the compressor after passing through the practical evaporator to be compressed again, an expansion valve installed between the phase separator and the freezer compartment evaporator and operating in accordance with a control signal of the controller to adjust the amount of liquid refrigerant flowing toward the compressor corresponding to the temperature of the freezer compartment; A first freezer compartment temperature sensor and a second freezer compartment temperature sensor installed at an inlet and an outlet of the freezer compartment evaporator to sense an inlet and an outlet temperature of the freezer compartment evaporator and send the detected value to a controller; A refrigerator compartment temperature sensor installed at an inlet of the refrigerator compartment evaporator and sensing an inlet temperature of the refrigerator compartment evaporator and sending the detected value to a controller; First and second phases are installed at the top and bottom of the phase separator, respectively, and include a first phase separator temperature sensor and a second phase separator temperature sensor for sensing the upper and lower temperatures of the phase separator and sending the detected value to the controller. If the temperature value detected by the separator temperature sensor is different from each other, the controller controls the opening time of the expansion valve according to the difference of the temperature value detected by the first and second freezer temperature sensors to allow normal operation to be performed. When the temperature value detected by the two-phase separator temperature sensor is the same, the controller opens the expansion valve depending on whether the temperature detected by the first and second phase separator temperature sensors is the same or different from the temperature detected by the refrigerator compartment temperature sensor. Cooling cycle of a refrigerator having two evaporators, characterized in that abnormal operation is performed while controlling the time differently from normal operation.