KR19980025608A - Refrigeration cycle device for rapid freezing function and control method - Google Patents

Abstract

The present invention relates to a refrigeration cycle device for a quick freezing function, and in the related art, by separately performing the freezing and rapid freezing by separate first and second evaporators, there is a hassle of having to operate on / off of the electronic valve a lot. In addition, the operation of the second evaporator can not be cooled through the first evaporator, and since the freezing is performed by direct cooling, there is a disadvantage in that the fast freezing of the food is not performed, thereby reducing the freshness of the food. In the case of rapid freezing operation, the fan can be cooled by changing the load around the installation of the first evaporator, and the frequency of opening and closing of the electronic valve is reduced, so that the noise reduction and the life of the electronic valve can be extended. By freezing water, that is, the maximum ice crystal generation zone of food during rapid freezing of food, it is possible to quickly freeze food by direct cooling and liver cooling. It is designed to keep food fresh and frozen.

Description

Refrigeration cycle device for rapid freezing function and control method

1 is a schematic view showing a general refrigeration cycle.

Figure 2 is a schematic view showing a conventional refrigeration cycle apparatus for a quick freezing function.

2 is a schematic view showing a refrigeration cycle device for a quick freezing function of the present invention.

3 is a configuration diagram schematically showing a modification of the refrigeration cycle device for a quick freezing function of the present invention.

＊ Description of symbols for main parts of the drawings ＊

1: Compressor 2: Condenser

3: capillary 3 ': first capillary

3: capillary 4: evaporator

4 ': first evaporator 4: second evaporator

5: Electronic side 6: Reverse side

7: first fan 8: first temperature sensor

9: second fan 10: second temperature sensor

11: control means 12: thermal expansion valve

The present invention relates to a refrigeration cycle device for a quick freezing function and a control method thereof, and more particularly to a refrigeration cycle device for a freezing and quick freezing and to control the freezing and rapid freezing of food in a fresh state and control thereof It is about a method.

As shown in FIG. 1, a general refrigeration cycle includes a compressor (1) for changing a low-temperature, low-pressure gaseous refrigerant into a high-temperature, high-pressure gaseous refrigerant, and a high-temperature, high-pressure gas state changed in the compressor (1). Condenser (2) for changing the refrigerant of the high temperature and high pressure liquid state, a capillary tube (3) for changing the high temperature and high pressure liquid refrigerant changed in the condenser (2) to a low temperature low pressure liquid refrigerant, and the capillary tube (3) It is composed of an evaporator (4) that absorbs external heat while changing the liquid refrigerant of the low temperature and low pressure changed in the gas state. Each component is connected by a refrigerant pipe.

The refrigeration cycle is applied to a refrigerator or an air conditioner and the like, by storing the fresh food or cooling / heating the room by absorbing external heat from the evaporator 4 and releasing heat to the outside from the condenser 2. The indoor environment is kept comfortable.

On the other hand, by applying the refrigeration cycle it is possible to have a function to rapidly freeze as needed, conventional refrigeration cycle device having a quick freezing function is as follows.

In a conventional refrigeration cycle apparatus having a rapid freezing function, as shown in FIG. 2, a condenser 2 is connected to a compressor 1 for compressing a refrigerant followed by a condenser 2 and a first capillary tube 3 '. The first and the first capillary tube 3 'is connected to an electronic valve 5 that opens and closes, and the electronic valve 5 is connected to a first evaporator 4', and the first evaporator 4 'is connected to the compressor. It is configured to make a cycle in connection with (1). The second capillary tube 3 is branched between the first capillary tube 3 'and the electronic valve 5 to connect the second capillary tube 3, and the second evaporator 4 having a rapid freezing function is connected thereto. The second evaporator 4 is followed by a reverse branch 6 for preventing the backflow of the refrigerant, and the reverse side 6 is connected to the other of the first evaporator 4 'and the compressor 1 on the other side. Each of the above components is connected by a refrigerant pipe.

The action of the structure is as follows.

First, in the case of performing the general refrigeration function, the refrigerant gas of the high temperature and high pressure is operated by the operation of the compressor 1 in the state in which the electromagnetic valve 5 is opened. The condenser 2-the first capillary tube 3 '-the electromagnetic valve 5- 1 evaporator (4 ')-go through the circulation cycle of the compressor (1), the refrigerant in the first evaporator (4') is changed from the liquid state to the gas state to absorb the external heat to maintain the freezing state. The refrigerant having passed through the first capillary tube 3 'does not flow to the second capillary tube 3 due to the resistance of the second capillary tube 3 but to the electron valve 5.

Next, in the case of performing the quick freezing function, the refrigerant gas of the high temperature and high pressure is operated by the operation of the compressor 1 in the state in which the electromagnetic valve 5 is closed, and the condenser 2-the first capillary tube 3 '-the second capillary tube 3 )-The second evaporator (4)-Reverse valve (6)-Through the circulation cycle of the compressor (1), the refrigerant depressurized in two stages through the first and second capillary tubes (3 ', 3) is the second evaporator ( In 4), it changes from liquid state to gaseous state and absorbs more external heat and rapidly freezes.

The reverse ground 6 prevents the refrigerant warmed by the heater during the defrost of the first evaporator 4 ′ from entering the second evaporator 4.

However, the conventional structure as described above has to perform a lot of on / off operation of the electronic valve (5) by separately performing the freezing and rapid freezing by separate first and second evaporators (4 ', 4). Not only there is a drawback, but there is a problem in that cooling through the first evaporator 4 ′ is impossible during operation of the second evaporator 4. In addition, since the freezing is made by direct cooling, there is a disadvantage in that the fast freezing of the food is not made, thereby reducing the freshness of the food.

Accordingly, an object of the present invention is to provide a refrigeration cycle device for a quick freezing function that can be stored frozen in a more fresh state and can perform freezing and rapid freezing at the same time.

In order to achieve the object of the present invention as described above, a compressor for compressing a refrigerant is connected to a condenser, a condenser is connected to a first capillary, a first capillary is connected to a first evaporator, and a first evaporator is opened and closed. An electron valve is connected to the electronic valve, which is connected to the compressor, and is branched between the first evaporator and the electronic valve to connect a second capillary tube, followed by a second capillary tube, and a second evaporator to the second evaporator. Subsequently, a reverse displacement is connected to prevent reverse flow, and the reverse displacement is connected between the electromagnetic valve and the compressor, and is composed of a compressor-condenser-first capillary tube-first evaporator-second capillary tube-second evaporator-reverse valve First and second temperature sensors for sensing the second cycle, the first and second fans and the temperatures respectively installed on the side of the first and second evaporators, and the first and second fans and the first and second temperature sensors The electronic surface and rapid freezing function combined refrigerating cycle apparatus characterized in that it comprises a control means which are connected to the compressor controls the operation is provided.

In addition, there is provided a refrigeration cycle device for a quick freezing function, characterized in that the second capillary tube is replaced with a thermal expansion valve that is opened and closed according to the temperature state of the second evaporator.

In addition, in a refrigeration cycle apparatus equipped with two evaporators to serve as a rapid freezing function, when the temperature of the first evaporator is higher than the set temperature by the detection of the first temperature sensor during the rapid freezing operation, the first fan is driven and the set temperature is increased. If it is lower than the step of stopping the driving of the first fan, and if the temperature of the coolant to be placed around the second evaporator outside the set temperature -1 ℃ ~ -5 ℃ by the detection of the second temperature sensor the second fan The control method of the refrigeration cycle apparatus for a quick freezing function characterized in that the step of driving and if the set temperature is in the range of -1 ° C to -5 ° C.

Hereinafter, a refrigeration cycle device for a quick freezing function and a control method thereof according to an embodiment of the present invention will be described.

In the refrigeration cycle apparatus for a quick freezing function of the present invention, as shown in FIG. 3, a condenser 2 is connected to a compressor 1 for compressing a solvent, followed by a condenser 2 and a first capillary tube 3 '. ) Is connected and the first evaporator 4 'is connected to the first capillary tube 3' and the electronic valve 5 which opens and closes is connected to the first evaporator 4 'and the electronic valve 5 is connected to the first evaporator 4'. The first cycle which is connected with the compressor 1 is comprised.

And branched between the first evaporator 4 'and the electron valve 5 to connect the second capillary tube 3, followed by the second capillary tube 3 to the second evaporator 4, and to the second evaporator 4 Subsequently, a reverse displacement 6 is connected to prevent reverse flow, and the reverse displacement 6 is connected between the electromagnetic edge 5 and the compressor 1 so that the compressor 1, the condenser 2, and the first capillary tube 3 are connected. ')-First evaporator (4')-second capillary tube (3)-second evaporator (4)-reverse displacement (6) and a second cycle consisting of the compressor (1).

In addition, a first fan 7 is installed at the side of the first evaporator 4 'and a first temperature sensor 8 for sensing the temperature of the first evaporator 4' is installed. In addition, a second fan 9 is installed at the side of the second evaporator 4, and a second temperature sensor 10 for sensing the temperature of the second evaporator 4 is installed.

The first and second fans 7 and 9 and the first and second temperature sensors 8 and 10 are connected to the control means 11, and the compressor 1 is also connected to the control means 11. Controlled by the control means 11.

Hereinafter, the operational effects of the refrigeration cycle apparatus for a quick freezing function and the control method of the present invention will be described.

In the refrigeration cycle apparatus for a rapid freezing function of the present invention, when performing the general freezing function, the refrigerant gas of the high temperature and high pressure is operated by the operation of the compressor 1 in the state in which the electromagnetic valve 5 is open. (3 ')-The first evaporator (4')-The electromagnetic valve (5)-The first evaporator (4 ') to absorb the external heat while maintaining the freezing state while circulating the first cycle through the compressor (1) do. The refrigerant through the first evaporator 4 ′ passes through the electron valve 5 instead of through the second capillary tube 3 because of the resistance of the second capillary tube 3.

Next, in the case of performing the quick freezing function, the refrigerant gas of the high temperature and high pressure is operated by the operation of the compressor 1 in the state in which the electromagnetic valve 5 is closed, the condenser 2-the first capillary tube 3 '-the first evaporator 4 ')-Second capillary tube (3)-second evaporator (4)-reverse displacement (6)-goes through the second cycle of the compressor (1), in the process by the detection of the first temperature sensor (8) If the internal temperature is lower than the set temperature of the control means 11, the coolant simply passes through. If the temperature is higher than the set temperature of the control means 11, the coolant is partially evaporated, and under the control of the control means 11, the first fan ( 7) is operated to keep below the set temperature. The refrigerant through the first evaporator 4 ′ is reduced in pressure via the second capillary tube 3 and flows into the second evaporator 4.

In addition, the second evaporator (4) sets the temperature range of the control means (11) by setting the temperature state of the food in the range of -1 ° C to -5 ° C, and is used for the detection of the second temperature sensor (10) for sensing the temperature. When the temperature of the food placed in the refrigerator becomes higher than the set temperature, the second fan 9 is operated. If it is within the set temperature range, the second fan 9 is stopped. Let's go.

The temperature setting range of food -1 ℃ ~ -5 ℃ should be within 30 minutes when the food is frozen as the maximum ice crystal production of food, so that it can be stored frozen for a long time without compromising the taste of the food. do.

In the second evaporator 4, if the food is outside the maximum ice crystal generating zone, the food is cooled by intercooling using a fan. When the food is within the maximum ice crystal producing zone, the operation of the fan is stopped and the direct cooling is performed to achieve metal freezing. .

When the temperature of the object to be cooled is -18 ° C or lower during the rapid freezing operation, or when the cooling time in the second evaporator 4 exceeds the set cooling time of the control means 11, the electronic valve 5 is opened to become a normal operation cycle. .

When defrosting the first and second evaporators, the reverse flow of the refrigerant is prevented by the reverse side 6 and the electromagnetic side 5.

In addition, as a modification of the present invention, as shown in FIG. 4, the second capillary tube 3 is replaced by a thermal expansion valve 12 that is opened and closed in accordance with an internal temperature state. The pressure inside the thermal expansion valve 12 changes according to the temperature of the second evaporator 4 so that the opening and closing of the thermal expansion valve 12 is adjusted according to the capacity of the second evaporator 4 to adjust the refrigerant flow rate and reduce the pressure of the pressure reducing device. It will play a role.

As described above, the present invention can be cooled by driving the fan in accordance with the variation of the load around the installation of the first evaporator (4 ') even during the rapid freezing operation, and the number of opening and closing of the electromagnetic valve (5) is also reduced noise And the lifetime of the electron valve 5 can be extended. In addition, the reverse flow of the refrigerant is prevented by the electromagnetic side 5 and the reverse side 6 during defrosting, thereby improving the efficiency of the cycle.

In addition, it is possible not only to consider the maximum ice crystal generation zone of the food to be frozen, that is, the rapid freezing of food, but also to freeze the food quickly by means of direct cooling and liver cooling, thereby freezing and storing the food more freshly.

Claims (3)

A compressor for compressing the refrigerant is connected to a condenser, followed by a first capillary, followed by a first evaporator, followed by an electronic valve that opens and closes. The electronic valve comprises: a first cycle connected with the compressor; The second capillary is connected between the first evaporator and the electron valve, and the second capillary is connected to the second evaporator, followed by the second evaporator, followed by a reverse displacement preventing reverse flow. A second cycle connected between the electromagnetic valve and the compressor comprising a compressor-a condenser-a first capillary tube-a first evaporator-a second capillary tube-a second evaporator-a reverse valve and the compressor; First and second temperature sensors configured to sense temperatures in the first and second fans and the inside of the first and second evaporators, respectively, the first and second fans and the first and second temperature sensors, the electronic valve and the compressor. Refrigeration cycle apparatus for a quick freezing function, characterized in that it comprises a control means connected to each connected to control the operation. The refrigeration cycle apparatus for a quick freezing function according to claim 1, wherein the second capillary tube is replaced with a thermal expansion valve that opens and closes according to a temperature state of the evaporator. In a refrigeration cycle apparatus equipped with two evaporators to serve as a quick freezing function, when the temperature of the first evaporator is higher than the set temperature by the detection of the first temperature sensor during the rapid freezing operation, the first fan is driven and When the low temperature is low, if the temperature of the coolant to be placed around the second evaporator outside the set temperature -1 ℃ to -5 ℃ by the detection of the second temperature sensor, the second fan is stopped. And a step of stopping the driving of the second fan when the temperature is within the range of the set temperature of -1 ° C to -5 ° C.