KR102205250B1 - Method and Apparatus for Removing Condensate and Frost in Unit Cooler for Cold Storage - Google Patents

Abstract

The present invention suppresses the generation of frost by re-evaporating without applying heat to the condensed water generated on the surface of the heat transfer pipe of the unit cooler for refrigeration storage, thereby maintaining a constant temperature and humidity in the storage and preventing deterioration of the quality of storage It relates to a method and apparatus for removing condensate and frost from a unit cooler for refrigeration storage,
A method of removing condensate and defrosting from a unit cooler for refrigeration storage includes the steps of operating the refrigerator system 20 to cool the interior of the storage unit 50 using the unit cooler 10 (S10); Sensing the surface temperature of the heat transfer tube 11 provided in the unit cooler 10 (S20); When the surface temperature of the heat transfer tube 11 falls below zero, stopping the refrigerator system 20 so that the refrigerant is discharged and the surface temperature of the heat transfer tube 11 rises to the interior temperature (S30); Evaporating the condensed water on the surface of the heat transfer pipe 11 by operating the blower 12 of the unit cooler 10 (S40); When the condensed water evaporates, re-operating the refrigerator system 20 (S60); It characterized in that it comprises a.

Description

Method and Apparatus for Removing Condensate and Frost in Unit Cooler for Cold Storage {Method and Apparatus for Removing Condensate and Frost in Unit Cooler for Cold Storage}

The present invention relates to a method and apparatus for removing condensed water and defrost in a unit cooler for refrigeration storage, and more particularly, to the condensed water generated on the surface of a heat transfer tube of the unit cooler by re-evaporating without applying heat, thereby preventing the generation of frost. The present invention relates to a method and apparatus for removing condensate and defrost of a unit cooler for refrigerated storage, which is capable of suppressing and maintaining a constant temperature and humidity in a storage room and preventing deterioration of the quality of storage.

In general, low-temperature storage is a facility to stabilize the supply and demand of agricultural products by controlling the temperature inside the storage room where agricultural products are stored using a refrigerator, and to maintain the freshness of agricultural products even for long-term storage. Agricultural products are stored in the refrigerator.

In order to keep the inside temperature constant in a low temperature storage room, when the temperature inside the storage room is higher than the upper limit of the set temperature, the refrigerator system operates and lowers the inside temperature. When the temperature inside the storage room reaches the lower limit of the set temperature, the freezer system It is stopped and the cycle is repeated so that the internal temperature gradually rises again.

The refrigerator system lowers the internal temperature by flowing a refrigerant having a temperature lower than the internal temperature of the chamber by about 5 to 15°C into the inside of the heat transfer pipe of the unit cooler. That is, when the internal temperature of the chamber is 0°C, the refrigerant of -5 to -15°C passes through the unit cooler. In this way, as the coolant having a low temperature passes through the unit cooler, the surface temperature of the heat transfer tube of the unit cooler decreases. At this time, since the blower located at the rear of the heat transfer tube blows toward the heat transfer tube, the air in the chamber is blown by the blower and is cooled by heat exchange while passing through the surface of the heat transfer tube.

In this process, when the surface temperature of the heat transfer tube reaches the dew point temperature of air, moisture in the air is condensed on the surface of the heat transfer tube in the form of water droplets. In addition, when the surface temperature of the heat transfer tube is below zero, condensed water droplets freeze to generate frost.

In this way, when the refrigerator system is operated, the condensate or frost generated on the surface of the heat transfer pipe of the unit cooler has a great influence on the performance of the refrigerator system and the humidity environment of the low-temperature storage. Specifically, when frost is generated on the surface of the heat transfer pipe of the unit cooler, the heat exchange efficiency decreases and the frost accumulates and becomes thicker, which further deteriorates the heat exchange efficiency and takes a longer time to cool the air in the compartment. Accordingly, not only the operating time of the refrigerator system is lengthened, but also energy consumption is increased. In addition, as the condensate and frost generated on the surface of the unit cooler increases, the air in the chamber takes away moisture and becomes dry air.When the air in the chamber is dried, the evaporation of moisture from the storage increases and the storage becomes dry. Quality deteriorates.

Therefore, it is desirable to quickly remove condensate or frost generated on the surface of the heat transfer pipe of the unit cooler. However, in order to remove condensate and frost on the surface of the heat transfer pipe, there is a problem that the operation of the refrigerator system must be stopped. Accordingly, in a general refrigerator system, defrosting is performed in which frost is allowed to accumulate on the surface of the heat transfer pipe of the unit cooler and then melted by applying heat at an appropriate time. In some cases, a defrost operation is performed in which the refrigerant in the refrigerator system is circulated in the opposite direction to remove frost.

However, such a defrosting operation cannot fundamentally solve problems such as a decrease in the efficiency of the unit cooler or an increase in moisture loss of the stored material due to dry air, and the problem of increasing the temperature fluctuation inside the storage during heating is also inevitable.

Meanwhile, as a result of researching the prior art related to the present invention, a number of patent documents have been searched, and some of them are as follows.

Patent Document 1 describes the step of discharging the defrost waste heat from the evaporator to the outside of the room in controlling the operation of the refrigeration cycle applied to the low-temperature storage, measuring the current change acting on the blower, and analyzing the acquired data to determine the optimal defrost time and Disclosed is a method for controlling an operation of a small- to medium-sized low-temperature storage, which improves the performance and energy consumption efficiency of a low-temperature storage by applying an algorithm including the step of determining the end time to control the defrost operation.

Patent Document 2 is provided with a storage space inside to store agricultural and fishery products at low temperature, a roof is provided so that at least 100 to 500 mm or more is further led out, and a rain-covered eave is integrally provided, and external control means or wireless control A main body provided with means, provided with at least one or more air pressure regulators to control air pressure and humidity, and provided with an entrance door; A unit cooler provided with a heater for drying and defrosting or maintaining a set temperature for concentrated and marine products stored in the main body, and a defrost heater overheating prevention sensor; And an outdoor unit provided outside the main body to drive the unit cooler to a set temperature. When the agricultural products stored in the low-temperature storage are dried by the user's setting, the temperature of the storage is raised by a heater above a certain temperature to dry the agricultural products, and after a set time, automatically blow and defrost. , Refrigeration and heater are driven to store concentrated and aquatic products at low temperatures, and automatically blow, defrost, refrigerate, and heater defrost according to the set temperature to maintain the freshness of stored agricultural products, and are stored after being humidified by self-generated condensate without a separate humidifier. Disclosed is a low-temperature storage for long-term storage of agricultural products and a control method thereof.

In Patent Document 3, by using the defrost water in a vaporized state without discharging it to the outside of the low-temperature storage, it is possible to more easily maintain a constant humidity in the low-temperature storage, as well as food such as fruits stored in the low-temperature storage. Disclosed is a defrosting device for a low-temperature store that can more easily prevent a decrease in product value and freshness of food by maintaining an optimized humidity.

Patent Document 4 installs a frost detection camera that measures the change in the area where freezing occurs to detect a more accurate defrosting operation time to improve the cooling efficiency of the evaporator, thereby preventing an increase in temperature and energy waste in a low-temperature storage, and In addition to preventing power consumption, it is possible to more easily maintain a constant humidity in the low-temperature storage by using the defrosted water in a vaporized state without discharging it to the outside of the low-temperature storage. It discloses a defrosting system for a low-temperature storage facility that can more easily prevent the deterioration of the product value and freshness of the food by being able to maintain the optimum humidity of the food.

Patent Document 1: KR10-1269068 B1 Patent Document 2: KR10-2015-0098339 A Patent Document 3: KR10-1529623 B1 Patent Document 4: KR10-2017-0021534 A

The present invention suppresses the generation of frost by re-evaporating the condensate generated on the surface of the heat transfer pipe of the unit cooler without applying heat, thereby maintaining a constant temperature and humidity in the storage storage, and preventing degradation of the quality of the storage. It is an object of the present invention to provide a method and apparatus for removing condensate and defrosting of a unit cooler for refrigeration storage.

Condensed water and defrosting method of the unit cooler for refrigeration storage according to the present invention for achieving the above object comprises the steps of operating a refrigerator system to cool the interior of the storage by using the unit cooler; Sensing the surface temperature of the heat transfer tube provided in the unit cooler; Stopping the refrigerant system when the surface temperature of the heat transfer tube falls below zero so that the refrigerant is discharged and the surface temperature of the heat transfer tube rises to the interior temperature; Evaporating the condensed water on the surface of the heat transfer pipe by operating a blower of the unit cooler; Restarting the refrigerator system when the condensate evaporates; It characterized in that it comprises a.

In addition, according to the method for removing condensate and defrosting of the unit cooler for refrigeration storage of the present invention, it is characterized in that it further comprises the step of stopping the operation of the blower when the surface temperature of the heat transfer pipe reaches a set temperature.

In addition, according to the method for removing condensate and defrosting of the unit cooler for refrigeration storage of the present invention, it is characterized in that it further comprises the step of stopping the operation of the blower when the relative humidity in the storage reaches a certain humidity.

In addition, the condensed water and defrosting apparatus of the unit cooler for refrigeration storage according to the present invention includes: a unit cooler including a heat transfer pipe through which the refrigerant supplied from the refrigerator system passes, a blower, and a blower control unit; A main control unit for controlling the operation of the refrigerator system; A temperature sensor that senses the surface temperature of the heat transfer tube and transmits a signal to the main control unit; Including, the main control unit is characterized in that when the surface temperature of the heat transfer pipe sensed by the temperature sensor reaches below zero, stopping the operation of the refrigerator system and operating the blower through the blower control unit.

In addition, according to the condensate and defrosting device of the unit cooler for refrigeration and storage of the present invention, the surface temperature of the heat transfer tube detected by the temperature sensor is compared with the set temperature, and when the surface temperature of the heat transfer tube reaches the set temperature, a signal is sent to the blower control unit. It characterized in that it further comprises a temperature controller to stop the operation of the blower by sending.

In addition, according to the condensed water and defrosting device of the unit cooler for refrigeration storage of the present invention, the blower control unit is characterized in that it is equipped with a timer to stop the operation of the blower after a certain period of time after the operation of the blower starts.

In addition, according to the condensate and defrosting device of the unit cooler for refrigeration storage of the present invention, a humidity sensor for sensing the relative humidity in the storage and a humidity controller for stopping the operation of the blower when the relative humidity in the storage reaches the set humidity. Characterized in that.

In addition, according to the condensed water and defrosting apparatus of the refrigerating storage unit cooler of the present invention, the blower control unit is characterized in that it further comprises a speed control unit for adjusting the number of rotations of the blower.

In addition, according to the condensate and defrosting device of the unit cooler for refrigeration storage of the present invention, it is possible to replace the step of sensing the surface temperature of the heat transfer tube provided in the unit cooler with the step of sensing the temperature inside the chamber of the low-temperature storage. It is characterized.

The method and apparatus for removing condensate and defrosting of the unit cooler for refrigeration according to the present invention increases the temperature of the heat transfer tube by stopping the freezer system when the temperature of the heat transfer tube falls below zero and the condensate starts to freeze while water droplets are formed on the heat transfer tube of the unit cooler. As a result, condensate and frost can be removed without applying heat to the heat transfer pipe, as well as condensate or frost, since it evaporates quickly by increasing the evaporation rate of water droplets by blowing air using a blower. There is an effect of preventing a decrease in the efficiency of the unit cooler due to a decrease in the efficiency of the unit cooler and maintaining the relative humidity in the storage above a certain level, thereby preventing quality degradation due to drying of the storage material.

In addition, according to the method and apparatus for removing condensate and defrost of the unit cooler for refrigeration and storage of the present invention, as the stop point of the blower operated to remove condensate and frost is set, power consumption due to the operation of the blower is reduced and There is an effect of being able to prevent exposure to this much wind.

In addition, according to the method and apparatus for removing condensate and defrosting of the unit cooler for refrigeration and storage of the present invention, the blower can be stopped based on the humidity in the storage, so that the relative humidity in the storage can be adjusted.

In addition, according to the method and apparatus for removing condensate and defrosting of the unit cooler for refrigeration and storage of the present invention, the rotation speed of the blower can be adjusted, thereby reducing power consumption and maintaining an appropriate air volume.

1 is a flow chart illustrating a method of removing condensate and defrosting of a unit cooler for refrigeration storage according to the present invention.
Figure 2 is a schematic view showing the condensate and defrosting device of the unit cooler for refrigeration storage according to the present invention.
Figure 3 is a block diagram showing a control path of the condensed water removal device of the unit cooler for refrigeration storage of the present invention.

Hereinafter, a method and apparatus for removing condensed water in the unit cooler for refrigeration storage according to the present invention will be described with reference to the accompanying drawings.

1 is a flow chart showing a method of removing condensate and defrosting of a refrigerated storage unit cooler according to the present invention, and FIG. 2 is a schematic configuration diagram showing a condensed water and defrosting apparatus of a unit cooler for refrigerating storage according to the present invention. , Figure 3 is a block diagram showing a control path of the condensed water removal device of the unit cooler for refrigeration storage of the present invention.

In the method for removing condensate and defrosting of the unit cooler for refrigeration according to the present invention, as shown in FIG. 1, the refrigerator system 20 is operated to cool the interior of the storage 50 using the unit cooler 10. Supplying a refrigerant to the unit cooler 10 (S10); Sensing the surface temperature of the heat transfer tube 11 provided in the unit cooler 10 (S20); When the surface temperature of the heat transfer tube 11 falls below zero, stopping the refrigerator system 20 so that the refrigerant is discharged and the surface temperature of the heat transfer tube 11 rises to the interior temperature (S30); Evaporating the condensed water on the surface of the heat transfer pipe 11 by operating the blower 12 of the unit cooler 10 (S40); Stopping the operation of the blower 12 when the surface temperature of the heat transfer pipe 11 reaches the set temperature (S50); When the condensed water evaporates, re-operating the refrigerator system 20 (S60); It is made including.

Here, instead of stopping the operation of the blower 12 based on the surface temperature of the heat transfer pipe 11 (S50), the relative humidity in the storage 50 is measured, and when the relative humidity reaches a certain humidity, the blower 12 It is also possible to perform the step (S55) of stopping the operation of.

For this purpose, the condensate and defrosting device of the unit cooler for refrigeration storage of the present invention, as shown in Figs. 2 and 3, the unit cooler 10, the refrigerator system 20, the main control unit 25, the temperature sensor 30 ).

The unit cooler 10 is installed inside the storage storage 50 to cool the storage 50, and the heat transfer pipe 11 through which the refrigerant supplied from the refrigerator system 20 passes, and air for circulation of air in the storage A blower 12 for circulating and a blower control unit 13 for controlling the operation of the blower 12 are included, and a temperature sensor 30 is provided on one side to sense the surface temperature of the heat transfer pipe 11.

The refrigerator system 20 supplies a cool refrigerant to the unit cooler 10 using a refrigeration circuit, and supplies a refrigerant having a temperature of about 5 to 15° C. lower than the internal temperature of the chamber to the unit cooler 10.

The main control unit 25 controls the operation of the refrigerator system 20 according to the internal temperature of the storage 50 or the surface temperature of the heat transfer tube 11 sensed by the temperature sensor 30, and the temperature sensor 30 When the surface temperature of the heat transfer pipe 11 sensed by this reaches below zero, the operation of the refrigerator system 20 is stopped and the blower 12 is operated through the blower control unit 13.

Then, the surface temperature of the heat transfer tube 11 sensed by the temperature sensor 30 is compared with the set temperature, and when the surface temperature of the heat transfer tube 11 reaches the set temperature, a signal is sent to the blower control unit 13 to send the blower 12 A temperature controller 35 to stop the operation of the may be further installed. At this time, it is natural that the set temperature for stopping the operation of the blower 12 must be the temperature of the image.

In addition, the blower control unit 13 may be provided with a timer 15 to automatically stop the operation of the blower 12 after a predetermined time elapses after the operation of the blower 12 starts. In addition, it is preferable that the blower control unit 13 includes a speed control unit 14 for adjusting the number of rotations of the blower 12 to reduce power consumption and maintain an appropriate air volume.

In addition, a humidity sensor 40 for sensing the relative humidity in the storage 50 and a humidity controller 45 for stopping the operation of the blower 12 when the relative humidity in the storage 50 reaches a set humidity may be further included. have. Accordingly, it is possible to adjust the relative humidity in the storage 50 to a certain level.

The operation of the condensed water and defrosting method and apparatus of the refrigerated storage unit cooler of the present invention configured as described above will be described as follows.

In order to control the temperature in the storage 50, when the refrigerator system 20 is operated, the refrigerant of the refrigerator system 20 is supplied to the heat transfer pipe 11 of the unit cooler 10 to cool the inside of the storage 50. At this time, the blower 12 of the unit cooler 10 blows air in the storage 50 so that heat exchange occurs on the surface of the heat transfer tube 11, and in this process, the heat transfer tube 11 is lower than the dew point temperature of the air. Moisture in the air is condensed due to the surface temperature and formed as water droplets on the surface of the heat transfer tube 11.

Thereafter, when the surface temperature of the heat transfer tube 11 is continuously lowered and falls below zero, water droplets formed on the surface of the heat transfer tube 11 freeze to generate frost. At this time, when the temperature sensor 30 senses the temperature of the heat transfer tube 11 and falls below zero, it sends a signal to the main control unit 25, so that the main control unit 25 stops the refrigerator system 20. Accordingly, the surface temperature of the heat transfer tube 11 increases, and the frost melts and turns into water droplets. At the same time, since the blower 12 is operated by the blower control unit 13 to blow air into the heat transfer tube 11, the evaporation rate of water droplets formed in the heat transfer tube 11 increases and evaporates quickly.

Through the above process, when all water droplets and frost condensed on the surface of the heat transfer pipe 11 are removed, the main fishing unit 25 restarts the refrigerator system 20 to maintain the temperature of the storage storage 50 below a certain level. .

Here, a method of removing condensate and defrost using the refrigerator system 20 and the blower 12 will be described as follows.

While the refrigerator system 20 is operating, since the refrigerant passes through the heat transfer tube 11, the surface temperature of the heat transfer tube 11 continuously decreases and falls below zero. However, when the refrigerator system 20 is stopped and the refrigerant escapes from the heat transfer tube 11, the surface temperature of the heat transfer tube 11 becomes the same as the internal temperature of the storage 50 within a few seconds. In addition, as the internal temperature of the storage unit 50 gradually increases until the refrigerator system 20 is operated again, the surface temperature of the heat transfer tube 11 also increases.

When the freezer system 20 is stopped and the surface temperature of the heat transfer tube 11 rises to an image, the frost on the heat transfer tube 11 melts and turns into water droplets, but the refrigerator system 20 is in a state where the water droplets are not removed quickly. When it is activated again, the water droplets freeze into the frost, forming a thicker frost.

Accordingly, in the present invention, the blower 12 is used to rapidly evaporate the condensed water on the surface of the heat transfer pipe 11 so as not to freeze again. In general, when the refrigerator system is stopped, the blower provided in the unit cooler is also stopped, but in the present invention, even if the refrigerator system 20 is stopped, the blower 12 of the unit cooler 10 through the blower control unit 13 is continuously operated. Make it possible. Accordingly, water droplets formed on the surface of the heat transfer tube 11 are rapidly evaporated by the air blown by the blower 12. Thereafter, when the surface temperature of the heat transfer tube 11 rises to an image, the condensed water on the surface of the heat transfer tube 11 is completely evaporated, so that even if the refrigerator system 20 is re-operated, the accumulated formation of frost disappears.

In addition, if the blower 12 of the unit cooler 10 is continuously operated, power consumption increases and the storage material is exposed to the wind and the quality of the storage material is degraded, so the temperature controller 35 detects it by the temperature sensor 30. When the surface temperature of the heat transfer tube 11 is compared with a set temperature set as an image, the blower 12 is stopped when the surface temperature becomes higher than the set temperature. At this time, the blower 12 may be automatically stopped after the blower 12 is operated for a certain period of time by using the timer 15.

In addition, the humidity sensor 40 and the humidity controller 45 may be used to control the stopping point of the blower 12. That is, when the relative humidity in the storage 50 reaches a certain humidity due to re-evaporation of the condensed water, the blower 12 is stopped. Accordingly, it is possible to adjust the relative humidity in the storage (50).

In addition, instead of sensing the surface temperature of the heat transfer tube of the unit cooler, the object of the present invention may be achieved by sensing the temperature in the storage chamber of the low-temperature storage.

Although described and illustrated in connection with embodiments for exemplifying the technical idea of the present invention, the present invention is not limited to the configuration and operation as described above, and deviates from the scope of the technical idea described in the claims. Without this, it will be well understood by those of ordinary skill in the art that many changes and modifications can be made to the present invention. Accordingly, all such appropriate changes and modifications and equivalents should be considered to be within the scope of the present invention.

10...unit cooler
11... heat transfer tube
12... blower
13...Blower control
14...speed control
15...timer
20... refrigerator system
25...Main control
30... temperature sensor
35...temperature controller
40... humidity sensor
45...humidity controller
50...Storage

Claims (8)

Operating the refrigerator system 20 to cool the interior of the storage 50 using the unit cooler 10 (S10);
Sensing the surface temperature of the heat transfer tube 11 provided in the unit cooler 10 (S20);
When the surface temperature of the heat transfer tube 11 falls below zero, the refrigerant is discharged by stopping the refrigerator system 20, and the surface temperature of the heat transfer tube 11 rises to the interior temperature (S30);
Evaporating the condensed water on the surface of the heat transfer pipe 11 by operating the blower 12 of the unit cooler 10 (S40);
Stopping the operation of the blower 21 when the surface temperature of the heat transfer tube 11 becomes higher than or equal to the set temperature set in the image or when the relative humidity in the storage 50 reaches a certain humidity; And
When the condensed water evaporates, re-operating the refrigerator system 20 (S60);
Condensate and defrosting method of the unit cooler for refrigeration storage comprising a. A unit cooler 10 including a heat transfer tube 11 through which a refrigerant having a temperature of 5 to 15°C lower than the internal temperature of the storage is supplied from the refrigerator system 20 to pass therethrough, a blower 12 and a blower control unit 13;
A main control unit 25 for controlling the operation of the refrigerator system 20;
A temperature sensor 30 that senses the surface temperature of the heat transfer tube 11 and transmits a signal to the main control unit 25;
Including,
The main control unit 25 stops the operation of the refrigerator system 20 when the surface temperature of the heat transfer tube 11 sensed by the temperature sensor 30 drops below zero, and the blower 12 through the blower control unit 13 Condensate and defrosting device of a unit cooler for refrigeration storage, characterized in that to operate. The method according to claim 2,
Further comprising a temperature controller 35,
When the surface temperature of the heat transfer tube 11 sensed by the temperature sensor 30 becomes higher than the set temperature set as an image, the temperature controller 35 sends a signal to the blower control unit 13 to stop the operation of the blower 12. Condensed water and defrosting device of the unit cooler for refrigeration storage, characterized in that. The method according to claim 2,
The blower control unit 13 includes a timer 15 to stop the operation of the blower 12 after a certain period of time after the operation of the blower 12 starts. Removal device. The method according to claim 2,
It characterized in that it further comprises a humidity sensor 40 for sensing the relative humidity in the storage 50 and a humidity controller 45 for stopping the operation of the blower 12 when the relative humidity in the storage 50 reaches a set humidity. Condensate and defrosting device of unit cooler for refrigeration storage. The method according to any one of claims 2 to 5,
The blower control unit 13 further comprises a speed control unit 14 for adjusting the number of rotations of the blower 12. Condensate and defrosting device of the unit cooler for refrigeration storage. delete delete

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