KR102386981B1 - Defrosting device of heat-exchanger for a cooler - Google Patents

Abstract

The present invention relates to a defrosting device for a heat exchanger for a cooler for storing agricultural/livestock products, seafood, food, pharmaceuticals, alcoholic beverages, plant seeds, etc. Frost is formed on the evaporator, and the frost is removed using a heater. As described above, in the defrosting method, the user roughly calculates the defrost time, operates the evaporator for 20 minutes, and then supplies power to the heater to remove the frost on the evaporator for 5 minutes. After that, as a repeated control method to operate the evaporator again, the frost is removed through the time set by the user.
And if frost accumulates on the cooling fins and the surface of the refrigerant tube of the evaporator No. 10-1788095, even if the blowing fan is operated, outside air does not flow between the evaporator and the blowing fan and the space between the evaporator and the blowing fan becomes a vacuum. Defrost is removed by using a wind pressure sensor that detects whether there is a vacuum.
However, the present invention installs a blade that expands when a strong wind by blowing force (wind) occurs in front of the blowing fan so that frost is accumulated on the evaporator so that outside air does not flow between the evaporator and the blowing fan and the space between the evaporator and the blowing fan is vacuum In this state, the blowing power is weakened (referred to as a breeze), and as a result, power is applied to the heater installed in the evaporator while the blade spread by the strong wind is folded by its own weight. do.

Description

DEFROSTING DEVICE OF HEAT-EXCHANGER FOR A COOLER

The present invention relates to a defrosting device for a heat exchanger for a cooler for storing agricultural/livestock products, seafood, food, pharmaceuticals, alcoholic beverages, plant seeds, etc. Frost is formed on the evaporator, and the frost is removed using a heater. As described above, in the defrosting method, the user roughly calculates the defrost time, operates the evaporator for 20 minutes, and then supplies power to the heater to remove the frost on the evaporator for 5 minutes. After that, as a repeated control method to operate the evaporator again, the frost is removed through the time set by the user.

And if frost accumulates on the cooling fin and the surface of the refrigerant tube of the evaporator No. 10-1788095, even if the blowing fan is operated, outside air does not flow between the evaporator and the blowing fan and the space between the evaporator and the blowing fan becomes a vacuum. Defrost is removed by using a wind pressure sensor that detects whether there is a vacuum.

However, the present invention installs a blade that unfolds when a strong wind is generated by the blowing force (wind) in front of the blowing fan so that frost is accumulated on the evaporator so that outside air does not flow between the evaporator and the blowing fan and the space between the evaporator and the blowing fan is vacuumed In this state, the blowing power is weakened (referred to as a breeze), which causes the blade to melt and remove the frost formed on the evaporator by applying power to the heater installed in the evaporator while the blade spread by the strong wind is folded by its own weight. Provides defrosting of heat exchangers for coolers.

For reference, unlike general household refrigerators, low-temperature warehouses keep the internal temperature up to the set temperature.

Frost is formed on the evaporator due to the humid air remaining inside the agricultural and fishery products and the low-temperature warehouse before reaching the evaporator, and the evaporator cannot function properly.

In general, the refrigeration cycle includes a compressor for compressing a gas refrigerant such as Freon into a gas refrigerant of high temperature and high pressure; a condenser for cooling, condensing, and liquefying the high-temperature and high-pressure gas refrigerant supplied from the compressor with external air; an expansion valve for depressurizing the liquid refrigerant from the condenser; It consists of an evaporator for cooling by absorbing ambient heat as the refrigerant pressure-reduced from the expansion valve is evaporated.

In a refrigeration system equipped with such a refrigeration cycle, cold air heat-exchanged with the refrigerant passing through the evaporator is supplied to the freezing chamber or the refrigerating chamber by the operation of a fan to perform cooling and refrigerating functions.

Such a conventional evaporator 100 includes a plurality of refrigerant tubes 110 through which the refrigerant passes therein as shown in FIGS. 1 and 2; A plurality of cooling fins 120 are coupled to the outer circumferential surface of the refrigerant tube 110 at intervals to increase the heat exchange efficiency of the refrigerant.

At this time, the refrigerant tube 110 is supported by the frame 130 having the closing cover 131 to allow the refrigerant to pass therethrough.

In addition, a blowing fan 140 is provided in the front region of the evaporator 100 , and a water collecting tank 150 in which the defrost water generated by the evaporator 100 is collected is provided at the lower portion.

At this time, as the refrigerant passing through the refrigerant tube 110 evaporates, heat is taken from the surroundings to form cold air, which is supplied to the low-temperature warehouse through the blower fan 140 .

And, when the refrigerant tube 110 takes heat from the air, the cooling fin 120 increases the contact area thereof to effectively take the heat of the air, thereby rapidly changing the surrounding air into cold air.

Therefore, the air inside the low-temperature warehouse is continuously circulated and formed into cold air by contact with the evaporator 100, and then becomes high-temperature by heat exchange with a material to be cooled, such as food stored in the warehouse while passing through the warehouse, and then back to the evaporator ( 100) and the cycle of coming into contact with it is repeated.

In this air circulation process, moisture contained in the air is condensed into water droplets on the blowing fan 140 in the evaporator 100, and the water droplets formed in this way are frozen by the low temperature in the evaporator 100 to form frost. will be.

The frost generated in this way is supplied with power into the evaporator 100 and melted and removed with heat generated by the defrost heater 200 installed to generate heat.

And, the defrost water of the evaporator 100 generated by the defrost heater 200 is collected in the water collecting tank 150 and then drained through the drain pipe 151 .

The above-described defrosting is removed using the heater 200. In summary, the removal control method for removing the evaporator 100 is operated for a certain time and then the heater 200 is operated when the preset time set by the user is reached. to remove the frost on the evaporator.

As described above, in the defrosting method, the user roughly calculates the defrosting time, operates the evaporator 100 for 20 minutes, and then supplies power to the heater 200 to remove the frost formed on the evaporator for 5 minutes. After that, as a repeat control method to operate the evaporator again,

Defrost is removed through the time set by the user.

By using such a method, power is automatically supplied to the heater 200 when the set time is reached regardless of whether frost is formed on the evaporator 100 , and a large amount of frost is implanted in the evaporator 100 so that the evaporator Considering that the defrost is not removed because the set time is not reached even though it is not functioning properly, unnecessary power is consumed.

In an amount to solve these problems, the "De-frost device of the heat exchanger for cooler" of the Republic of Korea Patent Office Registration No. 10-1788095 is

By installing a partition plate blocking the center in a position corresponding to between the first wind pressure sensor 10' and the second wind pressure sensor 10" and between the cooling tube 220 and the blower fan 250,

When comparing the first wind pressure sensor 10' and the second wind pressure sensor 10", if the suction power inside the evaporator is lower than the preset suction power, the power is supplied through the lever 7 by moving the elastic member 5 When the second wind pressure sensor 10" and the first wind pressure sensor 10' are compared, when the suction power inside the evaporator is higher than the preset suction power, the elastic member 5 is moved to move the lever (7) In the state that the power is turned off through

When the lever 7 of the first wind pressure sensor 10 ′ connected to the on/off power supply is turned on, it is determined that frost has formed on a portion corresponding to a part of the cooling tube 220 of the evaporator 230 and the control device When the first heater is operated through 500 to remove the frost on the cooling tube 220, and the lever 7 is turned off by defrosting, it is assumed that the frost has been removed from the cooling tube 220 of the evaporator 230. It is determined to cut off the power supplied to the first heater through the control device 500, and when the lever 7 of the first and second wind pressure sensors 10'10" connected to the on/off power source is turned on, the evaporator It is determined that frost is implanted in the portion corresponding to the entire cooling tube 220 of 230 , and stops the operation of the evaporator through the control device 500 , and operates the first and second heaters to be implanted on the cooling tube 220 . When the lever 7 of the first and second wind pressure sensors 10'10" is turned off after removing the defrost, it is determined that the frost has been removed from the entire cooling tube 220 of the evaporator 230. It is configured to operate the evaporator through the control device (500).

The conventional problems are as follows.

A partition plate blocking the center is installed at a position corresponding to the position between the cooling tube 220 and the blower fan 250 to detect both ends of the evaporator 230 through the first and second wind pressure sensors 10'10" to prevent frost. It is a technique to remove

In this way, both ends of the evaporator can be detected through the first and second wind pressure sensors 10'10" only when partitioned through the partition plate.

It is not easy to block the partition plate between the blowing fan 250 and the evaporator 230, and even if installed, it cannot be installed in close contact with the blowing fan, so that the partitioning effect does not occur. If the partition is not smooth, it is the same as if the partition plate has been penetrated, so there is no left/right vacuum deviation, so the effect of the first and second wind pressure sensors is meaningless.

In order to solve the above problems of the prior art, the present application installs a blade that expands when a strong wind by blowing force (wind) occurs, so that frost is accumulated on the evaporator so that outside air is not introduced between the evaporator and the blowing fan, and the evaporator and the blowing fan are blown When the space between the fans is in a vacuum state, the blowing power is weakened (referred to as a breeze), which causes the blades spread by strong winds to fold by their own weight, applying power to the heater installed in the evaporator to melt the frost technology to remove it.

The above problems will be further revealed in the specific content.

When described based on the illustration, both ends of the blade 400 in the longitudinal direction are connected to both ends of the blower fan 250 and the front box 300 by a hinge 410 so that the front of the blade 400 in the width direction is the hinge by its own weight. (410) as the central axis to descend, and to rise with the hinge (410) as the central axis as if spread by the strong wind of the blower fan (250),

A switch interference unit 412 for turning on/off the power of the switch unit 411 is installed in the hinge 410, and the switch unit 412 is installed at a position spaced apart from the hinge 410 by a predetermined interval to prevent the interference. In the configuration in which the part 412 rotates together with the hinge 410 to be turned on/off in the switch part 411,

The interference unit 412 and the switch unit 411 are two terminals 412a and 411a connected to a power source. When the two terminals 412a and 411a come into contact, power is supplied to a heater (not shown) installed in the pipe 220. It may be configured to be turned off when applied and relaxed.

At both ends of the front box 300 of the blower fan 250, one side in the width direction of both ends of the blade 400 in the longitudinal direction is connected with a hinge 410, and the other side in the width direction of the blade 400 (referred to as the front) has its own weight. to descend with the hinge 410 as a central axis by

When a strong wind is generated by the operation of the blower fan 250, it is blown by the strong wind so that the front of the blade 400 in the width direction rises with the hinge 410 as a central axis.

Furthermore, a heater (not shown) is closely installed to each of the plurality of pipes 220 of the evaporator 230 made of a plurality of pipes (corresponding to a cooling tube),

A horizontal bar 510 is installed so as to be slidable on the guide 500 between the plurality of pipes 220 and the blower fan 250, but one end 510a of the horizontal bar 510 is in close contact with the pipe 220. or in close proximity,

The other end 510b connects the on/off switch 520 for supplying or blocking power to the heater, but the operation part 520a of the switch is vertically disposed in the upper and lower long holes 401 formed at the rear of the blade 400 . to slide

In the state in which the front of the blade 400 rises by the strong wind of the blowing fan 250 when power is applied after connecting to the roller 520b

Among the plurality of pipes 220, the pipe 220a accumulating in frost is frozen together with one side 510a of the horizontal bar 510 so that the horizontal bar 510 cannot slide and move;

Since the pipe 220b that is not frosted is in a state in which the horizontal bar 510 is slidably movable, when a portion of the pipe 220 among the plurality of pipes 220 is frosted,

Since external air does not flow smoothly between the plurality of pipes 220 and the blowing fan 250 (the amount of inflow is small or insignificant), the space 251 between the evaporator 230 and the blowing fan becomes a vacuum state. The blowing power of the blowing fan 250 is weak (referred to as a breeze), so that the blade 400 in the hook direction (f) one side (f1) descends by its own weight.

In this process, the horizontal bar 510 frozen together with the pipe 220 due to frost is compressed by pushing the operating part 520a of the switch 520 installed on the horizontal board to the rear of the blade 400 and compressing the switch ( When 520) is turned on, power is applied to the heater to remove the frost accumulated on the pipe 220,

In the process where one side f1 in the width direction of the blade 400 descends by its own weight

The horizontal bar 510 that is not frozen together with the pipe 220 is configured in a state in which the operating part 520a of the switch 520 is not compressed so that the horizontal bar 510 moves backward and power is not applied to the heater. It is characterized by including.

As described above, the present application installs a blade that expands when a strong wind by blowing force (wind) occurs in front of the blowing fan so that outside air does not flow between the evaporator and the blowing fan and the space between the evaporator and the blowing fan is in a vacuum state. When the wind power is weakened (referred to as a breeze), power is applied to the heater installed in the evaporator while the blade spread in the strong wind is folded by its own weight. It has the effect of removing the frost by selecting only the pipes that have frosted among the pipes.

The above-mentioned effects are further revealed in the specific content.

It can be said that it is an effective defrosting method by providing a defrosting technology.

The above-mentioned effect is revealed in the specific content.

1 and 2 are explanatory views of a conventional evaporator,
3 is a perspective view of a defrosting device for a heat exchanger for a cooler using a blade of the present invention;
Figure 4 is a perspective view with the cover removed in the state of Figure 3;
Figure 5 is a side view showing the side in Figure 3;
6 is a schematic view of the present invention
A) is the state in which the front of the blade is raised,
B) is an explanatory diagram of the state in which the front of the blade is lowered.
7 is a switch device of the present invention,
A) indicates that the switch device is in the OFF state.
b) indicates that the switch device is on.

The configuration of the vehicle will be described with reference to the accompanying drawings, and embodiments thereof will be described in detail.

It performs a function of cooling the air by the heat exchanger 200 with the air in contact with the refrigerant. To this end, the heat exchanger 200 includes a cooling tube 220 through which a refrigerant flows, and a plurality of cooling fins 230 that increase an area in contact with the cooling tube 220 and air, that is, a heat exchange area. The cooling tube 220 is bent a plurality of times to form a sand-shaped overall shape. For details, please refer to Republic of Korea Patent Office Registration No. 10-1788095.

In addition, a blowing fan 250 is provided in the front region of the evaporator 230 , and a space 251 is formed between the evaporator 230 and the blowing fan 250 . For details, please refer to Republic of Korea Patent Office Registration No. 10-1788095.

Both ends of the blade 400 in the longitudinal direction are connected to both ends of the blower fan 250 and the front box 300 by hinges 410 so that the front of the blade 400 in the width direction is positioned on the hinge 410 by its own weight as a central axis. When it descends and a strong wind is generated by the blowing fan 250

The front of the blade 400 in the width direction rises with the hinge 410 as a central axis by strong wind,

A switch interference unit 412 for turning on/off the power of the switch unit 411 is installed in the hinge 410, and the switch unit 411 is installed at a position spaced apart from the hinge 410 by a predetermined distance. The interference unit 412 is configured as a switch device 411A that rotates together with the hinge 410 to turn the switch unit 411 on/off.

An example of the configuration is as follows.

When the heat exchanger 200 is operated, frost is accumulated on the cooling tube 220 in the refrigerating chamber (not shown).

That is, in the process of circulating the internal air of the refrigerating compartment, moisture contained in the air is condensed into water droplets on the blowing fan 250 in the evaporator 230 , and the water droplets formed in this way are cooled by the low temperature in the evaporator 100 . It freezes in the tube (corresponding to piping in the following description) to form frost.

As such, when frost is accumulated on the pipe 220, a vacuum is generated in the space 251 between the evaporator 230 and the blowing fan 250, and this causes the blowing fan 250 to have insignificant inlet air.

In strong winds (if there is no frost in the piping, there is a lot of air in the space, so strong winds are generated)

It is converted to a breeze (weak wind compared to strong wind).

When a breeze is generated in this way, the front of the blade 400 in front of the blower fan 250 descends with the hinge 410 as the central axis. In this process, the interference part 412 rotates together with the hinge 410. ) is to turn on the switch in the direction of rotation to apply power to the heater, so the frost accumulated in the pipe is removed.

When the frost is removed, the air is smoothly introduced into the space 251 through between the plurality of pipes 220 again, so the blower fan 250 generates a strong wind again, so that the front of the blade 400 in the width direction is The hinge 410 is raised and lowered as a central axis.

In this way, the frost is removed.

The interference unit 412 and the switch unit 411 are two terminals 412a and 411a connected to a power source. When the two terminals 412a and 411a come into contact, power is supplied to a heater (not shown) installed in the pipe 220. It may be configured to be turned off when applied and relaxed.

A blowing fan 250 is provided in the front region of the evaporator 230 , and a space a is formed between the evaporator 230 and the blowing fan 250 .

Further, a blowing fan 250 is installed in the front, and a pipe 220 corresponding to a cooling tube is installed in a position spaced apart from the blowing fan 250 by a predetermined distance in the rear, and the blowing fan 250 and the cooling In the heat exchanger 200 formed in the form of a closed box except for the tube 220,

The required configuration of the present application will be described next and an embodiment thereof will be described as follows.

At both ends of the front box 300 of the blower fan 250, one side in the width direction of both ends of the blade 400 in the longitudinal direction is connected with a hinge 410, and the other side in the width direction of the blade 400 (referred to as the front) has its own weight. to descend with the hinge 410 as a central axis by

When a strong wind is generated by the operation of the blowing fan 250 , the blade 400 is blown by the strong wind so that the front of the blade 400 in the width direction rises with the hinge 410 as a central axis.

An example of the above configuration will be described as follows.

If there is no obstacle (corresponding to frost) in the air suction direction (rear side of the blowing fan) of the blowing fan 250, the blowing fan 250 has a smooth suction power of air from the rear, so that the air discharge power is improved. That is, a strong wind is generated. do.

Conversely, if frost is accumulated on the pipe 220 (obstructive factors occur), the blowing fan 250 does not have a smooth suction power of air from the rear, so that the air discharge power is improved, that is, a breeze is generated.

Therefore, when a strong wind and a breeze occur, the blade 400 moves up and down with the hinge 410 as a central axis as if the front flaps.

In this moving process, the switch is turned on/off to supply and cut off power to the heater to remove the frost formed on the pipe 220 .

In the above description, strong winds and breezy winds are expressed for convenience of explanation.

And, the evaporator 230 is composed of a plurality of pipes (corresponding to the cooling tube).

A heater (not shown) is installed in close contact with each of the plurality of pipes 220 .

The longitudinal direction of the heater is installed in close contact with the longitudinal direction of the pipe 220 . Only then, when power is supplied to the heater by wire through the switch unit 411 and the switch 520, the frost is removed.

And, a horizontal bar 510 is installed so as to be slidable on the guide 500 between the plurality of pipes 220 and the blowing fan 250, but the horizontal bar 510, one end 510a is attached to the pipe 220. to be in close contact with or close to each other.

If it is placed in such a proximity position, when frost is formed and accumulated on the pipe 220, one end of the horizontal bar freezes and swells in the pipe 220 eventually.

And, the other end 510b of the horizontal bar 510 is connected to an on/off switch 520 for supplying or blocking power to the heater, but the operation part 520a of the switch is formed at the rear of the blade 400 To slide up and down in the long hole 401 up and down

In the state in which the front of the blade 400 rises by the strong wind of the blowing fan 250 when power is applied after connecting to the roller 520b

Among the plurality of pipes 220, the pipe 220a accumulating in frost is frozen together with one side 510a of the horizontal bar 510 so that the horizontal bar 510 cannot slide and move;

Since the pipe 220b that is not frosted is in a state in which the horizontal bar 510 is slidably movable, when a portion of the pipe 220 among the plurality of pipes 220 is frosted,

Since external air does not flow smoothly between the plurality of pipes 220 and the blowing fan 250 (the amount of inflow is small or insignificant), the space 251 between the evaporator 230 and the blowing fan becomes a vacuum state. The blowing power of the blowing fan 250 is weakened (referred to as a breeze), and the blade 400, fuk direction (f) one side (f1) descends by its own weight.

When the blowing force is weakened as described above, the blade descends to a predetermined position as if the front of the blade is sagging by the weight of the blade.

In this lowering process, the horizontal bar 510 frozen together with the pipe 220 due to frost is compressed by pushing the operating part 520a of the switch 520 installed on the horizontal board 510 behind the blade 400 . When the switch 520 is turned on, power is applied to the heater to remove the frost accumulated on the pipe 220 . When the defrost is removed during this process, the air inflow

Smoothly (more than when there is frost), the blade rises again.

In the process in which the blade 400, one side f1 in the suk-direction descends by its own weight

In the horizontal bar 510 that is not frozen together with the pipe 220, the operating part 520a of the switch 520 is not compressed, so that the horizontal bar 510 moves to the rear and does not apply power to the heater. .

The switch unit and the switch of the present application are configured to interlock with the control device to cut off the power supplied to the heater through the control device (not shown) and to supply power to the evaporator 230 .

As described above, the pipe 220 on which the frost is not implanted does not unnecessarily supply power to the heater, so power can be saved, and the cooling efficiency is not lowered because the pipe that is being cooled is not unnecessarily heated.

As described above, in the present invention, the cold air is not concentrated in one direction as the width direction front of the blade acts up and down by the strength and weakness according to the discharge wind of the blower fan . That is, the blade moves up and down according to the strength of the discharge wind without a separate driving device. Dispersing the exhaust wind,

In addition, there is an advantage that the frost is removed by the blade.

In addition, the blowing fan 250 allows external air (air inside the low-temperature warehouse) to pass through the plurality of pipes 220 through the rear of the plurality of pipes 220 and between the plurality of pipes 220 and the blowing fan 250 . Repeats discharging to the front of the blower fan.

In this process, moisture contained in the air is deposited on the plurality of pipes 220, and when frost is formed on the plurality of pipes 220 by more than the reference value, a vacuum state is continued between the evaporator 230 and the blowing fan 250. At this time, the blade The front of the is descended with the hinge as the central axis.

For reference, when the plurality of pipes 220 are used for a long period of time, foreign substances are adsorbed to the plurality of pipes. The sex is not implanted, but irregularly implanted here and there.

For example, among the total area of the plurality of pipes 220, there is a problem that a lot of frost is formed on the pipe located in the upper direction, and the pipe located in the lower direction is less implanted than the upper pipe.

In consideration of this case, cooling efficiency can be improved by removing the frost by applying power to the heater only on the frosted portion.

To supplement the description, the plurality of pipes 220 has different parts where frost is implanted depending on the crop, or the blower fan 250 is damaged due to long-term use, but the air in the low-temperature warehouse causes the plurality of pipes 220 to be absorbed by foreign substances. In the case of passing through, the passing direction is irregular when viewed from the area of the plurality of pipes.

At this time, the frost is implanted irregularly rather than evenly throughout the plurality of pipes 220 .

For technical details on the vacuum state between the blower fan and the evaporator and defrosting, please refer to Korean Patent Office Registration No. 10-1788095.

200: heat exchanger
220: cooling tube
230: evaporator
250: blow fan
300: box
400: blade
410: hinge
411: switch unit
411A: switch device
412: interference part

Claims (1)

A blowing fan 250 is installed in the front, and a cooling tube 220 is installed at a position spaced apart from the blowing fan 250 by a predetermined distance at the rear, except for the blowing fan 250 and the cooling tube 220 . In the heat exchanger 200 formed in the form of a sealed box,

At both ends of the front box 300 of the blowing fan 250, one side in the width direction of both ends of the blade 400 in the longitudinal direction is connected with a hinge 410, so that the other side in the width direction of the blade 400 (referred to as the front) has its own weight. to descend with the hinge 410 as a central axis by

When a strong wind is generated by the operation of the blower fan 250, it is blown by the strong wind so that the front of the blade 400 in the width direction rises with the hinge 410 as a central axis.

and installing a heater in close contact with each of the plurality of pipes 220 of the evaporator 230 made of a plurality of pipes 220,

A horizontal bar 510 is installed to be slidable on the guide 500 between the plurality of pipes 220 and the blower fan 250, but the horizontal bar 510, one end 510a is in close contact with the pipe 220. or in close proximity,

The other end 510b connects the on/off switch 520 for supplying or blocking power to the heater, but the operation part 520a of the switch is vertically disposed in the upper and lower long holes 401 formed at the rear of the blade 400 . to slide
In the state in which the front of the blade 400 rises by the strong wind of the blowing fan 250 when power is applied after connecting to the roller 520b

Among the plurality of pipes 220, the pipe 220a accumulating in frost is frozen together with one side 510a of the horizontal bar 510 so that the horizontal bar 510 cannot slide and move;
Since the pipe 220b that is not frosted is in a state in which the horizontal bar 510 is slidably movable, when a portion of the pipe 220 among the plurality of pipes 220 is frosted,

Since external air does not flow smoothly between the plurality of pipes 220 and the blowing fan 250 , the space 251 between the evaporator 230 and the blowing fan becomes a vacuum state, and the blowing power of the blowing fan 250 . This weakens (referred to as a breeze), and the blade 400, the sloping direction (f), one side (f1) descends by its own weight.

In this process, the horizontal board 510 frozen together with the pipe 220 due to frost is compressed by the operation part 520a of the switch 520 installed on the horizontal board being pushed behind the blade 400 and compressed. When 520) is turned on, power is applied to the heater to remove the frost accumulated in the pipe 220,
In the process in which the blade 400, one side f1 in the suk-direction descends by its own weight
The horizontal bar 510 that is not frozen together with the pipe 220 is configured in a state in which the operating part 520a of the switch 520 is not compressed, so that the horizontal bar 510 moves backward and power is not applied to the heater. Defrosting device of a heat exchanger for a cooler using a blade, characterized in that it comprises a.

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