KR102630292B1 - heat exchanging apparatus - Google Patents

Abstract

The present invention relates to a heat exchange device with a new structure that prevents foreign substances from accumulating inside pipes through which seawater passes, thereby reducing efficiency.
In the heat exchange device according to the present invention, the control means (37) receives signals from the first and second temperature sensors (35, 36) according to the mode, and operates the first and second heat exchangers (14, 15). The temperature of the coolant that has passed is monitored, and if the temperature of the coolant does not fall below the preset temperature, it is determined that foreign matter has accumulated inside the first or second heat exchanger (14, 15) and the mode is switched, automatically. Foreign matter accumulated inside the first or second heat exchanger (14, 15) is removed by backwashing.
Therefore, it is possible to prevent foreign substances from accumulating inside the first or second heat exchanger (14, 15), and to quickly respond when foreign substances suddenly accumulate inside the first or second heat exchanger (14, 15). There are advantages to this.

Description

Heat exchanging apparatus with reverse flushing function

The present invention relates to a heat exchange device with a new structure that prevents foreign substances from accumulating inside pipes through which seawater passes, thereby reducing efficiency.

Generally, power plants that generate a large amount of heat are equipped with a cooling device to cool the high heat generated during power generation, and the high-temperature cooling water generated by the cooling device is cooled using a separate heat exchange device.

At this time, since the heat exchange device requires a large amount of cold water, it is common to install a power plant on the beach and use seawater to cool the cooling water.

1 and 2 show a heat exchange device for cooling cooling water in this way, including a main water supply pipe 11 supplying seawater, and first and second water supply pipes 12 and 13 branched from the main water supply pipe 11. ), first and second heat exchangers (14,15) connected to the first and second water supply pipes (12,13), and a first and second heat exchanger (14,15) connected to the drain ends of the first and second heat exchangers (14,15) It is provided in the middle of the first and second drain pipes (16, 17) and the first and second water supply pipes (12, 13) and connects the first and second water supply pipes (12, 13) to the front first water supply unit (12a). , 13a) and the rear second water supply units (12b, 13b), and the first and second water supply control valves (18, 19) and a filter member 21 provided in the first water supply portions 12a and 13a of the first and second water supply pipes 12 and 13.

The first and second heat exchangers 14 and 15 are provided with a circulation pipe 22 through which high-temperature cooling water generated in the power plant passes.

The filter member 21 is configured in the form of a mesh with large eyes, and is configured to filter out bulky waste, etc. contained in seawater supplied through the first and second water supply pipes 12 and 13.

Therefore, by controlling the first and second water supply control valves (18, 19), the seawater supplied through the main water supply pipe (11) is supplied to the first or second water supply pipe (12, 13). When supplied to the heat exchangers 14 and 15, seawater exchanges heat with the high-temperature cooling water passing through the circulation pipe 22 to cool the cooling water, and the seawater with an increased temperature is supplied to the first or second drain pipe 16, 17) is discharged.

However, since the seawater supplied to the first and second heat exchangers 14 and 15 contains various foreign substances, including sand, when the heat exchange device is operated for a long time, the foreign substances flowing into the interior of the heat exchanger together with the seawater are heat exchanged. As it accumulates inside the machine, the flow rate of seawater passing through the heat exchanger is reduced, and as a result, a problem arises in which the cooling water passing through the circulation pipe 22 cannot be effectively cooled.

Therefore, when cooling the coolant using this heat exchange device, the coolant is cooled using the first heat exchanger 14, and if foreign substances accumulate inside the first heat exchanger 14 and the heat efficiency is reduced, By supplying seawater to the second heat exchanger (15), the cooling water is cooled using the second heat exchanger (15), and with the first heat exchanger (14) stopped, inside the first heat exchanger (14). Perform cleaning work to remove accumulated foreign matter.

And, when foreign matter accumulates inside the second heat exchanger (15), the coolant is cooled using the first heat exchanger (14), and the second heat exchanger (15) is cooled while the second heat exchanger (15) is stopped. ) Perform cleaning work to remove foreign substances accumulated inside the machine.

That is, the cooling water is continuously cooled by using a method of cleaning while using one of the first and second heat exchangers 14 and 15 while stopping the other heat exchanger.

Meanwhile, a method of cleaning the first and second heat exchangers (14, 15) involves supplying seawater to the first and second heat exchangers (14, 15) in the reverse direction to remove foreign substances accumulated inside the heat exchanger. , a backwashing method is used to discharge it to the outside through the supply end of the heat exchanger.

However, not only is it very cumbersome to clean foreign substances accumulated inside the first or second heat exchanger (14, 15), but also it is difficult to respond quickly when a large amount of foreign substances are momentarily introduced. It has been done.

Therefore, a new method to solve these problems has become necessary.

Registered Patent No. 10-1005996,

The present invention is intended to solve the above problems, and its purpose is to provide a heat exchange device with a new structure that prevents foreign substances from accumulating inside the pipe through which seawater passes, thereby reducing efficiency.

The present invention for achieving the above object includes a main water supply pipe (11) supplying seawater, first and second water supply pipes (12, 13) branched from the main water supply pipe (11), and the first and second water supply pipes (12, 13). First and second heat exchangers (14,15) connected to the water supply pipes (12,13), and first and second drain pipes (16,17) connected to the drain ends of the first and second heat exchangers (14,15) ), and is provided in the middle of the first and second water supply pipes (12, 13) to connect the first and second water supply pipes (12, 13) to the first water supply parts (12a, 13a) at the front and the second water supply at the rear. First and second water supply control valves (18, 19) divided into parts (12b, 13b) and controlling the flow of seawater supplied to the first and second heat exchangers (14, 15), and the first and second water supply control valves (18, 19) 2 A heat exchange device including a filter member (21) provided in the first water supply portions (12a, 13a) of the water supply pipes (12, 13), provided in the middle portion of the first and second drain pipes (16, 17). First and second drain control valves (23, 24), first and second branch pipes (25, 26) branched from the second water supply portions (12b, 13b) of the first and second water supply pipes (12, 13), and the first and second drain pipes A connecting pipe (27) connecting the first drain portions (16a, 17a) of (16, 17) to each other, the proximal end is simultaneously connected to the first and second branch pipes (25, 26), and the distal end is connected to the first and second branch pipes (25, 26). and an auxiliary drain pipe (28) formed with first and second branches (28a, 28b) connected to the second drain portions (16b, 17b) of the second drain pipes (16, 17), and the first and second branches. First and second induction valves 29 and 31 provided in the engines 25 and 26, respectively, and third and fourth induction valves 32 provided in the first and second branches 28a and 28b, respectively. , 33) and an auxiliary valve 34 provided in the middle of the connection pipe 27, including the first and second water supply control valves 18 and 19 and the first to fourth induction valves ( By controlling the operation of the first and second heat exchangers (14, 15), one of the first and second heat exchangers (14, 15) performs a cooling operation and the other is converted to a resting state, and at the same time, reverse flushing is performed. A heat exchange device with a backwash function is provided.

According to another feature of the present invention, the first and second heat exchangers (14, 15) are provided with a circulation pipe (22) through which the high-temperature cooling water generated in the power plant passes, and the circulation pipe (22) is provided. First and second temperature sensors (35, 36) that measure the temperature of the coolant cooled by passing through the first or second heat exchanger (14, 15), and the first and second temperature sensors (35, 36) ) and receives the first and second water supply control valves (18, 19), the first and second drain control valves (23, 24), and the first to fourth induction valves (29, 31, 32, 33). and a control means 37 for controlling the operation of the auxiliary valve 34. A heat exchange device with a backwash function is provided.

According to another feature of the present invention, it is connected to the first drain parts (16a, 17a) of the first and second drain pipes (16, 17) to pump high-pressure air into the first drain parts (16a, 17a). It further includes an air supply means (A) for supplying air, wherein the air supply means (A) penetrates the circumferential surface of the first drain parts (16a, 17a) and injects the first air supply means (A) into the inside of the first drain parts (16a, 17a). And an extension pipe 40 extending toward the second heat exchanger 14, 15, and an air compressor connected to the extension pipe 40 through an air supply pipe 41 to supply high-pressure air to the extension pipe 40 ( 50), wherein the extension pipe 40 is fixed to the circumferential surface of the first drain portion 16a and 17a and has a fixed pipe body with its tip facing toward the first and second heat exchangers 14 and 15. 41), an elastic tube body 42 made of an elastic material connected to the distal end of the fixed tube body 41, a vibrating tube body 43 connected to the front end of the elastic tube body 42, and a ring shape, and the vibrating tube body It includes a rotary ring body (44) rotatably coupled to the outer peripheral surface of the tip of (43), and a resistance plate (45) coupled to the circumferential surface of the rotary ring body (44), wherein the resistance plate (45) is It is disposed at an angle to the circumferential direction of the rotating ring body 44, and the vibrating tube body 43 is caused by the flow of water supplied to the first and second heat exchangers 14 and 15 through the first drain portions 16a and 17a. A heat exchange device with a backwash function is provided, which allows the device to vibrate in an irregular direction.

In the heat exchange device according to the present invention, the control means (37) receives signals from the first and second temperature sensors (35, 36) according to the mode, and operates the first and second heat exchangers (14, 15). The temperature of the coolant that has passed is monitored, and if the temperature of the coolant does not fall below the preset temperature, it is determined that foreign matter has accumulated inside the first or second heat exchanger (14, 15) and the mode is switched, automatically. Foreign matter accumulated inside the first or second heat exchanger (14, 15) is removed by backwashing.

Therefore, it is possible to prevent foreign substances from accumulating inside the first or second heat exchanger (14, 15), and to quickly respond when foreign substances suddenly accumulate inside the first or second heat exchanger (14, 15). There are advantages to this.

1 and 2 are diagrams showing the configuration of a conventional heat exchange device;
3 is a configuration diagram showing a heat exchange device according to the present invention;
4 is a block diagram of a heat exchange device according to the present invention;
5 and 6 are configuration diagrams showing the operation of the heat exchange device according to the present invention;
7 is a configuration diagram showing a second embodiment of the heat exchange device according to the present invention;
8 and 9 are side cross-sectional views showing main parts of a second embodiment of the heat exchange device according to the present invention;
Figure 10 is a front cross-sectional view showing the main part of the second embodiment of the heat exchange device according to the present invention;
Figures 11 and 12 are reference diagrams showing the operation of the second embodiment of the heat exchange device according to the present invention.

Hereinafter, the present invention will be described in detail based on the attached illustration drawings.

Figures 3 to 6 show a heat exchange device with a backwash function according to the present invention, which includes a main water supply pipe (11) supplying seawater, and first and second water supply pipes (12) branched from the main water supply pipe (11). , 13), first and second heat exchangers (14, 15) connected to the first and second water supply pipes (12, 13), and at the drain ends of the first and second heat exchangers (14, 15) It is provided in the middle of the connected first and second drain pipes (16, 17) and the first and second water supply pipes (12, 13) and connects the first and second water supply pipes (12, 13) to the first water supply part at the front. It is divided into (12a, 13a) and the second water supply portion (12b, 13b) at the rear, and the first and second water supply control valves ( 18 and 19) and the filter member 21 provided in the first water supply portions 12a and 13a of the first and second water supply pipes 12 and 13, respectively, is the same as the conventional one.

At this time, the first and second heat exchangers 14 and 15 are provided with a circulation pipe 22 through which high-temperature cooling water generated in the power plant passes.

And, according to the present invention, it is provided in the middle of the first and second drain pipes 16 and 17, and connects the first and second drain pipes 16 and 17 to the front first drain portions 16a and 17a and the rear first drain pipes 16 and 17, respectively. First and second drain control valves (23, 24) divided into second drain parts (16b, 17b), and second water supply parts (12b, 13b) of the first and second water supply pipes (12, 13) A connection pipe (27) connecting the first and second branch pipes (25, 26) branched from and the first drain portions (16a, 17a) of the first and second drain pipes (16, 17), The proximal end is simultaneously connected to the first and second branch pipes 25 and 26, and the distal end is connected to the second drain portions 16b and 17b of the first and second drain pipes 16 and 17. An auxiliary drain pipe (28) formed with two branch parts (28a, 28b), first and second induction valves (29, 31) provided in the first and second branch pipes (25, 26), respectively, and the first Third and fourth induction valves 32 and 33 provided in the first and second branches 28a and 28b, respectively, an auxiliary valve 34 provided in the middle of the connection pipe 27, and the circulation First and second temperature sensors 35,36 provided in the pipe 22, and signals from the first and second temperature sensors 35,36 are received, and the first and second water supply control valves 18 , 19) and control means (37) for controlling the operation of the first and second drain control valves (23, 24), first to fourth induction valves (29, 31, 32, 33), and the auxiliary valve (34). This is further provided.

The first and second temperature sensors (35, 36) are provided inside the discharge portion of the circulation pipe (22) and measure the temperature of the coolant cooled by passing through the first or second heat exchanger (14, 15). It is configured to do so.

The first and second water supply control valves (18, 19), the first and second drain control valves (23, 24), the first to fourth induction valves (29, 31, 32, 33), and the auxiliary valve (34) ) uses an electronically controlled valve that is controlled to open and close by a control signal from the control means (37).

The control means 37 operates the first and second water supply control valves 18 and 19 and the first and second water supply control valves 18 and 19 according to the temperature of the coolant measured by the first and second temperature sensors 35 and 36. By controlling the drain control valves (23, 24), the first to fourth induction valves (29, 31, 32, 33), and the auxiliary valve (34), the heat exchange device is switched to the first or second mode.

As shown in FIG. 5, the first mode uses the second water supply control valve 19, the first induction valve 29, the first and second drain control valves 23 and 24, and the third induction valve ( 32) is closed, and the first water supply control valve 18, the second induction valve 31, the auxiliary valve 34, and the fourth induction valve 33 are opened, and the main water supply pipe 11 is opened. The seawater supplied through the first water supply pipe 12 is supplied to the first heat exchanger 14 and exchanges heat with the cooling water passing through the circulation pipe 22 provided in the first heat exchanger 14 to cool the cooling water. Then, it is supplied in the reverse direction to the second heat exchanger (15) through the first drain part (16a) of the first drain pipe (16), the connection pipe (27), and the first drain part (17a) of the second drain pipe (17). Then, the second heat exchanger (15) is backwashed.

At this time, the seawater that passes through the second heat exchanger (15) in the reverse direction and backwashes the second heat exchanger (15) is connected to the second water supply portion (13b) of the second water supply pipe (13) and the second branch pipe (26). ) and is discharged to the outside through the connection pipe 27, the second branch portion 28b, and the second drain portion 17b of the second drain pipe 17.

As shown in FIG. 6, the second mode uses the first water supply control valve 18, the second induction valve 31, the first and second drain control valves 23 and 24, and the fourth induction valve ( 33) is closed, and the second water supply control valve 19, the second induction valve 31, the auxiliary valve 34, and the third induction valve 32 are opened, and the main water supply pipe 11 is opened. The seawater supplied through the second water supply pipe 13 is supplied to the second heat exchanger 15 and exchanges heat with the cooling water passing through the circulation pipe 22 provided in the second heat exchanger 15 to cool the cooling water. Afterwards, it is supplied in the reverse direction to the first heat exchanger 14 through the first drain part 17a of the second drain pipe 17, the connection pipe 27, and the first drain part 16a of the first drain pipe 16. Then, the second heat exchanger (15) is backwashed.

At this time, the seawater that passes through the first heat exchanger 14 in the reverse direction and backwashes the first heat exchanger 14 is connected to the second water supply part 12b of the first water supply pipe 12 and the first branch pipe 25. ) and is discharged to the outside through the connection pipe 27, the first branch portion 28a, and the second drain portion 16b of the first drain pipe 16.

The operation of the heat exchange device configured in this way is explained as follows.

First, the control means 37 switches the heat exchange device to the first mode, as shown in FIG. 5, and then receives a signal from the first temperature sensor 35 to operate the first heat exchanger 14. ), if the temperature of the coolant passing through does not fall below the preset temperature, it is determined that foreign matter has accumulated inside the first heat exchanger 14, and the heat exchange device is switched to the second mode as shown in FIG. 6. After the seawater passes through the second heat exchanger (15) to cool the cooling water, it is supplied in the reverse direction to the first heat exchanger (14) to backwash the first heat exchanger (14). Ensure that foreign substances accumulated inside the machine (14) are removed.

And, in the second mode, the control means 37 receives a signal from the second temperature sensor 36 and, when the temperature of the coolant passing through the second heat exchanger 15 does not fall below the preset temperature, As shown in FIG. 5, the heat exchange device is switched to the first mode, the seawater passes through the first heat exchanger 14 to cool the cooling water, and then is supplied in the reverse direction to the second heat exchanger 15 to cool the second heat exchanger 15. By backwashing the heat exchanger 15, foreign substances accumulated inside the second heat exchanger 15 are removed.

In the heat exchange device configured in this way, the control means (37) receives signals from the first and second temperature sensors (35, 36) according to the mode, and passes them through the first and second heat exchangers (14, 15). The temperature of one coolant is monitored, and if the temperature of the coolant does not fall below the preset temperature, it is determined that foreign matter has accumulated inside the first or second heat exchanger (14, 15) and the mode is switched, automatically. Foreign matter accumulated inside the first or second heat exchanger (14, 15) is removed by backwashing.

Therefore, it is possible to prevent foreign substances from accumulating inside the first or second heat exchanger (14, 15), and to quickly respond when foreign substances suddenly accumulate inside the first or second heat exchanger (14, 15). There are advantages to this.

7 to 12 show a second embodiment according to the present invention, which is connected to the first drain portions 16a and 17a of the first and second drain pipes 16 and 17 to form a first drain portion 16a. , 17a) is further provided with air supply means (A) for supplying high-pressure air to the interior.

The air supply means (A) penetrates the peripheral surface of the first drain portions (16a, 17a) and is directed toward the first and second heat exchangers (14, 15) inside the first drain portions (16a, 17a). It consists of an extension pipe (40) extending so that an air compressor (50) is connected to the extension pipe (40) through an air supply pipe (41) and supplies high-pressure air to the extension pipe (40).

As shown in FIGS. 8 to 10, the extension pipe 40 is fixed to the circumferential surface of the first drain portion 16a and 17a and has its distal end facing the first and second heat exchangers 14 and 15. A fixed tube body 41, an elastic tube body 42 made of an elastic material connected to the distal end of the fixed tube body 41, and a vibrating tube body 43 connected to the front end of the elastic tube body 42, in a ring shape. It is composed of a rotating ring body (44) rotatably coupled to the outer peripheral surface of the tip of the vibrating tube body (43), and a resistance plate (45) coupled to the circumferential surface of the rotating ring body (44).

The fixed pipe body 41 has a vertical portion 41a penetrating the circumferential surface of the first drain portion 16a and 17a, and the first and second heat exchangers 14 at the inner end of the vertical portion 41a. It consists of a horizontal portion 41b extending toward , 15).

The elastic tubular body 42 is made of an elastic silicon material, etc., and is coupled to the front end of the horizontal portion 41b so that it faces the first and second heat exchangers 14 and 15.

The vibrating tube body 43 is made of a high-strength metal material and is coupled to the elastic tube body 42 so as to face the first and second heat exchangers 14 and 15.

The rotating ring body 44 is rotatably coupled to the outside of the vibrating tube body 43 through a bearing 44a.

The resistance plate 45 is provided on one side of the rotating ring body 44, and is disposed inclined at a predetermined angle θ with the circumferential direction of the rotating ring body 44, as shown in FIG. 8.

Therefore, in the first and second modes, when water is supplied to the first and second heat exchangers 14 and 15 through the first drain units 16a and 17a, the first drain units 16a and 17a The force that rotates the resistance plate (45) in the circumferential direction of the vibrating tube body (43) by the pressure of the water flowing through and the force that pushes the resistance plate (45) toward the first and second heat exchangers (14, 15) are simultaneously applied. It works.

Therefore, as shown in FIG. 10, the resistance plate 45 and the rotating ring body 44 change direction while continuously rotating along the circumference of the vibrating tube body 43, and at the same time, the vibrating tube body 43 resists. It is tilted in a direction opposite to the direction of the plate 45.

That is, as shown in FIG. 11, when the resistance plate 45 is located on the upper side, the vibrating tube body 43 is tilted downward, and as shown in FIG. 12, the resistance plate 45 is located on the lower side. In this case, the vibrating tube body 43 is tilted upward.

The air supply pipe 41 has a branched end and is simultaneously connected to the extension pipe 40 provided in the first and second drain pipes 16 and 17, and the branched portion is operated and controlled by the control means 37. An air supply valve 52 is provided.

In addition, the control means 37 is configured to control the air supply valve 52 when switching the heat exchange device to the first or second mode to selectively supply air to the extension pipe 40.

That is, in the first mode, the control means 37 supplies air to the second drain pipe 17, and in the second mode, the control means 37 supplies air to the first drain pipe 16. ensure that it is supplied.

The heat exchange device configured in this way is such that when seawater is supplied in the reverse direction to the first or second heat exchanger (14, 15) and reverse flushing is performed, high-pressure air supplied through the air supply means (A) flows into the extension pipe (40). The advantage is that foreign matter accumulated in the first or second heat exchanger (14, 15) can be more effectively removed by being supplied to the first drain portion (16a, 17a) of the first or second drain pipe (16, 17). There is.

In particular, the extension pipe (40) includes a fixed pipe body (41) fixed to the circumferential surface of the first drain portion (16a, 17a) with its tip facing toward the first and second heat exchangers (14, 15); An elastic tube body 42 made of an elastic material connected to the distal end of the fixed tube body 41, a vibrating tube body 43 connected to the front end of the elastic tube body 42, and a ring-shaped structure of the vibrating tube body 43. It consists of a rotating ring body (44) rotatably coupled to the outer peripheral surface of the tip, and a resistance plate (45) coupled to the circumferential surface of the rotating ring body (44). When backwashing, the resistance plate (45) As the vibrating tube body 43 rotates along its circumference, the vibrating tube body 43 is tilted in various directions.

Therefore, there is an advantage that the air supplied by the air compressor 50 is discharged to the end of the vibrating tube body 43 flowing in any direction, allowing foreign substances to be more effectively discharged by the air.

11. Main water pipe 12,13. 1st and 2nd water supply pipe
14,15. First and second heat exchangers 16,17. 1st and 2nd drain pipe
18,19. First and second water supply control valves 21. Filter member
22. Circulation tube 23,24. First and second drain control valves
25,26. 1st and 2nd branch pipe 27. Connector pipe
28. Auxiliary drain pipes 29~33. First to fourth induction valves
34. Auxiliary valves 35,36. First and second temperature sensors
37. Control measures

Claims (3)

A main water supply pipe (11) that supplies seawater,
First and second water supply pipes (12, 13) branched from the main water supply pipe (11),
First and second heat exchangers (14, 15) connected to the first and second water supply pipes (12, 13),
First and second drain pipes (16, 17) connected to the drain ends of the first and second heat exchangers (14, 15),
It is provided in the middle of the first and second water supply pipes (12, 13) and connects the first and second water supply pipes (12, 13) to the first water supply parts (12a, 13a) at the front and the second water supply part (12b) at the rear. , 13b) and first and second water control valves (18, 19) that control the flow of seawater supplied to the first and second heat exchangers (14, 15),
In the heat exchange device including a filter member (21) provided in the first water supply portions (12a, 13a) of the first and second water supply pipes (12, 13),
It is provided in the middle of the first and second drain pipes (16, 17) and connects the first and second drain pipes (16, 17) to the first drain portions (16a, 17a) at the front and the second drain portion (16b) at the rear. , first and second drain control valves (23, 24) divided by 17b),
First and second branch pipes (25, 26) branched from the second water supply portions (12b, 13b) of the first and second water supply pipes (12, 13),
A connection pipe (27) connecting the first drain portions (16a, 17a) of the first and second drain pipes (16, 17) to each other,
The proximal end is simultaneously connected to the first and second branch pipes 25 and 26, and the distal end is connected to the second drain portions 16b and 17b of the first and second drain pipes 16 and 17. An auxiliary drain pipe (28) formed with two branches (28a, 28b),
First and second induction valves (29,31) provided in the first and second branch pipes (25,26), respectively,
Third and fourth induction valves 32 and 33 provided in the first and second branch portions 28a and 28b, respectively, and an auxiliary valve 34 provided in the middle of the connection pipe 27. including,
By controlling the operation of the first and second water supply control valves (18, 19) and the first to fourth induction valves (29, 31, 32, and 33), the first and second heat exchangers (14, 15) One of them acts as a cooling agent, while the other switches to a resting state, allowing counter-flushing to occur at the same time.
The first and second heat exchangers (14, 15) are provided with a circulation pipe (22) through which high-temperature cooling water generated from the power plant passes,
First and second temperature sensors (35, 36) provided in the circulation pipe (22) to measure the temperature of the coolant cooled by passing through the first or second heat exchanger (14, 15),
Signals from the first and second temperature sensors (35, 36) are received, and the first and second water supply control valves (18, 19) and the first and second drain control valves (23, 24) are used.
It further includes control means (37) for controlling the operation of the first to fourth induction valves (29, 31, 32, 33) and the auxiliary valve (34),
An air supply means (A) is connected to the first drain parts (16a, 17a) of the first and second drain pipes (16, 17) and supplies high-pressure air into the first drain parts (16a, 17a). Contains,
The air supply means (A) is
An extension pipe (40) extending through the circumferential surface of the first drain portions (16a, 17a) toward the first and second heat exchangers (14, 15) inside the first drain portions (16a, 17a). class,
It includes an air compressor (50) connected to the extension pipe (40) through an air supply pipe (41) and supplying high-pressure air to the extension pipe (40),
The extension pipe 40 is
A fixed pipe body (41) fixed to the circumferential surface of the first drain portion (16a, 17a) with its tip facing the first and second heat exchangers (14, 15),
An elastic tube body (42) made of an elastic material connected to the distal end of the fixed tube body (41),
A vibrating tube body (43) connected to the front end of the elastic tube body (42),
A rotating ring body (44) configured in a ring shape and rotatably coupled to the outer peripheral surface of the tip of the vibrating tube body (43),
It includes a resistance plate (45) coupled to the circumferential surface of the rotating ring body (44),
The resistance plate 45 is disposed at an angle to the circumferential direction of the rotating ring body 44, so that water flows through the first drain portions 16a and 17a to the first and second heat exchangers 14 and 15. A heat exchange device with a backwash function, characterized in that the vibrating tube body (43) is vibrated in an irregular direction by. delete delete

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