KR102039916B1 - A device for cleaning the surface of convection tube - Google Patents

Abstract

The present invention relates to a device for cleaning tubes of a heat exchanger, which washes the surfaces of a plurality of stacked tubes of the heat exchanger with high-pressure water. The device for cleaning tubes of a heat exchanger comprises: a vertical guide rail mounted on the tubes of the heat exchanger; a vertical driving part moved vertically along the vertical guide rail; a horizontal guide rail coupled to the vertical driving part and moved vertically according to the movement of the vertical driving part; a horizontal driving part moved horizontally along the horizontal guide rail; and a nozzle coupled to the horizontal drive part. As the nozzle is moved vertically or horizontally by a driving force of the vertical driving part or the horizontal driving part, the surfaces of the tubes of the heat exchanger are washed by high-pressure water sprayed from the nozzle.

Description

A device for cleaning the surface of convection tube}

The present invention is a cleaning device for cleaning the adhered adhered to the surface of the tube for heat exchanger, the operator directly enters between the tube bundle and another tube bundle in the state that the tube is stacked in multiple stages, the attachment of the tube surface by hand Unlike the prior art that washes, the guide rail is mounted on the top tube in a bundle of tube bundles in which a plurality of tubes are stacked, and with the driving force of the driving unit moving along the guide rail, the nozzle to which high-pressure water is sprayed back and forth or left and right While moving to, the tube cleaning device for the heat exchanger that can effectively clean not only the surface of the outermost tube in the tube bundle of a plurality of tube bundles stacked, but also the surface of the tube located in the inner side of the tube bundle.

Heat transfer is caused by conduction and convection phenomena. Heat transfer by conduction is a phenomenon in which heat is transferred when a plurality of objects having non-uniform temperatures come into contact with each other, and appears in proportion to the temperature difference of the objects. And the heat transfer phenomenon due to convection occurs through the fluid of the gas or liquid and the fluid is in constant contact with the heat transfer surface to perform heat exchange.

Heat exchanger installed in a large plant is composed of a tube that allows the heat exchange to flow inside the heat exchange medium. In particular, in order to exchange heat generated in a large boiler, these tubes are installed in a multi-stacked state at the top of the gas discharged from the boiler, including the heat generated in the boiler. That is, a plurality of tubes are stacked so that a set of tube bundles are installed, and another set of tube bundles are installed at regular intervals from the tube bundles. This is to maximize the efficiency of heat exchange generated in the boiler.

Dirt or foreign matter contained in the gas discharged from the boiler adheres to the surface of the tube, and the adhesion increases with time. That is, as the number of years of use of tubes stacked in multiple stages as such a heat exchanger increases, fouling adheres to the surface of the tubes. Over time, these deposits increase and become thicker, thereby lowering the heat transfer efficiency of the heat exchanger.

In order to solve this problem, it is necessary to periodically clean the surface of this multi-stacked tube. In other words, it is necessary to remove the deposit attached to the tube.

As shown in FIG. 1, conventionally, an operator enters between one end of a bundle of tubes and another end of a bundle of tubes to manually maintain the efficiency of the heat exchanger by washing the attachment of the tube surface with high pressure water.

However, a plurality of tubes are stacked up and down in one tube bundle. The space between this set of tube bundles and another set of tube bundles is very narrow. As the worker enters into such a narrow space and the manual work is performed, the worker's working environment is poor, and even if it is cleaned, only the surface of the outermost tube is cleaned, so the cleaning effect on the entire bundle of tubes is very low. none.

Furthermore, since the washing operation is performed by hand, a lot of cost and time is required, the efficiency of the washing operation is very low.

(Patent Document 1) KR20-0159279 B

In order to solve the problems according to the prior art described above, an object of the present invention is to propose a tube cleaning apparatus for a heat exchanger that can effectively and efficiently clean an adherent attached to a surface of a tube.

Specifically, unlike the prior art in which the worker manually enters between the tube bundle and the tube bundle, the cleaning device can be used to clean the surface of the tube by spraying high pressure water without the operator entering between the tube bundle and the tube bundle. I would like to suggest.

Furthermore, in cleaning the tube bundle, it is proposed a washing apparatus that can effectively clean the surface of the tube located inside the tube bundle as well as the tube disposed in the outermost or outermost vicinity.

In order to solve the problems according to the prior art described above, the heat exchanger tube washing apparatus according to the present invention, in the heat exchanger tube washing apparatus for washing the surface of a plurality of laminated heat exchanger tube (T) with high pressure water, for the heat exchanger Longitudinal guide rails 100 and 100 ′ mounted on the tube T; Vertical driving parts 200 and 200 ′ moved in a vertical direction along the vertical guide rails 100 and 100 ′; A horizontal guide rail 300 coupled to the vertical driving parts 200 and 200 ′ and vertically moved in accordance with the movement of the vertical driving parts 200 and 200 ′; A horizontal driving part 400 moving in a horizontal direction along the horizontal guide rail 300; And nozzles 530, 530 ′ and 540 coupled to the horizontal driving unit 400, wherein the nozzles 530, 530 ′ and 540 are vertically driven by the driving force of the vertical driving units 200 and 200 ′ or the driving force of the horizontal driving unit 400. While moving in the direction or the horizontal direction, the surface of the heat exchanger tube (T) is cleaned by the high pressure water sprayed from the nozzles (530, 530 ', 540).

Preferably, the longitudinal guide rails (100, 100 ') is composed of a pair located at regular intervals, the vertical driving unit (200,200'), the state is mounted on each of the pair of vertical guide rails (100, 100 ') A pair of longitudinal driving bodies 220 and 220 'moved in; A parallel moving maintenance connecting rod 230 connecting the pair of vertical driving bodies 220 and 220 '; And a vertical drive motor 240 coupled to any one vertical drive body 220 of the pair of vertical drive bodies 220 and 220 ', wherein the driving force of the vertical drive motor 240 is the parallel moving maintenance connecting rod. As the parallel movement maintaining connecting rod 230 is rotated to be transmitted to the 230, the pair of longitudinal driving bodies 220 and 220 ′ are moved in the longitudinal direction in parallel in the pair of longitudinal guide rails 100 and 100 ′. Both sides of the horizontal guide rail 300 are coupled to each of the pair of vertical drive bodies 220 and 220 ', and the horizontal direction of the pair of vertical drive bodies 220 and 220' moves in the longitudinal direction. The guide rail 300 is moved in the vertical direction.

Preferably, the horizontal drive unit 400, the horizontal drive body 420; And a horizontal driving motor 440 coupled to the horizontal driving body 420, and vertical rack gears 101 and 101 ′ are formed in the vertical guide rails 100 and 100 ′, respectively, and the horizontal guide rail 300. A horizontal rack gear 301 is formed, and vertical pinion gears 231 and 231 'are formed at both ends of the parallel movement holding connecting rod 230, and horizontal pinion gears are formed on the axis of the horizontal driving motor 440. 441 is formed.

Preferably, the vertical drive motor 240 and the horizontal drive motor 440 is an air motor, the vertical drive motor 240 and the horizontal drive to the air supply control unit 50 connected to the air supply pipe (52). In a state in which the motor 440 communicates with the communication tube 54, air is supplied to the vertical drive motor 240 and the horizontal drive motor 440.

Preferably, the dispensing body holder 450 coupled to the horizontal drive body 420; And a high pressure water dispensing body 520 held by the dispensing body holder 450, wherein the nozzles 530, 530 ', and 540 are located in plurality in a state connected to one end of the high pressure water dispensing body 520. End nozzle 530; Other end nozzles 530 'positioned in a plurality in a state connected to the other end of the high pressure water distribution body 520; And an inner nozzle 540 positioned in a plurality in a state connected to the inside of the high pressure water distribution body 520, wherein the high pressure water flowing through the high pressure water distribution body 520 is one end 530, the other end. The injection angle of the high pressure water injected through the nozzle 530 'and the inner nozzle 540, the injection angle of the high pressure water injected from the other nozzle 530' and the inner nozzle The injection angles of the high pressure water injected at 540 are different from each other.

Due to the above-mentioned problem solving means, the nozzle is not included in the tube bundle while the high pressure water is sprayed by the movement of the vertical drive portion and the horizontal drive portion moved along the guide rail without moving between the tube bundle and the tube bundle in the tube bundle. The surface of the finished tube can be cleaned, thereby increasing the effectiveness of the cleaning operation.

Furthermore, by varying the spray angles of the plurality of nozzles connected to the high pressure water distribution body, and maintaining a constant difference between the spray angles of the nozzles located in one line of the high pressure water distribution body and the spray angles of the nozzles adjacent thereto, High pressure water reaches not only the tube located on the outermost side of a bundle of tube bundles but also the surface of the tube located inside the bundle of tube bundles, thereby reducing the cost and time required for cleaning, thereby increasing cleaning efficiency. .

1 is a view showing a state in which the cleaning operation is made by the operator manually between the tube bundle and the tube bundle according to the prior art.
2 is a view schematically showing a tube washing apparatus for a heat exchanger according to the present invention.
3 is a view schematically showing a component for the horizontal drive unit to move along the horizontal guide rail.
4 is a view schematically illustrating a component for the vertical driving unit to be moved along the vertical guide rail.
5 is a view schematically showing a state seen from the top of the nozzle connected to the high pressure water distribution body.
6a and 6b schematically show the operation of the tube washing apparatus for the heat exchanger according to the present invention.
7 is a view showing data on the washing efficiency of the high pressure water.
8 is a view showing the cleaning efficiency according to the number of nozzles reflecting a certain degree of injection angle difference and the difference in the injection angle in a state where the injection angle difference between the nozzles.

Hereinafter, preferred embodiments of the method according to the present invention will be described with reference to the accompanying drawings. In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, terms to be described below are terms defined in consideration of functions in the present invention, which may vary according to the intention or convention of a user or an operator. Therefore, the definitions of these terms should be made based on the contents throughout the specification.

This will be described with reference to FIGS. 2 to 5.

Tube cleaning apparatus for a heat exchanger according to the present invention includes a vertical guide rail (100, 100 '), a vertical driving unit (200, 200'), a horizontal guide rail 300, a horizontal driving unit 400 and a nozzle (530, 530 ', 540).

It demonstrates with reference to FIG. 2 and FIG.

The vertical guide rails 100 and 100 ′ are positioned in pairs at regular intervals from each other. These vertical guide rails (100, 100 ') are mounted on the tube (T) for the heat exchanger. The heat exchanger tubes T are stacked in plural. A plurality of tubes (T) are stacked to form a set of tube bundles, and this set of tube bundles are configured in multiple stages.

A narrow space is formed between any one of the tube bundles and the adjacent tube bundles. Unlike the prior art, in which the worker enters and cleans the narrow space, a pair of longitudinal guide rails 100 and 100 'is mounted in the narrow space in the longitudinal direction of the tube T.

Of course, the vertical guide rails 100 and 100 'may be assembled. Therefore, it can be transported to various components and then mounted on the tube T of the workplace. These longitudinal guide rails 100, 100 'can be mounted on the best tube T in a set of tube bundles. That is, the plurality of tubes T may be positioned on the plurality of tubes T positioned at the top of the bundle of tube bundles stacked up, down, left, and right.

One end of each of the pair of vertical guide rails (100, 100 ') is fixed to the front fixing rod 110, the other end is fixed to the rear fixing rod (120). Within a predetermined range formed by the pair of longitudinal guide rails 100 and 100 ′, a plurality of tubes T positioned at the top of the bundle of tube bundles may be included. One longitudinal guide rail 100 is mounted on any one of the plurality of tubes T positioned at the top, and the other on the other tube T positioned at the top at regular intervals. The vertical guide rail 100 'is mounted.

The pair of longitudinal guide rails 100, 100 ′ in a fixed state connected to the front fixing rod 110 and the rear fixing rod 120 are movable in the longitudinal direction of the tube T on the uppermost tube T in one tube bundle. Of course.

Vertical rack gears (101, 101 ') are formed on each of the vertical guide rails (100, 100'). The vertical rack gears (101, 101 ') are preferably formed on the upper surface of the vertical guide rails (100, 100'). The pinion gears 231 and 231 'are rotated while being engaged on the vertical rack gears 101 and 101', and the vertical driving parts 200 and 200 'are moved in accordance with the rotation.

The roller guides 102 and 102 'are formed in a longitudinal direction of one end of the upper and lower surfaces of the vertical guide rails 100 and 100' having the vertical rack gears 101 and 101 'formed in the longitudinal direction of the vertical guide rails 100 and 100'. have. The vertical rollers 203 mounted on the vertical driving parts 200.200 'to be described later are rotated on the roller guides 102 and 102' to guide the movement of the vertical driving parts 200 and 200 '.

The vertical driving parts 200 and 200 'are moved in the vertical direction along the vertical guide rails 100 and 100'. That is, it moves back and forth in the longitudinal direction of the tube T.

The vertical driving parts 200 and 200 'include a vertical driving body 220 and 220', a parallel moving retaining connecting rod 230, a vertical driving motor 240, a vertical pinion gear 231 and 231 'and a vertical roller 203.

The vertical driving bodies 220 and 220 'are moved in rotation of the vertical pinion gears 231 and 231' while being mounted on both of the pair of vertical guide rails 100 and 100 '. The above-mentioned vertical rollers 203 are located in the upper and lower portions of one side of the vertical driving bodies 220 and 220 ', and the plurality of vertical rollers 203 are in contact with the roller guides 102 and 102'. As the vertical pinion gears 231 and 231 'are engaged with the vertical rack gears 101 and 101' by the operation of the driving motor 240, the vertical driving bodies 220 and 220 'are eventually moved in the longitudinal direction of the tube T.

The parallel moving maintenance connecting rod 230 connects a pair of longitudinal driving bodies 220 and 220 '.

The pair of longitudinally driven bodies 220, 220 'needs to be moved in parallel in the pair of longitudinal guide rails 100, 100'. When one longitudinal driving body is moved faster, the spray angles of the nozzles 530, 530 'and 540, which will be described later, may be changed, thereby lowering the washing efficiency, and the vertical pinion gears 231 and 231 may be vertically racked in a non-parallel state. As the engagement of the gears 101 and 101 'is displaced, the movement of the vertical driving bodies 220 and 220' may be restricted.

The driving force of the vertical driving motor 240 coupled to any one of the vertical driving bodies 220 of the pair of vertical driving bodies 220 and 220 'to generate driving force is not immediately transmitted to the vertical driving bodies 220 and 220'. The parallel movement retaining connecting rod 230 is transmitted, so that a pair of longitudinal pinion gears 231 and 231 'formed at both ends of the parallel movement maintaining connecting rod 230 rotate. Accordingly, the rotational speeds of the pair of longitudinal pinion gears 231 and 231 'are the same, and thus the movement speeds of the pair of longitudinal driving bodies 220 and 220' are also the same, so that they are parallel in the pair of longitudinal guide rails 100 and 100 '. Is moved.

The vertical drive motor 240 is mounted to any one of the vertical drive bodies 220 of the pair of vertical drive bodies 220 and 220 '. Of course, the means for driving the vertical drive motor 240 may be any means. Preferably, the vertical drive motor 240 may be an air motor.

The driving force of the vertical drive motor 240 is transmitted to the motor gear 242 mounted to the vertical drive motor 240, the motor gear 242 to the rotary gear 232 mounted to the parallel movement retaining connecting rod 230 It may be connected by a chain (235). The driving force transmitted to the motor gear 242 is transmitted to the rotary gear 232, the rotary gear 232 is rotated by the driving force transmitted to the rotary gear 232, and eventually the parallel movement maintaining connecting rod 230 is rotated, A pair of longitudinal pinion gears 231 and 231 'formed at both ends of the parallel movement retaining connecting rod 230 are rotated to move the vertical driving bodies 220 and 220'.

The parallel moving retaining connecting rod 230 preferably penetrates the vertical driving bodies 220 and 220 '. Vertical pinion gears 231 and 231 ′ are formed at both ends of the parallel moving retaining connecting rod 230 penetrating the vertical driving bodies 220 and 220 ′. The rotary gear 232 is fixedly coupled to the parallel moving retaining connecting rod 230, and may be fixedly coupled to the parallel moving maintaining connecting rod 230 just before passing through any one longitudinal driving body 220. to be.

The pair of longitudinal pinion gears 231 and 231 'is engaged with the pair of longitudinal rack gears 101 and 101' as described above, and the plurality of vertical rollers 203 mounted to the vertical driving bodies 220 and 220 ' As described above, the roller guides are rotated in contact with the roller guides 102 and 102 'formed at one end of the vertical guide rails 100 and 100'.

It demonstrates with reference to FIG. 2 and FIG.

The horizontal guide rail 300 is moved in the vertical direction according to the movement of the vertical driving bodies 220 and 220 'in a state coupled to the pair of vertical driving bodies 220 and 220'. That is, as the longitudinal driving bodies 220 and 220 'are moved in the longitudinal direction of the tube T, the horizontal guide rails 300 having both ends coupled to each of the pair of longitudinal driving bodies 220 and 220' are respectively formed by the tube ( Is moved back and forth in the longitudinal direction of T).

The horizontal guide rail 300 is connected across a pair of vertical guide rails 100 and 100 ′.

A horizontal rack gear 301 is formed on the upper surface of the horizontal guide rail 300, and the horizontal pinion gear 441, which will be described later, is rotated while being engaged.

Roller guides 302 are formed in the upper and lower ends of the upper surface of the horizontal guide rail 300 at a constant height in the longitudinal direction of the horizontal guide rail 300. The horizontal roller 403 to be described later is rotated while contacting the upper surface of the roller guide 302.

The horizontal driving part 400 includes a horizontal driving body 420, a horizontal driving motor 440, a distribution body holder 450, and a horizontal pinion gear 441.

The horizontal driving body 420 has horizontal rollers 403 formed on the upper and lower sides of one side. The horizontal roller 403 is rotated in contact with the roller guide 302 described above, and the horizontal driving body 420 is a horizontal guide rail 300 while the horizontal roller 403 is supported by the roller guide 302. ) As a result, the horizontal pinion gear 441, which will be described later, rotates while being engaged with the horizontal rack gear 301, and the horizontal driving body 420 is moved horizontally from side to side, wherein the horizontal roller 403 is connected to the roller guide 302. It rotates in a contacted state, and thus moves horizontally while the horizontal driving body 420 is supported.

The horizontal drive motor 440 is coupled to the horizontal drive body 420. As long as the means for driving the horizontal drive motor 440 may be any means, but preferably may be an air motor operated by the supply of air.

A horizontal pinion gear 441 is formed on the axis of the horizontal drive motor 440, and the horizontal pinion gear 441 is engaged with the horizontal rack gear 301. The axis of the horizontal drive motor 440 may be in a state passing through the horizontal drive body 400. The driving force of the horizontal drive motor 440 positioned in the opposite direction of the horizontal guide rail 300 with respect to the horizontal drive body 400 is transmitted to the axis of the horizontal drive motor 440 so that the upper portion of the horizontal guide rail 300 is provided. It may be transmitted to the horizontal pinion gear 441 that is engaged with the horizontal rack 301 located on the surface.

The movable driving motor 440 may be coupled to one side of the horizontal driving body 420, and the dispensing body holder 450 may be fixedly coupled to the other side of the horizontal driving body 420. The high pressure water distribution body 520, which will be described later, is held on the distribution body holder 450 in a fixed manner. The high pressure water is sprayed toward the tube T through the nozzles 530, 530 ′ and 540 while the nozzles 530, 530 ′ and 540, which will be described later, are connected to the high pressure water distribution body 520.

It demonstrates with reference to FIG.

The air supply control unit 50 communicates with the vertical drive motor 240 and the horizontal drive motor 440 through the communication tube 54. The air supply control unit 50 receives air from the air supply pipe 52, and the air supplied is the vertical drive motor 240 and the horizontal drive motor 440 as the air supply is adjusted in the air supply control unit 50. The operation of can be controlled.

The driving force of the vertical driving motor 240 and the driving force of the horizontal driving motor 440 are generated by the air supplied through the air supply control unit 50, and the driving force of the vertical driving motor 240 and the horizontal driving motor 440 is generated. With the driving force, the nozzles 530, 530 ′ and 540 coupled to the horizontal driving part 400 are moved in the vertical or transverse direction, and the surface of the tube T is washed with the high pressure water sprayed from the nozzles 530 and 530 ′ so that the attachment is removed. Removed.

It demonstrates with reference to FIG.

The high pressure water is supplied to the high pressure water distribution body 520 that is held in a fixedly coupled manner to the distribution body holder 450. The high pressure water may be injected at a pressure necessary to remove deposits attached to the surface of the plurality of stacked tubes T included in one end of the tube bundle. Preferably, it may be 500 to 800 bar, but the pressure may be increased or decreased depending on the number of tubes T stacked.

Chemicals may be added to such high pressure water. The chemicals added may be potassium hydroxide and hydrogen peroxide.

It demonstrates with reference to FIG. As can be seen from the table shown in Figure 7, there is a marked difference in the washing effect of the high pressure water in a state that does not contain potassium hydroxide and hydrogen peroxide.

The plurality of nozzles 530, 530 ′, 540 are connected to and communicated with the high pressure water distribution body 520. A plurality of nozzles 530, 530 ′, 540 communicate with the high pressure water distribution body 520, and the high pressure water containing the high pressure water or chemicals supplied to the high pressure water distribution body 520 through the nozzles 530, 530 ′, 540. Sprayed.

In cleaning the surface of the tube (T) included in a set of tube bundles, it is necessary to effectively clean the surface of the tube (T) located at or near the top of the set of tube bundles. The surface of the tube T located inside (spaced from the top) should also be cleaned effectively.

Through a plurality of nozzles (530, 530 ', 540) can not be effectively cleaned to the surface of the tube (T) located inside by only a simple high pressure water injection. In the washing apparatus according to the present invention, the spray angle of the high pressure water sprayed from the plurality of nozzles 530, 530 ′ and 540 may be different for each nozzle.

The plurality of nozzles 530, 530 ′, 540 are positioned in a plurality of nozzles 530, which are located in a plurality of states in a state connected to one end of the high pressure water distribution body 520, and connected to the other end of the high pressure water distribution body 520. The other end nozzle 530 ′ and a plurality of inner nozzles 540 positioned in a state connected to the inside of the high pressure water distribution body 520.

The high pressure water flowing through the high pressure water distribution body 520 is injected through the one end nozzle 530, the other end nozzle 530 ′, and the inner nozzle 540, and preferably, the high pressure water sprayed from the first nozzle 530. The injection angle, the injection angle of the high pressure water injected from the other end nozzle 530 'and the injection angle of the high pressure water injected from the inner nozzle 540 may be different from each other.

The high pressure water distribution body 520 may be formed in a predetermined length in a certain length, a plurality of end nozzles 530 at one end in the longitudinal direction of the high pressure water distribution body 520 may be positioned in a line at regular intervals. Likewise, a plurality of other end nozzles 530 'may be positioned in a line at regular intervals at the other end. Likewise, the inner nozzles 540 may be positioned in a line at regular intervals inside the high pressure water distribution body 520.

An injection angle of the high pressure water injected from the nozzle 530 may be different from an injection angle of the high pressure water injected from the other end nozzle 530 ′. Specifically, based on a vertical line vertically penetrating the high-pressure water distribution body 520, the spray angle of the one end nozzle 530 may be biased to one side, the spray angle of the other end nozzle 530 'is the vertical line described above. It may be a symmetry angle of the spraying angle of the nozzle 530 on the basis of.

For example, the injection angle of one end nozzle of the plurality of end nozzles 530 may be symmetrical with the spray angle of the other end nozzle corresponding to any one end nozzle. If the spray angle of one end nozzle is 60 degrees based on the vertical line, the spray angle of the other end nozzle corresponding thereto may be 120 degrees. The high pressure water sprayed from one end nozzle and the high pressure water sprayed from the other end nozzle corresponding thereto may be alternately sprayed.

In the tube washing apparatus for the heat exchanger according to the present invention, a plurality of nozzles (530, 530 ', 540) is moved back and forth in the longitudinal direction of the tube (T) and the cleaning operation is made, and after moving in the left and right directions, the tube (T) again Can be washed while moving back and forth in the longitudinal direction of the That is, after washing a predetermined range in the longitudinal direction, and moved to the left and right, while washing in the longitudinal direction of the tube (T) again in a new constant range. In addition, the type of tubes used in the large boiler is very limited, so that the diameter of the tube T in which the cleaning operation is performed may be mostly the same diameter.

In this situation, in order to clean the surface of the tube T while the plurality of nozzles 530, 530 ′, 540 move in the longitudinal direction of the tube T, the spray angles of the plurality of nozzles 530, 530 ′, 540 are adjusted. In this case, it is possible to effectively clean the surfaces of all the tubes T included in the tube bundle.

The spray angle of the one end nozzle 530 and the spray angle of the other end nozzle 530 'are symmetrical with respect to the vertical line, so that a plurality of nozzles 530, 530 ′, 540 connected to the high pressure water distribution body 520 are connected to the tube T. When the high pressure water is injected while moving in the longitudinal direction of, the high pressure water injected from the nozzle 530 once reaches one side of the tube (T), the high pressure water injected from the other end nozzle (530 ') is the other side of the tube (T) Cleaning is effective by touching Therefore, in the state traversing the middle portion of the tube T, one side of the portion corresponding to the bottom of the middle portion by the high pressure water sprayed from the nozzle 530 on one side, the other end ( 530 'may be washed by the high pressure water sprayed.

In washing a plurality of stacked tubes T included in one end of the bundle, a plurality of nozzles 530, 530 ′ and 540 are positioned above the one end of the bundle to inject high pressure water, and a plurality of other nozzles ( 530, 530 'and 540 are positioned below the bundle of tube bundles to inject high pressure water upwards, thereby cleaning the entire tube T contained in the bundle of tube bundles.

The injection angles of the high pressure water injected from the plurality of end nozzles 530 may all be different from each other, and the injection angles of the high pressure water injected from the plurality of other end nozzles 530 'may all be different from each other.

A plurality of tubes T are stacked in one tube bundle. It is laminated | stacked by the tube T located in the outermost side, the tube T located next to the outermost side, and the tube T located further inward. These tubes T are not positioned in line, but are stacked in such a way that the lower tube T is positioned at a position between the tube T and the tube T in order to maximize the heat exchange efficiency. .

Any one of the plurality of end nozzles 530 is sprayed aiming at one side of the outermost tube (T), another nozzle is aimed at one side of the tube (T) located on the outermost next inner side And another nozzle is sprayed while aiming at one side of the tube T, which is located next to the inner side.

Alternatively, one of the plurality of end nozzles 530 is sprayed to aim at one side of the outermost tube (T), another nozzle is sprayed at a point away from more than one side of the outermost tube (T) The high pressure water sprayed in this way may be reflected while being obliquely contacted with the outermost tube T, and the high pressure water may be washed while being sprayed in such a manner that the reflected high pressure water is in contact with one side of the tube T located at the outermost inner side. .

In this manner, a plurality of other end nozzles 530 ′ are sprayed while aiming at the other side of the plurality of tubes T stacked.

The high pressure water is sprayed in this way from above and below the bundle of tube bundles, which can effectively clean the surface of all the tubes T included in the bundle of tube bundles.

In the plurality of end nozzles 530, the difference between the spray angle at one end nozzle and the spray angle at the other end nozzle positioned closest to the one end nozzle is closest to the spray angle at the other end nozzle. It may be equal to the difference in the spray angles at another one end nozzle positioned.

Similarly, in the plurality of other nozzles 530 ', the difference between the injection angle at one end of the nozzle and the injection angle at the other end located closest to the other end nozzle is different from that of the other end nozzle. It may be equal to the difference in injection angles at the other end nozzle positioned closest.

In the plurality of end nozzles 530, the difference in the spray angles of the nozzles may be the same. The diameters of all the tubes T included in one end of the bundle bundle are the same, and the stacked manner is also stacked with regularity in a constant manner. As described above, the plurality of nozzles 530, 530 ′, 540 are moved in the longitudinal direction of the tube T, and after washing the surface of the tube T, the nozzles 530, 530 ′, 540 are moved left and right, and moved again in the longitudinal direction. Clean the surface).

By maintaining a constant difference in the spray angles between the plurality of end nozzles 530, when moving in the lateral direction and then washing while moving in the longitudinal direction again, a consistent and identical washing effect can be maintained. The difference in the injection angle can be set to a certain difference in consideration of the number of the stack of the tube (T) and the diameter of the tube (T).

Referring to Figure 8 will be described the cleaning efficiency according to the difference in the injection angle between the plurality of end nozzles (530). FIG. 8 illustrates the cleaning efficiency according to the number of injection nozzles 530 reflecting a certain injection angle difference and the injection angle difference in a state where the injection angle difference between the nozzles 530 is set.

Based on a vertical line penetrating the high pressure water distribution body 520 vertically, when only one nozzle is mounted at +30 degrees, the effective distance is 2 m and the pressure of the high pressure water is 30% at 500 bar, and 3 m at 600 bar. %, 45m for 4m 700bar, the maximum efficiency of the washing is 55% for 5m 800bar.

When only two nozzles of +30 degree and +25 degree are equipped, the maximum efficiency of the cleaning is 60%, and when only three nozzles of +30 degree, +25 degree and +20 degree are equipped, the maximum of cleaning The efficiency is 68%.

In this way, it can be seen that the eight end nozzles 530 are mounted in a line, and the maximum efficiency can be increased to 99% while the difference in the spray angles between them is set at 5 degrees.

As a result, the high pressure water injected is more likely to be injected into the air at an angle of more than +30 degrees, and the high pressure water is more likely to be injected into the air at an angle smaller than -5 degrees.

As the jet angles of the eight end nozzles 530 are continuously mounted with a difference of 5 degrees, the high pressure water as well as the outermost tube T directly contact the outermost next tube T or the outermost tube T as well. Whether it is in contact with and reflected to the outermost next tube T, the inner tube T can be effectively cleaned.

In conclusion, the eight end nozzles 530 are mounted on one end of the high-pressure water distribution body 520, but are mounted in a row with a difference of 5 degrees from the spray angle, so that the entire tube included in one end of the tube bundle ( In cleaning the surface of T), it can be seen that the cleaning efficiency up to 99% can be achieved.

The same applies to a plurality of other end nozzles 530 'symmetrically positioned in the plurality of one end nozzles 530, and the high pressure water sprayed from the one end nozzle 530 and the other end nozzles 530' is alternated in the middle of the tube T. It is possible to effectively clean the portion of the portion below or the entire portion of the portion above.

The injection angle of the high pressure water injected from the nozzle 530, the injection angle of the high pressure water injected from the other end nozzle 530 ′, and the injection angle of the high pressure water injected from the inner nozzle 540 may be different from each other. The injection angles of the nozzle 530 and the other nozzle 530 'are as described above.

The inner nozzle 504 preferably sprays high pressure water in a direction perpendicular to the high pressure water distribution body 520. For the cleaning effect, as the same difference between the symmetry and the spraying angle of the one end nozzle 530 and the other end nozzle 530 'is reflected, insufficient injection in the vertical direction may be achieved. Therefore, the nozzle for maintaining the spray angle in the vertical direction is required, the inner nozzle 540 located inside the high pressure water distribution body 520 sprays the high pressure water in the vertical direction on the high pressure water distribution body 520. desirable. Therefore, it is preferable that the high pressure water is sprayed at different spray angles of the one end nozzle 530, the other end nozzle 530 ′, and the inner nozzle 540.

In the present specification, the present invention has been described with reference to the embodiments shown in the drawings so that those skilled in the art can easily understand and reproduce the present invention, which is merely exemplary, and those skilled in the art can make various modifications and equivalents from the embodiments of the present invention. It will be appreciated that embodiments are possible. Therefore, the protection scope of the present invention will be defined by the claims.

50: air supply control unit
52: air supply pipe 54: communication pipe
100, 100 ': vertical guide rail
101, 101 ': Vertical rack gear 102, 102': Roller guide 110: Front stand 120: Rear stand
200, 200 ': vertical driving part
220: longitudinal drive body
203: Vertical roller 230: Parallel movement retaining connecting rods 231, 231 ': Vertical pinion gear
232: rotary gear 235: chain 240: vertical drive motor 242: motor gear
300: horizontal guide rail
301: horizontal rack gear 302: roller guide
400: horizontal driving part
420: horizontal drive body 440: horizontal drive motor 441: horizontal pinion gear
450: dispensing body holder
520: high pressure water distribution body 530: one end nozzle 530 ': the other end nozzle 540: inner nozzle

Claims (5)

In the heat exchanger tube washing apparatus for washing the surface of the heat exchanger tube (T) stacked in a plurality of high pressure water,
Vertical guide rails 100 and 100 'mounted on the heat exchanger tube T;
Vertical driving parts 200 and 200 ′ moved in a vertical direction along the vertical guide rails 100 and 100 ′;
A horizontal guide rail 300 coupled to the vertical driving parts 200 and 200 ′ and vertically moved in accordance with the movement of the vertical driving parts 200 and 200 ′; And
It includes a horizontal drive unit 400 is moved in the horizontal direction along the horizontal guide rail 300,
The horizontal drive unit 400 is a horizontal drive body 420; And a horizontal driving motor 440 coupled to the horizontal driving body 420,
A dispensing body holder 450 coupled to the horizontal driving body 420;
A high pressure water distribution body 520 which is held by the distribution body holder 450; And
Further comprising a nozzle (530, 530 ', 540) coupled to the high pressure water distribution body 520,
The high pressure water sprayed from the nozzles 530, 530 ′, 540 while the nozzles 530, 530 ′, 540 are moved in the vertical direction or the horizontal direction by the driving force of the vertical drives 200, 200 ′ or the driving force of the horizontal drive unit 400. The surface of the heat exchanger tube (T) is washed by
The nozzles 530, 530 ′, 540 may include one end nozzle 530 positioned in plural in a state connected to one end of the high pressure water distribution body 520; Other end nozzles 530 'positioned in a plurality in a state connected to the other end of the high pressure water distribution body 520; And an inner nozzle 540 positioned in plural in a state connected to the inside of the high pressure water distribution body 520,
High pressure water flowing through the high pressure water distribution body 520 is injected through the one end nozzle 530, the other end nozzle 530 'and the inner nozzle 540,
The injection angle of the high pressure water injected from the one end nozzle 530, the injection angle of the high pressure water injected from the other end nozzle 530 'and the injection angle of the high pressure water injected from the inner nozzle 540 are different from each other,
The injection angles of the high pressure water injected from the plurality of end nozzles 530 are all different from each other,
The injection angles of the high pressure water injected from the plurality of other nozzles 530 'are all different from each other,
In the plurality of end nozzles 530, the difference between the spray angle at one end nozzle and the spray angle at the other end nozzle positioned closest to the one end nozzle is different from the spray angle at another end nozzle. Is the same as the difference in the spray angle at the other end of the nozzle,
In a plurality of the other end nozzles 530 ', the difference between the injection angle at one end of the nozzle and the injection angle at the other end of the nozzle located closest to the other end nozzle is different from that of the other end nozzle. Tube cleaning apparatus for heat exchangers equal to the difference in injection angles at another end nozzle positioned in close proximity.
The method of claim 1,
The vertical guide rails (100, 100 ') is composed of a pair located at regular intervals,
The vertical driving unit 200, 200 ',
A pair of longitudinal driving bodies 220 and 220 'moved in a state in which they are mounted on both sides of the pair of longitudinal guide rails 100 and 100';
A parallel moving maintenance connecting rod 230 connecting the pair of vertical driving bodies 220 and 220 '; And
It includes a vertical drive motor 240 coupled to any one of the vertical drive body 220 of the pair of vertical drive body (220,220 '),
As the driving force of the vertical drive motor 240 is transmitted to the parallel movement maintaining connecting rod 230 and the parallel movement maintaining connecting rod 230 is rotated, the pair of longitudinal driving bodies 220 and 220 ' Vertically moved parallel to the guide rails (100, 100 '),
In the state where both ends of the horizontal guide rail 300 is coupled to each of the pair of vertical drive bodies 220 and 220 ', the horizontal guide in accordance with the longitudinal movement of the pair of vertical drive bodies 220 and 220'. Rail 300 is a tube cleaning device for the heat exchanger to move in the vertical direction.
The method of claim 2,
Vertical rack gears 101 and 101 'are formed in each of the vertical guide rails 100 and 100', and horizontal rack gears 301 are formed in the horizontal guide rail 300.
Longitudinal pinion gears (231,231 ') are formed at each end of each of the parallel moving retaining connecting rods (230), and a horizontal pinion gear (441) is formed on the shaft of the horizontal drive motor (440).
The method of claim 3, wherein
The vertical drive motor 240 and the horizontal drive motor 440 is an air motor,
In the state in which the vertical drive motor 240 and the horizontal drive motor 440 is connected to the communication tube 54 to the air supply control unit 50 connected to the air supply pipe 52, the air is the vertical drive motor 240 And tube washing apparatus for the heat exchanger supplied to the horizontal drive motor (440).
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