KR200398579Y1 - Heat exchanger cleaning device using mixture fluid with a solid particle storage tank - Google Patents

Abstract

The present invention is a vertical heat exchanger tube by injecting a mixed fluid of solid particles and water from the upper part of the heat exchanger to the hot exhaust gas passes into the heat exchanger tube of the shell (tube & tube type) heat exchanger having a vertical heat exchanger tube Provides a heat exchanger cleaning device that uses a mixed fluid having a solid particle tank for cleaning the heat transfer pipe wall while flowing inside and which can be operated by clearly distinguishing whether to supply the mixed fluid or only water to the heat exchanger. It's there.

Description

Heat exchanger cleaning device using mixture fluid with a solid particle storage tank}

The present invention is to clean the heat exchanger to reduce fouling and corrosion in the heat exchanger heat transfer surface that occurs when using a heat exchanger for recovering waste heat from the exhaust gas containing high-temperature corrosive contaminants discharged from industrial furnaces of the industry Relates to a device.

More specifically, high temperature exhaust gas passes into the heat exchanger tube of a shell & tube type heat exchanger having a vertical heat exchanger tube, and vertical heat transfer is performed by injecting a mixed fluid of solid particles and water from the top of the heat exchanger to pollutants formed in the heat exchanger tube. A heat exchanger cleaning device that uses a mixed fluid having a solid particle tank for cleaning the heat transfer pipe wall while flowing down the pipe, and which can be operated by clearly distinguishing whether to supply the mixed fluid or only water to the heat exchanger. will be.

In the conventional mixed fluid cleaning type heat exchanger, the mixed fluid of solid particles and water is injected from the upper part of the heat exchanger to supply solid particles and water to the vertical heat pipe at the same time to clean the heat transfer surface of the heat exchanger, and the solid particles in the mixed fluid tank configuration. Apply a fine filter in the middle to separate water and water.

In order to fluidize the solid particles, water is sprayed from the top to a position stacked under the tank.

However, in this type of mixed fluid tank, there is a possibility that the fine filter is blocked by the contaminants.

And, by using a method of fluidizing by spraying water on the top of the solid particles under the tank, there is a problem that the fluidization is not a smooth structure, it is difficult to control the retention amount of the solid particles.

In addition, a method of reliably determining whether or not the solid particles are supplied to the ejector according to the fluidization of the solid particles is also incomplete.

Accordingly, there is a problem in that it is not clear how to determine whether to supply the mixed fluid to the heat exchanger or to supply only the water.

An object of the present invention devised to solve the above problems, the hot exhaust gas passes into the heat exchanger tube of the shell (tube & tube type) heat exchanger having a vertical heat exchanger tube, the contaminants formed in the heat exchanger tube at the top of the heat exchanger A mixed fluid with a solid particle tank is used to spray the mixed fluid of solid particles and water and flows down the vertical heat pipe to clean the heat pipe wall, and to clearly distinguish whether to supply the mixed fluid or only water to the heat exchanger. To provide a heat exchanger cleaning device that can be operated by.

The present invention for achieving the above object is a heat exchanger cleaning device for supplying a mixed fluid to clean the inside of the heat exchanger, the mixed fluid tank through which the mixed fluid passed through the heat exchanger flows; A solid particle tank which is integrated with the mixed fluid tank and in which solid particles of the mixed fluid of the mixed fluid tank sink and are stored; A fluidization pump forcibly supplying water of the upper portion of the mixed fluid tank to the lower portion of the solid tank; An ejector having an input port connected to a lower portion of the mixed fluid tank and an upper portion of the mixed fluid tank, and an output port connected to the heat exchanger to supply a mixed fluid; And an ejector pump installed between the input port of the ejector and the lower portion of the mixed fluid tank.

In the mixed fluid tank is characterized in that the separating plate for separating the solid particles contained in the mixed fluid is installed.

In addition, between the output port of the ejector and the heat exchanger is characterized in that the hydrocon for increasing the solid particle density of the mixed fluid is further installed.

In addition, the water separated from the hydrocon is characterized in that for connecting the hydrocon and the mixed fluid tank to be supplied to the mixed fluid tank.

Hereinafter, the present invention will be described in detail.

In order to facilitate fluidization of solid particles, a separate solid particle tank is provided at the bottom of the mixed fluid tank and an input port of the ejector is located on the upper side of the solid particle tank.

The solid particle tank has a vertical cylindrical shape and a water supply port is installed on the lower side of the solid particle tank.

Accordingly, when water is supplied to the lower part of the tank of solid particles filled with solid particles, all the solid particles in the solid particle tank are suspended and floated to the upper part of the vertical cylindrical tank of the solid particles to be fluidized. A fluidized bed of solid particles is formed near the input port of the attached ejector.

In this state, when water is supplied to the water supply part of the ejector, the mixed fluid of the solid particles and water near the input port of the ejector may be sucked to form a mixed fluid, which is supplied to the upper part of the heat exchanger connected to the outlet of the ejector.

 When supplying water to the lower part of the solid particle tank is stopped, the fluidized bed of the solid particles formed on the upper part of the solid particle tank disappears, and all the solid particles sink to the bottom of the solid particle tank. Accordingly, since there is no solid particles at the input port of the ejector, only water is supplied to the heat exchanger through the ejector.

Therefore, the mixed fluid can be supplied using an ejector depending on whether or not water is supplied to the bottom of the tank of the solid particles, and only water can be supplied.

And. By installing a visible window on the upper side of the solid particle tank and looking at the position of the upper surface of the solid particles in the stagnant state, the retention amount of the solid particles can also be measured accurately.

The water that is fed into the ejector and the water at the bottom of the solid particle tank are sucked from the top of the separator plate of solid particles and water in the mixed fluid tank.

Only water without solid particles passing through the separator is present at this location.

The mixed fluid suspended from the lower part of the solid particle tank and the mixed fluid supplied to the heat exchanger through the ejector flow into the inlet part of the separating plate in the mixed fluid tank at the side of the separating plate.

Some of the solid particles in the mixed fluid are lowered to the lower part of the separator plate by their own weight, and some of the solid particles are introduced to the upper part of the separator plate together with water.

As the mixed fluid passes through the upper part of the separator plate and moves to the inlet of the fluidization pump, the solid particles all descend to the upper surface of the separator plate by their own weight, and the solid particles reaching the upper surface of the separator plate are separated through the inclined surface of the separator plate. It descends to the bottom of the plate and is discharged through a hole in the bottom of the separator plate.

Therefore, the separator serves as a kind of gravity separator.

Such a separator can be maintained to some extent as a separator, unlike a filter, even if water is contaminated to some extent by impurities.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

The heat exchanger cleaning device of the present invention is connected to a general heat exchanger (20).

The heat exchanger 20 is a substantially cylindrical tank, in which an array of vertical heat pipes 6 through which a cooling fluid flows is installed.

Cooling fluid is supplied and discharged through the cooling fluid inlet (3) and the cooling fluid outlet (4) in the arrangement of the vertical heat pipe (6), and the circulation is caused by the cooling fluid pump (5).

An exhaust gas inlet 1 is formed above the heat exchanger 20, and an exhaust gas outlet 2 is formed below the heat exchanger 20.

Therefore, the hot exhaust gas containing contaminants introduced through the exhaust gas inlet 1 is cooled through heat exchange while passing through the interior of the vertical heat pipe 6, and then discharged through the exhaust gas outlet 2.

The mixed fluid supplied from the heat exchanger cleaning device of the present invention is supplied to the mixed fluid nozzle 17 installed at the end of the mixed fluid supply pipe 13 through the mixed fluid supply pipe 13 connected to the upper side of the heat exchanger 20. Sprayed.

In addition, the lower portion of the heat exchanger 20 is gradually narrower in cross-sectional area to facilitate the collection of the mixed fluid, the collected mixed fluid is fed back to the heat exchanger cleaning device of the present invention.

The present invention largely comprises a mixed fluid tank (7), a solid particle tank (8), an ejector (11) and two pumps (10, 14).

The mixed fluid tank 7 and the solid particle tank 8 are integrally formed, and the solid particle tank has a smaller cross-sectional area than the mixed fluid tank 7 to facilitate the collection of the solid particles.

A separator plate 9 is provided at an intermediate position of the mixed fluid. The separating plate 9 is a plurality of inclined plates, and serves to separate the solid particles from the mixed fluid by their own weight.

The solid particle tank (8) is provided with a solid particle visible window (15), so that the loading amount of the solid particles therein can be visually confirmed.

An upper portion of the mixed fluid tank 7 and a lower portion of the solid particle tank 8 are connected by a pipe, and a fluidization pump 14 is installed therebetween.

The lower portion of the mixed fluid tank 7 is connected to the ejector 11 by a pipe, and the upper portion of the mixed fluid tank 7 and the ejector 11 are connected by a pipe.

That is, the lower part of the ejector 11 and the solid particle tank 8 connected to the upper part of the mixed fluid tank 7 are connected to each of the one branched branch, respectively, the upper part of the mixed fluid tank 7 It is also possible to connect separately with.

An ejector pump 7 is installed between the ejector 11 and the upper portion of the mixed fluid tank 7.

As described above, two tubes are connected to the input port of the ejector 11, and the output port of the ejector 11 is connected to the heat exchanger 20.

Hydrocone 12 is formed between the heat exchanger 20 and the output port of the ejector 11 to increase the density of the mixed fluid discharged through the ejector 11.

The input port of the hydrocon 12 is connected to the ejector 11, the output port of the hydrocon 12 is two, one mixed fluid supply pipe 13 for supplying a mixed fluid to the heat exchanger 20 ) And the other is connected to supply the water extracted from the mixed fluid back to the mixed fluid tank (7).

Hereinafter, the appearance of the operation according to the embodiment of the present invention.

The upper portion of the mixed fluid tank 7, that is, the upper portion of the separation plate 9, is supplied to the lower portion of the solid particle tank 7 by the fluidization pump 14, and is discharged by the ejector pump 10. It is supplied to the ejector 11.

Water introduced by the fluidization pump 14 under the solid tank floats solid particles in the solid particle tank 8 to fluidize at an inlet portion of the ejector 11.

The mixed fluid in which the solid particles are fluidized, and the ejector 11 supplied with the water introduced by the ejector pump 10 mix both of them, by the force of the ejector pump 10 and the hydrocon ( 12).

In the hydrocon 12, water is separated from the mixed fluid and sent to the mixed fluid tank 7, and the mixed fluid having a higher density is supplied to the mixed fluid nozzle 17 through the mixed fluid supply pipe 13. Spray.

The mixed fluid supplied into the heat exchanger 20 cleans the vertical heat pipe 6, is collected from the lower side, and is sent to the mixed fluid tank 7 again.

The mixed fluid is circulated by repeating the above process.

A mixed fluid or water supplied from the heat exchanger 20 and the hydrocon 12 is introduced into the upper portion of the separator 9, and a solid particle tank 8 is provided from the lower portion of the separator 9. The mixed fluid is suspended, and the mixed fluid flows in. The solid particles contained in the mixed fluid descend to the upper surface of the separating plate 9 by their own weight, and flow down along the inclined upper surface of the separating plate 9. Through the hole at the bottom of the bottom of the separator plate 9 is lowered into the solid particle tank (8), or fluidized in the inlet portion of the ejector (11).

 Therefore, the separator 9 serves as a kind of gravity dust collector to prevent the solid particles from flowing into the ejector pump 10 and the fluidization pump 14.

In addition, the retention amount of the solid particles can be confirmed through the solid particle visible window 15.

When the fluidization pump 14 is stopped and supply of water to the lower part of the solid particle tank 8 stops, the fluidized bed of the solid particles formed on the upper part of the solid particle tank 8 disappears, and all of the solid particles are removed. It sinks to the bottom of the solid particle tank (8).

Accordingly, since there is no solid particles at the input port of the ejector 11, only water is supplied to the heat exchanger 20 through the ejector 11.

The present invention described above is possible to those skilled in the art to which the present invention belongs, various substitutions, modifications and changes can be made within the scope without departing from the spirit of the present invention and the above-described embodiments and attached It is not limited by the drawings.

Through the present invention, the hard to remove contaminants attached to the exhaust gas side heat transfer surface in the heat exchanger vertical heat transfer pipe can be automatically cleaned using a mixed fluid of solid particles and water.

In addition, it is possible to control the supply of the mixed fluid or water to the heat exchanger by determining the fluidization of the solid particles depending on whether or not the water supply to the solid particle tank.

Therefore, at first, the mixed fluid is supplied to the heat exchanger to increase the cleaning effect. After cleaning using the mixed fluid, only the water is supplied to clean the heat exchanger, and at the same time, the solid particles in the mixed fluid pipe are removed to smoothly transfer the next mixed fluid. I can keep it.

In other words, the conventional method of cleaning the heat exchanger supplying only water spray or solid particles was used, but when the pollution is severe, the cleaning effect can be dramatically increased by simultaneously using the solid particles and water.

After washing of the heat exchanger, the water may be contaminated by impurities of the heat exchanger. In this case, the separator such as fine wire mesh is contaminated and cannot serve as a separator. However, the separation plate using the gravity dust of the present invention has a solid particle size of several mm, the separation effect is sure, can be used in contaminated water supply.

In addition, the retention amount of the solid particles can be confirmed through the visible window of the solid particle tank, so that the supply amount of the solid particles can be known.

In addition, by increasing the cleaning effect of the heat exchanger to improve the heat transfer performance, it is possible to reduce the size of the heat exchanger by using a small heat transfer tube.

1 is a conceptual diagram of a heat exchanger cleaning apparatus using a mixed fluid having a solid particle tank according to an embodiment of the present invention

<Description of the symbols for the main parts of the drawings>

1: exhaust gas inlet 2: exhaust gas outlet

3: cooling fluid inlet 4: cooling fluid outlet

5: cooling fluid pump 6: vertical heat pipe

7: Mixed Fluid Tank 8: Solid Particle Tank

9: Separator 10: Ejector Pump

11: ejector 12: hydrocone

13: Mixed fluid supply pipe 14: fluidization pump

15: solid particle visible window 16: mixed fluid

17: mixed fluid nozzle 20: heat exchanger

Claims (4)

In the heat exchanger cleaning device for supplying a mixed fluid to clean the inside of the heat exchanger, A mixed fluid tank into which the mixed fluid passing through the heat exchanger is introduced; A solid particle tank which is integrated with the mixed fluid tank and in which solid particles of the mixed fluid of the mixed fluid tank sink and are stored; A fluidization pump forcibly supplying water of the upper portion of the mixed fluid tank to the lower portion of the solid tank; An ejector having an input port connected to a lower portion of the mixed fluid tank and an upper portion of the mixed fluid tank, and an output port connected to the heat exchanger to supply a mixed fluid; And And an ejector pump installed between the input port of the ejector and the lower portion of the mixed fluid tank. The heat exchanger cleaning apparatus according to claim 1, wherein a separation plate for separating solid particles contained in the mixed fluid is provided in the mixed fluid tank. The heat exchanger cleaning device of claim 1, further comprising a hydrocone between the output port of the ejector and the heat exchanger to increase the solid particle density of the mixed fluid. The apparatus of claim 3, wherein the water separated from the hydrocon is connected to the mixed fluid tank so that the water separated from the hydrocon is supplied to the mixed fluid tank.