KR20190027977A - Wave generatoring apparatus - Google Patents

Abstract

Provided in the present invention is a wave generating apparatus, which generates air having periodical wave within a pipe in order to prevent debris from being fixated or slush and rust from being formed within a pipe by using impact generated by the wave. Therefore, blockage of the pipe is prevented, and liquidity of fluid is improved.

Description

{WAVE GENERATING APPARATUS}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a wave generating device, and more particularly, to a wave generating device that forms periodic waves in a fluid supplied through a piping facility.

Generally, facilities such as a power plant, a steel mill, and a chemical plant are provided with a piping system including a piping for transferring fuel such as liquid fuel, raw materials and various chemical substances, and air such as exhaust gas generated during the process .

Such a piping facility is a facility suitable for continuously supplying a liquid material or air, and as the liquid material or air is continuously supplied, it becomes a factor to be fixed in the inside of the piping, or to form slush or rust.

In this way, when foreign substances such as liquid substances are fixed to the inside of the pipe, or when slush, rust, or the like is formed, the flow path of the pipe is blocked to prevent smooth transportation. Particularly, the bending portion or the connecting portion of the pipe may not be sufficiently secured by a foreign substance or the like.

In addition, as an example of the liquid material transferred by the piping, when the piping is clogged, strong alkaline, strong acid solution, etc. used for pickling, surface washing and the like are blocked from being smoothly supplied in the piping facility, So that the clogging part of the piping is required to be repaired or replaced.

In addition, if the internal flow path of the piping is severely blocked, leakage may occur from the piping and various kinds of harmful chemical substances may be discharged, thereby contaminating the surrounding environment and facilities, and posing a threat to the safety of workers.

However, in the conventional art, it is difficult to confirm the exact position even if foreign matter is adhered to the inside of the piping, slush, rust, etc., and it takes a lot of cost for repairing and replacing, which makes maintenance of the piping difficult.

Conventionally, a technique for a " Coanda jet spraying structure for dust collection facility pulsing ", which removes dust and the like adhering to the interior of a dust collection facility by jetting high-pressure air, is disclosed and used in Japanese Patent Application Laid-Open No. 10-2016-0137234 have.

However, such a jet injection structure simply injects fluid (air) at a high pressure, which limits the effective removal of foreign matter adhering to the piping. Accordingly, there is a need to develop a technique for more effectively removing foreign substances in the piping have.

Publication No. 10-2016-0137234

In order to solve the above-mentioned problems, the present invention generates air having a periodic wave in the inside of a pipe, and prevents the formation of foreign matter, slush, and rust in the inside of the pipe due to the impact caused by the wave Thereby preventing clogging of the piping and improving the fluidity of the fluid.

According to an aspect of the present invention, there is provided a wave generating apparatus including a first flow path connected to a pipeline through which fluid is supplied, A body having an inlet port formed therein; A first chamber which is inserted into the inside of the body and which has an inner circumferential surface formed with a second flow path continuous with the first flow path and which is connected to the inlet port between the outer circumferential surface and the body, A first partition member for discharging the fluid along the inner circumferential surface of the second flow path to accelerate the fluid; And a third flow path which is inserted into one side of the first partition member and which pressurizes and fixes the first partition member and whose inner circumferential surface is continuous with the second flow path, And a second partition member formed with a second chamber connected to the second chamber and discharging the compressed air from the second chamber to the third passage and forming a pulsation on the fluid.

A first slit is formed between the body and the end of the first partitioning member to discharge compressed air from the first chamber. The compressed air discharged through the first slit flows through the inner circumferential surface of the second flow path, And the flow rate can be accelerated by the Coanda effect.

A second slit through which the compressed air is discharged from the second chamber is formed between the first partition member and the second partition member. The compressed air discharged through the second slit passes through the passage And may cause pulsation due to the flow rate variation.

Further, a first sealing portion for sealing a gap may be provided at one side between the body and the first partition member.

Further, a second sealing portion for sealing a gap may be provided at one side between the first partition member and the second partition member.

A flange for connection with the pipe may be formed at the end of the body and the end of the first partition member.

According to the present invention, it is possible to prevent the foreign matter from sticking, slushing, rusting or the like to the inside of the pipe by generating an impact on the pipe by jetting air having a periodic wave to the fluid passing through the pipe at a high speed, Accordingly, clogging of the pipe can be prevented, and the pressure of the fluid can be kept constant.

Further, since the present embodiment suppresses the clogging of the piping, it is easy to maintain and manage the piping, and accordingly, it is not necessary to replace or repair the piping unnecessary, thereby contributing to the process stability and the overall productivity improvement.

Further, since the flow rate of the fluid supplied through the pipe is kept constant, the fluid such as pickling or surface cleaning liquid can be supplied according to the designed capacity, and the process can be stably maintained.

1 is a perspective view of a wave generator according to an embodiment of the present invention;
2 is a partially cut-away perspective view of a wave generator according to an embodiment of the present invention;
3 is a cross-sectional view of a wave generator according to an embodiment of the present invention;

Certain terms are hereby defined for convenience in order to facilitate a better understanding of the present invention. Unless otherwise defined herein, scientific and technical terms used in the present invention shall have the meanings commonly understood by one of ordinary skill in the art. Also, unless the context clearly indicates otherwise, the singular form of the term also includes plural forms thereof, and plural forms of the term should be understood as including its singular form.

FIG. 1 is a perspective view of a wave generator according to an embodiment of the present invention, FIG. 2 is a partially cutaway perspective view of a wave generator according to an embodiment of the present invention, FIG. Fig.

Hereinafter, a wave generator 100 according to an embodiment of the present invention will be described with reference to FIGS. 1 to 3. FIG.

The wave generator 100 according to an embodiment of the present invention may be utilized to remove foreign substances adhering to the piping by generating waves in the fluid passing through the piping connected between piping of the piping system.

The wave generating device 100 may include a body 110, a first partition member 120, and a second partition member 130.

The body 110 may be connected to one end of the pipe, and may be formed in a shape corresponding to the external shape of the pipe. In one example, the tubing may be provided in the form of a circular pipe, and the body 110 may also be provided in the form of a corresponding circular pipe.

A first flow path 10 continuous with the flow path of the pipe may be formed on the inner circumferential surface of the body 110.

Also, the body 110 may include an extension that is spaced a predetermined distance from the end portion and has a larger diameter. The body 110 may have an inlet 112 through which compressed air flows from the outside to one side of the extension.

Meanwhile, the first partitioning member 120 may be inserted into the body 110 and installed therein. The first partition member 120 may be formed in a cylindrical shape corresponding to the body 110 and a second flow path 20 connected to the first flow path 10 of the body 110 may be formed on the inner peripheral surface thereof .

In addition, the first partition member 120 may be formed such that the outer circumferential surface thereof is spaced apart from the inside of the body 110, that is, the extending portion. The first chamber 114 may be formed in the space between the first partitioning member 120 and the expansion unit. The first chamber 114 is filled with the air introduced from the inlet 112.

The compressed air filled in the first chamber (114) can be discharged along the inner circumferential surface of the second flow path (20). Here, since the air discharged from the first chamber 114 flows along the inner circumferential surface of the second flow path 20 and is expanded only to one side, the air can be accelerated and discharged at a high speed.

As described above, the air discharged from the first chamber 114 is accelerated at a high speed and can increase the flow rate of the flow channel supplied through the pipe during the discharge.

Specifically, a first slit 116 may be formed between the body 110 and the end of the first partitioning member 120.

The first slit 116 is filled in the first chamber 114 and the compressed air can be discharged. At this time, since the first slit 116 is discharged to move along the inner circumferential surface of the second flow path 20, by the coanda effect The flow rate of the fluid supplied to the pipe can be increased.

Meanwhile, the second partitioning member 130 may be inserted into the first partitioning member 120. The inner circumferential surface of the second partition member 130 may form a third flow path 30 that is continuous with and connected to the second flow path 20.

The outer circumferential surface of the second partitioning member 130 may be formed with the second chamber 122 between the outer circumferential surface of the second partitioning member 130 and the first partitioning member 120.

The second chamber 122 may be connected to the first chamber 114 and a connection pipe 118 for connecting the first chamber 114 and the second chamber 122 to one side of the first partition member 120 May be provided.

The second chamber 122 may be supplied with compressed air in the first chamber 114 via the connection tube 118. The first chamber 114 fills and compresses the air introduced through the inlet 112 and discharges the compressed air to the second flow path 20 through the first slit 116. A part of the air flows through the connection tube 118 To the second chamber 122.

The volume of the second chamber 122 is preferably smaller than the volume of the first chamber 114. In addition, the air supplied to the second chamber 122 may be pressurized as compared to the first chamber 114.

The air supplied to the second chamber 122 may be discharged to the third flow path 30. The amount of air discharged from the second chamber 122 to the third flow path 30 may be smaller than the amount of air discharged from the first chamber 114.

Specifically, a second slit 124 may be formed between the first partition member 120 and the second partition member 130 to discharge compressed air from the second chamber 122.

The air discharged from the second slit 124 can strike the fluid passing through the third flow path 30 and can be struck in the process of colliding with the fluid accelerated by the Coanda effect of the air discharged from the first slit 116 It acts as a resistor due to speed and flow rate variation and can cause pulsation.

Thus, the air discharged from the second chamber 122 can strike the fluid passing through the third flow path 30. The fluid passing through the third flow path 30 is accelerated by the Coanda effect of the air discharged from the first chamber 114 and is relatively low discharged from the second chamber 122, Resistance may be generated by the air that has, and thus a wave may be generated in the fluid and cause periodic pulsation.

Preferably, the second slit 124 may be inclined with respect to the discharge direction of the air, so that the fluid passing through the third flow path 30 may be pulsated in a vortex shape.

As described above, the fluid discharged from the wave generator 100 according to the present embodiment accelerates and generates pulsation. As a result, an impact can be generated in the process of colliding with the pipe, thereby eliminating foreign matter adhering to the inner peripheral surface of the pipe. .

In addition, the wave generator 100 of the present embodiment can generate a larger impact on the surface of the pipe due to the cavitation effect generated by the air supplied with the fluid. In addition, in the process of splitting air into smaller particles in the process of colliding with the pipe, air can generate more shock waves, thereby more effectively eliminating foreign substances and the like adhered to the pipe.

In addition, in this embodiment, a first sealing portion 132 may be provided at one side between the body 110 and the first partition member 120 to seal the gap to prevent air from being discharged.

For example, the first sealing part 132 may include a first receiving groove formed on one of the body 110 and the first partition member 120 and a first O-ring member inserted into the first receiving groove .

In order to seal the gap between the first partitioning member 120 and the second partitioning member 130, air may be discharged through the gap between the first partitioning member 120 and the second partitioning member 130, 2 sealing portion 134 may be provided.

For example, the second sealing portion 134 includes a second receiving groove formed on one of the first partitioning member 120 and the second partitioning member 130 and a second O-ring member inserted into the second receiving groove can do.

In addition, in this embodiment, the second partitioning member 130 may be formed to be shorter than the first partitioning member 120, and may be completely housed inside the first partitioning member 120.

The end of the body 110 and the end of the first partitioning member 120 may be formed with flanges 110a and 130a for easy connection to the piping.

The operation of the wave generator constructed as described above will be described below.

First, the wave generating device is connected between the pipes, and the fluid can be supplied from the pipe.

That is, the fluid S1 supplied from the pipe is supplied to the first flow path 10 through the inlet of the body 110, and to the second flow path formed inside the first partition member 120.

On the other hand, high-pressure air A1 may be supplied to the inlet 112 of the body 110. The air s2 supplied to the inlet 112 is filled in the first chamber 114 and compressed and can be injected between the first flow path 10 and the second flow path 20 through the first slit 116 .

At this time, the air A2 blown from the first slit 116 can be discharged along the inner circumferential surface of the first partition member 120, and the axial flow S2 is generated in the fluid supplied from the pipe due to the Coanda effect The flow rate can be amplified.

In addition, a part of the air A1 supplied to the first chamber 114 may be supplied to the second chamber 122 through the connection pipe 118 and filled.

The air A3 supplied to the second chamber 122 can be discharged through the second slit 124 between the second flow path 20 and the third flow path 30. [

The air discharged from the second slit 124 collides with the axial flow S2 due to the fluid amplified by the Coanda effect and can generate a flow S3 having periodic waves in this process.

As described above, the wave generator 100 of the present embodiment can apply shock to the pipe by the axial flow S2 due to the amplified fluid and the flow S3 with periodic waves, and the impact applied to the pipe Foreign materials and the like can be effectively removed to prevent clogging of the piping.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It will be understood that various changes and modifications may be made without departing from the spirit and scope of the invention.

100: wave generating device 110: body
112: inlet 114: first chamber
116: first slit 120: first partition member
122: second chamber 124: second slit
130: second partition member 132: first sealing portion
134: second sealing portion

Claims (6)

A body connected to the piping between which the fluid is supplied and having a first flow path continuous with the piping and an inlet through which air flows into the first flow path;
A first chamber which is inserted into the inside of the body and which has an inner circumferential surface formed with a second flow path continuous with the first flow path and which is connected to the inlet port between the outer circumferential surface and the body, A first partition member for discharging the fluid along the inner circumferential surface of the second flow path to accelerate the fluid; And
A first partition member which is inserted into one side of the first partition member and which pressurizes and fixes the first partition member and whose inner circumferential surface forms a third flow path which is continuous with the second flow path and which is connected to the first chamber between the outer circumferential surface and the first partition member A second chamber formed with a second chamber for discharging the air compressed in the second chamber to the third passage and forming a pulsation on the fluid;
And a wave generator.
The method according to claim 1,
A first slit through which compressed air is discharged from the first chamber is formed between the body and the end of the first partitioning member,
The compressed air discharged through the first slit moves along the inner circumferential surface of the second flow path and accelerates the flow velocity by the Coanda effect.
The method according to claim 1,
A second slit through which compressed air is discharged from the second chamber is formed between the first partition member and the end of the second partition member,
The compressed air discharged through the second slit collides with the fluid passing through the flow path, and pulsation occurs due to a flow rate deviation.
The method according to claim 1,
And a first sealing portion for sealing a gap is provided at one side between the body and the first partition member.
The method according to claim 1,
And a second sealing portion for sealing a gap is provided at one side between the first partition member and the second partition member.
The method according to claim 1,
Wherein a flange is formed at an end of the body and at an end of the first partition member for connection with the piping.

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