KR101320030B1 - Apparatus for treating wastewater - Google Patents

Abstract

The present invention relates to a condensate discharge pressure reducing device, and a condensate discharge pressure reducing device includes a cylindrical body formed with a condensate inlet and a condensate outlet, a decompression unit for reducing the condensate containing a high-pressure gas introduced through the condensate inlet; There is provided a condensate discharge pressure decompression device including a rotating shaft supporting the decompression unit and penetrating the main body, and a condensate gas outlet through which the decompressed gas is discharged from the decompression unit.
Accordingly, the pressure of the condensate is discharged by reducing the pressure, which can prevent the corrosion of the surrounding equipment to operate the equipment efficiently, can solve the management problems. In addition, it is possible to prevent a problem that a safety accident occurs to the worker due to the condensate discharged at high pressure by promoting the safety of the worker.

Description

Apparatus for treating wastewater

The present invention relates to a condensate treatment apparatus, and more particularly, to a condensate treatment apparatus for reducing the pressure of the condensate to discharge the condensate more effectively.

Temperature differences generally occur inside devices such as chillers, air dryers, steam lines, and the like used in facilities of steel mills. This results in the generation of condensate in the hot part of the plant, and the device for discharging it is used. Conventional condensate discharge device as shown in Figure 1 and 2, there is an electrode type condensate discharge device, a magnetic condensate discharge device and the like.

A conventional condensate discharge device will be described with reference to FIGS. 1 and 2.

The electrode type condensate discharge device 10 of FIG. 1 controls the amount of condensate by an electrical signal, and condensate and gas included therein are introduced into the condensate discharge device internal space 12 through the condensate inlet 11. Is collected.

The level of the condensate collected in the condensate discharge device internal space 12 is detected by the electrode rod 15 provided in the main body 13. When the water level detector 14 that detects the water level of the condensate water reaches a certain level or more, the water level detector 14 sends a signal to the electrically connected electronic valve 16 and the flow path of the condensate outlet 17 is opened. Therefore, the condensed water collected in the condensate discharge device inner space 12 is discharged to the outside.

Here, when the flow rate of the condensate collected in the condensate discharge device internal space 12 drops, the water level detector 14 detects this. At this time, the water level detector 14 sends a signal to the electromagnetic valve 16, the condensate outlet 17 is closed.

Magnetic condensate discharge device 20 of Figure 2 is a way to control the discharge of the condensate using the permanent magnets (23a, 23b), the condensate and the gas contained therein is introduced through the condensate inlet pipe 26 and the condensate discharge device It is collected in the inner space 21.

Then, the permanent magnet 23b mounted on the float 22 that rises due to the buoyancy caused by the condensate is raised. This lowers another permanent magnet 23a which blocks the air flow path of the stem 24. At this time, the air flow path of the stem 24 is opened to supply high pressure air to the air cylinder 28, and the valve 29 of the condensate discharge pipe is opened by the high pressure air. Therefore, the condensate and the gas contained therein are discharged to the outside through the condensate discharge pipe 27 at a time.

The conventional condensate discharge device 10, 20 has a problem that the condensate is discharged at a high pressure because the discharge pressure of the condensate discharges the condensate in the same way as the main pressure. This high pressure discharge of condensate causes widespread scattering, causing corrosion of the surrounding equipment, and there are problems in efficiency and management of the equipment.

In addition, there is a problem that a safety accident occurs to the operator due to the condensate discharged at a high pressure.

Korean Patent Publication No. 10-2003-0050534

The present invention provides an apparatus for treating condensate.

The present invention is connected to the condensate discharge device can be operated, provides a condensate treatment device that can lower the discharge pressure of the condensate.

The present invention provides a condensate treatment apparatus for reducing the discharge pressure of the condensate discharge to prevent the efficient operation of the equipment and corrosion of the adjacent device.

Condensate treatment apparatus according to an embodiment of the present invention,

A body having a condensate inlet and a condensate outlet formed therein and having a space therein; and

A decompression unit formed inside the main body and configured to depressurize condensate containing high pressure gas introduced through the condensate inlet; and a rotating shaft supporting the decompression unit and penetrating the main body; And a gas outlet through which the gas decompressed in the decompression unit is discharged.

The main body includes a tubular tube and a pair of outer sidewalls formed to face in parallel to both ends of the tubular tube, wherein the condensate inlet and the gas outlet are formed above the main body, and a condensate outlet is formed below the main body. .

The condensate treatment apparatus includes an angle adjusting member for adjusting the path of the condensate so that the condensate is sprayed perpendicularly to the end of the impeller blade, and the condensate inlet is disposed obliquely with respect to the main body or in the condensate inlet. The adjustment member is installed so that the condensate is injected perpendicular to the end of the impeller blades.

The decompression unit is formed in communication with the lower portion of the condensate inlet, and includes an impeller including an impeller blade rotated by the condensate flowing in, and a pressure reducing unit outer wall is formed on the side of the impeller formed.

The impeller blade is provided with a plurality, the end is bent at a predetermined angle. The rotary shaft penetrates in the horizontal direction of the main body, an impeller blade is formed in a direction crossing the longitudinal direction of the rotary shaft, and the rotary shaft is mounted by a bearing formed on the outer side wall and rotated by a rotary motion of the impeller.

The condensate treatment device is spaced apart from the decompression unit is installed in the inner space of the main body, a decompression passage through which the gas decompressed by the decompression unit is formed, the decompression plate can be rotated by the rotating shaft and along the rotating shaft A plurality of spaced apart from each other is installed.

Condensate treatment apparatus according to an embodiment of the present invention can be coupled to the operation of the condensate discharge device, the pressure of the condensate is discharged under reduced pressure. The condensate pressure discharged thereto is reduced and can be naturally discharged to the outside without scattering. Therefore, it is possible to prevent corrosion of the surrounding equipment, bring about efficient operation of the equipment, and solve management problems.

In addition, it is possible to prevent a problem that a safety accident occurs to the worker due to the condensate discharged at high pressure by promoting the safety of the worker.

1 is a cross-sectional view showing a cross section of the electrode-type condensate discharge device.
2 is a cross-sectional view showing a cross section of the magnetic condensate discharge device.
3 is in accordance with an embodiment of the present invention. The cross section which looked at the condensate processing apparatus from the horizontal direction is sectional drawing.
4 is a cross-sectional view of the condensate treatment device viewed from the longitudinal direction of the cross section in which the condensate inlet is formed in accordance with an embodiment of the present invention.
5 is in accordance with an embodiment of the present invention. A perspective view of a pressure reducing unit including an impeller is shown.
6A is in accordance with an embodiment of the present invention. A cross section of the pressure reducing unit outer wall is shown.
6B is in accordance with an embodiment of the present invention. A pressure reducing unit including an impeller is a front view shown.
7 is in accordance with an embodiment of the present invention. A wing of the impeller is shown in perspective view.
8 is according to an embodiment of the present invention It is sectional drawing which shows the rotating shaft of a condensate processing apparatus, and a pressure reduction plate.
9 is in accordance with an embodiment of the present invention A pressure reducing plate of the condensate treatment device is shown in front view.
10 is according to an embodiment of the present invention. Condensate discharge pressure Flow chart of the condensate and the gas contained within the pressure reducing device.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, it should be noted that the same components or parts among the drawings denote the same reference numerals whenever possible. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted so as not to obscure the subject matter of the present invention.

The condensate treatment device may be connected to the condensate discharge device and used, and the discharge pressure of the condensate is discharged to the outside. That is, the condensate discharged from the condensate outlet 17 (see FIG. 1) and the condensate discharge pipe 27 (see FIG. 2) of the conventional condensate discharge device may be introduced through the condensate inlet 400 (see FIG. 3) of the condensate treatment device. Can be.

3 is a cross-sectional view of the condensate treatment device viewed in a transverse direction. Referring to FIG. 3, the condensate treatment apparatus includes a body 100 having a condensate inlet 400 and a condensate outlet 500 and having an inner space. In addition, the decompression unit 700 for decompressing the condensate containing the high-pressure gas introduced through the condensate inlet 400, and the rotary shaft 200 which is formed to support the decompression unit 700 and penetrates the main body 100; , And a gas outlet 600 through which the gas decompressed in the decompression unit 700 is discharged.

Hereinafter, each component of the condensate treatment apparatus will be described with reference to FIGS. 3 to 9.

Referring to FIG. 3, the main body 100 is formed such that the tubular tube 110 and the outer sidewalls 120a and 120b vertically upright on both sides of the tubular tube 110 face each other. The tubular tube 110 and the outer sidewalls 120a and 120b are fastened by bolts 130. The main body 100 preferably forms a tubular shape for ease of installation of the pressure reduction unit 700, but is not limited to the tubular shape and may be formed in a shape having a space therein.

The condensate inlet 400 and the gas outlet 600 are formed on the tubular tube 110. A condensate outlet 500 is formed below the outer sidewall 120a adjacent to the gas outlet 600. In addition, the lower side of the tubular tube 110 is in communication with the decompression unit 700 is formed with a condensate storage space 140.

Condensate inlet 400 is a large amount of condensate is introduced from the outside of the main body 100, the condensate is introduced in a state in which the high pressure is not removed. As shown in FIG. 4, a through hole is formed at one side of the upper surface of the main body 100, and a condensate inlet 400 is formed in communication with the upper part of the through hole. In addition, the angle adjusting member 410 is formed inside the condensate inlet 400. The flow path through which the condensed water is introduced into the main body 100 at a predetermined angle (for example, 30 degrees to 60 degrees) is formed by the angle adjusting member 410. This is to efficiently rotate the impeller blade 720 which will be introduced in the condensed water to be described later.

The gas outlet 600 is formed to be spaced apart from the condensate inlet 400 in the longitudinal direction of the main body 100. A through hole is formed in an upper portion of the main body 100, and a gas outlet 600 is formed in communication with an upper portion of the through hole. The gas outlet 600 passes through the decompression unit 700 and the decompression plate 300 which will be described later, and the gas of the condensed water that has been decompressed is discharged. In addition, the cross-sectional area of the gas outlet 600 is wider than the cross-sectional area of the condensate inlet 400. This is to smoothly discharge the gas separated from the condensate.

The condensate outlet 500 may be formed on the outer side wall 120a. A through hole is formed below the first outer side wall 120a, and a condensate outlet 500 may be formed in communication with an upper portion of the through hole.

In the condensate outlet 500, the condensate separated from the high pressure gas is discharged from the decompression unit 700 to be described later. The condensed water is moved to the lower portion of the main body 100 by riding the decompression unit outer wall 730 and then collected in the condensate storage space 140. When the amount of condensate is collected beyond the condensate storage space 140, the condensate flows along the lower surface of the main body 100 and is discharged to the outside through the condensate outlet 500.

The condensate storage space 140 may be formed in communication with the decompression unit 700 at one lower side of the tubular tube 110.

5 is a perspective view illustrating a pressure reduction unit 700 including an impeller 710, and FIG. 6A is a cross-sectional view illustrating a cross section of the outer wall 730 of the pressure reduction unit.

3 and 5, the decompression unit 700 may be formed in communication with the lower portion of the condensate inlet 400 and may be formed in the main body 100 adjacent to the second outer sidewall 120b. The pressure reduction unit 700 includes an impeller 710 including an impeller blade 720 rotating by condensed water, and an outer wall 730 of a disc-shaped pressure reduction unit formed on a side of the impeller 710. The pressure reducing unit outer wall 730 includes a through hole 732, and a plurality of through holes 732 are formed at a predetermined angle in a radial direction from the center of the pressure reducing unit outer wall 730. In addition, the pressure reducing unit outer wall 730 is fixed to the inner surface of the tubular tube 110 is formed.

Here, as shown in FIG. 6A, a hole 731 is formed through which the rotation shaft 200 (see FIG. 3) can penetrate to the central portion of the pressure reducing unit outer wall 730.

As the condensed water introduced from the condensate inlet 400 passes through the decompression unit 700, the separated and decompressed gas moves into the main body through the through hole 732. At this time, the decompression is primarily performed, and after that, the decompression is performed through the decompression plate 300 described later. This is because the gas rotates the impeller blades 720 to consume one energy, the pressure of the gas is reduced while passing through the through hole 732 formed in the outer wall 730 of the pressure reduction unit. In addition, the pressure of the gas is reduced while passing through the space between the plurality of decompression plate 300 and hit the sensitization plate 300, passing through the decompression through holes 312, 322, 332 and holes (313, 323) included in the decompression plate.

Figure 6b is a front view showing a decompression unit including an impeller, Figure 7 is a perspective view of the wing of the impeller is shown. In general, the impeller is a major part of the blower or compressor and has several vanes or vanes arranged at equal intervals on the circumference. 6B and 7, the impeller 710 (see FIG. 5) has several impeller blades 720 formed in the radial direction about the rotation axis 200. Impeller wing 720 is formed surrounding the rotating shaft 200 in a direction crossing the longitudinal direction of the rotating shaft. Impeller blade 720 is a plate shape having a predetermined length and width extending in the longitudinal direction, one end of the extension line is bent inward at a predetermined angle (for example, 10 degrees to 30 degrees). This is for the impeller blade 720 to be efficiently rotated by inducing the condensed water introduced from the condensate inlet 400 is injected perpendicular to the impeller blade 720.

The incoming condensate is directly injected into the cross section of the impeller blade 720 (see FIG. 5), and the impeller blade 720 is rotated. The rotating shaft 200 is rotated by the impeller blade 720 is rotated.

3 and 8, the rotating shaft 200 penetrates the inside in the horizontal direction of the main body 100 and is formed in a cylindrical shape extending in the longitudinal direction. The rotating shaft 200 is mounted by a bearing 210 formed on the outer surfaces of the outer sidewalls 120a and 120b, and the rotation of the rotating shaft is induced by the mounting of the bearing 210. In addition, the decompression unit 700 and the decompression plate 300 described later are supported by the rotation shaft 200.

The condensate treatment apparatus may further include a pressure reducing plate 300.

8 and 9, the decompression plate 300 is supported by a rotating shaft therethrough, and a plurality of pressure reducing plates 300 are formed at predetermined intervals in the longitudinal direction of the rotating shaft 200. The decompression plate 300 is formed perpendicular to the rotation shaft 200, and is formed between the decompression unit 700 and the first outer side wall 120a on the other side.

Decompression plate 300 is in the shape of a disk, a plurality of pressure-sensitive through-holes 312, 322, 332 are formed. At least two pressure reducing passages 312, 322, and 332 are formed in the radial direction at the center of the pressure reducing plate 300. In addition, at the edge of the decompression plate 300, a plurality of grooves 313 and 323 for depressurizing condensate may be formed at a predetermined angle.

According to one embodiment of the present invention, the decompression plate 330 adjacent to the decompression unit 700 includes a plurality of decompression passages 332 in the decompression plate 330. The other pressure reducing plates 310 and 320 spaced apart at predetermined intervals include a plurality of pressure reducing passages 312 and 322 and grooves 313 and 323 at edges thereof. By the rotation of the rotary shaft 200, the plurality of decompression plates (310, 320, 330) is also rotated, the pressure-sensitive through holes (312, 322, 332) is also rotated. Gas passing through the through hole 732 of the decompression unit outer wall 730 (see FIG. 5) passes through the decompression plate 300 which rotates, and the secondary decompression is performed. This is because the gas passes through the space between the plurality of decompression plate 300 and hit the sensitizing plate 300, the pressure of the gas is reduced while passing through the decompression through holes 312, 322, 332 and holes 313, 323 included in the decompression plate .

10 is a flow chart of condensate and gases contained in the condensate treatment apparatus. Referring to Figure 10, the operation of the condensate treatment apparatus according to the present invention will be described.

Condensate treatment apparatus of the present invention configured as described above can be used in connection with the condensate discharge device, the discharge pressure of the condensate is discharged to the outside pressure. The condensate discharged from the condensate outlet 17 (refer to FIG. 1) and the condensate discharge pipe 27 (refer to FIG. 2) of the conventional condensate discharge device is introduced through the condensate inlet 400 of the condensate treatment device.

The incoming condensate contains high pressure gas. The condensate is introduced into the decompression unit 700 formed in communication with the bottom of the condensate inlet 400. Decompression unit 700 includes an impeller 710, the incoming condensate hits one end of the extension line bent at a predetermined angle (for example, 10 degrees to 30 degrees) of the impeller blades 720.

At this time, the condensate hits the inside of the decompression unit outer wall 730 by the rotation of the impeller blade 720, and the high pressure gas contained in the condensate is separated and decompressed. The decompressed gas is introduced into the main body 100 through the through hole 732 of the decompression unit outer wall 730. The condensate separated from the gas under high pressure is introduced into the lower portion of the main body 100 along the pressure reducing unit outer wall 730 and is discharged to the condensate outlet 500.

The gas introduced into the main body 100 passes through the decompression through holes 312, 322, 332 of the decompression plate 300 which is formed on the rotating shaft and rotates, and is decompressed secondary. Secondary pressure reduction of the gas is made through a plurality of pressure reduction plate 300, the reduced pressure is discharged through the gas outlet 600 formed on the main body 100. Therefore, the scattering by the high pressure of condensate is prevented.

As mentioned above, although this invention was demonstrated in detail through the preferable Example, the scope of the present invention is not limited to a specific Example, Comprising: It should be interpreted by the attached Claim. It will also be appreciated that many modifications and variations will be apparent to those skilled in the art without departing from the scope of the present invention.

10: electrode condensate discharge device 20: magnetic condensate discharge device
100: main body 110: tubular tube
120: outer side wall 200: axis of rotation
210: bearing 300: pressure reducing plate
400: condensate inlet 500: condensate outlet
600: gas outlet 700: pressure reduction unit
710: impeller 720: impeller wing
730: outer wall of the pressure reduction unit

Claims (10)

A body having a condensate inlet and a condensate outlet and having a space therein;
A decompression unit formed inside the main body and including an impeller blade rotating by condensate flowing in communication with a lower portion of the condensate inlet, and decompressing the condensate containing a high-pressure gas introduced through the condensate inlet;
A rotating shaft supporting the decompression unit and penetrating through the main body and being rotated by the rotation of the impeller blade;
A pressure reducing plate spaced apart from the pressure reducing unit and installed in the inner space of the main body; And
A gas outlet through which the decompressed gas passes through the decompression unit and the decompression plate;
Condensate treatment device comprising a.
The method according to claim 1,
The body includes a tubular tube and a pair of outer sidewalls formed to face in parallel to both ends of the tubular tube,
The condensate inlet and the gas outlet are formed above the main body,
Condensate treatment apparatus is formed under the main body condensate outlet.
The method according to claim 1,
The condensate inlet comprises an angle adjusting member for adjusting the path of the condensate so that the condensate is injected perpendicular to the end of the impeller blades.
The method according to claim 3,
The condensate inlet is arranged at an angle to the body, or
The control member is installed in the condensate inlet,
A condensate treatment device for discharging the condensate perpendicularly to an end of the impeller blade.
The method according to claim 1,
The depressurization unit includes an impeller including the impeller blades, and a condensate treatment device including an outer wall of the decompression unit formed on a side of the impeller and having a through hole formed therein.
The method according to claim 5,
The impeller wing is provided with a plurality, the end portion is a condensate treatment device is bent at an angle of 10 ° to 30 °.
The method according to claim 1,
And the rotating shaft penetrates in the horizontal direction of the main body, and the impeller blades are formed in a direction crossing the longitudinal direction of the rotating shaft.
The method according to claim 2,
And the rotating shaft is mounted by a bearing formed on the outer side wall.
The method according to any one of claims 1 to 8,
The decompression plate is a condensate treatment apparatus is formed through a pressure reducing passage through which the gas decompressed by the pressure reducing unit passes, the rotating shaft is supported through, and rotated by the rotating shaft.
The method according to claim 9,
The decompression plate is provided with a plurality of decompression plates spaced apart from each other along the rotation axis.

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