KR101890254B1 - apparatus for chromaticity treatment of waste water - Google Patents

Abstract

The present invention relates to an apparatus for chromaticity treatment of wastewater, and more specifically, to an apparatus for chromaticity treatment of wastewater, which can effectively improve the chromaticity of the wastewater by forming fine ozone bubbles in the wastewater and oxidizing chromogenic materials of the wastewater to ozone. The apparatus for the chromaticity treatment of the wastewater according to the present invention comprises: a tubular chromaticity treating container having an empty interior and formed to be long in the vertical direction; a wastewater inflow means installed in the chromaticity treatment container to introduce the wastewater stored in a wastewater storage container into the interior of the chromaticity treatment container; a wastewater circulation unit circulating the wastewater introduced into the chromaticity treatment container to the wastewater storage container; and an ozone bubble forming means forming ozone bubbles in the wastewater flowing through a wastewater supply pipe connecting the wastewater storage container and the wastewater inflow means.

Description

Apparatus for chromaticity treatment of waste water

The present invention relates to a device for treating color of wastewater, and more particularly, to a device for treating color of wastewater which can effectively reduce the chromaticity of wastewater by forming fine ozone bubbles in wastewater and oxidizing the color- will be.

The livestock wastewater generated during the processing of livestock manure is a typical wastewater containing chromaticity. It is not easy to remove the color, and it can be recognized as visually contaminated water, which may cause mistrust on the water treatment. Many researches have been done for giving.

Livestock wastewater is a high concentration of organic wastewater containing a large amount of nutrients such as nitrogen and phosphorus and contains a high concentration of refractory and odorous substances.

Removal of the chromaticity results in decomposition of the polymer organic material into small molecules, which facilitates further processing and accelerates the natural decomposition. Thus, efforts have been made to remove the chromaticity from wastewater.

Conventional methods for removing the chromaticity of wastewater include biological treatment methods, activated carbon, ozone treatment, and chemical treatment.

As disclosed in Korean Patent No. 10-0450588, the ozone treatment method has an advantage in that the color of the wastewater can be treated at a relatively low cost. However, there is a problem that it is difficult to increase the treatment effect by ozone only by a simple contact method of injecting ozone into wastewater.

Korean Patent No. 10-0450588: Decolorization system of effluent from livestock wastewater using ozone

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide a device for treating a wastewater chromaticity capable of effectively improving chromaticity of wastewater by forming fine ozone bubbles in wastewater, have.

In order to achieve the above object, the apparatus for treating color of waste water according to the present invention comprises: a tubular chromatic treatment tank having an empty interior and a long vertical length; A wastewater inflow means installed in the chromaticity treatment tank for introducing the wastewater stored in the wastewater storage tank into the interior of the chromaticity treatment tank; A wastewater circulation unit for circulating wastewater flowing into the chromaticity treatment tank to the wastewater storage tank; And an ozone bubble forming means for forming ozone bubbles in the wastewater flowing through the wastewater supply pipe connecting the wastewater storage tank and the wastewater inflow means, wherein the wastewater inflow means is connected to the wastewater supply pipe, And a guide tube coupled to a lower portion of the bending tube and having a spiral guide collar formed on an inner circumferential surface thereof; an extension tube coupled to a lower portion of the guide tube and extending in the bottom direction of the color processing vessel; And protruding ribs formed on the inner circumferential surface of the extension pipe so as to protrude at a predetermined interval to delay the flow of the wastewater passing through the extension pipe.

And a cooling unit for lowering the temperature of the wastewater flowing into the chromaticity treatment tank to increase the holding power of the ozone bubbles in the wastewater.

The cooling unit may include a coin pipe installed inside the chromaticity treatment tank to surround the extension pipe and through which cooling water flows, a cooling water circulation pipe connected to both ends of the coin pipe, and a cooler connected to the cooling water circulation pipe to cool the cooling water do.

And ultraviolet treatment means for irradiating ultraviolet rays to the wastewater that stays inside the chromaticity treatment tank.

The ozone bubble forming means includes a transfer pump installed in the wastewater supply pipe for transferring wastewater, an ozone supply unit for injecting ozone into the waste water supply pipe, and an ozone supply unit installed in the waste water supply pipe, And a fine bubble generator that generates fine ozone bubbles.

Wherein the micro bubble generator includes a center portion in which an inflow path for introducing the wastewater into which the ozone is injected is formed and a side of which is formed with an exhaust port connected to the inflow path, A collision cover provided between the impact surface and the center portion and having a swirling space portion for pivoting the wastewater colliding with the impact surface about the center portion; And a housing coupled to the impact cover at the outside of the impact cover and inserted into a discharge path formed at the other side of the center portion.

As described above, the present invention can effectively improve the chromaticity of wastewater by forming fine ozone bubbles in the wastewater to improve the contact efficiency between the wastewater and ozone.

FIG. 1 is a configuration diagram showing a configuration of an apparatus for processing a color of a wastewater according to an embodiment of the present invention,
FIG. 2 is a cross-sectional view showing the inside of the chromaticity treating tank applied to FIG. 1,
3 is a cross-sectional view of the waste water inflow means installed in the chromaticity treatment tank applied to FIG. 1,
FIG. 4 is an exploded perspective view of the microbubble generator of FIG. 1,
Fig. 5 is a cross-sectional view of Fig. 4,
FIG. 6 is an excerpted cross-sectional view showing the main part of FIG. 4,
7 is a sectional view showing the operation of Fig. 4,
FIG. 8 is a block diagram showing a configuration of an apparatus for processing a color of a wastewater according to another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an apparatus for processing a color of a wastewater according to the present invention will be described in detail with reference to the accompanying drawings.

1 to 7, the apparatus for treating color of wastewater according to the present invention comprises a chromaticity treating tank 100, waste water inflow means for introducing waste water into the interior of the coloring treatment tank 100, To the waste water storage tank 1, and ozone bubble forming means for forming ozone bubbles in the wastewater.

The chromaticity treating tank 100 is hollow and has a vertically long shape. The chromaticity treating tank 100 may be formed in a cylindrical shape. An exhaust valve 107 is installed in the upper portion of the chromaticity treating tank 100 so that ozone undissolved in waste water can be discharged.

The chromaticity treating tank 100 may be formed of two parts, that is, an upper casing 101 and a lower casing 105. The upper casing 101 and the lower casing 105 are coupled to each other by a flange 103.

The chromaticity treating tank 100 is installed on the base table 90. A caster 95 is installed on the lower portion of the base table 90 so as to be movable.

The wastewater stored in the wastewater storage tank 1 flows into the chromaticity treatment tank 100.

A predetermined amount of wastewater is stored in the wastewater storage tank (1). The wastewater stored in the wastewater storage tank 1 flows into the chromaticity treatment tank 100 and the wastewater discharged from the chromaticity treatment tank 100 flows into the wastewater storage tank 1 again. Thus, the waste water is circulated continuously through the waste water storage tank 1 and the coloring treatment tank 100, and the chromogenic material is removed by the ozone. The finally treated wastewater can be discharged through the drain pipe 4. When the wastewater is discharged to the outside through the drain pipe 4, a certain amount of wastewater flows into the wastewater storage tank 1 through the wastewater replenishment pipe 2 to be replenished.

The wastewater stored in the wastewater storage tank (1) is discharged through the wastewater supply pipe (3) and flows into the chromaticity treatment tank.

The waste water supply pipe 3 is provided with a valve 5 for opening and closing the pipe.

The ozone bubble forming means forms ozone bubbles in the wastewater flowing through the wastewater supply pipe.

The ozone bubble forming means includes a transfer pump 7 installed in the waste water supply pipe 3 for transferring waste water, an ozone supply unit for injecting ozone into the waste water supply pipe 3, And a fine bubble generator (15) for generating minute ozone bubbles in the wastewater.

The ozone supply unit includes an ozone injection pipe 9 connected to the waste water supply pipe 3 and an ozone generator 8 connected to the ozone injection pipe 9 to supply ozone.

The ozone generator 8 injects ozone into the waste water supply pipe 3 through the ozone injection pipe 9.

The wastewater containing ozone is mixed with the gas being finely crushed while passing through the impeller of the transfer pump 7 and introduced into the fine bubble generator 15.

The fine bubble generator 15 is installed in the wastewater supply pipe 3 and functions to generate minute ozone bubbles in the wastewater containing ozone. The ozone bubbles generated in the microbubble generator 10 have a micrometer or nanometer size.

The illustrated fine bubble generator 15 includes a center portion 20 having an inflow passage 21 into which wastewater flows and having an injection port 27 connected to the inflow passage 21 at a side thereof, A bomb that is formed in the wastewater that has passed through the bombardment cover 50 to a micrometer or a nano- And a housing 70 formed in a meter size.

The micro bubble generator 15 can regulate the size of the bubble to a micrometer or a nanometer level and can stably maintain the generated bubble in the liquid phase for a long time.

The center portion 20 includes a body 30 coupled to the impact cover 50, an interference head 40 formed at the end of the body 30 to interfere with the flow of the mixed liquid passing through the discharge path 71, And an inclined groove 45 formed at an outer side of the interference head 40 so as to be inclined at regular intervals.

The body 30 includes a threaded portion 31 having a thread formed on the outer circumferential surface thereof, a first tapered portion 33 extending from the upper portion of the threaded portion 31 and having a gradually smaller diameter, And a second tapered portion 37 extending from the upper portion of the intermediate portion 35 and having a gradually increasing diameter. The intermediate portion 35 is formed to extend from the upper portion to be spaced from the inner circumferential surface of the impact cover 50.

The interference head 40 is formed on the upper portion of the second tapered portion 37. The interference head 40 is formed to be larger than the upper diameter of the second tapered portion 37.

A plurality of oblique grooves 45 are formed outside the interference head 40. The inclined grooves 45 are formed to be inclined in a predetermined direction. By this inclined groove 45, the swirling flow of the wastewater passing around the interference head 40 can be accelerated. The size of the bubble formed according to the width and depth of the inclined groove 45 can be adjusted. For example, if the width of the oblique groove 45 is narrow and the depth is low, more fine bubbles are formed. When the width of the oblique groove 45 is wide and the depth is deep, a larger bubble is formed.

In the center portion 20, an inflow path 21 through which wastewater containing ozone flows is formed. In the illustrated example, the inflow path 21 is formed at the lower portion of the screw portion 31 and extends a certain length in the upward direction. Therefore, the lower portion of the center portion 20 serves as an inlet of the inflow passage 21. [ The first circulation pipe (160) is connected to the inlet of the inflow path (21). The inflow path 21 extends to the intermediate height of the intermediate portion 35.

The inflow channel 21 has a reduced diameter portion 23 whose diameter gradually decreases as the distance from the inlet formed at the lower portion of the threaded portion 31 and an enlarged diameter portion 23 formed to extend from the reduced diameter portion 21, 25).

Two outlets 27 are formed on the side surface of the intermediate portion 35 so that the wastewater flowing into the inflow path 21 can be ejected to the outside of the center portion 20. The jet port 27 is formed to be connected to the inflow path 21 through the side surface of the intermediate portion 35. The jet port 27 is formed in an oblique direction so that the wastewater, which is preferably jetted, can be pivoted in the swirl space portion 55 to be described later. 6, the jet port 27 is formed so as to penetrate from the outer side to the inner side of the intermediate portion 35 and to penetrate in a direction deviating from the center A of the inflow path 21. As shown in FIG.

In the illustrated example, two air outlets 27 are formed, but it is needless to say that one or more air outlets 27 may be formed.

The wastewater flowing into the inflow passage 21 of the center portion 20 passes through the reduced diameter portion 23 and speeds up. And collides first with the end of the elongated portion 25 and returns and is ejected at a high speed through the ejection port 27. [ At this time, the wastewater ejected through the jet port 27 collides with the impact surface of the impact cover 50, and bubbles in the wastewater are finely split in this process. The impact surface of the impact cover 50 means the inner surface of the impact cover 50.

The impact cover 50 is coupled to one side of the center portion 20 from the outside of the center portion 20 and has a swirling space portion 55 ).

The impact cover 50 includes a body 60 having a screw thread formed on an inner circumferential surface thereof and threaded to be screwed to the housing 70 on the outer circumferential surface thereof and a body 60 extending from the body 60, (60) having an outer diameter smaller than the outer diameter of the shaft portion (60).

The screw portion 31 of the center portion 20 is inserted and screwed into the inside of the body 60. A swirling space portion 55 is formed inside the shaft portion 65. The inner diameter of the shaft portion (65) is formed to be larger than the outer diameter of the body (30). A mounting groove is formed on the outer peripheral surface of the shaft portion 65, and a sealing member 67 for holding the airtightness is mounted in the mounting groove.

Since the upper portion of the center portion 20 is formed higher than the upper portion of the impact cover 50, the interference head 40 of the center portion 20, Lt; / RTI >

The housing 70 is engaged with the impact cover 50 outside the impact cover 50. A discharge passage (71) is formed inside the housing (70). The interference head of the center portion 20 is inserted into the discharge passage 71.

The housing 70 includes a skirt portion 80 having a thread formed on an inner peripheral surface thereof and screwed to the body portion 60 and a conical portion 83 formed on the skirt portion 80 and having a gradually smaller outer diameter And a joint portion 85 formed on the conical portion 83. A second circulation pipe (163) is connected to the joint part (85). The wastewater having fine ozone bubbles is discharged to the second circulation pipe 163 through the joint portion 85.

The discharge passage 71 formed inside the housing 70 includes a connection passage 73 connected to the swivel space portion 55 and a connection passage 73 extending upwardly from the connection passage 73 to surround the interference head 40, An intermediate passage 75 whose diameter progressively decreases as it advances, and a discharge passage 77 extending upward from the intermediate passage 75. A concavo-convex portion may be formed on the inner circumferential surface of the housing 70, which is not shown but is in contact with the intermediate passage 75. The concavo-convex portion can form a fine vortex in the wastewater passing through the intermediate passage (75), thereby increasing the effect of generating fine bubbles.

The housing 70, which is screwed to the impact cover 50, is movable up and down according to the rotation direction. 5, the interference head 40 and the inner peripheral surface of the housing 70 are spaced apart from each other by a predetermined distance in a state where the interference head 40 is positioned below the intermediate passage 75. [ 7, when the housing 70 is moved downwardly as shown in FIG. 7, the interference head 40 is positioned above the intermediate passage 75 and the interference head 40 and the housing 70 70 are narrowed. By moving the housing 70 up and down as described above, the gap between the interference head 40 and the inner circumferential surface of the housing 70 is widened or narrowed so that the size of the bubble is reduced to a nanometer level (1 to 1000 nm) . That is, when the distance between the interference head 40 and the inner circumferential surface of the housing 70 is increased, micrometer-level bubbles are formed. When the distance between the interference head 40 and the inner circumferential surface of the housing 70 is narrowed, .

Thus, the micro-bubble generator 15 can adjust the size of the ozone bubbles to the micrometer or nanometer level.

The wastewater from which the ozone bubbles are generated while passing through the fine bubble generator 15 flows into the coloring treatment tank 100 through the wastewater inflow means.

The wastewater inflow means includes a bending tube 110 connected to the wastewater supply pipe 3 and extending from the outside of the coloring treatment tank 100 to the inside and bent downward, An extension tube 115 coupled to the lower portion of the tube tube 111 to extend in the bottom direction of the coloring treatment tank 100 and a plurality And protruding ribs 117 protruding at regular intervals to delay the flow of the wastewater passing through the extension pipe 115.

The lower end of the extension pipe 115 is spaced a certain distance from the bottom of the chromaticity treatment tank 100.

The wastewater flowing into the bending tube 110 is passed through the guide tube 111, and a swirling flow is formed by the guide vanes 113 to disperse the ozone bubbles evenly into the wastewater. The wastewater that has passed through the line pipe (111) flows into the extension pipe (115). The wastewater flowing into the extension pipe (115) moves downward along the flow path formed inside the extension pipe (115). At this time, since a plurality of protruding ribs 117 are formed on the inner circumferential surface of the extension pipe 115, the flow of the wastewater is delayed due to a large number of vortexes. Accordingly, the number of contact between the ozone bubbles and the wastewater increases, and the decomposition of organic matter by ozone can be greatly improved.

The wastewater circulation part circulates the wastewater flowing into the coloring treatment tank 100 to the wastewater storage tank 1 through the inlet means.

The illustrated wastewater circulation section comprises a wastewater circulation pipe 10 connecting the chromaticity treatment tank 100 and the wastewater storage tank 1 and a pump 11 installed in the wastewater circulation pipe 10. The waste water circulation pipe (10) is provided with a valve (13) for opening and closing the pipe.

The waste water is continuously circulated through the waste water storage tank 1 and the coloring treatment tank 100 through the waste water circulation unit. The wastewater circulates, and the chromogenic material in the wastewater is effectively decomposed by the strong oxidizing power of ozone.

The present invention may further include a cooling unit 120 for lowering the temperature of the wastewater flowing into the chromaticity treatment tank 100 to increase the holding power of ozone bubbles in the wastewater.

The cooling unit 120 includes a coin pipe 121 installed inside the chromaticity treatment tank 100 to enclose the extension pipe 115 and a cooling water circulation pipe 123 connected to both ends of the coin pipe 121, And a cooler 122 connected to the cooling water circulation pipe 123 to cool the cooling water. The circulation pump 125 and the valve 127 are installed in the cooling water circulation pipe 123.

A typical refrigeration cycle can be applied to the chiller.

In another embodiment of the present invention, ultraviolet processing means may be further provided.

Referring to FIG. 8, the present invention further includes ultraviolet treatment means 130 for irradiating ultraviolet rays to the wastewater staying inside the chromaticity treatment tank 100.

The illustrated ultraviolet treatment means 130 includes a cylindrical optical chamber 131 provided in the base table 90 and a first connection pipe 135 connecting the lower portion of the optical chamber 131 and the chromaticity treatment tank 100, A second connection pipe 137 for connecting the upper part of the optical chamber 131 to the chromaticity treatment tank 100 and a second connection pipe 137 installed inside the optical chamber 131 to supply ultraviolet rays to the wastewater passing through the optical chamber 131 (Not shown) for irradiating ultraviolet rays.

The wastewater that stays inside the chromaticity treatment tank circulates through the optical chamber 131 and ultraviolet rays are irradiated while circulating through the optical chamber 131 to decompose and treat various organic substances in the wastewater. The oxidation treatment of organic substances by the AOP (Advanced Oxidation Process) method is effective for chromaticity treatment together with ozone.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation. Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

1: Wastewater storage tank 3: Wastewater supply pipe
7: Transfer pump 8: Ozone generator
15: fine bubble generator 100: chromaticity treatment tank
111: Sun Hall 115:
122: cooler

Claims (6)

A base table provided with a caster;
A tubular chromaticity treating vessel installed on the base table and having an interior hollow and formed vertically up and down;
A wastewater inflow means installed in the chromaticity treatment tank for introducing the wastewater stored in the wastewater storage tank into the interior of the chromaticity treatment tank;
A wastewater circulation unit for circulating wastewater flowing into the chromaticity treatment tank to the wastewater storage tank;
And ozone bubble forming means for forming ozone bubbles in the wastewater flowing through the wastewater supply pipe connecting the wastewater storage tank and the wastewater inflow means,
The wastewater inflow means comprises a bending tube connected to the wastewater supply pipe and extending from the outside of the chromaticity treatment tank to the inside and bent downward, a wire tube coupled to a lower portion of the bending tube and having a helical guiding collar on an inner circumferential surface thereof, And a plurality of projecting ribs formed on the inner circumferential surface of the extension pipe so as to protrude at a predetermined interval to delay the flow of the wastewater passing through the extension pipe,
And a cooling unit for lowering the temperature of the wastewater flowing into the chromaticity treatment tank to increase the holding power of ozone bubbles in the wastewater,
The cooling unit may include a coin pipe installed inside the chromaticity treatment tank to surround the extension pipe and through which cooling water flows, a cooling water circulation pipe connected to both ends of the coin pipe, and a cooler connected to the cooling water circulation pipe to cool the cooling water In addition,
Further comprising ultraviolet treatment means for irradiating ultraviolet rays to the wastewater staying inside the chromaticity treatment tank,
The ultraviolet processing means includes a cylindrical optical chamber provided in the base table, a first connection pipe connecting the lower portion of the optical chamber to the chromaticity treatment tank, and a second connection pipe connecting the upper portion of the optical chamber and the chromaticity treatment tank. And an ultraviolet lamp that is installed inside the optical chamber and emits ultraviolet rays to the wastewater passing through the optical chamber. delete delete delete The ozone generator according to claim 1, wherein the ozone bubble forming means comprises: a transfer pump installed in the waste water supply pipe for transferring wastewater; an ozone supply unit for injecting ozone into the waste water supply pipe; And a fine bubble generator for generating fine ozone bubbles in the wastewater while passing the wastewater. The ozone generator according to claim 5, wherein the microbubble generator comprises: a center portion having an inlet path through which the wastewater into which the ozone is injected is formed and a side surface formed with an outlet port connected to the inlet path; And an impingement surface coupled to one side of the impingement surface is formed on the inner side and between the impingement surface and the center portion, wastewater colliding with the impingement surface is pivotally moved about the center portion, And a housing coupled to the impact cover outside the impact cover, the housing being inserted into a discharge passage formed on the other side of the center portion.

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