KR20110010501U - Apparatus for cleaning waste water - Google Patents

Abstract

The present invention relates to a wastewater purification apparatus containing various hardly decomposable harmful substances such as dioxins, and more particularly, disinfects ozone in wastewater and supplies it to a reaction tube while sterilizing the oxide material and organic substances by ozone. And the step of treating dioxins and residual organic substances by the oxidation by hydrogen peroxide (H 2 O 2) injection, and the step of treating by wastewater and redox by electrolysis while moving the waste water up and down between the electrode plates in the prior art. Compared with the treatment of wastewater by ozone and ultraviolet lamps, it is economical and more effective in treating various hardly decomposable hazardous substances in the wastewater to effectively improve various water environments.

Description

Wastewater treatment device containing hardly degradable harmful substances {APPARATUS FOR CLEANING WASTE WATER}

The present invention relates to a device for purifying wastewater containing various hardly decomposable toxic substances such as dioxins, and more particularly, disinfects ozone in wastewater and supplies it to the reaction tube while sterilizing oxides and organic substances by ozone. And the step of treating dioxins and residual organic substances by the oxidation by hydrogen peroxide (H 2 O 2) injection, and the step of treating the waste water by electrolytic sterilization and redox while moving the waste water up and down between the electrode plates. The present invention relates to a wastewater treatment apparatus including a hardly decomposable toxic substance that maximizes the improvement of water quality by economically and effectively treating the hardly degradable toxic substance of the waste water.

With industrial development, environmental pollution, especially water pollution, has become a serious problem for mankind.

In the water pollution, treatment of various hardly decomposable harmful substances such as dioxins, among others, is very serious.

Various treatment apparatuses have been known to solve this problem. For example, as disclosed in Korean Patent Publication No. 2001-0089727, wastewater containing harmful substances such as dioxin is contacted with microbubble ozone to oxidatively decompose harmful substances. The wastewater containing residual ozone is irradiated with ultraviolet rays.

However, this conventional method oxidizes harmful substances by simply contacting the waste water with ozone, so that ozone is not dissolved and reacts evenly in the waste water, and thus the degradation efficiency of dioxins or other harmful substances decreases, and when treated by UV irradiation. Since ultraviolet rays are not evenly penetrated into the wastewater by bubbles or foreign substances, there is a problem in that the decomposition efficiency of dioxins or other harmful substances is lowered.

In addition, the ultraviolet irradiation method by the conventional ultraviolet lamp, there is a non-economical problem that the cost of using wastewater treatment as well as the inconvenience of using, such as replacement of the ultraviolet lamp.

The present invention is designed to solve the problems of the prior art as described above, and aims to maximize water quality by economically and effectively treating various hardly decomposable toxic substances such as dioxins contained in the waste water.

In other words, by dissolving and supplying ozone to the wastewater, the process of sterilization of oxidized substances and organic substances by ozone, oxidation process by injecting hydrogen peroxide (H2O2), treatment of dioxins and residual organic substances, and electrolysis by electrode plate Since the treatment step is repeated by sterilization and redox, the purpose is to maximize the improvement of water quality by economically and effectively removing the hardly decomposable harmful substances in the wastewater.

The present invention has a primary reaction tube for primary reaction treatment by ozone under the ejector dissolving and supplying ozone to the waste water transported by a pump, and a secondary reaction tube for secondary reaction treatment by hydrogen peroxide injection. Equipped; The reaction vessel installed below the first and second reaction tubes has a cylindrical primary partition wall outside the reaction tube so that the wastewater passing through the reaction pipe is directed upwardly to the first moving path, and the primary tank outside the primary partition wall. The wastewater overflowed from the bulkhead is directed downward to the second channel, and then upwardly directed to the third channel through the lower gap and protrudes upward from the primary bulkhead between the primary bulkhead and the reaction tank so as to be discharged to the outlet of one side. It is provided with a secondary partition of the cylindrical form; The primary and secondary partitions are characterized in that they are formed of an electrode plate electrically connected to the rectifier so that the wastewater guided to the first, second, and third moving paths is subjected to the tertiary reaction by electrolysis.

In the upper part of the secondary reaction tube of the present invention, while having a narrow guide of the diameter of the reaction tube to form at least one protrusion continuously protruding up and down to the inner wall surface further comprises a micro-bubble portion to finely split the ozone particles by collision have.

The inner wall surface of the primary partition wall and the outer periphery of the secondary reaction tube is characterized by forming a plurality of wing blades for vortex generation in the upflow wastewater.

The present invention dissolves ozone in wastewater containing various hardly decomposable harmful substances such as dioxins, and supplies it to the reaction tube while sterilizing the oxide material and organic substances by ozone, and oxidizing by hydrogen peroxide (H2O2) injection. Dioxin, residual organic material treatment step, and the waste water is moved up and down between the reaction plate and the electrode plate, and the treatment step by the electrolysis sterilization and redox effect is repeated to economically and effectively treat the non-degradable harmful substances of the waste water. It will have the effect of maximizing the improvement of the cause of environmental pollution.

1 is a cross-sectional configuration of the present invention.
Figure 2 is a cross-sectional configuration of the present invention.
Figure 3 is an enlarged view showing the microbubble generating portion of the secondary reaction tube of the present invention.
Figure 4 is a front cross-sectional view showing another embodiment of the present invention.
5 is a state diagram used in the present invention.

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

The wastewater treatment apparatus including the hazardous substance of the present invention, as shown in FIGS. 1 to 3, is primarily discharged by ozone to the lower part of the ejector 10 that dissolves and supplies ozone to wastewater transported by a pump (not shown). A primary reaction tube 11 for reaction treatment and a secondary reaction tube 21 for secondary reaction treatment by hydrogen peroxide injection,

The reaction tank 50 installed below the first and second reaction tubes 11 and 21 has a cylindrical primary shape outside the reaction tube so that the wastewater passing through the reaction tube is directed upwardly to the first moving path 101. After the bulkhead 51 and the wastewater overflowed from the primary bulkhead outside the primary bulkhead are directed downward to the second moving path 102, the bulkhead 51 is returned to the third moving path 103 through the lower gap 53. It is provided with a cylindrical secondary partition wall 52 protruding upward than the primary partition wall between the primary partition and the reaction tank so as to be discharged upstream and discharged to the outlet 55 of one upper portion,

The first and second partition walls 51 and 52 may be formed of electrode plates electrically connected to a rectifier (not shown) to discharge wastewater guided to the first, second, and third moving paths 101, 102, and 103. And tertiary reaction treatment by electrolysis.

That is, in the first reaction tube 11, ozone reacts with the oxidized substances and organic substances in the waste water to perform sterilization treatment. In the second reaction tube 21, ozone is converted into OH radicals by hydrogen peroxide (H2O2). While forming, a process of reacting and removing dioxin or residual organic material by oxidizing OH radicals is performed. In the third reaction tank 50, the dioxin or residual organic material is reacted again by redox reaction by electrolysis. At the same time, the sterilization process is repeated.

At this time, the upper part of the secondary reaction tube 21 to guide the narrow diameter of the reaction tube while forming at least one protrusion (26) protruding upward and downward continuously to the inner wall surface to finely split the ozone particles by collision ( 25) is further provided.

In addition, at the inner wall surface of the primary partition wall 51 and the outer periphery of the secondary reaction tube 21, a plurality of wing blades 54 for vortex generation are formed in the wastewater moving upwardly to the first moving path 101. It is configured by.

In addition, the present invention may be implemented differently as shown in Figure 4, the primary partition 51 ', which is compared with the above-described embodiment to form the primary partition 51' in the cylindrical, but Is formed to have an inclined portion 51'-1, the diameter of which narrows toward the upper portion.

As the reference numerals, 8 denotes an injection hole for injecting ozone into the ejector 10, and 22 denotes an injection hole for injecting hydrogen peroxide water.

Next will be a look at the operation and action of the subject innovation configured as described above.

The device of the present invention is installed and used to purify wastewater containing various hardly decomposable harmful substances such as dioxins, but may be installed or used with a separate treatment facility such as a virtual negative pressure tank or a flocculation tank.

Hereinafter, with reference to the apparatus of the present invention, the waste water is first transported by a pump (not shown) and supplied to the ejector 10, so that ozone is sucked and dissolved by the flow rate pressure of the waste water.

As such, the ozone-dissolved wastewater passes through the primary reaction tube 10, and ozone reacts with the oxidized substances and organic substances in the wastewater to perform sterilization treatment.

As described above, the wastewater passing through the primary reaction tube 11 flows into the secondary reaction tube 21 and guides the diameter of the reaction tube narrowly to continuously form the plurality of protrusions 26 protruding upward and downward on the inner wall. The ozone particles (bubbles) collide with each other at the plurality of projections (25), so that the process is evenly distributed in the waste water.

As such, the wastewater that has passed through the microbubble portion 25 undergoes a treatment process in which ozone reacts with hydrogen peroxide water by injecting hydrogen peroxide to form OH radicals and reacts with dioxins or residual organic substances by oxidizing OH radicals to remove them. do.

At this time, the ozone is distributed evenly in the waste water while passing through the microbubble portion 25 to maximize the oxidation of the OH radicals to perform the treatment efficiency excellently.

As such, the wastewater passing through the secondary reaction tube 21 enters the reactor 50 and hits the bottom of the reactor, and then guides upward flow through the first moving path 101 between the primary partition 51 and the reaction. And overflowed from the primary partition wall 51 and guided downward through the second moving path 102 between the primary partition wall 51 and the secondary partition wall 52, and a lower gap of the secondary partition wall 52. Through the 53 to be guided upward flow through the third moving path 103 between the secondary partition 52 and the reaction vessel is to be discharged to the discharge port (55).

In particular, the wastewater is the primary, secondary diaphragm 51 formed of an electrode plate electrically connected to a rectifier (not shown) via the first, second, third moving paths 101, 102, 103 by zigzag up and down. By the redox effect of the electrolysis of) 52, the dioxin or the remaining organic substance is reacted again and removed, and at the same time, the sterilization treatment is repeated.

In addition, by the electrolysis by the primary and secondary diaphragms 51 and 52 will also remove harmful substances such as nitrogen contained in the waste water.

Furthermore, in the first moving path 101, a plurality of vanes 54 are formed on the inner wall surface of the primary partition wall 51 and the outer periphery of the secondary reaction tube 21, so that the vortex of the wastewater moving upwardly. Mixing with the generation will further maximize the treatment efficiency by the above-mentioned electrolysis and other ozone.

In addition, since the primary partition wall 51 'is formed to have an inclined portion 51'-1, the diameter of which narrows from the lower portion to the upper portion as shown in FIG. 4, mutual contact and mixing due to the residence time of the wastewater or the generation of vortices. By further improving the treatment efficiency by the above-mentioned electrolysis and other ozone will be further maximized.

Therefore, the device of the present invention dissolves and supplies ozone to the wastewater, and sterilizes the oxidized substances and organic substances by ozone, and the dioxins and residual organic substance treatment steps by the oxidation by hydrogen peroxide (H2O2) injection, and the electrode plate. Since the treatment step by the sterilization and redox effect is repeated by electrolysis by the electrolysis, it is more economical than the conventional treatment of wastewater by ozone and ultraviolet lamp, and more effectively removes the hardly decomposable harmful substances of the wastewater, thereby effectively improving the various water quality environment. You will have an advantage.

In addition, although the device of the present invention is not shown in the drawings, the first and second bulkheads inside the reactor 50 may be simply formed in the form of a partition without electrically connecting to a rectifier. Wastewater subjected to the first and second reaction treatments through the pipes 11 and 21 is guided through the first, second and third moving paths 101, 102 and 103 from the inside of the reaction tank 50 without electrolysis. Of course, it may be treated to be discharged to the outlet 55 through the secondary reaction and other precipitation, imparting process.

That is, in the same structure as in the above-described embodiment, the water quality is improved by treating the waste water to remove hardly decomposable harmful substances and other foreign substances by the simple structure excluding the treatment process by electrolysis.

10: ejector 11: primary reaction tube
21: secondary reaction tube 50: reactor
51,51 ': Primary bulkhead 52: Secondary bulkhead
53: lower clearance 55: outlet
25: microbubble portion 26: projection
54: wing blade 51'-1: ramp
101,102,103: 1st, 2nd, 3rd moving path

Claims (4)

Primary reaction tube 11 for primary reaction treatment with ozone to the lower part of ejector 10 for dissolving and supplying ozone to waste water transported by a pump, and secondary reaction tube for secondary reaction treatment by hydrogen peroxide injection. 21,
The reaction tank 50 installed below the first and second reaction tubes 11 and 21 has a cylindrical primary shape outside the reaction tube so that the wastewater passing through the reaction tube is directed upwardly to the first moving path 101. After the bulkhead 51 and the wastewater overflowed from the primary bulkhead outside the primary bulkhead are directed downward to the second moving path 102, the bulkhead 51 is returned to the third moving path 103 through the lower gap 53. It is provided with a cylindrical secondary partition wall 52 protruding upward than the primary partition wall between the primary partition and the reaction tank so as to be discharged upstream and discharged to the outlet 55 of one upper portion,
The first and second bulkheads 51 and 52 are formed of electrode plates electrically connected to the rectifier to electrolyze the wastewater guided to the first, second and third moving paths 101, 102 and 103 by electrolysis. Wastewater treatment apparatus comprising a non-degradable harmful substance characterized in that the third reaction treatment.
Primary reaction tube 11 for primary reaction treatment with ozone to the lower part of ejector 10 for dissolving and supplying ozone to waste water transported by a pump, and secondary reaction tube for secondary reaction treatment by hydrogen peroxide injection. 21,
The reaction tank 50 installed below the first and second reaction tubes 11 and 21 has a cylindrical primary shape outside the reaction tube so that the wastewater passing through the reaction tube is directed upwardly to the first moving path 101. After the bulkhead 51 and the wastewater overflowed from the primary bulkhead outside the primary bulkhead are directed downward to the second moving path 102, the bulkhead 51 is returned to the third moving path 103 through the lower gap 53. The first, second, and third traveling paths having a cylindrical secondary partition wall 52 protruding upward from the primary partition wall and between the primary partition wall and the reaction tank so as to be discharged upwardly and discharged to the discharge port 55 at one upper side thereof ( 101) (102) (103) wastewater treatment apparatus comprising a non-degradable harmful substances, characterized in that configured to third-treatment treatment of the wastewater.
The method according to claim 1 or 2,
At least one microbubble portion 25 is formed in the upper part of the secondary reaction tube 21 to guide the diameter of the reaction tube narrowly and protrude continuously up and down at least one or more projections 26 on the inner wall surface to finely split the ozone particles by collision. Waste water treatment apparatus comprising a non-degradable harmful substances characterized in that further comprising.
The method according to claim 1 or 2,
The inner wall surface of the primary partition wall 51 and the outer periphery of the secondary reaction tube 21 are formed by forming a plurality of vanes 54 for vortex generation in the wastewater moving upstream to the first moving path 101. Wastewater treatment apparatus comprising a difficult to decompose harmful substances.

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