KR102603704B1 - Apparatus for electro-coagulative treatment - Google Patents

Abstract

It relates to an electrocoagulation treatment device that reduces most of nitrate (NO3-) contained in wastewater to nitrogen gas, comprising: a reaction tank in which wastewater is received; An electrode plate mounted inside the reaction tank and performing an electrical reaction; and a contact part for applying direct current electricity to the electrode plates, wherein the plurality of electrode plates mounted on the reaction tank are alternately contacted with the (+) pole and the (-) pole, respectively, and between the plurality of electrode plates. One or more upper partition walls are formed so that waste water is transported through the lower part of the upper partition wall, and one or more lower partition walls are formed between the plurality of electrode plates so that waste water is transported through the upper part of the lower partition wall.
With this configuration, the electrical contactor is mounted in a concealed manner in the longitudinal direction of the mounting contact part, making it easy to maintain, have a clean appearance, and reduce the risk of electric shock, and the polarity of the electrode plate mounted on the reaction tank is This has the effect of maximizing the replacement cycle of the electrode plate.
In particular, the wastewater transported by the vortex path formed on the lower surface of the upper partition and the upper surface of the lower partition is mixed, thereby increasing the removal efficiency of nitrate nitrogen.

Description

Apparatus for electro-coagulative treatment}

The present invention relates to an electrocoagulation treatment device, and more specifically, to a device that can maximize the replacement cycle of electrode plates, efficiently remove nitrate nitrogen from wastewater, and especially facilitate the replacement of electrode plates. It relates to an electrocoagulation treatment device.

Recently, as urbanization and industrial advancement have progressed, the types of pollutants contained in discharged wastewater have become more diverse, and accordingly, various wastewater treatment methods are required to remove such pollutants. In particular, it is one of the contaminants that exist in water in the form of ammonia/ammonium, nitrite, nitrate, and organic nitrogen such as urea and amino acids. Nitrogen causes a deficiency of dissolved oxygen in water, causing eutrophication, red tide, fish toxins, etc.

Therefore, efforts are continuing to reduce the nitrogen content in wastewater to prevent the worsening and spread of water pollution.

As part of these efforts, a biological treatment method that uses microorganisms to decompose nitrate in wastewater is known, but this method has the problem of being very slow, difficult to control, and generating other organic products.

As another method, various chemical treatment methods are known to induce reduction of nitrate by adding chemicals. However, even when using this chemical method, a lot of time is consumed for the reduction reaction, it is difficult to obtain the desired reduction efficiency, and there is a risk that the total nitrogen content in water may increase due to unreacted amide added. In addition, such chemical treatment is economically undesirable because it requires a large installation space and a large amount of chemicals.

While there are expectations for a technology that can prevent water pollution by nutrient salts by treating nitrate more efficiently than the existing methods described above, a wastewater treatment method incorporating electrochemical treatment technology has recently been proposed.

The electrochemical treatment method refers to placing wastewater containing pollutants to be removed between an anode plate and a cathode plate and applying an electric current to induce an electrochemical reaction through the oxidation-reduction reaction of the electrode, thereby removing pollutants in the wastewater or making them harmless. It refers to a method of changing ingredients.

Document 1: Patent Publication No. 10-2013-0033804 (published on April 4, 2013) “Nitrogen and phosphorus removal device using electrocoagulation” Document 2: Public Patent Publication No. 10-2012-0021367 (published on March 9, 2012) “Wastewater treatment device using electrocoagulation” Document 3: Registered Patent Publication No. 10-1047890 (announced on July 8, 2011) “Flow rate reduction device for high-efficiency sedimentation in sewage and wastewater reaction tank and reaction tank using the same” Document 4: Patent Publication No. 10-2005-0104972 (published on November 3, 2005) “Sewage water treatment process using electrocoagulation dephosphorization and membrane separation activated sludge method and wastewater treatment device using the same”

However, since conventional electrocoagulation and electrooxidation facilities require separate replacement of electrode plates, there is the inconvenience of having to disconnect the electrical connection and reconnect after replacing the electrode plate each time it is replaced. In particular, the removal efficiency of nitrate nitrogen is low. There is a problem with it being low.

Therefore, the present invention was created to solve the problems described above, and the purpose of the present invention is to maximize the replacement cycle of the electrode plate, efficiently remove nitrate nitrogen from wastewater, and in particular, replace the electrode plate. It relates to an electrocoagulation treatment device that can be easily implemented.

The above object is achieved by the present invention, and an electrocoagulation treatment device according to one aspect of the present invention includes a reaction tank in which wastewater is received; An electrode plate mounted inside the reaction tank and performing an electrical reaction; and a main body that includes a contact part for applying direct current electricity to the electrode plate, wherein the reaction tank has an open top and closed sides and bottom to accommodate wastewater. It consists of a pair of mounting contact parts formed on both upper edges of the main body, and the electrode plate is made of a conductor; It consists of a holder mounted on the upper end of the electrode plate, and the contact part includes an electric contact member made of a conductor and mounted on the holder contact part; It consists of the stand to which electricity is applied by contacting the electric contact bulb, and the plurality of electrode plates mounted on the reaction tank are alternately contacted with the (+) pole and the (-) pole, respectively, and one side of the mounted electrode plate A wastewater passage through which wastewater is transported is formed at a certain distance between the edge and the inner surface of the reaction tank, and the wastewater passages formed by the electrode plate and the other adjacent electrode plate are formed to face each other, and a pair of the above An electrode change unit is installed to switch the (+) and (-) poles applied to each of the pair of electric contacts mounted on the mounting contact portion, and one or more upper partition walls are formed between the plurality of electrode plates. Wastewater is transported through the lower part of the upper partition, and one or more lower partitions are formed between the plurality of electrode plates so that wastewater is transported through the upper part of the lower partition, and the electrical contactor is hidden in the longitudinal direction of the mounting contact part. It is mounted so that a part is exposed and comes into contact with the holder to apply electricity, and a vortex path is formed on the lower end of the upper partition and the upper surface of the lower partition, respectively, and the upper and lower partitions are connected to the main body. A pair of mounting contact parts that are respectively fixed and formed on both upper edges of the main body include a horizontal mounting contact plate that is bent outward from the edge of the main body and formed as one piece; It consists of a vertical mounting contact plate that protrudes downward from the horizontal mounting contact plate, the vertical mounting contact plate is formed to be spaced apart from the outer surface of the main body, and the electrical contact plate is connected to the horizontal mounting contact plate and the vertical mounting contact plate. Each of the electrode plates is embedded and connected to a contact plate, and the plurality of electrode plates are connected to the main body in a zigzag manner, so that the wastewater passage is also formed in a zigzag pattern, and the vortex path is formed by cutting a portion of a plane into a straight line, and the upper partition wall The vortex path formed on the lower end surface and the upper surface of the lower partition is characterized in that it is formed at an angle with the adjacent vortex path.

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According to the above-mentioned configuration of the present invention, the electrical contactor is mounted in a concealed manner in the longitudinal direction of the mounting contact part, and a portion is exposed and comes into contact with the holder to apply electricity, so it is easy to maintain, has a clean appearance, and prevents electric shock. It has the effect of reducing the risk.

In addition, since the plurality of electrode plates mounted on the reaction tank are alternately contacted with the (+) pole and the (-) pole, respectively, the polarity of the electrode plate mounted on the reaction tank changes, thereby maximizing the replacement cycle of the electrode plate. It has an effect that extends to .

In particular, the wastewater transported by the vortex path formed on the lower surface of the upper partition and the upper surface of the lower partition is mixed, thereby increasing the removal efficiency of nitrate nitrogen.

1 is a perspective view of an electrocoagulation treatment device according to an embodiment of the present invention.
Figure 2 is a cross-sectional view of the electrocoagulation treatment device shown in Figure 1.
Figure 3 is a cross-sectional view of an electrocoagulation treatment device according to another embodiment of the present invention.
Figure 4 is a partially cut away perspective view of the lower bulkhead shown in Figure 3.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, and like reference numerals will be used for like parts throughout the drawings.

The features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings. Prior to this, terms or words used in this specification and claims should not be construed in their usual, dictionary meaning, and the inventor may appropriately define the concept of the term in order to explain his or her invention in the best way. It must be interpreted with meaning and concept consistent with the technical idea of the present invention based on the principle that it is.

Figures 1 and 2 are a perspective view and a cross-sectional view of an electrocoagulation treatment device according to an embodiment of the present invention.

As shown in the drawing, the electrocoagulation treatment device according to the present invention, denoted by reference numeral 10, consists of a reaction tank 20, an electrode plate 30, and a contact part.

The reaction tank 20, which has an open top, accommodates wastewater, and the electrode plate 30 is mounted inside the reaction tank 20 containing the wastewater to perform an electrical reaction.

The contact part refers to a part where electricity is contacted, and direct current electricity supplied from the outside is applied to the electrode plate 30.

The contact portion is formed on both upper edges of the main body 21 of the reaction tank 20, and refers to each portion where the electric contact bulb 25 and the holder 33, which will be described later, come into contact.

This electrocoagulation treatment device 10 allows wastewater to flow in the main body 21 of the reaction tank 20, and a (-) electric current is applied to the cathode plate by the contact portion on one side of the main body 21. When electrolysis is performed by supplying (+) current to the positive electrode plate by the contact part from the other side of the main body 21, most of the nitrate (NO3-) contained in the wastewater is converted to nitrogen gas. It is removed by reduction or precipitation with metal salts.

And the electrode plate 30 is composed of an electrode plate 31 made of a conductor and a holder 33 mounted on the upper end of the electrode plate 31. The holder 33 is formed integrally with the electrode plate 31. It may be formed by fixing separate parts.

As shown in FIG. 2, the contact part is mounted on the stand contact part 23 and includes an electric contact bulb 25 made of a conductor, and the stand 33 to which electricity is applied by contacting the electric contact bulb 25. ).

That is, the holder 33 is made of a conductor because it is electrically connected to the electric contact bulb 25 and the electrode plate 31.

In addition, as shown in the drawing, the holder 33 is formed to protrude to one side from the top of the electrode plate 31 and comes into contact with the electrical contact bulb 25.

In addition, the electric contact bulb 25 is mounted in a concealed manner in the longitudinal direction of the mount contact portion 23, and a portion is exposed and comes into contact with the holder 33 so that electricity is applied.
That is, the mounting contact portion 23 is formed on both upper edges of the main body 21, and includes a horizontal mounting contact plate 23a and a horizontal mounting contact plate 23a that is bent outward from the edge of the main body 21 and formed as one piece. It consists of a vertical mounting contact plate (23b) that protrudes downward from the mounting contact plate (23a). Accordingly, the vertical contact plate 23b is formed to be spaced apart from the outer surface of the main body 21 (see Figure 2).
The electrical contactor 25 is embedded and connected to the horizontal contact plate 23a and the vertical contact plate 23b, respectively.

This configuration makes it easy to maintain, has a clean appearance, and reduces the risk of electric shock.

Additionally, the plurality of electrode plates 30 mounted on the reaction tank 20 may be alternately contacted with the (+) pole and (-) pole, respectively.

An electrode change unit (not shown) that switches the (+) pole and (-) pole applied to the pair of electric contact bulbs 25 respectively mounted on the pair of stand contact parts 23 will be installed. You can. Accordingly, since the polarity of the electrode plate 30 mounted on the reaction tank 20 changes, the replacement cycle of the electrode plate 30 is extended to the maximum.

As shown in the drawing, a wastewater passage 50 through which wastewater is transported is formed at a certain distance between one edge of the mounted electrode plate 30 and the inner surface of the reaction tank 20, and the electrode plate ( The wastewater passage 50 formed by the other electrode plate 30 adjacent to 30 is formed to face each other.
Additionally, the plurality of electrode plates 30 are connected to the main body 21 in a zigzag manner. Accordingly, the wastewater passage 50 is also formed in a zigzag pattern.

Another embodiment of the present invention will be described with reference to FIGS. 3 and 4.

Figure 3 is a cross-sectional view of the electrocoagulation treatment device 10 according to another embodiment of the present invention, and Figure 4 is a partially cut away perspective view of the lower partition 73.

As shown in the figure, one or more upper partition walls 71 are additionally formed between the plurality of electrode plates 30 so that wastewater is transported through the lower part of the upper partition wall 71, and the plurality of electrode plates ( 30), one or more lower partition walls 73 are additionally formed so that wastewater is transported through the upper part of the lower partition wall 73.

Additionally, the upper partition 71 and the lower partition 73 may be respectively fixed to the main body 21.

As shown in FIG. 4, a vortex path 77 is additionally formed on the lower surface of the upper partition 71 and the upper surface of the lower partition 73.
The vortex path 77 is formed by cutting a portion of a plane into a straight line, and the vortex path 77 formed on the lower end surface of the upper partition 71 and the upper surface of the lower partition wall 73, respectively, is It is formed at an angle to the adjacent vortex path 77 (see Figure 4).
Since the wastewater transported by the adjacent vortex passage 77 is mixed, the removal efficiency of nitrate nitrogen is increased.

What has been described above is only one embodiment for carrying out the electrocoagulation treatment device 10 according to the present invention, and the present invention is not limited to the above-described embodiment, and as claimed in the claims below, the present invention Without departing from the gist, anyone with ordinary knowledge in the field to which the invention pertains will say that the technical idea of the present invention is to the extent that various modifications can be made.

10: Electrocoagulation treatment device 20; reaction tank
21: Main body 23: Mounting contact part
25: electric contact bulb 30: electrode plate
31: pole plate 33: stand
50: wastewater passage 71: upper bulkhead
73: lower bulkhead 77: vortex

Claims (11)

A reaction tank containing wastewater; An electrode plate mounted inside the reaction tank and performing an electrical reaction; And a contact part that applies direct current electricity to the electrode plate,
The reaction tank includes a main body that is open at the top and closed at the sides and bottom to accommodate wastewater; It consists of a pair of mounting contact parts formed on both upper edges of the main body,
The electrode plate includes an electrode plate made of a conductor; It consists of a stand mounted on the upper part of the electrode plate,
The contact unit includes an electric contact unit mounted on the stand contact unit and made of a conductor; It consists of the holder through which electricity is applied by contacting the electric contact bulb,
The plurality of electrode plates mounted on the reaction tank are alternately contacted with the (+) pole and (-) pole, respectively,
A wastewater passage through which wastewater is transported is formed at a certain distance between one edge of the mounted electrode plate and the inner surface of the reaction tank, and the wastewater passage formed by the other electrode plate adjacent to the electrode plate is opposed to the other electrode plate. formed,
An electrode change unit is installed to switch the (+) pole and (-) pole respectively applied to the pair of electric contact bulbs respectively mounted on the pair of mounting contact parts,
One or more upper partition walls are formed between the plurality of electrode plates so that waste water is transported through the lower part of the upper partition wall, and one or more lower partition walls are formed between the plurality of electrode plates so that waste water is transported through the upper part of the lower partition wall. And
The electric contact bulb is mounted in a concealed manner in the longitudinal direction of the stand contact part, and a portion is exposed and comes into contact with the stand to apply electricity,
A vortex path is formed on the lower surface of the upper bulkhead and the upper surface of the lower bulkhead, respectively,
The upper partition wall and the lower partition wall are each fixed to the main body,
A pair of mounting contact parts formed on both upper edges of the main body, respectively, include a horizontal mounting contact plate that is bent outward from the edge of the main body and formed as one piece; It consists of a vertical mounting contact plate that protrudes downward from the horizontal mounting contact plate, and the vertical mounting contact plate is formed to be spaced apart from the outer surface of the main body,
The electrical contact bulb is embedded and connected to the horizontal contact plate and the vertical contact plate, respectively,
The plurality of electrode plates are connected to the main body in a zigzag pattern, and the waste water passage is also formed in a zigzag pattern,
The vortex is formed by cutting a portion of a plane into a straight line,
An electrocoagulation treatment device, characterized in that the vortex path formed on the lower end surface of the upper partition and the upper surface of the lower partition wall is formed at an angle with respect to the adjacent vortex path. delete delete delete delete delete delete delete delete delete delete

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