KR101696062B1 - Apparatus for filtering of solution - Google Patents

Abstract

A solution filtering apparatus according to the present invention comprises: a circulation line connected to an electrolytic cleaning tank of an electrolytic cleaning line (ECL), for flowing out a cleaning solution from the electrolytic clean tank and re-introducing the cleaning solution; And a filtering means provided in the circulation line for separating and removing the iron particles contained in the cleaning solution by using a magnetic force, wherein the filtering means is provided in the circulation line, A separator for generating a magnetic force to separate the magnetic particles from each other; And a removing part connected to the separating part and removing the iron powder attached to the separating part when the magnetic force of the separating part is cut off.
As described above, according to the present invention, there is provided a circulation line for allowing the cleaning solution to flow out from the electrolytic clean tank, and filtering means provided in the circulation line for separating and removing the iron component contained in the cleaning solution by using the magnetic force, It is possible to prevent the re-contamination of the steel sheet due to the iron powder by effectively removing the iron powder contained in the iron powder and further removing the separated iron powder completely.

Description

Apparatus for filtering of solution

The present invention relates to a solution filtering apparatus, and more particularly, to a solution filtering apparatus for filtering iron contained in a cleaning solution in an electrolytic clean line.

Electrolytic Cleaning Line (ECL) generates fine bubbles in the cleaning solution (sodium hydroxide solution) by using the current flowing from the anode to the cathode in the electric cleaning tank (ECT) It is a facility that makes it possible to clean the surface of steel sheet.

In the electrolytic clean line, cleaning is performed using an alkaline solution as a cleaning solution in order to remove foreign substances on the surface of the steel sheet. In the cleaning process, iron ions on the surface of the steel plate are dissolved in the cleaning solution, Iron ions are reduced to produce iron particles and iron particles are generated.

In this electrolytic cleaning line, as shown in Fig. 1, a positive electrode 2a and a negative electrode 2b are provided in the electrolytic clean tank 2 so that a current flows.

When the current flows through the rectifier 3, a current flows into the anode 2a and the cathode 2b. At this time, the anode 2a and the cathode 2b, which have a narrow gap, A strong current flows through the portion facing the cathode 2b and a magnetic field (induction magnetic field) is formed at the corners of the anode 2a and the cathode 2b by the current flowing at this time and the iron powder contained in the cleaning solution is attached.

In this situation, the actual iron deposition may occur at the corners of the facing positive electrode 2a and the negative electrode 2b. However, due to the flow of the solution caused by the movement of the steel strip 1, More iron is attached to the edges.

If the iron is continuously adhered, the mass of the iron becomes larger and the oil and the various contaminants are clogged on the surface of the iron to cause a pollution-causing lump.

If such a lump grows larger, it will create a black stain on the steel plate 1, and as a result, it will act as a defective product of electroplating production.

Such problems are limited in the operation of the existing electrolytic clean line, and the difficulty in using the electroplated product causes the productivity of the electroplated product to deteriorate.

It is an object of the present invention to provide a solution filtering device which is developed to solve the above-mentioned problems, and which separates and further removes iron particles contained in a cleaning solution in an electrolytic clean line.

According to an aspect of the present invention, there is provided a solution filtering apparatus including: a transfer route for transferring a solution; And filtering means provided on the conveying route for separating and removing iron contained in the solution of the conveying route by using a magnetic force, wherein the filtering means is provided on the conveying route, A separator for generating a magnetic force for magnetically separating the iron powder; And a removing part connected to the separating part and removing the iron powder attached to the separating part when the magnetic force of the separating part is cut off.

At this time, the separator may include a case pipe disposed in a part of the circulation line; And an electromagnet mounted inside the casing tube, wherein the elimination unit is connected to the rear end of the casing tube so as to bypass the cleaning solution in the circulation line when the supply current of the electromagnet is blocked, The following bypass pipe; And a backwash filter mounted on the bypass pipe.

The removing unit may include: a control member electrically connected to the electromagnet to control a supply current of the electromagnet; A first valve mounted at a rear end of a connection portion between the case pipe and the bypass pipe, the first valve being electrically connected to the control member; And a second valve mounted at an inlet of the bypass pipe and electrically connected to the control member.

The separator may further include a guide pipe taperably mounted in the case pipe so as to guide the cleaning solution to the inner surface side of the case pipe in the reverse direction of the cleaning solution.

The filtering means may further include a screen member extending from an outer edge of the inlet of the guide tube to the inner surface of the case tube so as to filter foreign matter.

Further, the filtering means may be a permanent filter disposed in the bending portion where the cleaning solution collides in the circulation line at the rear end of the casing tube, so as to separate the iron powder not contained in the separation portion of the cleaning solution, And a re-separation unit having a magnet.

The filtering unit may further include a mesh filter disposed in the circulation line at the rear end of the casing tube so as to filter fine foreign matter.

On the other hand, the transfer route is a circulation line connected to an electrolytic cleaning tank of an electrolytic cleaning line (ECL) and flowing out the cleaning solution from the electrolytic cleaning tank, and the solution may be a cleaning solution .

Here, the electrolytic clean tank may include: a pair of positive and negative electrodes spaced apart from each other; And a pair of cathodes spaced apart from each other in the direction of movement of the steel plate from the anode to the cathode, wherein the circulation line is connected to the space between the anode and the cathode in the electrolytic clean tank .

The solution filtering apparatus according to the present invention comprises a circulation line for flowing out the cleaning solution from the electrolytic clean tank and introducing the cleaning solution back into the electrolytic clean tank and a filtering means provided on the circulation line for separating and removing the iron component contained in the cleaning solution by using the magnetic force , The iron powder contained in the cleaning solution is efficiently separated, and further, the separated iron powder is completely removed, thereby preventing re-contamination of the steel sheet due to iron powder.

1 is a schematic view showing a general electrolytic clean line;
FIG. 2 is a view showing a solution filtering apparatus according to an embodiment of the present invention disposed in the electrolytic clean line of FIG. 1;
FIG. 3 is a view showing the inside of the solution filtering apparatus of FIG. 2;
Fig. 4 is a right side view showing the separator in the solution filtering apparatus of Fig. 3; Fig.

Hereinafter, exemplary embodiments of the present invention will be described in detail. In the drawings, like reference numerals are used to refer to like elements throughout the drawings, even if they are shown on different drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

The present invention includes a conveying route for conveying a solution and a filtering means provided on a conveying route for separating and removing iron particles contained in a solution of the conveying route by using magnetic force.

When the present invention is applied to an electrolytic cleaning line as an embodiment, the transfer route is connected to an electrolytic cleaning tank of an electrolytic cleaning line (ECL) as a circulating line, and after the cleaning solution flows out from the electrolytic cleaning tank Re-inflows. Further, the solution is a cleaning solution.

FIG. 2 is a view showing a solution filtering apparatus according to an embodiment of the present invention disposed in the electrolytic clean line of FIG. 1, FIG. 3 is an internal view of the solution filtering apparatus of FIG. 2, FIG. 7 is a right side view showing a separation portion in a solution filtering apparatus. FIG.

Referring to the drawings, the present invention includes a circulation line CL connected to an electrolytic clean tank 2 and filtering means provided in the circulation line CL.

Here, the circulation line CL is connected to an electrolytic cleaning tank 2 (ECT) of an electrolytic clean line, and is configured to flow out the cleaning solution from the electrolytic clean tank 2 do.

Specifically, the circulation line CL sucks the cleaning solution from the electrolytic clean tank 2, passes through the inside of the electrolytic clean tank 2, and then flows into the circulation pump P to generate a circulation force for re- Of course.

This circulation line CL is a line that bypasses the cleaning solution in the electrolytic clean tank 2 in order to separate and remove the iron particles generated by dissolving the iron ions of the steel sheet 1 in the cleaning solution in the cleaning process.

The filtering means may be provided in the circulating line CL so that the circulating line CL separates and removes iron contained in the cleaning solution using magnetic force.

Specifically, the filtering unit may include a separation unit 10 provided in the circulation line CL and a removal unit 20 connected to the separation unit 10.

Here, the separator 10 is a portion that generates magnetic force to separate the iron powder contained in the cleaning solution by a magnetic force, and the removal unit 20 includes a separator 10, It is the part that removes the attached iron.

The separator 10 may include a casing 11 disposed in a part of the circulation line CL and an electromagnet 12 installed inside the casing 11.

First, the casing tube 11 may be made of a synthetic resin material to prevent the electromagnet 12 installed therein from being contaminated and to remove iron powder attached to the electromagnet 12 later. In addition, the casing tube 11 preferably has a cylindrical structure as in the overall cross-sectional structure of the circulation line CL for preventing foreign matter from being caught.

In addition, the electromagnet 12 is installed inside the casing tube 11, and a part of the electromagnet 12 extends outward to receive a current, and the magnitude of the magnetic force can be adjusted by adjusting the intensity of the electric current. The electromagnet 12 pulls the iron powder contained in the cleaning solution passing through the case tube 11 by a magnetic force, thereby separating the iron powder from the cleaning solution.

The separating unit 10 may further include a guide pipe 13 installed inside the case pipe 11 so as to form a double pipe structure together with the case pipe 11.

The guide pipe 13 can be tapered in the reverse direction of the cleaning solution in the case pipe 11 so that the cleaning solution is guided to the inner surface side of the case pipe 11. [

In other words, as the cleaning solution passes through the case tube 11, the distance from the center of the case tube 11 to the inner surface of the case tube 11 in which the electromagnet 12 is disposed is maintained at a certain distance, The guide tube 13 allows the cleaning solution to pass through the casing tube 11 while being guided to the inner surface side of the casing tube 11. [

The guide tube 13 is disposed at a predetermined distance from the inner surface of the case tube 11 in the case tube 11 and tapers in the reverse direction of the washing solution, 11 to the inner surface of the casing tube 11 so as to be as close as possible to the electromagnet 12, thereby effectively separating the iron powder contained in the cleaning solution.

The guide tube 13 preferably has a structure that is connected and fixed to the case tube 11 by a connection frame 13a extending inward from the inner surface of the case tube 11. At this time, Can take the shape of a cross.

In addition, the filtering means may further comprise a screen member (30) for filtering foreign matter.

Specifically, the screen member 30 may have a structure extending from the outer edge of the inlet of the guide pipe 13 to the inner surface of the case pipe 11. [ The screen member 30 functions to filter foreign matters having a relatively large particle size.

The removal unit 20 may include a bypass pipe 21 connected to the circulation line CL and a backwash filter 22 installed in the bypass pipe 21.

The bypass pipe 21 is connected at one end to the rear end of the case pipe 11 and at the other end to the circulation line CL and is connected to the circulation line CL when the supply current of the electromagnet 12 is interrupted. The cleaning solution is bypassed.

The backwash filter 22 is installed in the bypass pipe 21. The backwash filter 22 can make a flow of the fluid in the opposite direction to the cleaning direction unlike the general filter, As a filter that can be used for cleaning, it is needless to say that any conventional backfill filter can be used without being limited by the present invention.

The removal unit 20 further includes a control member C electrically connected to the electromagnet 12, a first valve V1 and a second valve V2 electrically connected to the control member C .

Here, the control member C is electrically connected to the electromagnet 12 to control the supply current of the electromagnet 12.

The first valve V1 is installed at the rear end of the case pipe 11 at the connection point with the bypass pipe 21 and is electrically connected to the control member C so that the supply current of the electromagnet 12 is interrupted May be configured to be closed.

The second valve V2 may be installed at the inlet of the bypass pipe 21 and electrically connected to the control member C so that the second valve V2 is opened when the supply current of the electromagnet 12 is interrupted.

The control member C has an electrical connection structure to the first valve V1 and the second valve V2 in such a manner that the control member C is connected to the first motor V1, M1 and a second motor M2 for driving the second valve V2.

The filtering unit may further include a re-separation unit 10 for separating the iron powder contained in the cleaning solution, which is not separated from the separation unit 10, by magnetic force.

At this time, the permanent magnet 40 is used in the re-separating unit 10 and is disposed in the bending portion where the cleaning solution collides in the circulation line CL at the rear end of the case pipe 11, 10), it is possible to more easily separate the iron powder.

In addition, the filtering means may further include a mesh filter (50) to filter fine foreign matter. The mesh filter 50 is disposed in the circulation line CL at the rear end of the casing tube 11 and functions to filter relatively minute foreign matter that has passed through the screen member 30 disposed in the separating section 10 at the previous stage do.

The electrolytic clean tank 2 includes a pair of anodes 2a spaced vertically apart from each other and a pair of cathodes 2b spaced apart from each other in the traveling direction of the steel plate 1 from the anode 2a, 2, the circulation line CL is connected to the side of the electrolytic clean tank 2 in the spacing space 2c between the anode 2a and the cathode 2b in the upper part of the electrolytic clean tank 2 desirable.

That is, the circulation line CL is connected to the side portion of the electrolytic clean tank 2, and is connected to a side point corresponding to the spacing space 2c between the upper anode 2a and the cathode 2b .

This is because the iron powder and the foreign substance contained in the cleaning solution move from the anode 2a to the cathode 2b by the fluid flow (flow of the cleaning solution) generated due to the progress of the steel sheet 1, The lower cathode 2b is lowered by the influence of gravity mostly under the lower cathode 2b, so that the problem does not occur.

In the present invention having the above-described configuration, the circulation line CL is communicated with the side portion of the electrolytic clean tank 2, and the space corresponding to the spacing space 2c between the upper anode 2a and the cathode 2b The filtering effect can be maximized by removing the iron only in a place where contamination actually occurs while the amount of cleaning solution to be treated is small.

The present invention configured as described above is characterized in that it comprises a circulation line (CL) for flowing out the cleaning solution from the electrolytic clean tank (2) and introducing it again, and a circulation line (CL) for separating and removing the iron component contained in the cleaning solution It is possible to prevent the re-contamination of the steel sheet 1 due to the iron powder by effectively separating the iron powder contained in the cleaning solution and completely removing the separated iron powder.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood that various changes and modifications may be made without departing from the scope of the appended claims.

1: steel plate 2: electrolytic clean tank
2a: anode 2b: cathode
2c: separation space CL: circulation line
P: Circulation pump 10: Separation part
11: Case tube 12: Electromagnet
13: guide tube 13a: connection frame
20: Removal 21: Bypass pipe
22: backwash filter C: control member
V1: first valve V2: second valve
M1: first motor M2: second motor
30: Screen member 40: Permanent magnet
50: Mesh filter

Claims (9)

A transfer route for transferring the solution; And
And filtering means provided on the conveying route for separating and removing iron contained in the solution of the conveying route by using magnetic force,
Wherein the filtering means comprises:
A separator provided at the transfer route for generating a magnetic force for magnetically separating the iron powder contained in the cleaning solution; And
A removing unit connected to the separating unit and removing iron powder attached to the separating unit when the magnetic force of the separating unit is cut off;
And,
Wherein the separating portion includes a case pipe disposed at a portion of the conveyance route; An electromagnet mounted inside the casing tube; And a guide pipe taperably mounted in the case pipe so as to guide the cleaning solution to the inner surface side of the case pipe in the reverse direction of the cleaning solution.
The method according to claim 1,
The removing unit
A bypass pipe connected to the rear end of the casing tube and leading to the conveyance route again so that the cleaning solution is bypassed from the conveyance route when the supply current of the electromagnet is interrupted; And
A backwash filter mounted on the bypass pipe;
And a filter for filtering the solution.
3. The method of claim 2,
The removing unit
A control member electrically connected to the electromagnet to control a supply current of the electromagnet;
A first valve mounted at a rear end of a connection portion between the case pipe and the bypass pipe, the first valve being electrically connected to the control member; And
A second valve mounted at an inlet of the bypass tube and electrically connected to the control member;
Further comprising: a filter for filtering the solution.
delete The method according to claim 1,
Wherein the filtering means comprises:
A screen member extending from the outer edge of the inlet of the guide tube to the inner surface of the case tube so as to filter foreign matter;
Further comprising: a filter for filtering the solution.
The method according to any one of claims 1, 2, 3, and 5,
Wherein the filtering means comprises:
A re-separator having a permanent magnet disposed in a bent portion where the cleaning solution collides with the conveying route at the rear end of the case tube so as to separate the iron powder not contained in the separating portion of the cleaning solution by using a magnetic force;
Further comprising: a filter for filtering the solution.
The method according to any one of claims 1, 2, 3, and 5,
Wherein the filtering means comprises:
A mesh filter disposed on the conveying route at the rear end of the casing tube so as to filter fine foreign matter;
Further comprising: a filter for filtering the solution.
The method according to claim 1,
The transfer route is a circulation line connected to an electrolytic cleaning tank of an electrolytic cleaning line (ECL), which flows out the cleaning solution from the electrolytic cleaning tank after flowing out the cleaning solution,
Wherein the solution is a cleaning solution.
delete

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