KR101320320B1 - Apparatus for collectting plating solution in electric plating equipment - Google Patents

Abstract

The present invention relates to a plating solution recovery device of a horizontal cell electroplating apparatus for collecting and recovering the plating solution flows along the edge of the steel sheet to the rear end of the plating roll and the backup roll in the horizontal cell electroplating process, the present invention The plating solution recovery apparatus of the horizontal cell electroplating apparatus according to the embodiment is a device for recovering the plating solution input to the horizontal cell electroplating apparatus, the plate of the steel sheet in the rear region of the horizontal cell electroplating apparatus in the direction that the steel sheet proceeds An upper movable block unit and a lower movable block unit spaced apart from each other on the upper and lower edge portions thereof; An upper air spraying unit and a lower air spraying unit which are respectively installed in the upper movable block unit and the lower movable block unit to inject air to an edge portion of the steel sheet; An upper collecting unit installed in the upper movable block unit to collect and discharge the plating solution of the steel plate edge portion scattered by the air injected from the upper air spraying unit; And a lower collecting unit installed in the lower movable block unit to collect and discharge the plating solution of the steel sheet edge portion scattered by the air injected from the lower air spraying unit.

Description

Plating solution recovery device for horizontal cell electroplating equipment {APPARATUS FOR COLLECTTING PLATING SOLUTION IN ELECTRIC PLATING EQUIPMENT}

The present invention relates to a plating solution recovery device of a horizontal cell electroplating apparatus, and more particularly, to collect and recover the plating solution flowing along the edge of the steel sheet to the rear end of the plating roll and the backup roll in the horizontal cell electroplating process. A plating solution recovery apparatus of a horizontal cell electroplating apparatus.

In general, steel sheets widely used for home appliances and automobile materials are plated with zinc-based metals and metal alloys to improve corrosion resistance while maintaining excellent surface appearance. In particular, the plating of the surface of the steel sheet is carried out using a horizontal cell (LCC-H; Liquid Cushion Cell-Horizontal) type electroplating apparatus capable of continuous plating to improve the productivity of the process.

For a technique of plating zinc-nickel or zinc on the surface of a steel sheet using a conventional horizontal cell type electroplating apparatus, "electroplating method and apparatus (registered patent 10-0967714)" and "plating electrode of a horizontal cell electroplating apparatus It is known in detail in the "protective device (patent 10-0841769)".

In general, an insoluble electrode is used for sulfate bath plating using a horizontal cell type electroplating apparatus, and the electrode is generally formed to have a length of 1500 to 2000 mm to work with a current density of about 200 A / dm and a current of 50 KA per plating cell. This makes it possible to operate at a high current density to facilitate alloy plating. Such a plating facility is schematically shown in FIGS. 1A and 1B.

Figure 1a is a view showing the configuration of a general horizontal cell type electroplating apparatus, Figure 1b is a view showing that the plating solution flows out from the general horizontal cell type electroplating apparatus.

As shown in FIG. 1A, in the horizontal cell type electroplating apparatus, the steel sheet S advances through a space between a pair of plating electrodes 1a and 1b arranged up and down, and the steel sheet S and the plating electrode are moved. An interval of approximately 9 mm is formed between (1a, 1b). Then, the plating solution is supplied through the solution nozzle 2 at intervals between the steel sheet S and the plating electrodes 1a and 1b.

Further, on both sides of the plating electrodes 1a and 1b, a plating roll 3 composed of a high hardness of steel material and a plating roll 3 are installed to supply a plating current (-) to the steel sheet S. On the opposite side of the steel sheet S, a back-up roll 4 is provided to transfer the steel sheet S by bringing the steel sheet S into close contact with the plating roll 3 with a reduction force of approximately 4 to 5 kg / cm 2. Thus, a predetermined space in which the plating process is performed as the plating solution 5 is filled by the plating roll 3 and the backup roll 4 disposed before and after the plating electrodes 1a and 1b and the plating electrodes 1a and 1b is filled. Phosphorus plating cell is provided. As a result, the steel sheet S is brought into contact between the plating roll 3 and the backup roll 4 so that the plating roll 3 and the backup roll 4 are transported by rotation. Through the plated current of the cathode is supplied to the steel sheet (S) through the beautiful surface and excellent color production of the product is possible continuously.

In addition, a drip pan 6 for collecting the plating solution 5 discharged from the plating cell is provided at the lower portion of the plating roll 3 and the backup roll 4 arranged before and after the plating cell.

As described above, before and after the plating cell, the plating roll 3 and the backup roll 4 are installed up and down to form a dam before and after the plating cell by squeezing the steel sheet S. As shown in FIG. 1B, there is a problem in that perfect squeezing is not performed at the edge portion of the steel sheet S between the plating roll 3 and the backup roll 4, in particular, a thick steel sheet. When the work is more severe, the plating solution (5) exits the plating roll (3) located at the rear end of the plating cell along the steel plate (S) and the back end of the backup roll (4) to the plating cell (5). There is a problem that must be supplemented from time to time.

In particular, the plating solution 5, which has undergone the plating operation, is gradually thinner and newly renewed to maintain the concentration of the plating solution 5 filled in the plating cell differently from the plating solution supplemented with the plating cell. There was a difficulty to continuously perform the concentration make-up operation that suitably adjusts the concentration of the plating solution (5) to be filled, and the production by supplying the expensive plating solution (5) periodically and continuously There was a problem of rising costs.

In addition, the plating solution 5 flowed to the rear end of the plating roll 3 and the backup roll 4 by the steel sheet (S) causes a waste water treatment problem, and mixed with other solutions to the surface defects such as plating stains There was a problem such as causing.

Patent Registration 10-0967714 (2010. 06. 25) Patent Registration 10-0841769 (2008. 06. 20)

In the present invention, the plating solution filled in the plating cell surrounded by the plating electrode, the plating roll, and the backup roll is collected and collected separately from the edge portion of the steel plate together with the steel plate exiting to the rear end of the plating cell. The present invention provides a plating solution recovery apparatus for a horizontal cell electroplating apparatus capable of preventing defects from occurring on the surface of a steel sheet and preventing contamination of other equipment by the plating solution.

In addition, the present invention provides a plating solution recovery device for a horizontal cell electroplating apparatus which can reduce the production cost of the product by restraining the plating solution from unnecessary loss as the plating solution is discharged from the plating cell together with the steel sheet.

Plating solution recovery apparatus of the horizontal cell electroplating apparatus according to an embodiment of the present invention is a device for recovering the plating solution to be put into the horizontal cell electroplating apparatus, the rear of the horizontal cell electroplating apparatus in the direction that the steel sheet proceeds An upper movable block unit and a lower movable block unit spaced apart from each other on upper and lower edge portions of the steel sheet in the region; An upper air spraying unit and a lower air spraying unit which are respectively installed in the upper movable block unit and the lower movable block unit to inject air to an edge portion of the steel sheet; An upper collecting unit installed in the upper movable block unit to collect and discharge the plating solution of the steel plate edge portion scattered by the air injected from the upper air spraying unit; And a lower collecting unit installed in the lower movable block unit to collect and discharge the plating solution of the steel sheet edge portion scattered by the air injected from the lower air spraying unit.

The upper movable block unit and the lower movable block unit are each provided with a built-in pipe through which air flows, and each of the built-in pipes is connected to a flexible pipe to which air is supplied, and the upper air spray unit and the lower air spray unit Fixed pipes connected to the other side of the built-in pipes, respectively; A nozzle housing connected to an end of the fixed pipe; It characterized in that it comprises a plurality of nozzles installed in the nozzle housing.

The plurality of nozzles are arranged in a line in the width direction of the steel sheet, the plurality of nozzles are inclined in the edge direction from the center of the steel sheet is characterized in that the inclined toward the rear region direction of the horizontal cell electroplating apparatus.

The upper collecting unit includes a first cover surrounding an upper region and a front region of the upper air spraying unit; A pair of first side plates extending from the side of the first cover to surround the side regions of the upper air spray unit; Extends in the direction of the upper air spray unit from the front end of the first cover to collect and discharge the plating solution scattered by the air injected from the upper air spray unit while surrounding the lower area of the first cover; A lower plate extending from an upper air injection unit to an injection path of air directed toward the steel sheet, the lower plate extending from a front end of the first cover to be concave downward; It is characterized in that the inclined portion extending from the rounding portion is formed to be inclined downward in the direction of the injection path of the air.

The first cover and the lower plate are formed up to an area beyond the edge of the steel plate, and a first discharge port for discharging the collected plating solution is formed at a position corresponding to an area outside the edge of the steel plate among the rounding parts of the lower plate. It is characterized by.

The lower collecting unit includes a second cover surrounding the lower region and the front region of the lower air spraying unit to collect and discharge the plating solution scattered by the air injected from the lower air spraying unit; A pair of second side plates extending from the side of the second cover to surround the side regions of the lower air spraying unit; An upper plate extending from the front end of the second cover in the direction of the lower air injection unit to surround the upper area of the second cover, and extending from the lower air injection unit to the injection path of air directed to the steel sheet; do.

The bottom surface of the second cover is characterized in that the second outlet for discharging the collected plating solution is formed.

The upper movable block unit and the lower movable block unit are provided with driving means for moving the upper movable block unit and the lower movable block unit in the width direction of the steel sheet between the edge position of the steel sheet and the groove position deviated from the edge portion of the steel sheet, respectively. It is characterized by.

The upper moving block unit and the lower moving block unit are provided with a detection sensor for detecting the edge position of the steel plate, respectively, and when the edge sensor is detected by the detection sensor during the movement by the drive means driving of the drive means in conjunction with this Characterized in that it is stopped.

According to this embodiment, when performing continuous plating in the plating cell, which is a plating bath, by separately collecting and recovering the plating solution from the edge of the steel sheet to the rear end of the plating roll and the backup roll, the additional plating according to the waste of the plating solution is collected. Solution makeup can be suppressed to reduce the production cost of the plated steel sheet.

In addition, as the plating solution used for electroplating is prevented from being mixed with other solutions and remaining on the surface of the steel sheet, it is possible to suppress the occurrence of plating stains and to improve the quality of the product, and to treat the plating solution spilled with the steel sheet. This can reduce the cost of wastewater treatment.

Figure 1a is a view showing the configuration of a general horizontal cell type electroplating apparatus,
Figure 1b is a view showing that the plating solution flows out of a typical horizontal cell type electroplating apparatus,
2 is a view showing a plating solution recovery apparatus of a horizontal cell electroplating apparatus according to an embodiment of the present invention,
Figure 3 is an enlarged view of the main part showing a plating solution recovery device of the horizontal cell electroplating apparatus according to an embodiment of the present invention,
Figure 4a is a plan view of the main part showing a plating solution recovery device of the horizontal cell electroplating apparatus according to an embodiment of the present invention,
Figure 4b is a side view showing the main part showing the plating solution recovery apparatus of the horizontal cell electroplating apparatus according to an embodiment of the present invention,
5a to 5c is an operating state diagram showing an operating state of the plating solution recovery apparatus according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It will be apparent to those skilled in the art that the present invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, It is provided to let you know. Wherein like reference numerals refer to like elements throughout.

2 is a view showing a plating solution recovery device of the horizontal cell electroplating apparatus according to an embodiment of the present invention, Figure 3 is a main portion showing a plating solution recovery device of the horizontal cell electroplating apparatus according to an embodiment of the present invention 4A is an enlarged view of the main part showing a plating solution recovery device of the horizontal cell electroplating apparatus according to an embodiment of the present invention, Figure 4b is a plating of the horizontal cell electroplating apparatus according to an embodiment of the present invention Main side view showing the solution recovery device.

As shown in the drawings, the plating solution recovery apparatus of the horizontal cell electroplating apparatus according to the exemplary embodiment of the present invention is spaced apart from the upper and lower edge portions of both sides of the steel sheet S in the rear region of the horizontal cell electroplating apparatus. An upper movable block unit 100 and a lower movable block unit 100a; An upper air spray unit (200) and a lower air spray unit (200a) installed in the upper movable block unit (100) and the lower movable block unit (100a) to inject air to the edge portion of the steel sheet (S); The edge portion of the steel sheet (S) is installed in the upper movable block unit 100 and the lower movable block unit (100a) is scattered by the air injected from the upper air spraying unit 200 and the lower air spraying unit (200a) And an upper collecting unit 300 and a lower collecting unit 400 for collecting and discharging the plating solution.

The upper movable block unit 100 and the lower movable block unit 100a are provided at upper and lower regions of both side edge portions of the steel sheet S, respectively, and are installed to be movable in the width direction of the steel sheet S. Based on (S) has a configuration that is symmetrical with each other up, down, left and right. Thus, in describing the upper mobile block unit 100 and the lower mobile block unit 100a, a pair of the upper mobile block unit 100 and the lower mobile block unit 100a are installed in pairs, respectively, in order to prevent unnecessary descriptions from overlapping. ) As one of the representatives.

The upper movable block unit 100 is a unit installed on both side edge portions of the steel sheet (S), by the driving means 120 to be described later the edge portion of the steel sheet (S) and the edge of the steel sheet (S) It is moved in the width direction of the steel plate S between the groove positions deviated from the part.

The upper movable block unit 100 includes a block body 110 having a substantially rectangular parallelepiped shape. At this time, the block body 110 is formed with a built-in pipe 111 through which the air injected through the upper air injection unit 200 flows, the one end of the built-in pipe 111, the block body 110 is Even if moved, the flexible pipe 101 is connected to smoothly provide air to the built-in pipe (111).

In addition, both ends of the block body 110 communicate with each other, and the shaft hole 112 is formed to be parallel to the width direction of the steel sheet (S). At this time, it is preferable that a screw thread is formed on the inner circumferential surface of the shaft hole 112. In addition, the guide shaft 123, the deformed 113 is formed so as to be adjacent to the shaft hole 112 and both ends are in communication with the shaft hole 112.

Thus, the driving means 120 for moving the block body 110 in the width direction of the steel plate (S) to the shaft hole 112 and the guide hole 113 formed in the block body 110 is connected.

The driving means 120 is installed through the shaft hole 112 and the outer circumferential surface of the screw shaft 121 is formed to be screwed to the screw thread formed on the inner peripheral surface of the shaft hole 112 and the screw shaft 121 to rotate It includes a motor 122 to make. Thus, the screw shaft 121 is rotated by the operation of the motor 122, and the block body 110 is moved in the longitudinal direction of the screw shaft 121 by the rotation operation of the screw shaft 121.

In addition, the driving means 120 includes a guide shaft 123 installed through the guide hole 113 formed in the block body 110. Thus, when the screw shaft 121 is rotated, the block body 110 is not rotated together with the screw shaft 121 to be moved in the longitudinal direction along the screw shaft 121 and the guide shaft 123.

On the other hand, the upper moving block unit 100 is provided with a detection sensor 130 for detecting the edge position of the steel sheet (S). Thus, the upper movable block unit 100 waits at the groove position deviated from the edge position of the steel sheet S when the welded portion of the steel sheet S passes through the plating cell portion, and then the steel sheet is driven by the driving means 120. While detecting the edge position of the steel sheet (S) by the sensing sensor 130 while moving to the edge position of (S), in conjunction with this to stop the motor 122 of the drive means 120, the upper movable block unit ( The movement of the upper part 100 is stopped so that the upper moving block unit 100 is positioned so that the steel sheet S is immediately above the edge portion.

The upper air spray unit 200 and the lower air spray unit 200a are respectively installed in the upper movable block unit 100 and the lower movable block unit 100a to inject air to the edge portion of the steel sheet S. In the plating cell serves to scatter the plating solution (5) flowing out to the edge portion of the steel sheet (S) from the steel sheet (S).

The upper air spraying unit 200 and the lower air spraying unit 200a have a configuration that is symmetrical with each other up, down, left, and right on the basis of the steel plate S, similarly to the above-described upper and lower movable block units 100 and 100a. Have Thus, in describing the upper air spraying unit 200 and the lower air spraying unit 200a, the upper air spraying unit 200 and the lower air spraying unit 200a are provided in pairs, respectively, in order to prevent unnecessary descriptions from overlapping. ) As one of the representatives.

The upper air spraying unit 200 includes a fixed pipe 210 connected to the other side of the built-in pipe 111 formed in the block body 110; A nozzle housing 220 connected to an end of the fixed pipe 210; The nozzle housing 220 includes a plurality of nozzles 230.

The fixed pipe 210 serves as a passage for supplying air to the plurality of nozzles 230 and the means for fixing the nozzle housing 220 so that the plurality of nozzles 230 can inject air in a predetermined direction As the plurality of nozzles 230 are inclined in the edge direction from the center of the steel sheet (S) to be installed inclined in the rear region direction of the horizontal cell electroplating apparatus, that is, the steel sheet is drawn out from the horizontal cell electroplating apparatus. It is bent so that it can be installed.

The nozzle housing 220 is a means for branching the air supplied through the fixed pipe 210 to the plurality of nozzles 230, and its shape and size may be variously changed without being limited to a specific shape and size. have.

The plurality of nozzles 230 are means for injecting air directly onto the steel sheet S. In order to smoothly scatter the plating solution 5 buried on the surface of the steel sheet S, the plurality of nozzles 230 may include the steel sheet. It is arrange | positioned in line in the width direction of (S), and is arrange | positioned obliquely with the surface of the steel plate S. As shown to FIG. The number of the nozzles 230 is not limited to a specific number but is preferably applied corresponding to the size of the steel sheet (S). In this embodiment, three nozzles 230 are provided in a row.

The upper air spraying unit 200 and the lower air spraying unit 200a configured as described above are buried on the surface of the steel sheet S by injecting air to the edge portion of the steel sheet S through the nozzle 230. The plating solution 5 is scattered to separate the plating solution 5 from the steel sheet S.

The plating solution 5 scattered as described above is collected and recovered by the upper collecting unit 300 and the lower collecting unit 400.

The upper collecting unit 300 is installed to surround the upper air spraying unit 200 and collects and recovers the plating solution 5 scattered by the air injected from the upper air spraying unit 200. A first cover 310 largely surrounding the upper region and the front region of the upper air spray unit 200; A pair of first side plates (320) extending from the side of the first cover (310) to surround the side regions of the upper air spray unit (200); The lower plate 330 extends from the front end of the first cover 310 toward the upper air spray unit 200 to surround the lower area of the first cover 310.

The first cover 310 and the first side plate 320 are connected to each other and the plating solution 5 is applied to an area in which the upper air injection unit 200 is installed, and the air injected from the upper air injection unit 200. ) Is provided in a shape surrounding the upper region, the front region and the side region of the upper air injection unit 200 to include the region to be scattered. Preferably, the first cover 310 is preferably rounded in the front area so that the scattering plating solution 5 smoothly flows down along the inner circumferential surface of the first cover 310.

The lower plate 330 is a means for capturing and discharging the plating solution 5 flowing down the inner circumferential surface of the first cover 310, and the upper air spray is formed at the front end of the first cover 310. Although extending in the direction of the unit 200, it is preferable to extend only to the injection path of the air in order to ensure the injection path of the air is injected from the upper air injection unit 200 toward the steel sheet (S).

In particular, the lower plate 330 may include a rounding part 331 extending from the front end of the first cover 310 to be concave downward; The inclined part 332 extends from the rounding part 331 and is formed to be inclined downward in the direction of the jet path of the air. In this case, the lower plate 330 is formed with the rounded portion 331 and the inclined portion 332 long in the width direction of the steel sheet (S) to have a constant cross-section in the width direction of the steel sheet (S), preferably the first 1 The cover 310 and the lower plate 330 are formed to extend to the area beyond the edge portion of the steel sheet (S).

At this time, the first discharge port 340 for discharging the collected plating solution 5 is formed at a position corresponding to a region outside the edge portion of the steel plate S of the rounding part 331 of the lower plate 330. Thus, the plating solution 5 scattered by air flows down the inner circumferential surface of the first cover 310 and is collected in the rounding part 331 and then discharged from the upper collecting unit 300 through the first outlet 340. At this time, the discharged plating solution 5 is not discharged to the upper surface of the steel sheet (S), but passes through the space beyond the edge portion of the steel sheet (S) and discharged to the drip pan (6) provided in the lower portion of the steel sheet (S) Be sure to

In addition, when the plating solution 5 scattered by air is scattered to the inclined portion 332 without being collected by the first cover 310 and the rounding portion 331, the plating solution 5 is inclined in the edge direction with respect to the steel sheet S. As the air is injected, the plating solution 5 is scattered to the inclined portion 332 in the region beyond the edge portion of the steel sheet S, and then flows downward along the inclined portion 332 to the upper surface of the steel sheet S. It is not discharged to pass through the space beyond the edge portion of the steel sheet (S) to fall to the drip pan 6 provided in the lower portion of the steel sheet (S).

On the other hand, the lower collecting unit 400 is installed so as to surround the lower air spraying unit (200a) means for collecting and recovering the plating solution (5) scattered by the air injected from the lower air spraying unit (200a) As a, it has a structure similar to the structure symmetrical with respect to the upper collecting unit 300 and the steel sheet (S).

The lower collecting unit 400 has a second cover 410 surrounding the lower region and the front region of the lower air spraying unit 200a, as in the upper collecting unit 300; A pair of second side plates 420 extending from the side of the second cover 410 so as to surround the side regions of the lower air spraying unit 200a; An upper plate 430 extends from the front end of the second cover 410 toward the lower air spray unit 200a to surround the upper area of the second cover 410.

The second cover 410 and the second side plate 420 are connected to each other so that the plating solution is scattered to the area where the lower air injection unit 200a is installed, and the air injected from the lower air injection unit 200a. It is provided in a shape surrounding the lower region, the front region and the side region of the lower air injection unit 200a to include an area.

The second cover 410 and the second side plate 420 have a shape for collecting and discharging the plating solution 5 scattered by the air injected from the lower air spray unit 200a, in particular the second The front region of the second cover 410 is preferably rounded to allow the plating solution 5 to flow smoothly along the inner circumferential surface of the cover 410.

In addition, a second discharge port 440 is formed on the bottom surface of the second cover 410 to discharge the collected plating solution 5. Thus, the plating solution 5 scattered by air flows down along the inner circumferential surface of the second cover 410 and is collected on the bottom surface of the second cover 410 and then the lower collecting unit (440) through the second outlet 440. 400 to be discharged to the drip pan 6 provided in the lower portion of the steel sheet (S).

The upper plate 430 is a means for preventing the plating solution 5 from being scattered and attached to the lower surface of the steel sheet S when the plating solution is scattered by the air injected from the lower air spray unit 200a. It extends in the direction of the lower air injection unit 200a at the front end of the second cover 410, except that the air is sprayed from the lower air injection unit 200a to secure the injection path of the air toward the steel sheet S. It is preferable to extend only to the injection path of.

At this time, the upper plate 430 is manufactured in the same shape as the lower plate 330 in order to facilitate the manufacture, but is not limited to the shape shown, the plating solution 5 is scattered while ensuring a sufficient spray path of air is It can be implemented by changing to a variety of shapes that can be prevented from being attached to the lower surface of the steel sheet (S) again.

The operation state of the plating solution recovery device configured as described above will be described with reference to the drawings.

5a to 5c is an operating state diagram showing an operating state of the plating solution recovery apparatus according to an embodiment of the present invention.

Plating solution recovery apparatus according to an embodiment of the present invention to correspond to the upper and lower edge regions of both sides of the steel sheet (S), respectively, the moving block unit (100, 100a), air spraying unit (200, 200a) and collecting unit 300 , 400).

Each of the moving block units 100 and 100a, the air spraying units 200 and 200a and the collecting units 300 and 400 have an operation state similar to each other and is disposed in one edge region of the steel sheet S. The operation state of the unit 100, the upper air injection unit 200 and the upper collecting unit 300 will be described as a representative.

As shown in FIG. 5A, the upper movable block unit 100 is positioned directly above the edge portion of the steel sheet S. As shown in FIG. At this time, although not shown in the drawings, when the welding portion of the steel sheet (S) attached by welding different steel sheets (S) during the plating process of the continuous steel sheet (S) passes through the plating cell by the drive means 120 The upper movable block unit 100 is moved to the home position, which is a position away from the edge portion of the steel sheet S, and after the welding part of the steel sheet S exits the plating cell, the portion immediately above the edge portion of the steel sheet S again. Moved to the original position. At this time, the movement of the upper movable block unit 100 is made by the rotation of the screw shaft 121 is rotated by the operation of the motor 122, the drive means 120, the upper movable block unit 100 is a steel sheet (S) The operation of being positioned directly above the edge portion of the) is controlled by the detection sensor 130 for detecting the edge position of the steel sheet (S).

On the other hand, a continuous plating process of the steel sheet (S) is performed in the state that the upper movable block unit 100 is positioned directly above the edge portion of the steel sheet (S), wherein the edge portion of the steel sheet (S) to the plating cell The filled plating solution 5 flows out together. This apparatus recovers the plating solution 5 which flowed out to the edge part of the steel plate S in this way.

In other words, the air supplied through the flexible pipe 101 passes through the built-in pipe 111 of the block body 110, the fixed pipe 210 of the upper air spray unit 200, and the nozzle housing 220 sequentially. It is injected to the steel sheet (S) through a plurality of nozzles 230, wherein the air is sprayed inclined in the edge direction from the center of the steel sheet (S) is preferably inclined in the direction of the rear region of the horizontal cell electroplating apparatus. . Therefore, the plating solution 5 scattered by air is not scattered to the center of the steel sheet S, but to the outer region of the steel sheet S, and the plating solution 5 is not scattered in the direction of other equipment other than the plating equipment. Do not.

The plating solution 5 scattered by air is collected by the upper collecting unit 300. As shown in FIG. 5B, the plating solution 5 scattered is in contact with the inner circumferential surface of the first cover 310. It flows downward along the inner circumferential surface and is collected in the rounding part 331 of the lower plate 330. At this time, the plating solution 5 scattered to the inclined portion 332 without being scattered by the first cover 310, the first side plate 320, and the rounding portion 331 is formed of a steel sheet along the inclination of the inclined portion 332. S) flows down the area beyond the edge portion and is directly recovered to the drip pan 6.

And, as shown in FIG. 5C, the plating solution 5 collected in the rounding part 331 of the lower plate 330 is provided on the lower part of the steel plate S through the first outlet 340. Is discharged and recovered.

When the plating solution 5 filled in the plating cell flows out of the plating cell along the edge portion of the steel plate S, the plating solution 5 is scattered and then collected and recovered to plate the steel plate S. The quality can be improved and the loss of the plating solution 5 can be suppressed, and the contamination of other equipment by the plating solution 5 can also be prevented.

Although the present invention has been described with reference to the accompanying drawings and the preferred embodiments described above, the present invention is not limited thereto but is limited by the following claims. Accordingly, those skilled in the art will appreciate that various modifications and changes may be made thereto without departing from the spirit of the following claims.

1a, 1b: plating electrode 2: solution nozzle
3: plating roll 4: backup roll
5: plating solution 6: drip pan
100: upper movable block unit 101: flexible pipe
110: block body 111: internal piping
112: shaft ball 113: guide ball
120: drive means 121: screw shaft
122: motor 123: guide shaft
130: detection sensor 100a: lower moving block unit
200: upper air spray unit 210: fixed pipe
220: nozzle housing 230: nozzle
200a: lower air spray unit 300: upper collecting unit
310: first cover 320: first side plate
330: lower plate 331: rounding part
332: inclined portion 340: first outlet
400: lower collecting unit 410: second cover
420: second side plate 430: top plate
440: second outlet

Claims (9)

Apparatus for recovering the plating solution to the horizontal cell electroplating device,
An upper movable block unit and a lower movable block unit spaced apart from upper and lower sides of both edge portions of the steel sheet in the rear region of the horizontal cell electroplating apparatus in a direction in which the steel sheet proceeds;
An upper air spraying unit and a lower air spraying unit which are respectively installed in the upper movable block unit and the lower movable block unit to inject air to an edge portion of the steel sheet;
An upper collecting unit installed in the upper movable block unit to collect and discharge the plating solution of the steel plate edge portion scattered by the air injected from the upper air spraying unit;
And a lower collecting unit installed in the lower movable block unit to collect and discharge the plating solution of the steel sheet edge portion scattered by the air sprayed from the lower air spraying unit.
The method according to claim 1,
The upper movable block unit and the lower movable block unit are each formed with internal pipes through which air flows, and each side of each internal pipe is connected with a flexible pipe for supplying air,
The upper air spray unit and the lower air spray unit is fixed pipe connected to the other side of the built-in pipe, respectively; A nozzle housing connected to an end of the fixed pipe; Plating solution recovery apparatus of a horizontal cell electroplating apparatus comprising a plurality of nozzles installed in the nozzle housing.
The method according to claim 2,
The plurality of nozzles are arranged in a line in the width direction of the steel sheet, the plurality of nozzles are inclined in the edge direction from the center of the steel sheet while being inclined toward the rear region direction of the horizontal cell electroplating apparatus Plating solution recovery apparatus of cell electroplating apparatus.
The method of claim 1, wherein the upper collecting unit
A first cover surrounding an upper region and a front region of the upper air spray unit;
A pair of first side plates extending from the side of the first cover to surround the side regions of the upper air spray unit;
Extends in the direction of the upper air spray unit from the front end of the first cover to collect and discharge the plating solution scattered by the air injected from the upper air spray unit while surrounding the lower area of the first cover; A lower plate which is injected from the upper air spray unit and extends to the spray path of air directed to the steel sheet,
The lower plate may include a rounding part extending from a front end of the first cover to be concave downward; Plating solution recovery device of the horizontal cell electroplating apparatus characterized in that divided into the inclined portion extending from the rounding portion to be inclined downward in the direction of the injection path of the air.
The method of claim 4,
The first cover and the lower plate is formed to the area beyond the edge portion of the steel sheet,
The plating solution recovery apparatus of the horizontal cell electroplating apparatus, characterized in that the first discharge port for discharging the collected plating solution is formed at a position corresponding to a region outside the edge portion of the steel plate of the rounded portion of the lower plate.
The method of claim 1, wherein the lower collecting unit
A second cover surrounding the lower region and the front region of the lower air injection unit to collect and discharge the plating solution scattered by the air injected from the lower air injection unit;
A pair of second side plates extending from the side of the second cover to surround the side regions of the lower air spraying unit;
An upper plate extending from the front end of the second cover in the direction of the lower air injection unit to surround the upper area of the second cover, and extending from the lower air injection unit to the injection path of air directed to the steel sheet; Plating solution recovery device of the horizontal cell electroplating apparatus.
The method of claim 6,
A plating solution recovery device of a horizontal cell electroplating apparatus, characterized in that a second outlet for discharging the collected plating solution is formed on the bottom surface of the second cover.
The method according to claim 1,
The upper movable block unit and the lower movable block unit are provided with driving means for moving the upper movable block unit and the lower movable block unit in the width direction of the steel sheet between the edge position of the steel sheet and the groove position deviated from the edge portion of the steel sheet, respectively. Plating solution recovery device of the horizontal cell electroplating apparatus characterized in that the. The method according to claim 8,
The upper moving block unit and the lower moving block unit are provided with a detection sensor for detecting the edge position of the steel plate, respectively, and when the edge sensor is detected by the detection sensor during the movement by the drive means driving of the drive means in conjunction with this Plating solution recovery device of the horizontal cell electroplating apparatus characterized in that the stop.

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