KR20190054473A - Device for removing dendrite of plated strip - Google Patents

Abstract

Provided is an apparatus for removing dendrites of a plated steel sheet. According to the present invention, the apparatus for removing dendrites of a plated steel sheet comprises: an edge mask disposed along an edge unit of a steel sheet strip; a roller for removing dendrites generated in a strip edge unit; and a roller adhesion unit for allowing the roller to adhere to the strip edge unit.

Description

TECHNICAL FIELD [0001] The present invention relates to a device for removing dendritic crystals of a plated steel sheet,

The present invention relates to an apparatus for removing dendritic crystals of a coated steel sheet.

Generally, an electroplating process, which is one of steelmaking processes, proceeds by a method of electrolytically and chemically decomposing and bonding a plating solution to form a coating film of metal, for example, zinc on the surface of a steel sheet.

Such an electroplating process should be continuously performed to produce a large amount of coated steel sheet, and a horizontal cell structure is generally used for this purpose.

Since the horizontal cell uses a plating solution of a sulfuric acid base having a low electrical conductivity, it shortens the distance between the steel plate (-) and the anode electrode (+) to prevent overvoltage.

However, there is a limitation in the proximity of an edge mask to prevent over-plating of the edge portion of the steel sheet and occurrence of dendrites at a short inter-electrode distance.

As a result, excessive gold and dendritic crystals are generated in a part of the edge portion, and the dendritic crystal grows into a tree shape while passing through several plating baths. The larger the amount of the plating steel, the larger the size of the dendritic crystal grows.

During the electroplating process, the plating solution flows from the lower part to the upper part, and bubbles are generated by the side reaction (2H ⁺ + 2e ^- > H ₂ ↑), and the hydrogen bubbles in the lower part are moved to the upper side while escaping to both sides of the steel sheet.

As described above, the phenomenon of moving upward from the bottom of the plating solution and the hydrogen bubbles moving from the bottom to the top cause the dendritic crystal, which is incompletely fused, to fall off from the edge portion of the steel sheet.

However, in the inside of the plating cell, since the edge mask is close to the steel plate on both sides with the steel plate sandwiched therebetween, the plating solution does not escape to the side in the plating cell, but exits only before and after the plating cell .

In addition, the plating solution that has escaped to the rear end of the plating cell is rotated along the Conductor Roll, so that the dendritic crystal dropped between the steel sheet and the conductive roll, resulting in product failure due to dent .

The present invention intends to provide a dendritic crystal removing device of a plated steel sheet in which a roller fixed to an edge mask moving in a fluid manner along an edge of a steel sheet can come into contact with the steel plate edge portion before entering the plating bath of the steel sheet to drop the dendritic crystal.

The apparatus for removing dendritic crystals of a coated steel sheet according to an embodiment of the present invention may include an edge mask disposed at regular intervals along an edge of a steel strip.

The dendritic crystal removing device includes a roller for arbitrarily rotatably provided on the edge mask and for dropping the dendritic crystal generated in the strip edge portion and a roller tightening portion provided on the roller and for bringing the roller into close contact with the strip edge portion .

The dendritic crystal removing apparatus may further include a gap adjusting unit provided on an outer surface of the edge mask to adjust the gap between the edge mask and the steel strip edge.

A plurality of energizing rolls and backup rolls for sequentially passing the steel strips are disposed at regular intervals on the top and bottom of the steel strip and a plating bath is provided between the energizing roll and the adjacent energizing roll, And the plating bath.

The roller contact portion includes an extension plate extending to the outside of the edge mask, a frame fixedly coupled to the extension plate, a moving frame provided at a predetermined distance from the frame, the roller being rotatably engaged with the frame, And an elastic member for applying an elastic force to the roller.

And one end of the moving frame may be provided with two hinge plates for arbitrarily rotating the roller by the hinge pin at a predetermined distance.

The frame may be provided with a guide rod for guiding movement of the moving frame.

The elastic member may be provided on the outer circumferential surface of the guide rod.

The outer circumferential surface of one end of the guide rod may be formed with a male thread to be engaged with the nut.

And the inner thread of the other end of the guide rod may be formed with a female thread to be engaged with the bolt.

The gap adjusting portion may include a linear sensor for detecting the edge portion of the steel strip, which is provided outside the one end portion and the other end portion of the plating bath.

The gap adjusting unit may include a rod member fixedly installed at an outer surface of the edge mask at a predetermined interval, an adjusting member body fixed to one end of the rod member, and a screw member screwed to the adjusting member body, And a ball screw nut.

And one end of the ball screw may be coupled to a servo motor for rotating the ball screw in one direction or the other direction.

The servo motor may be one that approaches or separates the edge mask to the strip edge portion according to the detection information of the linear sensor.

According to the embodiment of the present invention, the roller fixed to the edge mask comes into contact with the steel plate edge portion before entering the plating bath of the steel sheet, thereby eliminating the dendrite due to the dropout of the dendritic crystal.

1 is a schematic partially cutaway perspective view showing a state of installation of a dendritic crystal removing device of a plated steel sheet according to an embodiment of the present invention.
2 is a partially exploded perspective view of a resinous crystal removing apparatus of a coated steel sheet according to an embodiment of the present invention.
3 is a partially assembled perspective view of an apparatus for removing dendritic crystals of a coated steel sheet according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Wherever possible, the same or similar parts are denoted using the same reference numerals in the drawings.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to limit the invention. The singular forms as used herein include plural forms as long as the phrases do not expressly express the opposite meaning thereto. Means that a particular feature, region, integer, step, operation, element and / or component is specified, and that other specific features, regions, integers, steps, operations, elements, components, and / And the like.

All terms including technical and scientific terms used herein have the same meaning as commonly understood by those of ordinary skill in the art to which the present invention belongs. Predefined terms are further interpreted as having a meaning consistent with the relevant technical literature and the present disclosure, and are not to be construed as ideal or very formal meanings unless defined otherwise.

1 is a schematic partially cutaway perspective view showing a state of installation of a dendritic crystal removing device of a plated steel sheet according to an embodiment of the present invention.

FIG. 2 is a partially exploded perspective view of an apparatus for removing dendritic crystals of a galvanized steel sheet according to an embodiment of the present invention, and FIG. 3 is a partially assembled perspective view of an apparatus for removing dendritic crystals of a galvanized steel sheet according to an embodiment of the present invention.

The apparatus for removing dendritic crystals of a coated steel sheet according to an embodiment of the present invention includes an edge mask 101 disposed at regular intervals along both edge portions 101 of a steel strip 100 to prevent overvoltage of the strip edge portion 101, (Edge Mask) 200.

The edge mast 200 may be disposed at a certain distance from the edge portion 101 of the strip.

The dendritic crystal removing apparatus may include a roller 210 that is rotatably installed in the edge mask 200 and collides with the dendritic crystal generated in the strip edge portion 101 to drop the dendritic crystal.

The roller 210 may be an idle roller that is rotatable with respect to the edge mask 200.

The dendritic crystal removing device may include a roller tightening part 300 installed on the roller 210 to closely contact the roller 210 with a force of a predetermined magnitude to the strip edge part 101.

The dendritic crystal removing apparatus includes a gap adjusting unit 400 provided on the outer surface of the edge mask 200 to adjust the gap between the edge mask 200 and the edge portions 101 on both sides of the steel strip 100 .

The upper and lower portions of the steel strip 100 may be provided with a conductive roll 10 and a backup roll 20 for sequentially passing the steel strip 100.

A plurality of energizing rolls 10 and backup rolls 20 may be installed at regular intervals along the traveling direction of the strip 100. [

Therefore, the steel strip 100 sequentially passes between the plurality of energizing rolls 10 and the backup roll 20, and then passes between the upper electrode (not shown) and the lower electrode (not shown).

Between the energized roll 10 and the adjacent energizing roll 10, plating baths 30 and 40 for spraying and storing plating solutions respectively on the upper and lower sides of the strip 100 may be provided.

The roller adhering portion 300 is provided between the energizing roll 10 and the plating bath 30 so that the dendrite crystals 100 generated beforehand in the strip edge portion 101 before entering the plating bath 30 Can be removed and removed.

The roller contact portion 300 may also include an extension plate 301 extending outwardly of the inner core 201 of the edge mask 200 and a frame 310 fixedly coupled to the extension plate 301 have.

The roller contact part 300 may include a moving frame 320 installed at a predetermined distance from the frame 310 and coupled with the roller 210 in a rotatable manner.

At least one roller contact unit 300 is provided between the frame 310 and the moving frame 320 to apply the elastic force of a predetermined magnitude from the moving frame 320 to the strip edge unit 101 The elastic member 330 may be formed of an elastic material.

In addition, two hinge plates 340 may be provided at one end of the moving frame 320 to allow the roller 210 to rotate freely by the hinge pin 341 at a predetermined distance.

At least one guide rod 350 for guiding the movement of the moving frame 320 may be fixedly coupled to the frame 310.

The elastic member 330 may be installed on the outer circumferential surface of the guide rod 350 so that the elastic member 330 can be guided by the guide rod 350 when the moving frame 320 is moved.

The elastic member 330 applies an elastic force of a predetermined magnitude from the frame 310 to the moving frame 320. Accordingly, the roller 210 can be brought into close contact with a force of a predetermined magnitude on the strip edge portion 101.

At least one or more ribs 303 for preventing deformation of the extension plate 301 may be formed in the extension plate 301 in a predetermined size and shape.

The frame 310 may be made of resin or the like so that the roller contact portion 300 is fixed to the edge mask 200 and the guide rod 350 is smoothly moved.

The frame 310 may be fixedly coupled to the extension plate 301 by at least one bolt 311 and a nut 313 or the like.

A nut release preventing cap 315 may be provided at the upper end of the nut 313 to prevent the nut 313 from being separated.

The nut release preventing cap 315 may be formed in a square shape or the like so as to easily prevent the nut 313 from being separated.

The extension plate 301 and the frame 310 may be formed with engaging holes 302 and 312 for inserting the bolts 311 into the frame.

An engaging groove 316 may be formed at the upper end of the frame 310 so that the nut detachment prevention cap 315 is inserted into and coupled with the upper surface of the frame 310.

In addition, at least one engaging hole 321 for inserting the guide rod 350 into the moving frame 320 may be formed.

The two hinge plates 340 may be formed with a hinge pin engagement hole 343 to which the hinge pin 341 is coupled.

In addition, the roller 210 may be formed with an insertion hole 211 through which the hinge pin 341 is inserted.

The hinge pin 341 may be provided with a detachment prevention pin 343 for preventing the detachment of the hinge pin 341 coupled to the hinge pin engagement hole 343.

The one end of the hinge pin 341 may be formed with a release prevention pin engagement hole 342 for engagement with the release prevention pin 343.

At least one engaging hole 317 for inserting the guide rod 350 into the frame 310 may be formed.

A male thread 351 may be formed on the outer circumferential surface of one end of the guide rod 350 to be coupled to the nut 318 so as to fix the guide rod 350 to the frame 310.

A detachment prevention pin 319 may be coupled to one end of the guide rod 350 to prevent detachment of the guide rod 350 when the nut 318 and the male screw 351 are engaged.

The guide rod 350 may be formed with an engagement hole 353 for engaging with the detachment prevention pin 319.

A screw thread 355 may be formed on the inner circumferential surface of the other end of the guide rod 350 to engage with the bolt 323 so as to fix the guide rod 350 to the moving frame 320.

The interval adjusting unit 400 includes at least one or more spacing adjusting units 410 and 420 for detecting the edge portions 101 of the steel strip 100, ).

The linear sensors 410 and 420 may be installed to be supported by a support frame 50 installed outside the one end and the other end of the plating baths 30 and 40.

The gap adjusting unit 400 may include a rod member 430 disposed in the width direction of the strip (y direction in FIG. 1) and fixedly installed at an outer surface of the edge mask 200 at regular intervals .

The gap adjusting portion 400 may include an adjusting body 440 disposed in the longitudinal direction of the strip (x direction in FIG. 1) and fixed to one end of the rod member.

The gap adjusting part 400 may include a ball screw 450 and a ball screw nut 451 screwed to the adjusting part body 440 to move the adjusting part body in the width direction y of the strip .

The ball screw 450 is rotated at one end of the ball screw 450 in one direction or another direction to move the edge mask 200 toward or away from the edge 100 of the strip 100 by a predetermined distance. (460) may be combined.

The servo motor 460 sets the width and the amount of meandering of the steel strip 100 according to the detection information of the strip edge portion 101 measured by the linear sensors 410 and 420, To the edge portion 101 of the base portion 101. [

The rod member 430 may be disposed in the width direction y of the strip and perpendicular to the outer surface of the edge mask.

Also, the regulating body 440 may be disposed in the longitudinal direction (x) of the strip 100 and perpendicular to the rod member 430.

Hereinafter, the operation of the apparatus for removing dendritic crystals of a coated steel sheet according to an embodiment of the present invention will be described with reference to FIGS. 1 to 3. FIG.

First, the principle of adjusting the distance between the edge portion 101 of the steel strip 100 and the edge mask 200 by the gap adjusting portion 400 will be described.

The edge portions 101 of the steel strip 100 are sensed by the linear sensors 410 and 420 provided on the outer sides of one end and the other end of the plating baths 30 and 40 to be spaced apart from the edge portion 101 An imaginary line is created to bring the edge mask 200 close to the imaginary line.

That is, when the linear sensors 410 and 420 detect the edge portion 101 of the steel strip 100, the servo motor 460 is driven to rotate the ball screw 450 in one direction or the other direction.

The adjustment body 440 is moved forward or backward to the strip edge portion 101 by the rotation of the ball screw 450 and the ball screw nut 451.

When the regulating section body 440 is moved forward or backward to the strip edge section 101, the rod member 430 fixed to the regulating section body 440 is similarly advanced or reversed.

The edge mask 200 fixed to the rod member 430 is also advanced or retracted to the strip edge portion 101 so that the edge mask 200 comes close to the virtual line of the edge portion 101, Can be spaced from the imaginary line of the portion (101).

The width and the diagonal amount of the steel strip 100 detected by the linear sensors 410 and 420 are transmitted to the servo motor 460 to trace the edge 101 of the steel strip 100, (200). ≪ / RTI >

When the edge mask 200 is brought close to the edge portion 101 of the strip 100, the roller 210 provided on one side of the edge mask 200 is positioned on the strip edge portion 101 As shown in Fig.

The spacing thus protruded can be arbitrarily adjusted by adjusting the nut 318 of the guide rod 350. [

If the distance between the edge portion 101 of the steel strip 100 and the edge mask 200 is set to be equal to the interval between the edge portions of the edge mask 200 and the edge portion of the edge mask 200, And moves by the set interval.

Since the elastic member 330 is compressed at a predetermined interval between the frame 310 and the moving frame 320, the elastic force of the elastic member 330 can be transmitted to the edge of the steel strip edge portion (101).

Since the elastic member 330 is provided on the outer circumferential surface of the guide rod 350, it can be guided by the guide rod 350 during compression.

Even if the steel strip 100 by the close speed of the back-up roll 20 in each of the plating baths 30 and 40 is skewed by an arbitrary set amount, it is absorbed by the elastic force of the elastic member 330 So that the always-on roller 210 is brought into close contact with the edge portion 101.

Since the roller 210 is in close contact with the edge portion 101 before the steel strip 100 passes through the energizing roll 10 and the backup roll 20 and then enters the plating bath, So that the dendritic crystal 1-1 generated on the roller 210 collides with the roller 210.

3, the dendritic crystal 1-1 collides with the idler roller 210 rotatably coupled to the moving frame 320 by the hinge pin 341, so that the dendritic crystal 1-1 is separated from the strip edge portion 101 Can be eliminated.

As described above, the idle roller 210 removes the dendritic crystal grown in the pre-plating baths 30 and 40 before entering the next plating baths 30 and 40, thereby artificially removing the process of growing the dendritic crystal and dropping it in the plating bath .

Therefore, it is possible to prevent the occurrence of dent due to the growth of the dendritic crystal, which is generated stably in the post-plating operation.

10: energized roll
20: Backup Roll
30, 40: Plating bath
100: strip
101: edge portion
200: Edge mask
210: Rollers
300: Roller contact portion
400:

Claims (13)

An edge mask disposed at regular intervals along edge portions of the steel strip,
A roller for arbitrarily rotatably installed on the edge mask and for dropping the dendritic crystal generated in the strip edge portion,
And a roller contact portion provided on the roller to closely contact the roller with the strip edge portion,
And the dendritic crystal removing device of the plated steel sheet. The method according to claim 1,
Further comprising a gap adjusting unit (120) provided on an outer surface of the edge mask to adjust a gap between the edge mask and the edge of the steel strip strip. 3. The method according to claim 1 or 2,
A plurality of energizing rolls and backup rolls for sequentially passing the steel strips are installed at upper and lower portions of the steel strip at regular intervals,
A plating bath is provided between the energizing roll and the adjacent energizing roll,
Wherein the roller adhering portion is provided between the energizing roll and the plating bath. The method according to claim 1,
Wherein the roller-
An extension plate extending outwardly of the edge mask,
A frame fixedly coupled to the extension plate,
A moving frame which is installed at a predetermined distance from the frame and in which the roller is rotatably engaged,
And an elastic member provided between the frame and the moving frame for applying an elastic force to the roller. 5. The method of claim 4,
And two hinge plates for connecting the rollers in a rotatable manner by a hinge pin are installed at a predetermined distance at one end of the moving frame. Apparatus for removing dendritic crystals of plated steel sheets. 5. The method of claim 4,
And a guide rod for guiding the movement of the moving frame is coupled to the frame. The method according to claim 6,
Wherein the elastic member is provided on an outer peripheral surface of the guide rod. 8. The method of claim 7,
And a male screw coupled to the nut is formed on the outer peripheral surface of one end of the guide rod. 9. The method of claim 8,
And an inner thread for engaging with the bolt is formed on the inner circumferential surface of the other end of the guide rod. The method of claim 3,
Wherein the interval adjusting unit comprises:
And a linear sensor provided on an outer side of one end and the other end of the plating bath for detecting an edge portion of the steel strip. 11. The method of claim 10,
Wherein the interval adjusting unit comprises:
A rod member fixedly installed on an outer surface of the edge mask at regular intervals,
An adjusting body fixed to one end of the rod member,
And a ball screw and a ball screw nut screwed to the adjuster body to move the adjuster body in the width direction of the strip. 12. The method of claim 11,
And a servo motor for rotating the ball screw in one direction or the other direction is coupled to one end of the ball screw. 13. The method of claim 12,
Wherein the servo motor approaches or separates the edge mask with the strip edge portion according to detection information of the linear sensor.

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