KR100782738B1 - Apparatus for removing metallic powder from the surface of conduct rolls - Google Patents

Abstract

An apparatus for removing metallic powder from a surface of a conductive roll is provided to effectively remove the metallic powder when the metallic powder is formed on the surface of the conductive roll. An apparatus for removing metallic powder from the surface of a conductive roll includes a support frame(10). The support frame is disposed on the conductive roll in a longitudinal direction of the conductive roll and is fixed to a support structure. The support frame is fixed to a side support structure at its both ends, and has an inversed U-shaped structure. The support frame includes a plurality of bearing blocks(15a,15b), and a screw shaft(20). The blocks are disposed on the conductive roll. The screw shaft can be rotated on the bearing blocks.

Description

Apparatus For Removing Metallic Powder From The Surface of Conduct Rolls}

1 is a perspective view showing an electrolytic zinc-nickel plating apparatus according to the prior art;

2 is a perspective view showing a state in which the metal powder is attached to the edge surface of the strip in the electro zinc-nickel plating equipment according to the prior art;

3 is a layout view in which the metal powder removing apparatus of the conductive roll surface according to the present invention is mounted in an electro zinc-nickel plating apparatus;

4 is a front view showing the detailed structure of the metal powder removing apparatus of the conductive roll surface according to the present invention;

5 is a cross-sectional view of the magnetic roller provided in the metal powder removing apparatus of the conductive roll surface according to the present invention;

6 is a layout view in which the metal powder removing apparatus of the conductive roll surface according to the present invention is mounted in an electro zinc-nickel plating facility.

       <Description of the symbols for the main parts of the drawings>

1 .... Metal powder removal apparatus on the surface of the conductive roll according to the present invention

5 .... support structure 10 .... support

15a, 15b .... Bearing block 20 .... Screw shaft

30 .... Driving means 50 .... Magnetic roller

52 .... Female thread part 55 .... Guide rod

57 .... sleeve bearing 60 ... magnet part

62 .... Protrusion 100 .... Zinc-Nickel Plated

110 .... strip 120 .... conductive roll

125 .... conductive roll band 140 .... metal powder

The present invention relates to an apparatus for removing metallic powder from the conductive roll surface of a zinc-nickel electroplating strip manufacturing process, and more particularly, by effectively removing metal powder generated by current concentration at a strip edge during continuous operation. The present invention relates to an apparatus for removing metal powder on a conductive roll surface which is improved to improve the surface quality of a strip.

In general, in a carousel zinc-nickel electroplating strip manufacturing process, as shown in FIG. 1, the strip 110 passes through the zinc-nickel plating bath 100, and supplies power while guiding the strip 110. The conductive roll 120 is provided to proceed with the electroplating operation.

The conductive roll 120 is rotated in the plating bath 100 by the drive means 30 (not shown), the configuration is a rubber coating to form the outer shell of the conductive roll 120 in appearance The layer 122 and the conductive roll band part 125 formed in the center part of the conductive roll 120 are included. In particular, the conductive roll band 125 is made of a special material called Wiscallpy CRA30 material to function to uniformly transmit the current of the strip (110).

In addition, the conductive roll band portion 125 is formed to have a width of approximately 700 mm and supplies current for electroplating to the strip 110 wound around.

On the other hand, the strip 110 through which the plating operation is performed while passing through the zinc-nickel plating bath 100, a lot of tension is applied in the process of passing through the conductive roll 120, and thus the band portion 125 of the conductive roll 120 is formed. The electroplating work is carried out with good contact and accordingly good current flow. In addition, since the strip 110 has various widths, electroplating is performed while varying the width of about 700 to 1650 mm.

The strip 110 has a concentration phenomenon of plating current at both edge portions of the strip 110 during electroplating, and a so-called burning phenomenon occurs at both edge portions such that the metal powder 140 exists. .

Accordingly, such metal powder 140 is present in the rubber coating layer 122 portion of the conductive roll 120, which is a metal on the surface of the wide strip 110 when the strip 110 changes from small to wide. There is a problem that the powder 140 is attached to reduce the quality of the electroplating product.

This state is shown in FIG. That is, in the case of electroplating that the width of the trailing strip 110 is greater than the width of the preceding strip 110, the metal powder 140 generated from the preceding narrow strip 110 has a wide strip 110. The metal powder 140 had a problem of greatly deteriorating the surface quality of the electroplating strip 110.

In addition, as described above, the metal powder 140 attached to the surface of the conductive roll 120 gradually grows in a large size and protrudes from the surface of the conductive roll 120 so that the surface of the strip 110 is wound around the conductive roll 120 and moved. It was to cause cracks or bends in the product, and to cause the failure of the finished product.

SUMMARY OF THE INVENTION The present invention has been made to solve the conventional problems as described above, and an object thereof is that when metal powder is formed on the surface of the conductive roll by current concentration at the strip edge during electroplating, it is possible to effectively remove the trailing strip. The present invention provides an improved apparatus for removing metal powder on a conductive roll surface to effectively improve surface quality of an electroplating strip by effectively preventing adhesion to the surface.

And the present invention can prevent the bending of the strip surface due to the metal powder generated by protruding from the surface of the conductive roll, improved work efficiency and improved to produce a good quality strip having a beautiful surface of the electroplating product The present invention provides a device for removing metal powder on the surface of a conductive roll.

In order to achieve the above object, the present invention, in the electroplating apparatus for electroplating the surface of the strip,

A support disposed on the upper side of the conductive roll in the longitudinal direction of the conductive roll and fixed to the support structure;

A screw shaft rotatable on a bearing block fixed to the support object;

Drive means for rotating the screw shaft forward and backward; And

And a magnetic roller mounted to the screw shaft by screwing and movable in the longitudinal direction of the conductive roll, and attaching and removing metal powder attached to the conductive roll surface from the conductive roll by magnetic force.
The magnetic roller includes a female screw portion screwed to the screw shaft and a cylindrical magnet portion coaxially disposed rotatably through a sleeve bearing to the female screw portion, the female screw portion being disposed on a guide rod coaxially disposed on the screw shaft. Provided is a metal powder removal apparatus for the surface of the conductive roll, characterized in that it is slidably coupled.

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And the present invention preferably, the magnetic roller is formed on the surface of the plurality of sharp protrusions are formed by crushing the metal powder attached to the surface of the conductive roll and then attached by magnetic force metal on the surface of the conductive roll Provided is a powder removing device.

In addition, the present invention is preferably characterized in that the screw shaft, the drive means and the magnetic rollers are arranged in a plurality of side by side in the longitudinal direction of the conductive roll to remove metal powders located at both edge portions of the strip from the conductive roll. Provided is a metal powder removal apparatus for a conductive roll surface.

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

The metal powder removing apparatus 1 of the conductive roll surface according to the present invention is applied to an electroplating apparatus for performing electroplating on the surface of the strip 110, as shown in FIGS. 3 and 4.

The metal powder removing device 1 of the conductive roll surface according to the present invention has a support 10 which is arranged in the longitudinal direction of the conductive roll 120 on the upper side of the conductive roll 120 and fixed to the supporting structure 5. do.

Both ends of the support 10 are fixed to the lateral support structure 5 of the plating bath 100, and have a rigid fin-shaped structure, and in the longitudinal direction of the conductive roll 120, that is, the strip 110. ) In the width direction.

And the support 10 is disposed on the upper side of the conductive roll 120, and provided with a plurality of bearing blocks (15a, 15b) fixed on the support (10), the bearing block (15a) ( And a screw shaft 20 rotatable on 15b). The screw shaft 20 is supported on the inside of the bearing block 15b so that one side passes through the bearing block 15a and the other side is rotatable.

In addition, the present invention includes a drive means 30 for rotating the screw shaft 20 forward and reverse.

The driving means 30 may be formed of an electric motor capable of forward and reverse rotation, and the worker may connect the screw shaft 20 to the shaft 30a of the driving means 30 to provide bearing blocks 15a and 15b. ), The screw shaft 20 is rotated forward and reverse.

And the present invention is screwed to the screw shaft 20 is movable in the longitudinal direction of the conductive roll 120, the metal powder 140 attached to the conductive roll surface is attached from the conductive roll 120 by magnetic force And a magnetic roller 50 to be removed.

As shown in FIG. 5, the magnetic roller 50 forms a female screw portion 52 therein and is screwed to the screw shaft 20, and the screw shaft 20 is connected to the female screw portion 52. The guide rod 55 is slidably fitted in parallel with each other, and both ends of the guide rod 55 are fixed to the outside of the bearing blocks 15a and 15b.

Through this structure, when the driving means 30 rotates forward and reverse, the female screw portion 52 screwed onto the screw shaft 20 is along the guide rod 55 and the screw shaft 20, that is, It moves linearly left and right in the longitudinal direction of the conductive roll 120.

In addition, the magnet roller 50 is coupled to the outer side of the female screw portion 52 so that the cylindrical magnet portion 60 is coaxially rotatable through the sleeve bearing 57. That is, the magnet portion 60 is rotatable on the female screw portion 52 through the sleeve bearing 57 disposed in the center thereof.

In addition, an outer circumferential surface of the cylindrical magnet portion 60 of the magnet roller 50 is close to the surface of the conductive roll 120 but is not in contact with it. This is because when the magnetic roller 50 is moved by the driving means 30, the magnetic roller 50 is close to the conductive roll 120 but is not in contact with it so as not to damage the surface of the conductive roll 120. It is a state.

Therefore, the magnet part 60 attaches the metal powder 140 attached to the surface of the conductive roll 120 to the surface by using the magnetic force provided in the magnet part 60.

In addition, the present invention preferably, a plurality of sharp protrusions 62 are formed on the surface of the magnetic roller 50 to crush the metal powder 140 attached to the surface of the conductive roll 120 and then to the magnetic force. Attach it. That is, a plurality of pointed protrusions 62 are formed on the outer surface of the magnet portion 60 of the magnet roller 50, and the protrusions 62 remain in close proximity to the outer surface of the conductive roll 120. The pointed protrusions 62 fracture the metal powder 140 protruding from the conductive roll surface. The pointed fine protrusions 62 may be limitedly disposed at the center portion of the magnet part 60.

Therefore, when the conductive roll 120 is rotated, the metal powders 140 are in contact with the fine protrusions 62 and are crushed, and the crushed metal powders 140 are caused by the magnetic force provided in the magnetic roller 50. It is attached to the surface of the magnet portion 60.

And the present invention preferably, the screw shaft 20, the drive means 30 and the magnetic rollers 50 are arranged in a plurality of side by side in the longitudinal direction of the conductive roll 120, respectively, both edges of the strip 110 The metal powders 140 located in the portion are removed from the conductive roll 120.

As shown in FIG. 6, the magnetic rollers 50 are disposed at both edge portions of the strip 110 so that the plurality of metal rollers 140 may be arranged side by side to remove the metal powder 140 from the conductive roll 120. will be. In this case, the operator can easily move the position of the magnet roller 50 separately in accordance with the position of the metal powder 140 attached to the surface of the conductive roll 120.

The metal powder removing device 1 of the conductive roll surface according to the present invention configured as described above has a metal powder 140 formed by current concentration at both edge portions of the strip 110 during the electroplating operation, and the conductive roll 120 When attached to the metal powder 140 is effectively removed.

In such a case, the operator performs the electroplating of the narrow strip 110 and then removes the metal powder 140 from the conductive roll 120 before plating the wide strip 110.

To this end, the magnetic roller 50 is moved to a portion where the metal powder 140 is formed, and at this time, the operator operates the driving means 30, and the screw shaft 20 is rotated by the driving means 30. The magnetic roller 50 moves to the point where the female screw portion 52 moves along the guide rod 55 in the longitudinal direction of the conductive roll 120 to form the metal powder 140.

When the conductive roll 120 is rotated in this state, the metal powders 140 attached to the conductive roll 120 are attached to the outer surface of the magnet part 60 of the magnetic roller 50 by magnetic force. In the process, the fine protrusions 62 formed on the surface of the magnet part 60 crush the metal powder 140 so that it is more easily attached to the magnet part 60 side.

On the other hand, since the magnet part 60 of the magnet roller 50 is rotatable on the female screw part 52, due to the friction of the metal powder 140 and the magnet part 60 in accordance with the rotation of the conductive roll 120. It can rotate on the female screw part 52. Therefore, the metal powder 140 is attached to the surface of the magnet part 60 by being moved from the conductive roll 120, and the conductive roll 120 is in a state where the metal powder 140 is cleaned.

In this way, the metal powder 140 attached to the rubber coating layer 122 of the conductive roll 120 is removed, and the wide strip 110 is electroplated by changing the width of the wide strip 110. There will be no metal powder 140 attached to the electroplating operation while maintaining excellent quality of the surface of the strip 110.

According to the present invention as described above, when the metal powder is produced by the concentration of current at the strip edge during the electrical operation of the strip, it is possible to ensure a stable surface quality of the strip stably by removing it from the conductive roll surface cleanly from the initial generation Can be.

And since the metal powder is crushed and removed, it is possible to prevent the bending of the strip surface generated by protruding from the surface of the conductive roll, to improve the work efficiency and to produce a good quality strip having a beautiful surface of the electroplating product. Is obtained.

While the invention has been shown and described with respect to specific embodiments thereof, it has been described by way of example only to illustrate the invention, and is not intended to limit the invention to this particular structure. Those skilled in the art will appreciate that various modifications and changes of the present invention can be made without departing from the spirit and scope of the invention as set forth in the claims below. Nevertheless, it will be clearly understood that all such modifications and variations are included within the scope of the present invention.

Claims (4)

In the electroplating apparatus for electroplating the surface of the strip, A support disposed on the upper side of the conductive roll in the longitudinal direction of the conductive roll and fixed to the support structure; A screw shaft rotatable on a bearing block fixed to the support object; Drive means for rotating the screw shaft forward and backward; And And a magnetic roller mounted to the screw shaft by a screw and movable in the longitudinal direction of the conductive roll, and attaching and removing metal powder attached to the conductive roll surface from the conductive roll by magnetic force. The magnetic roller includes a female screw portion screwed to the screw shaft and a cylindrical magnet portion coaxially disposed rotatably through a sleeve bearing to the female screw portion, the female screw portion being disposed on a guide rod coaxially disposed on the screw shaft. Metal powder removing device on the surface of the conductive roll, characterized in that it is slidably coupled. delete The method of claim 1, wherein the magnetic roller is formed with a plurality of sharp protrusions on the surface of the metal powder to remove the metal powder attached to the surface of the conductive roll and then attached by magnetic force to remove the metal powder on the surface of the conductive roll Device. The conductive roll according to claim 1, wherein the screw shaft, the driving means and the magnetic rollers are arranged in a plurality of side by side in the longitudinal direction of the conductive roll to remove metal powders located at both edge portions of the strip from the conductive roll. Metal powder removal device on the surface.

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