KR102207705B1 - Roller apparatus and plating systems - Google Patents

Abstract

The present invention relates to a roller device and a plating facility, comprising: a roller member extending in one direction and rotatable; And blocking members disposed on both sides of the roller member to surround the circumference of the roller member. And a support member for fixing the blocking member so that only the roller member can rotate, and it is possible to suppress or prevent the fluid from scattering during processing of the object to be treated.

Description

Roller apparatus and plating systems

The present invention relates to a roller device and a plating facility, and more particularly, to a roller device and a plating facility capable of suppressing or preventing fluid from scattering in a process of processing an object to be treated.

In general, the cold rolling process of a steel mill includes an electroplating process of forming a plating layer on the surface of the steel sheet in order to improve the corrosion resistance of the steel sheet. This electroplating process uses a plating solution such as sulfuric acid containing metal ions such as zinc, and may be performed using an electroplating facility including a pair of electrodes and a roller device. In this electroplating process, a metal ions contained in the plating solution can be attached to the steel sheet by attaching metal ions contained in the plating solution to the steel sheet by applying a current to the electrode and the steel sheet while transporting the steel sheet using a roller device to generate a potential difference between the electrode and the steel sheet. .

Meanwhile, in the electroplating process, a plating solution may be supplied between electrodes to form a plating layer in a state in which the steel sheet is immersed in the plating solution. Accordingly, the upper roller member and the lower roller member are disposed at the front and rear sides of the electrode with respect to the transfer direction of the steel sheet, and edge masks are disposed on both sides of the electrode to fill the plating solution between the electrodes. The plating solution filled between the electrodes may flow toward the upper roller member and the lower roller member disposed in front and rear of the electrode and may be collected in a collection tank for recovering the plating solution. At this time, since the upper roller member and the lower roller member are formed to extend in a direction crossing the transfer direction of the steel sheet, for example, in the width direction of the steel sheet, the plating solution may rapidly flow out of the upper roller member and the lower roller member. . When the plating solution rapidly flows out of the upper roller member and the lower roller member as described above, the plating solution is not filled between the electrodes, so that the plating layer cannot be formed smoothly on the surface of the steel sheet. Therefore, by installing a ring-shaped blocking member called a slinger on both sides of the upper roller member and the lower roller member, the phenomenon that the plating solution rapidly leaks to both the upper and lower roller members is suppressed.

Such a blocking member is fitted to the upper roller member and the lower roller member, and is connected to rotate together with the lower roller member and the upper roller member. Therefore, when the upper and lower roller members are rotated to transfer the steel sheet, the blocking member rotates together with the upper and lower rollers, and the plating solution embedded in the blocking member is scattered to the surrounding facilities by centrifugal force. Is done. The plating solution scattered in this way adheres to surrounding facilities, and there is a problem in that the surrounding facilities are corroded or damaged.

In addition, when the scattered plating solution adheres to the roller member, there is a problem in that a defect is generated in the plating layer, resulting in a decrease in process yield and productivity.

KR 10-0833077 B KR 10-2014-0003686 A

The present invention provides a roller device and a plating facility capable of suppressing the scattering of fluid in the process of processing an object to be treated.

The present invention provides a roller device and a plating facility capable of improving the process yield and productivity of an object to be treated.

The present invention provides a roller device and plating facility that facilitates maintenance of the facility.

A roller device according to an embodiment of the present invention includes a roller member extending in one direction and rotatable; And blocking members disposed on both sides of the roller member to surround the circumference of the roller member. And a support member for fixing the blocking member so that only the roller member can rotate.

The roller member, a rotation shaft extending in one direction; And a roller body provided to surround the center of the rotation shaft, wherein the blocking member is provided at an edge of the rotation shaft and may be disposed to be spaced apart from the outer peripheral surface of the rotation shaft.

It may include a gap maintaining member for maintaining a gap between the rotation shaft and the blocking member.

The gap maintaining member may include a first magnet provided in the blocking member; And a second magnet provided on the rotation shaft, wherein the first magnet and the second magnet may be provided so that the same pole faces each other.

A lubrication member may be provided on an outer circumferential surface of the rotation shaft facing the blocking member.

The lubricating member may include at least one of a structure formed of the same material as the blocking member and provided on the roller member, and a coating film formed on at least one of the roller member and the blocking member using a lubricant. .

A groove portion recessed along an outer circumferential surface of the rotation shaft facing the blocking member may be formed, and at least a portion of the blocking member may be disposed in the groove portion.

And a connection member connected to the rotation shaft to fix the support member, and the connection member includes a bearing block whose inner side contacting the rotation shaft becomes a free side, and an outer side to which the support member is fixed becomes a fixed side. can do.

It may include an auxiliary support member provided to be spaced apart from the roller member to fix the support member.

A plating facility according to an embodiment of the present invention is a plating facility for forming a plating layer on a surface of an object to be treated using a plating solution, comprising: a roller member for transferring the object to be treated; A blocking member disposed to block the movement of the plating solution to the outside of the roller member; And a support member for supporting the blocking member so as to independently rotate the roller member.

The support member may be fixed by separating the blocking member from the roller member at one end.

A gap maintaining member for generating a repulsive force between the roller member and a surface facing the blocking member may be included so that a gap is formed between the roller member and the blocking member.

A lubricating member may be included on at least one surface where the roller member and the blocking member face each other.

The roller member may include a groove recessed along an outer circumferential surface facing the blocking member, and the blocking member may be provided such that at least a portion of the blocking member is inserted into the groove.

The roller member includes an upper roller member and a lower roller member, the blocking member is located at both ends of each roller member in a direction in which the roller members extend, and the support member is an upper support member located above the upper roller member And a lower support member positioned under the lower roller member.

The object to be treated includes a steel plate, and a separation distance between the roller member and the blocking member may be greater than 0 mm and less than or equal to 5 mm.

According to an embodiment of the present invention, it is possible to suppress or prevent the fluid from scattering during processing of the object to be treated. A roller member for transporting the object to be treated and a blocking member provided in the roller member can be independently configured. Accordingly, when the roller member is rotated, the blocking member is kept in a fixed state, so that splashing or scattering of the fluid attached to the blocking member can be suppressed or prevented. Through this, it is possible to reduce the maintenance cost of the facility by preventing contamination or damage to surrounding facilities due to scattering of a fluid such as a plating solution. In addition, the scattered fluid is prevented from adhering to surrounding facilities and causing defects in the object to be treated, thereby improving the quality and productivity of the object to be treated.

1 is a schematic view showing a plating facility according to an embodiment of the present invention.
Figure 2 is a perspective view showing the structure of the main part of the plating equipment shown in Figure 1;
3 is a cross-sectional view of the roller device taken along line A-A' in FIG. 2;
4 is a cross-sectional view of an upper roller device according to a first modified example of the present invention.
5 is a cross-sectional view of an upper roller device according to a second modified example of the present invention.
6 is a cross-sectional view of an upper roller device according to a third modified example of the present invention.
7 is a cross-sectional view of the upper roller device taken along line B-B' of FIG. 7;
8 is a cross-sectional view of an upper roller device according to a fourth modified example of the present invention.
9 is a cross-sectional view of an upper roller device according to a fifth modified example of the present invention.
10 is a view showing a comparison of the state of use of a general roller device and a roller device according to an embodiment of the present invention.

Hereinafter, a method and an apparatus for manufacturing a cast iron according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in a variety of different forms, only the present embodiments make the disclosure of the present invention complete, and the scope of the invention to those of ordinary skill in the art It is provided to inform you. In the description, the same reference numerals are assigned to the same components, and the drawings may be partially exaggerated in size in order to accurately describe the embodiments of the present invention, and the same numerals refer to the same elements in the drawings.

The roller device according to the present invention can prevent the fluid attached to the roller device from scattering during the process of processing the object to be treated. Hereinafter, a plating facility for forming a plating layer on a steel plate, which is one of the targets, will be described, for example, a roller device applied to an electroplating facility. Can be applied to process.

1 is a view schematically showing a plating facility according to an embodiment of the present invention, FIG. 2 is a perspective view showing a structure of the main parts of the plating facility shown in FIG. 1, and FIG. 3 is a view taken along line A-A' of FIG. It is a cross-sectional view of a roller device.

Referring to FIG. 1, a plating facility according to an embodiment of the present invention includes an electrode 11 installed in a plating solution bath (not shown) that provides a space for forming a plating layer on an object to be treated, for example, a steel plate S. , It may include a roller device 200 provided in front and rear of the electrode 11 in the conveying or traveling direction of the steel plate S, and a nozzle 12 for supplying a plating solution. Here, the direction in which the plating solution bath is extended and the direction in which the steel plate S is transferred are defined as the longitudinal direction, and the direction intersecting the longitudinal direction is defined as the width direction.

The plating solution bath may be provided to extend in one direction, and may be used as a path for transporting or advancing the steel plate (S). An electrode 11 may be provided inside the plating solution bath. The electrode 11 may include an upper electrode 11a and a lower electrode 11b spaced apart in the vertical direction. The upper electrode 11a and the lower electrode 11b are provided to face each other, so that a space for forming a plating layer on the steel plate S may be formed.

The roller device 200 is provided at the front and rear sides of the electrode 11 in the transfer direction of the steel plate S, and can transfer the steel plate S between the upper electrode 11a and the lower electrode 11b through rotation. have. The roller device 200 may include an upper roller device 210 and a lower roller device 220, and is installed adjacent to the electrode 11 to accommodate a plating solution between the electrode 11 and the electrode 11 Can be formed. In addition, edge masks 40 may be provided on both sides of the electrode 11 in a direction crossing the transfer direction of the steel plate S. The edge mask 40 may be formed of an insulator, and may be provided to surround the edge of the steel plate S in order to prevent the current from being concentrated at the edge portion in the width direction of the steel plate S. Accordingly, the plating solution supplied through the nozzle 12 may be filled in a space formed between the electrode 11, the roller device 200, and the edge mask 40. The plating facility may include a collection tank 13 for recovering the plating solution supplied to the space formed between the electrode 11, the roller device 200 and the edge mask 40. The collection tank 13 may be disposed under the roller device 200 in the width direction of the plating solution tank.

Referring to FIG. 2, a plating facility according to an embodiment of the present invention includes roller members 212 and 222 for transferring an object to be treated, such as a steel plate S, and applying a current to the steel plate S, and a roller Blocking members 216 and 226 provided on both sides of the roller members 212 and 222 to block the movement of the plating solution to the outside of the members 212 and 222 and disposed to surround the outer circumferential surfaces of the roller members 212 and 222 ) And the support members 230a and 230b supporting the blocking members 216 and 226 so that only the roller members 212 and 222 rotate. In addition, the plating facility according to an embodiment of the present invention may include a side cover member 30 for blocking outflow of the plating solution to the outside.

The roller device 200 may include a lower roller device 220 and an upper roller device 210 provided above the lower roller device 220.

The lower roller device 220 extends in one direction and is provided on both sides of the rotatable lower roller member 222 and the lower roller member 222 and is disposed to surround the lower roller member 222 ( It may include a lower support member 230b for fixing the lower blocking member 226 so that only the 226 and the lower roller member 222 can rotate.

The lower roller member 222 includes a lower rotation shaft 223 disposed in the width direction of the plating solution bath or the width direction of the steel plate S, and a lower roller body 224 provided to surround the center of the lower rotation shaft 223. I can. At this time, the lower roller body 224 may be formed to be at least longer than the width of the steel plate (S).

The lower blocking member 226 may be formed of a material such as rubber, and may be formed in a ring shape so as to surround the edge of the lower rotation shaft 223.

The upper roller device 210 is provided on both sides of the upper roller member 212 and the upper roller member 212 arranged parallel to the lower roller member 222 on the upper part of the lower roller member 222, and is provided on both sides of the upper roller member ( It may include an upper blocking member 216 disposed to surround the periphery of 212 and an upper support member 230a for fixing the upper blocking member 216 so that only the upper roller member 212 can rotate. In this case, the upper roller member 212 may include an upper rotation shaft 213 extending in the width direction of the plating solution bath, and an upper roller body 214 provided to surround the center of the upper rotation shaft 213. At this time, the upper roller body 214 may be formed to be at least longer than the width of the steel plate (S), and may be formed to have a length similar to or the same as the lower roller body 224.

The upper blocking member 216 may be formed of a material such as rubber, and may be formed in a ring shape to surround the edge of the upper rotation shaft 213. In this case, the upper blocking member 216 and the lower blocking member 226 may be provided in plural, and may be connected to the upper rotation shaft 213 and the lower rotation shaft 223 so as to be alternately or alternately disposed. And the upper blocking member 216 and the lower blocking member 226 may be formed to have the same diameter, one of the upper blocking member 216 and the lower blocking member 226, for example, the diameter of the lower blocking member 226 May be formed larger.

The steel plate S may be transferred through the lower roller member 222 and the upper roller member 212 by rotation of the lower roller member 222 and the upper roller member 212. At this time, the upper roller member 212 pressurizes while applying current to the steel plate S, and the lower roller member 222 serves to support the steel plate S and the upper roller member 212 in close contact with each other. Accordingly, the upper roller body 214 of the upper roller member 212 may be formed of steel or the like having conductivity and high strength. And the lower roller body 224 supports the steel plate S from the lower part of the upper roller body 214 so that the steel plate S can be in close contact with the upper roller body 214, and is made of rubber material having elasticity. Can be formed.

In addition, the side cover member 30 may be provided on both sides of the upper roller device 210 and the lower roller device 220, for example, at the edges of the upper rotation shaft 213 and the lower rotation shaft 223, respectively. The side cover member 30 may prevent the plating solution from flowing out of the upper roller body 214 and the lower roller body 224 together with the upper blocking member 216 and the lower blocking member 226. The side cover member 30 may include a frame-shaped side cover body 31 forming an outer shape, and an inner skin 32 provided inside the side cover body 31. In this case, the inner skin 32 may be formed of a material having softness such as rubber. The side cover member 30 is disposed in a direction that intersects the direction in which the upper rotation shaft 213 and the lower rotation shaft 223 extend, for example, in a vertical direction, and the upper rotation shaft 213 and the lower rotation shaft through the inner skin 32 It can be installed to wrap (223). In this case, the side cover member 30 may be provided in more than one, and may be disposed so as to alternate with the upper blocking member 216 and the lower blocking member 223 or alternately.

In this way, the lower roller device 210 and the upper roller device 220 may be formed in a similar structure as the material of the lower roller body 224 and the upper roller body 214 are different. Therefore, hereinafter, the upper roller device 220 will be described as an example, and if necessary, the lower roller device 220 will be described.

3, the upper roller member 212 includes an upper rotation shaft 213 provided to extend in one direction, that is, in the width direction of the plating solution tank, and an upper roller body provided to surround at least a portion of the upper rotation shaft 213 ( 214) may be included. At this time, the upper rotation shaft 213 may be connected to a driver (not shown) for providing rotational force outside the plating bath.

The upper blocking member 216 may be formed in a ring shape, and may be provided to surround the upper rotation shaft 213. At this time, the inner diameter of the upper blocking member 216 may be formed larger than the diameter of the upper rotation shaft 213, and the outer diameter of the upper blocking member 216 may be formed to be at least larger than the diameter of the upper roller body 214. Through this configuration, the upper blocking member 216 may be disposed to be spaced apart from the outer peripheral surface of the upper rotation shaft 213.

A through hole (not shown) and a fixing groove (not shown) for connecting to the upper support member 230a may be formed in the upper blocking member 216. Alternatively, the upper blocking member 216 may be cut along the radial direction as shown in FIG. 8. At this time, the upper blocking member 216 may be formed with a through hole and a fixing groove for connecting to the upper support member 230a around the cut surface 216a, for example, inside the cut surface 216a.

The upper support member 230a may fix the upper blocking member 216 so that only the upper rotation shaft 213 is rotated, for example, the upper rotation shaft 213 can rotate relative to the upper blocking member 216. In other words, the upper support member 230a fixes the upper blocking member 216 to be spaced apart from the outer circumferential surface of the upper rotation shaft 213 so that it does not contact the upper rotation shaft 213 when the upper rotation shaft 213 is rotated, or The upper blocking member 216 may be fixed so as not to rotate together with the rotation shaft 213. In this case, each of the upper support member 230a and the lower support member 230b may be disposed in any direction in the circumferential direction of the upper rotation shaft 213 and the lower rotation shaft 223. However, in order to efficiently support the upper blocking member 216 and the lower blocking member 226, the upper support member 230a is on the upper side of the upper rotation shaft 213, and the lower support member 230b is the lower rotation shaft 223 It is better to place it on the lower side of ).

The upper support member 230a fixes the support frame 232 provided in parallel with the upper rotation shaft 213 to support the upper blocking member 216 through one end, and the upper blocking member 216 to the support frame 232a. It may include a first fixing member (234a) for. In this case, the support frame 232a may be disposed to be spaced apart from the upper rotation shaft 213, and may be formed to have a length capable of supporting the plurality of upper blocking members 216. In addition, a protrusion 233a for fixing the upper blocking member 216 may be formed on the support frame 232a. The protrusion 233a may be formed to extend in a direction crossing the length direction of the support frame 232a, for example, in a vertical direction. The protrusions 233a may be formed in the same number as the number of the upper blocking members 216, and a fastener for fastening the first fixing member 234a for fixing the upper blocking member 216 to each protrusion 233a (Not shown) may be formed.

The support frame 232a may be connected to the upper rotation shaft 213 using the second fixing member 236a. When the upper support member 230a is connected to the upper rotation shaft 213, there is a problem that the upper support member 230a and the upper blocking member 216 rotate due to the rotation of the upper rotation shaft 213. Accordingly, an upper connection member 240a, which enables rotation of the upper rotation shaft 213 and fixes the upper support member 230a, may be installed on the upper rotation shaft 213. In addition, the support frame 232a may be fixed to the upper connection member 240a using the second fixing member 236a. As for the upper connection member 240a, an outer side to which the upper support member 230a is connected becomes a fixed side, and an inner side to which the upper rotation shaft 213 is connected may be a bearing block or the like. Here, it has been described that the upper support member 230a is connected to the upper rotation shaft 213, but the upper support member 230a includes a plating bath or a separate auxiliary support member (not shown) spaced apart from the upper roller member 212. It can also be connected to other structures.

Through this configuration, the upper support member 230a can fix the upper blocking member 216 to be spaced apart from the outer peripheral surface of the upper rotation shaft 213. At this time, the support frame 232a is inserted into the through hole of the upper blocking member 216, and the first fixing member 234a is inserted into the fixing hole formed in the protrusion 233a and the fixing groove formed in the upper blocking member 216. By inserting, the upper blocking member 216 can be fixed to the support frame 232a. In addition, the support frame 232a to which the upper blocking member 216 is fixed may be fixed to the upper connection member 240a using the second fixing member 236a. Alternatively, after first fixing the support frame 232a to the upper connection member 240a, the upper blocking member 216 may be fixed to the support frame 232a.

Hereinafter, various modified examples of the roller device will be described.

4 is a cross-sectional view of an upper roller device according to a first modified example of the present invention.

Referring to FIG. 4, an upper roller device according to a first modified example of the present invention includes an upper roller member 212 for transferring a steel plate S and applying a current to the steel plate S, and an upper roller member 212. ), provided on both sides of the upper roller member 212 to block the movement of the plating solution to the outside, and disposed to surround the outer circumferential surface of the upper roller member 212, and the upper roller member 212 ), and an upper support member 230a for fixing the upper blocking member 216 so as to rotate only, and a gap maintaining member 250 for maintaining a gap between the upper blocking member 216 and the upper roller member 212. I can.

The upper blocking member 216 may be fixed to the upper support member 230a and provided to be spaced apart from the upper rotation shaft 213. At this time, one side of the support frame 232a may be connected to the upper rotation shaft 213 through the upper connection member 240a. Accordingly, as time elapses, sagging may occur due to the load of the support frame 232a and the upper blocking member 216. In this case, the upper blocking member 216 contacts the upper rotation shaft 213, and friction may occur between the upper blocking member 216 and the upper rotation shaft 213. Accordingly, the upper blocking member 216 may maintain a predetermined distance from the upper rotation shaft 213, that is, a distance by using the space maintaining member 250. At this time, the distance between the upper blocking member 216 and the upper rotation shaft 213, for example, a separation distance may be greater than 0 mm and less than or equal to 5 mm, more preferably about 2 to 4 mm. When the separation distance between the upper blocking member 216 and the upper rotation shaft 213 is too small, the support frame 232a is struck by the load of the support frame 232a and the upper blocking member 216, so that the upper blocking member 216 is There is a risk of contacting the upper rotation shaft 213. On the other hand, when the separation distance between the upper blocking member 216 and the upper rotating shaft 213 is too large, the plating solution flows out between the upper blocking member 216 and the upper rotating shaft 213 and the upper electrode 11a and the lower electrode ( There is a problem in that it is difficult to smoothly form a plating layer on the surface of the steel sheet (S) because the plating solution is not filled between 11b).

The gap maintaining member 250 may include a first magnet 250a connected to the upper blocking member 216 and a second magnet 250b connected to the upper rotation shaft 213. Here, the first magnet 250a and the second magnet 250b may be permanent magnets or electromagnets. Each of the first magnet 250a and the second magnet 250b may be formed in a ring shape, and the first magnet 250a and the second magnet 250b are formed on the upper side by using the third fixing members 252a and 252b. It may be fixed to the blocking member 216 and the upper rotation shaft 213, respectively. At this time, the first magnet 250a and the second magnet 250b may be connected to the upper blocking member 216 and the upper rotation shaft 213 so that the same pole faces each other. For example, the first magnet 250a and the second magnet 250b may be connected to the upper rotation shaft 213 and the upper blocking member 216 so that the N poles face each other. Alternatively, the first magnet 250a and the second magnet 250b may be connected to the upper blocking member 216 and the upper rotation shaft 213 so that the S poles face each other. In this way, when the first magnet 250a and the second magnet 250b are installed so that the same poles face each other, a repulsive force is generated between the first magnet 250a and the second magnet 250b, resulting in the upper blocking member 216 and the upper The spacing between the rotating shafts 213 may be maintained. Accordingly, it is possible to suppress or prevent the blocking member 216 from contacting the upper rotation shaft 213.

5 is a cross-sectional view of an upper roller device according to a second modified example of the present invention.

Referring to FIG. 5, an upper roller device according to a second modified example of the present invention includes an upper roller member 212 for transferring a steel plate S and applying a current to the steel plate S, and an upper roller member 212. ), provided on both sides of the upper roller member 212 to block the movement of the plating solution to the outside, and disposed to surround the outer circumferential surface of the upper roller member 212, and the upper roller member 212 ), and an upper support member 230a for fixing the upper blocking member 216 so as to rotate only, and a gap maintaining member 250 for maintaining a gap between the upper blocking member 216 and the upper roller member 212. I can. At this time, at least a portion of the upper rotation shaft 213 of the upper roller member 212 may have a groove 213a recessed along the circumferential direction of the upper rotation shaft 213, and a part of the upper blocking member 216 is a groove part. It can be arranged to be inserted into (213a). The grooves 213a may be formed in the same number as the upper blocking member 216.

When the groove 213a is formed in the upper rotation shaft 213 and a part of the upper blocking member 216 is disposed so as to be inserted into the groove 213a, the gap between the upper rotation shaft 213 and the upper blocking member 216 is Since it does not occur, the phenomenon that the plating solution L flows out of the upper roller member 212 can be more effectively suppressed or prevented while allowing the relative rotation of the upper rotation shaft 213.

6 is a cross-sectional view of an upper roller device according to a third modified example of the present invention, and FIG. 7 is a cross-sectional view of the roller device taken along line B-B' of FIG. 6.

Referring to FIG. 6, an upper roller device according to a third modified example of the present invention includes an upper roller member 212 for transferring a steel plate S and applying a current to the steel plate S, and an upper roller member 212. ), provided on both sides of the upper roller member 212 to block the movement of the plating solution to the outside, and disposed to surround the outer circumferential surface of the upper roller member 212, and the upper roller member 212 ), and an upper support member 230a for fixing the upper blocking member 216 so as to rotate only, and a gap maintaining member 250 for maintaining a gap between the upper blocking member 216 and the upper roller member 212. I can. At this time, at least a portion of the upper rotation shaft 213 of the upper roller member 212 may have a groove 213a recessed along the circumferential direction of the upper rotation shaft 213, and a part of the upper blocking member 216 is a groove part. It can be arranged to be inserted into (213a). In addition, the spacing member 250 may include a first magnet 250a connected to the upper blocking member 216 and a second magnet 250b connected to the upper rotation shaft 213. The first magnet 250a and the second magnet 250b may be formed in a ring shape, respectively, and the first magnet 250a and the second magnet 250b are cut off the top through the third fixing members 252a and 252b. It may be connected to the member 216 and the groove part 213a of the upper rotation shaft 213, respectively. At this time, the first magnet 250a and the second magnet 250b may be connected to the upper blocking member 216 and the upper rotation shaft 213 so that the same pole faces each other. For example, the first magnet 250a and the second magnet 250b may be connected to the upper blocking member 216 and the upper rotation shaft 213 so that the N poles face each other. Alternatively, the first magnet 250a and the second magnet 250b may be connected to the upper blocking member 216 and the upper rotation shaft 213 so that the S poles face each other. In this way, when the first magnet 250a and the second magnet 250b are installed so as to face the same poles, a repulsive force is generated between the first magnet 250a and the second magnet 250b. Therefore, a gap is maintained between the upper blocking member 216 and the upper rotating shaft 213, thereby enabling the relative rotation of the upper rotating shaft 213 and suppressing the phenomenon that the upper blocking member 216 contacts the upper rotating shaft 213 or Can be prevented.

Here, when the second magnet 250b is integrally formed, there is a problem that it is difficult to install the second magnet 250b into the upper rotation shaft 213 and install it in the groove 213a. Therefore, as shown in FIG. 7, the second magnet 250b is divided into at least two pieces to form an arc shape, and can be fixed to the groove 213a using the second fixing member 236a. have. In addition, the first magnet 250a may be divided into at least two or more pieces to form an arc shape, and may be fixed to the upper blocking member 216 using third fixing members 252a and 252b. In addition, the upper blocking member 216 may be cut in the radial direction of the upper blocking member 216 and may be installed to surround the upper rotation shaft 213 in the circumferential direction.

8 is a cross-sectional view of an upper roller device according to a fourth modified example of the present invention.

Referring to FIG. 8, an upper roller device according to a fourth modified example of the present invention includes an upper roller member 212 for transferring a steel plate S and applying a current to the steel plate S, and an upper roller member 212. ), provided on both sides of the upper roller member 212 to block the movement of the plating solution to the outside, and disposed to surround the outer circumferential surface of the upper roller member 212, and the upper roller member 212 ) May include an upper support member 230a for fixing the upper blocking member 216 to rotate and a lubricating member 260 for preventing friction between the upper blocking member 216 and the upper roller member 212 .

The upper blocking member 216 may be formed of rubber or the like, and the upper rotation shaft 213 may be formed of a metal material. Therefore, when the upper blocking member 216 contacts the upper rotation shaft 213, there is a problem that the upper blocking member 216 is worn or damaged. Therefore, it is possible to suppress or prevent the upper blocking member 216 from being worn or damaged due to contact with the upper rotation shaft 213 by using the lubrication member 260. The lubrication member 260 may be formed in a ring shape, and may be provided on at least one surface where the upper blocking member 216 and the upper rotation shaft 213 face each other, for example, on an outer peripheral surface of the upper rotation shaft 213.

The lubrication member 260 may include a structure formed of the same material as the upper blocking member 216, for example, rubber. When the upper blocking member 216 and the lubricating member 260 contact each other, the lubricating member 260 may cause slippage between the upper blocking member 216 and the lubricating member 260 to suppress friction. In particular, when the upper blocking member 216 and the lubricating member 260 are wet with the plating solution, such an effect may be further increased.

When the lubricating member 260 is formed of the same material as the upper blocking member 216 in this way, even if the upper blocking member 216 contacts the lubricating member 260, friction does not occur, so that the lubricating member 260 and the upper part Abrasion or damage of the blocking member 216 can be suppressed. Here, the lubricating member 260 is described as being connected to the upper rotation shaft 213, but the lubricating member 260 may be connected to the upper blocking member 216, and the upper rotation shaft 213 and the upper blocking member 216 It can also be connected. In this case, when the lubrication member 260 is connected only to the upper blocking member 216, the lubrication member 260 may be formed of the same material as the upper rotation shaft 213. And when the lubricating member is connected to the upper rotation shaft 213 and the upper blocking member 216, the lubricating member connected to the upper rotation shaft 213 and the lubricating member connected to the upper blocking member 216 are made of the same material. It is good to form.

The lubrication member 260 may be connected to the upper rotation shaft 213 without using a separate fixing member. In this case, the lubrication member 260 may be formed of a material having elasticity, such as a rubber material, to increase adhesion with the upper rotation shaft 213. Alternatively, the lubrication member 260 may be connected to the upper blocking member 216 using a separate fixing member such as a bolt.

Here, an example in which the lubricating member 260 is formed as a separate structure has been described, but the lubricating member 260 may include a coating film formed using a lubricant. At this time, the coating film may be formed using a lubricant. In this case, the coating film may be formed using a lubricant that does not dissolve in the plating solution, and may be formed on at least one of the upper rotation shaft 213 and the upper blocking member 216.

In addition, a lubricating member 260 formed in a ring-shaped structure may be installed on the upper rotation shaft 213, and a coating film may be additionally formed on the surface of the lubricating member 260 and the upper blocking member 216 using a lubricant. have.

Referring to FIG. 9, the upper roller device according to the fifth modified example of the present invention includes an upper roller member 212 for transferring a steel plate S and applying a current to the steel plate S, and an upper roller member 212. ), provided on both sides of the upper roller member 212 to block the movement of the plating solution to the outside, and disposed to surround the outer circumferential surface of the upper roller member 212, and the upper roller member 212 ) May include an upper support member 230a for fixing the upper blocking member 216 to rotate and a lubricating member 260 for preventing friction between the upper blocking member 216 and the upper roller member 212 . In this case, at least a portion of the upper rotation shaft 213 may have a groove 213a that is depressed along the circumferential direction, and a part of the upper blocking member 216 may be disposed to be inserted into the groove 213a. In addition, the lubrication member 260 may be formed in the groove 213a.

In this way, when the groove part 213a is formed in the upper rotation shaft 213, at least a part of the upper blocking member 216 is arranged to be inserted into the groove part 213a, and the lubricating member 260 is formed in the groove part 213a, , It is possible to more effectively suppress or prevent the leakage of the plating solution L between the upper rotation shaft 213 and the upper blocking member 216. At the same time, it is possible to suppress a phenomenon in which the upper blocking member 216 is worn or damaged due to contact with the rotating upper rotation shaft 213.

The embodiments and modified examples described above are not limited to each description and may be combined with each other.

Hereinafter, a method of forming a plating layer on a steel sheet using a plating facility according to an embodiment of the present invention will be described.

10 is a view showing a comparison of the state of use of a general roller device and a roller device according to an embodiment of the present invention.

When the steel plate S is provided, the steel plate S can be drawn into one side of the plating solution tank using the roller device 200 of the plating facility and transferred between the upper electrode 11a and the lower electrode 11b. At this time, before transferring the steel plate S between the upper electrode 11a and the lower electrode 11b, the process of injecting a plating solution between the upper electrode 11a and the lower electrode 11b using the nozzle 12 And, a process of applying current to the upper roller body 214 and the upper electrode 11a and the lower electrode 11b of the roller device 200 may be performed. When the electrode is applied in this way, the upper electrode 11a and the lower electrode 11b may act as an anode, and the upper roller body 214 may act as a cathode. At this time, the upper roller body 214 itself may not serve as a cathode, but may serve to apply a current in order to directly contact the steel plate S to form a cathode.

When a plating solution is supplied between the upper electrode 11a and the lower electrode 11b, and current is applied to the upper roller body 214, the upper electrode 11a, and the lower electrode 11b, the upper electrode 11a and the steel plate (S), a potential difference between the steel plate S and the lower electrode 11b may occur. Accordingly, metal ions contained in the plating solution move to and adhere to the steel sheet S having a low electric potential, thereby forming a plating layer on the surface of the steel sheet S.

In the process of plating the steel plate S as described above, the upper roller member 212 and the lower roller member 222 may rotate at a rotation speed of about 100 m/min. At this time, in the roller device according to the prior art, since the upper blocking member 216 is directly connected to the upper rotation shaft 213, as shown in FIG. 10A, when the upper rotation shaft 213 rotates, the upper rotation shaft ( 213). Accordingly, there is a problem that the plating solution buried in the upper blocking member 216 is splashed or scattered in all directions to contaminate surrounding facilities.

On the other hand, in the roller device according to the embodiment of the present invention, since the upper blocking member 216 is fixed to the upper support member 230a, as shown in FIG. 10B, even if the upper rotation shaft 213 rotates It is possible to maintain a fixed state without rotating together with the upper rotation shaft 213. In other words, the upper roller member 212 can rotate independently without affecting the upper blocking member 216. Here, only the upper roller device 210 has been mentioned, but the lower roller device 220 may also have the same effect.

Accordingly, it is possible to prevent the plating solution from splashing or scattering due to rotation of the upper blocking member 216 and the lower blocking member 226. In addition, it is possible to prevent the scattered plating solution from contaminating the surrounding facilities, thereby facilitating maintenance of the surrounding facilities.

In the above, the present invention has been described with reference to the above-described embodiments and the accompanying drawings, but the present invention is not limited thereto, but is limited by the claims to be described later. Therefore, those of ordinary skill in the art will appreciate that the present invention can be variously modified and modified without departing from the spirit of the claims to be described later.

110a: upper electrode 110b: lower electrode
120: nozzle 200: roller device
210: upper roller device 212: upper roller member
213: upper rotation shaft 213a: groove
214: upper roller body 216: blocking member
220: lower roller device 230a: upper support member
240a: upper connecting member 250: gap maintaining member
260: lubrication member

Claims (16)

A roller member extending in one direction and rotatable;
Blocking members disposed on both sides of the roller member to surround the circumference of the roller member;
A connection member connected to the roller member to rotate only the roller member; And
Including; a support member that supports the blocking member to be spaced apart from the roller member so that only the roller member can rotate, and is connected to the connection member,
A portion of the roller member facing the blocking member includes a groove recessed along an outer circumferential surface of the roller member, and a portion of the blocking member is inserted into the groove to block outflow of fluid between the blocking member and the roller member. Roller device. The method according to claim 1,
The roller member,
A rotating shaft extending in one direction; And
Includes; a roller body provided to surround the center of the rotation shaft,
The blocking member is provided at the edge of the rotation shaft, the roller device disposed to be spaced apart from the outer peripheral surface of the rotation shaft. The method according to claim 2,
A roller device comprising a gap maintaining member for maintaining a gap between the rotation shaft and the blocking member. The method of claim 3,
The spacing member,
A first magnet provided in the blocking member; And
Includes; a second magnet provided on the rotation shaft,
The first magnet and the second magnet is a roller device provided so that the same pole faces. The method according to claim 2,
A roller device comprising a lubricating member on an outer circumferential surface of the rotating shaft facing the blocking member. The method of claim 5,
The lubricating member is formed of the same material as the blocking member, the roller device including at least one of a structure provided on the roller member, and a coating film formed on at least one of the roller member and the blocking member using a lubricant . The method according to any one of claims 2 to 6,
The groove portion is a roller device formed on the rotation shaft. The method according to any one of claims 2 to 6,
A roller device including a bearing block in which the connecting member has an inner side in contact with the rotation shaft being a free side, and an outer side to which the support member is fixed is a fixed side. delete As a plating facility for forming a plating layer on the surface of an object to be treated using a plating solution,
A roller member for transferring the object to be processed;
A blocking member disposed to block the movement of the plating solution to the outside of the roller member;
A connection member connected to the roller member to rotate only the roller member; And
Including; a support member that supports the blocking member to be spaced apart from the roller member so as to independently rotate the roller member, and is connected to the connection member,
A portion of the roller member facing the blocking member includes a groove recessed along an outer circumferential surface of the roller member, and a portion of the blocking member is inserted into the groove to block outflow of fluid between the blocking member and the roller member. Plating equipment. delete The method of claim 10,
Plating equipment comprising a gap maintaining member for generating a repulsive force between the roller member and the blocking member so as to form a gap between the roller member and the blocking member. The method of claim 10,
Plating equipment comprising a lubricating member on at least one surface facing the roller member and the blocking member. delete The method according to claim 12 or 13,
The roller member includes an upper roller member and a lower roller member,
The blocking member is located at both ends of each roller member in the direction in which the roller members extend,
The support member is a plating facility comprising an upper support member positioned above the upper roller member and a lower support member positioned below the lower roller member. The method according to claim 12 or 13,
The object to be treated includes a steel plate,
Plating equipment in which the separation distance between the roller member and the blocking member is more than 0 mm and less than 5 mm.

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