KR20120069803A - Perpendicular continuous type plating apparatus - Google Patents

Abstract

PURPOSE: A perpendicular continuous plating apparatus is provided to obtain an automated process by using a clamp which automatically holds substrates drawn out successively and separates from the substrates after plating. CONSTITUTION: A perpendicular continuous plating apparatus comprises an unwinding roll(10), a winding roll(20), a main body(30), a conveyor(40), a plurality of clamps(50), a first rotating member(60), and a second rotating member(70). A clamp comprises a supporting part, a pressing part, a spring, and first and second contact parts which are opened by a guide member when the conveyor runs so that a substrate is arranged or removed and closed by the elasticity of the spring by after passing through the guide member. The guide member is installed in the main body and presses the upper side of the pressing part when the conveyor runs so that the second contact part separates from the first contact part.

Description

Vertical continuous type plating apparatus

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vertical continuous plating apparatus, and more particularly, to a vertical continuous plating apparatus in which a clamp is automatically separated from a substrate after the clamp is automatically caught and moved to plate a substrate which is continuously standing out and drawn out.

In general, substrates such as lead frames and printed circuit boards (PCBs) on which various electronic components are surface mounted are generally made of a hard material, and after plating a copper foil layer having excellent conductivity on the surface of such a substrate, necessary patterns are printed. After that, the necessary parts are mounted to complete the module and the product.

Looking at the conventional method of plating a copper foil on a rigid substrate, it is to be plated on the surface of the copper foil layer by gripping and transporting the substrate cut in a predetermined unit on an infinitely circulating belt.

However, in the copper foil plating apparatus using the same method, the plated material was easy to hard materials such as a semiconductor lead frame, but it was not easy to plate the copper foil on a flexible printed circuit board (FPCB).

Recently, due to the miniaturization and slimming of products, the use of FPCB instead of rigid leadframes and PCBs is increasing.

In the manufacturing process of such FPCB, a copper alloy film is formed by plating a copper alloy body on a surface of a substrate provided in a film form, and then, after removing a portion except a circuit pattern, a pattern is printed, and various parts are coated on the surface. It is supposed to be surface mounted.

In this case, the substrate may be a film, lead frame, FPCB, and the like.

Therefore, in recent years, in order to plate such a hard board | substrate, the board | substrate wound by the roll form is plated vertically and continuously moving, and this is wound up in roll form again.

In this case, since the substrate is standing vertically, it may be bent downward due to its own weight, and in order to prevent this, the substrate is held by using a plurality of clamps.

However, in this prior art, a technique for automatically holding or automatically detaching the clamp from the substrate drawn out continuously is insufficient.

In addition, if the tension is not constant while the substrate is drawn out and moved, problems with plating and the entire process could occur.

The present invention is to solve the above-mentioned problems, the vertical continuous plating apparatus that can maintain a constant tension on the continuously drawn out substrate, and the clamp is to automatically hold the substrate and automatically separated to achieve an automated process The purpose is to provide.

In order to achieve the above object, the vertical continuous plating apparatus of the present invention comprises: an unwinding roll on which a substrate is wound; A winding roll for winding the substrate withdrawn from the unwinding roll; A main body having a plating bath in which the substrate withdrawn from the unwinding roll is plated while moving to the take-up roll; A closed curved conveyor disposed above the plating bath and mounted to the main body to move the substrate from the unwinding roll to the take-up roll; A plurality of clamps that hold an upper portion of the substrate and are mounted to the conveyor and move with the conveyor; A first rotating body mounted to the main body to rotate the conveyor in contact with an inner end of the conveyor; A vertical continuous plating apparatus comprising a second rotating body mounted to the main body and in contact with an inner end of the conveyor to rotate the conveyor, wherein the clamp has an upper portion coupled to the conveyor and a lower portion contacting the substrate. A support portion having a first contact portion formed thereon; A press portion having a center portion rotatably hinged to the support portion and having a second contact portion contacting the first contact portion with the substrate interposed therebetween; A spring disposed between the upper portion of the pressing portion and the support portion to add elastic force to the pressing portion, and the main body presses the upper portion of the pressing portion when the conveyor rotates, so that the second contact portion is pressed against the first contact portion. The guide member is mounted to be opened, the clamp is the first contact portion and the second contact portion is opened by the guide member during the rotation of the conveyor, the substrate is placed or withdrawn therebetween, the clamp is Passing through the guide member is characterized in that the first contact portion and the second contact portion again contact each other by the elastic force of the spring.

The guide member may include: a first guide member disposed in a direction opposite to the first rotatable body with the substrate drawn out from the release roll therebetween; It consists of a second guide member which is disposed in the opposite direction of the second rotating body, with the substrate wound between the winding rolls, wherein the first guide member is before the substrate and the conveyor are arranged in parallel with each other The first contact portion and the second contact portion are opened to each other until the substrate is disposed between the first contact portion and the second contact portion by contacting the upper portion of the pressing portion in the direction of the substrate. The second guide member is in contact with the upper portion of the pressing portion before the substrate and the conveyor are disposed parallel to each other to rotate the second contact portion in the direction of the substrate so that the substrate from between the first contact portion and the second contact portion The first contact portion and the second contact portion are separated from each other until detached.

An upper portion of the pressing portion is mounted with a pressing roller which rotates in contact with the guide member.

The guide member includes a pressing surface protruding in the conveyor direction; A first inclined surface formed at one side of the pressing surface to be inclined in an opposite direction of the conveyor; The second inclined surface formed to be inclined in the opposite direction of the conveyor is formed on the other side of the pressing surface, the upper portion of the pressing portion is in contact with the first inclined surface so that the second contact portion is gradually opened with respect to the first contact portion, The first contact portion and the second contact portion are maintained in contact with the pressing surface, and the second contact portion is brought closer to the first contact portion in contact with the second inclined surface.

It is disposed between any one of the unwinding roll and the main body or between the main body and the take-up roll, further comprises a substrate tension holding unit for moving the substrate to a constant tension.

According to the vertical continuous plating apparatus of the present invention as described above has the following effects.

The clamp automatically opens the first contact portion and the second contact portion by the guide member when the conveyor rotates, and after the substrate is placed or drawn out therebetween, the clamp passes through the guide member to the first member. The contact part and the second contact part are automatically brought into contact with each other again by the elastic force of the spring, so that the clamp can be separated from the substrate after automatically holding and moving the plate which is continuously drawn out, thereby achieving an automated process. .

In addition, it is possible to maintain a constant tension on the substrate continuously drawn out by the substrate tension holding unit.

1 is a plan view of a vertical continuous plating apparatus according to an embodiment of the present invention,
Figure 2 is a side structure diagram of a vertical continuous plating apparatus according to an embodiment of the present invention,
3 is a perspective view of a clamp according to an embodiment of the present invention,
4 is an explanatory diagram for explaining a process of holding a substrate by a clamp according to an embodiment of the present invention;
5 is an explanatory diagram for explaining a process of detaching a clamp from a substrate according to an embodiment of the present invention;
6 is a state structure diagram when the clamp is holding the substrate according to the embodiment of the present invention;
7 is a state structure diagram when the clamp is open according to the embodiment of the present invention,

1 is a plan view of a vertical continuous plating apparatus according to an embodiment of the present invention, Figure 2 is a side structure diagram of a vertical continuous plating apparatus according to an embodiment of the present invention, Figure 3 according to an embodiment of the present invention Figure 4 is a perspective view of the clamp, Figure 4 is an explanatory diagram for explaining the process of holding the substrate by the clamp according to an embodiment of the present invention, Figure 5 is a view for explaining the process of the clamp is separated from the substrate according to an embodiment of the present invention 6 is an explanatory view of the state when the clamp according to the embodiment of the present invention is holding the substrate, and FIG. 7 is a state structure diagram when the clamp according to the embodiment of the present invention is opened.

1 and 2, the vertical continuous plating apparatus of the present invention, the unwinding roll 10, the winding roll 20, the main body 30, the conveyor 40, the clamp 50 ), A first rotating body 60, a second rotating body 70, and a substrate tension holding unit 80.

The unwinding roll 10 is formed in a cylindrical shape, and the substrate 90 is continuously wound.

The winding roll 20 is formed in a cylindrical shape, and is wound around the substrate 90 drawn out from the unwinding roll 10 continuously.

The main body 30 is disposed between the unwinding roll 10 and the take-up roll 20 and has a plating bath 31, so that the substrate 90 withdrawn from the unwinding roll 10 is the plating bath. It is plated while moving to the winding roll 20 passing through the (31).

The conveyor 40 is disposed above the plating bath 31 and mounted to the main body 30.

The conveyor 40 rotates to move the substrate 90 from the unwinding roll 10 to the take-up roll 20, and is formed in a closed curve shape.

The conveyor 40 may be configured in various types such as a chain conveyor, flat belt conveyor, timing belt conveyor.

The clamp 50 is composed of a plurality of the conveyor 40 is mounted, and moves with the conveyor 40 when the conveyor 40 is rotated.

The clamp 50 serves to hold the upper portion of the substrate 90 drawn out from the unwinding roll 10 and to move to the take-up roll 20.

The substrate 90 moves from the unwinding roll 10 to the winding roll 20 in a vertical state while a plurality of the clamps 50 hold the upper portion of the substrate 90 at a constant interval. Therefore, it is possible to prevent the substrate 90 from bending downward due to its own weight or from unevenly acting on the tension of the substrate 90.

The detailed structure of the clamp 50 will be described later.

The first rotating body 60 is formed in a cylindrical shape and is mounted on the main body 30 to rotate the conveyor 40 in contact with an inner end of the conveyor 40.

The second rotating body 70 is formed in a cylindrical shape and is mounted to the main body 30, and rotates the conveyor 40 in contact with the inner end of the conveyor 40.

At least one of the first rotating body 60 and the second rotating body 70 generates a rotating force by a motor or the like to rotate the conveyor 40.

When the conveyor 40 is formed of a chain, the first rotating body 60 and the second rotating body 70 are made of sprockets, and when the conveyor 40 is made of a belt or the like, the second rotating body is formed. 70 and the second rotating body 70 is made of a pulley, so that the conveyor 40 can be rotated well.

The substrate tension holding unit 80 is disposed between the unwinding roll 10 and the main body 30 and / or between the main body 30 and the take-up roll 20 so that the substrate 90 has a constant tension. Take it with you.

The substrate tension holding unit 80 is composed of a rotating roller in contact with the substrate 90, a rotating bar coupled to the rotating roller, and an elastic member for adding an elastic force to rotate the rotating bar.

The rotating bar and the rotating roller are always rotated in the direction in which the substrate 90 is kept tight by the elastic member, and the substrate 90 is always in the tensioned state by the substrate tension holding unit 80. You can move.

In addition, the first rotating body 60 and / or the second rotating body 70 is slidably mounted to the main body 30, and moves automatically when the length of the conveyor 40 is increased by using it for a long time. The conveyor 40 may always have a constant tension and maintain a taut state.

As shown in FIGS. 3, 6, and 7, the clamp 50 includes a support part 51, a pressing part 55, and a spring 59.

An upper portion of the support portion 51 is coupled to the conveyor 40, and a lower portion of the support portion 51 has a first contact portion 54 contacting the substrate 90.

The support part 51 is formed in the plate-shaped main portion 52 coupled to the conveyor 40, and a plurality of the main portion 52 is spaced apart from each other to protrude downwardly and the first portion at the bottom It consists of the leg part 53 in which the contact part 54 was formed.

A second portion of the pressing portion 55 is rotatably hinged to a leg portion 53 of the support portion 51, the second portion contacting the first contact portion 54 with the substrate 90 interposed therebetween. The contact portion 57 is formed.

The pressing portion 55 is formed with a bent portion 56 bent in a direction away from the support portion 51 with respect to the lower portion with respect to the center.

The spring 59 is disposed between the bent portion 56 and the leg portion 53 forming the upper portion of the pressing portion 55, the direction away from the leg portion 53 to the bent portion 56 Add elastic force.

As shown in FIG. 6 in the free state by the elastic force of the spring 59, the first contact portion 54 and the second contact portion 57 are in contact with each other, and as shown in FIG. When the part 56 moves in the direction in which the spring 59 is compressed, the second contact part 57 rotates in a direction away from the first contact part 54 so that the first contact part 54 and the second contact part are rotated. (57) are mutually open.

In addition, the main body 30 presses the bent part 56 formed on the pressing part 55 when the conveyor 40 rotates, so that the second contact part 57 is connected to the first contact part 54. It is equipped with a guide member to open against the.

The guide member, the pressing surface 37 protruding in the direction of the conveyor 40, the first inclined surface 38 formed to be inclined in the opposite direction of the conveyor 40 on one side of the pressing surface 37, and the On the other side of the pressing surface 37, a second inclined surface 39 formed to be inclined in the opposite direction of the conveyor 40 is formed.

When the clamp 50 moves, the bent part 56 formed on the pressing part 55 may be in contact with the first inclined surface 38 to compress the spring 59 while the second contact part 57 may be pressed. The first contact portion 54 is gradually opened to the first contact portion 54, the first contact portion 54 and the second contact portion 57 to maintain the mutually open state in contact with the pressing surface 37, the second inclined surface ( The second contact portion 57 is brought closer to the first contact portion 54 by the elastic restoring force of the spring 59 compressed in contact with 39.

Accordingly, the clamp 50 has the first contact portion 54 and the second contact portion 57 open by the guide member when the conveyor 40 rotates, and the substrate 90 is disposed or withdrawn therebetween. After that, the clamp 50 passes through the guide member such that the first contact portion 54 and the second contact portion 57 again contact each other by the elastic force of the spring 59.

The guide member may include a first guide member 35 disposed in a direction opposite to the first rotatable body 60 with the substrate 90 drawn out from the unwinding roll 10 and the winding roll. The second guide member 36 is disposed in a direction opposite to the second rotating body 70 with the substrate 90 wound therebetween.

The first guide member 35 is in contact with the bent portion 56 before the substrate 90 and the conveyor 40 are disposed in parallel to each other to contact the second contact portion 57 with the substrate 90. Direction so that the first contact portion 54 and the second contact portion 57 are separated from each other until the substrate 90 is disposed between the first contact portion 54 and the second contact portion 57. When the substrate 90 is disposed between the first contact portion 54 and the second contact portion 57, the second contact portion 57 may be connected to the first contact portion 54 by the elastic restoring force of the spring 59. The first contact portion 54 and the second contact portion 57 are rotated in the direction to hold the substrate 90.

In addition, the second guide member 36 contacts the bent portion 56 before the substrate 90 and the conveyor 40 are disposed not to be parallel to each other, thereby contacting the second contact portion 57 with the substrate. The first contact portion 54 and the second contact portion 57 are mutually open until the substrate 90 is separated from the first contact portion 54 and the second contact portion 57 by rotating in the (90) direction. After the substrate 90 is separated from the first contact portion 54 and the second contact portion 57, the second contact portion 57 is moved by the elastic restoring force of the spring 59. The first contact portion 54 and the second contact portion 57 are in contact with each other by rotating in the direction of (54).

The upper portion of the pressing portion 55, that is, the bent portion 56 may be in direct contact with the guide member, but the bending portion 56 is in contact with the guide member while the pressing portion 55 is moving. The pressure roller 58 which rotates in contact with the guide member is rotatably mounted in the opposite direction of the support 51.

The pressure roller 58 rotates along the guide member when the clamp 50 moves while being in contact with the guide member, so that the clamp 50 can be moved well by the conveyor 40.

Hereinafter, an operation process of the present invention having the above-described configuration will be described.

As the first rotating body 60 and the second rotating body 70 rotate, the conveyor 40 rotates.

As the conveyor 40 rotates, the clamp 50 coupled to the conveyor 40 also rotates together with the conveyor 40.

On the other hand, the unwinding roll 10 pulls out the substrate 90 being wound, and the unwinding roll 20 winds up the substrate 90 drawn out from the unwinding roll 10.

As shown in FIG. 4, the clamp 50 moving around the first rotating body 60 to the substrate 90 is connected to the first contact portion 54 by the first guide member 35. The second contact portions 57 are separated from each other.

4 (a) shows the operating state of the support 51 and the bent portion 56, Figure 4 (b) shows the operating state of the first contact portion 54 and the second contact portion (57). It is.

Before the pressing roller 58 mounted on the bent portion 56 comes into contact with the first guide member 35, the support 51 and the bent portion 56 are shown in FIG. 4 (a). As shown in FIG. 4B, the first contact portion 54 and the second contact portion 57 are spaced apart from each other.

As the conveyor 40 rotates, when the pressure roller 58 contacts the first inclined surface 38 of the first guide member 35, the bent portion 56 is illustrated in FIG. 4 (a). The curved portion 56 keeps being moved toward the support 51 until the pressure roller 58 passes through the pressing surface 37 by gradually moving toward the support 51.

In this case, before the substrate 90 and the conveyor 40 are disposed in parallel with each other, the pressing roller 58 mounted on the pressing unit 55 may have a first direction of the first guide member 35. In contact with the inclined surface 38.

Then, when the pressure roller 58 touches the second inclined surface 39, the bent portion 56 is gradually opened from the support portion 51 by the elastic restoring force of the spring 59 that has been compressed since then. When the clamp 50 is completely removed from the first guide member 35, the bent portion 56 is spaced apart from the support 51 as in the beginning.

In addition, the first contact part 54 and the second contact part 57 positioned below the support part 51 and the bent part 56 have the conveyor 40 as shown in FIG. 4 (b). As the pressure roller 58 contacts the first inclined surface 38 of the first guide member 35 as it rotates, the second contact portion 57 gradually moves away from the first contact portion 54 toward the pressure roller. The second contact portion 57 moves away from the direction of the first contact portion 54 until 58 passes through the pressing surface 37 while maintaining a state of mutual separation.

After that, when the pressure roller 58 touches the second inclined surface 39, the second contact portion 57 is connected to the first contact portion 54 by the elastic restoring force of the spring 59 that has been compressed since then. When the clamp 50 is completely disengaged from the first guide member 35, the first contact portion 54 comes into contact with the second contact portion 57 as in the beginning.

In this case, when the first contact portion 54 is separated from the second contact portion 57 by the first guide member 35, the clamp 50 is connected to the first contact portion 54. By being disposed across the upper portion of the substrate 90, the first contact portion 54 and the second contact portion 57 are positioned opposite to each other with respect to the substrate 90.

After that, when the clamp 50 is separated from the first guide member 35, the second contact portion 57 moves toward the first contact portion 54 by the elastic restoring force of the spring 59. The substrate 90 disposed therebetween is pressed, so that the first contact portion 54 and the second contact portion 57 automatically hold the upper portion of the substrate 90.

This is because the pressing part 55 rotates with respect to the support part 51 and ascends to a higher position than before the lower end of the second contact part 57 is rotated, so that the height H as shown in FIG. The substrate 90 is disposed through the space.

Thus, the substrate 90 coupled to the clamp 50 is plated while passing through the plating bath 31.

After the plating is finished, the clamp 50, which holds the substrate 90 and moves as shown in FIG. 5, is formed by the second guide member 36 and the first contact portion 54 and the second contact portion 57. ) Are separated from each other.

5 (a) shows the operating state of the support 51 and the bent portion 56, Figure 5 (b) shows the operating state of the first contact portion 54 and the second contact portion (57). It is.

Before the pressing roller 58 mounted on the bent portion 56 contacts the second guide member 36, the support 51 and the bent portion 56 are shown in FIG. 5 (a). As described above, the first contact portion 54 and the second contact portion 57 are in contact with each other with the substrate 90 interposed therebetween as shown in FIG.

As the conveyor 40 rotates, when the pressure roller 58 touches the first inclined surface 38 of the second guide member 36, the bent portion 56 is shown in FIG. 5 (a). The curved portion 56 keeps being moved toward the support 51 until the pressure roller 58 passes through the pressing surface 37 by gradually moving toward the support 51.

In this case, before the substrate 90 and the conveyor 40 are disposed not to be parallel to each other, the pressing roller 58 mounted on the upper portion of the pressing unit 55 may be formed of the second guide member 36. 1 is in contact with the inclined surface 38.

Then, when the pressure roller 58 touches the second inclined surface 39, the bent portion 56 is gradually opened from the support portion 51 by the elastic restoring force of the spring 59 that has been compressed since then. When the clamp 50 is completely separated from the second guide member 36, the bent portion 56 is spaced apart from the support 51 as in the beginning.

In addition, the first contact part 54 and the second contact part 57 positioned below the support part 51 and the bent part 56 have the conveyor 40 as shown in FIG. 5 (b). As the pressure roller 58 contacts the first inclined surface 38 of the second guide member 36 as it rotates, the second contact portion 57 gradually moves away from the first contact portion 54 toward the pressure roller. The second contact portion 57 moves away from the direction of the first contact portion 54 until 58 passes through the pressing surface 37 while maintaining a state of mutual separation.

After that, when the pressure roller 58 touches the second inclined surface 39, the second contact portion 57 is connected to the first contact portion 54 by the elastic restoring force of the spring 59 that has been compressed since then. When the clamp 50 is completely disengaged from the second guide member 36, the first contact portion 54 is in contact with the second contact portion 57 as in the beginning.

In this case, when the first contact portion 54 is separated from the second contact portion 57 by the second guide member 36, the clamp 50 is connected to the first contact portion 54. By being disposed across the upper portion of the substrate 90, the first contact portion 54 and the second contact portion 57 are positioned in the same direction with respect to the substrate 90.

After that, when the clamp 50 is separated from the second guide member 36, the second contact portion 57 moves toward the first contact portion 54 by the elastic restoring force of the spring 59. The first contact portion 54 and the second contact portion 57 are in contact with each other without the substrate 90.

This is because the pressing part 55 rotates with respect to the support part 51 and ascends to a position higher than before the lower end of the second contact part 57 is rotated, so that the height H shown in FIG. The clamp 50 is separated from the substrate 90 through the space.

In this way, the substrate 90 separated from the clamp 50 is wound up through the winding roll 20.

On the other hand, when the substrate 90 moving from the unwinding roll 10 to the take-up roll 20 is loosened, the substrate 90 is tensioned by the substrate tension holding unit 80 to maintain a constant tension. do.

According to the present invention as described above, the continuously moving substrate 90 can be subjected to plating and winding again while maintaining a constant tension without sagging, and also the substrate 90 by the clamp 50 and the guide member The clamp 50 may be automatically snapped or disengaged.

Vertical continuous plating apparatus of the present invention is not limited to the above-described embodiment, it can be carried out in a variety of modifications within the allowable range of the technical idea of the present invention.

10: unwinding roll, 20: winding roll, 30: main body, 31: plating bath, 35: first guide member, 36: second guide member, 37: pressing surface, 38: first inclined surface, 39: second inclined surface, 40: conveyor, 50: clamp, 51: support portion, 52: main portion, 53: leg portion, 54: first contact portion, 55: pressing portion, 56: bending portion, 57: second contact portion, 58: pressing roller, 59 : Spring, 60: first rotating body, 70: second rotating body, 80: substrate tension holding unit, 90: substrate,

Claims (5)

An unwinding roll on which the substrate is wound; A winding roll for winding the substrate withdrawn from the unwinding roll; A main body having a plating bath in which the substrate withdrawn from the unwinding roll is plated while moving to the take-up roll; A closed curved conveyor disposed above the plating bath and mounted to the main body to move the substrate from the unwinding roll to the take-up roll; A plurality of clamps that hold an upper portion of the substrate and are mounted to the conveyor and move with the conveyor; A first rotating body mounted to the main body to rotate the conveyor in contact with an inner end of the conveyor; In the vertical continuous plating apparatus is mounted to the main body, consisting of a second rotating body for rotating the conveyor in contact with the inner other end of the conveyor,
The clamp is,
An upper part coupled to the conveyor and having a first contact part formed at a lower part thereof in contact with the substrate;
A press portion having a center portion rotatably hinged to the support portion and having a second contact portion contacting the first contact portion with the substrate interposed therebetween;
A spring disposed between the upper portion of the pressing portion and the support portion to add an elastic force to the pressing portion,
The main body is equipped with a guide member for pressing the upper portion of the pressing portion when the conveyor rotates to open the second contact portion with respect to the first contact portion,
The clamp is connected to the first contact part and the second contact part by the guide member when the conveyor rotates, and after the substrate is disposed or withdrawn therebetween, the clamp passes through the guide member and the first contact part. The vertical continuous plating apparatus, characterized in that the second contact portion is in contact with each other again by the elastic force of the spring. The method of claim 1,
The guide member
A first guide member disposed in a direction opposite to the first rotating body with the substrate drawn out from the unwinding roll in between;
It is made of a second guide member disposed in the opposite direction of the second rotating body, with the substrate wound between the winding roll,
The first guide member is in contact with the upper portion of the pressing portion before the substrate and the conveyor are disposed in parallel to each other to rotate the second contact portion toward the substrate so that the substrate is between the first contact portion and the second contact portion. The first contact portion and the second contact portion are mutually open until arranged,
The second guide member is in contact with the upper portion of the pressing portion before the substrate and the conveyor are not parallel to each other to rotate the second contact portion toward the substrate so that the substrate between the first contact portion and the second contact portion The vertical continuous plating apparatus, characterized in that the first contact portion and the second contact portion is separated from each other until separated from. The method of claim 2,
Vertical pressurizing plating apparatus, characterized in that the pressing roller is rotated in contact with the guide member on the upper portion of the pressing portion. 4. The method according to claim 2 or 3,
The guide member,
A pressing surface protruding in the conveyor direction;
A first inclined surface formed at one side of the pressing surface to be inclined in an opposite direction of the conveyor;
On the other side of the pressing surface is formed a second slope inclined in the opposite direction of the conveyor,
The upper portion of the pressing portion,
Contacting the first inclined surface such that the second contact portion is gradually opened with respect to the first contact portion,
In contact with the pressing surface to maintain the first contact portion and the second contact portion apart from each other,
And the second contact portion is brought closer to the first contact portion in contact with the second inclined surface. 3. The method according to claim 1 or 2,
And a substrate tension holding part disposed between the unwinding roll and the main body or between the main body and the winding roll to move the substrate at a constant tension.

Images