WO2019119820A1 - Electroplating transmission system - Google Patents

Abstract

Disclosed is an electroplating transmission system. The electroplating transmission system comprising: a fixed bracket; two steel wheels rotatably mounted on the fixed bracket; a conveyor belt made of an electrically conductive material, the conveyor belt surrounding outer sides of the two steel wheels and forming a first straight line conveying zone and a second straight line conveying zone that are oppositely arranged, as well as a first arc-shaped conveying zone and a second arc-shaped conveying zone that are oppositely arranged; a plurality of connecting plates fixedly arranged on an upper side of the conveying belt; multiple pairs of conducting heads, with each pair of conducting heads being arranged on two opposite sides on the top portion of each connecting plate; multiple steel belt wire clamps fixedly arranged on a lower side of the conveyor belt, with each steel belt wire clamp being arranged to clamp a circuit board; two rows of conductive copper bars mounted on the fixed bracket and arranged on two sides of the first straight line conveying zone; multiple pairs of steel belt wire conductive brushes, with each pair of steel belt wire conductive brushes being oppositely mounted onto the two rows of conductive copper bars, and each steel belt wire conductive brush being electrically connected to the corresponding conductive copper bar; and a negative pole copper bar electrically connected to the two rows of conductive copper bars.

Description

Plating drive system

The present application claims the priority of the Chinese patent application entitled "A Bilateral Steel Strip Conducting Wire Plating Transmission System" on December 18, 2017, the application number is 201711364426.5, the entire contents of which are incorporated herein by reference. In the public.

Technical field

The present disclosure relates to the field of electroplating technology, for example, to an electroplating transmission system.

Background technique

The common vertical plating equipment is to drive the circuit board along the plating tank filled with electroplating liquid through the circulating single-sided conductive transmission system, and the circuit board continuously enters from the first end of the electroplating tank and from the second end of the electroplating tank. Output, during which the plating solution in the plating bath is plated on the surface of the board. Chinese patent document CN204874806U discloses a continuous electroplating transmission system comprising a frame, two rotating wheels mounted on the frame, a transmission belt wound around the two rotating wheels, and a plurality of fixed belts fixed on the transmission belt in the vertical direction. A mounting plate, a plated clip placed on the bottom of the mounting plate, and a power supply assembly that powers the plated clip. The power supply assembly includes a conductive track fixed to the frame, a brush disposed on the conductive track, and a power receiving plate fixed to the upper portion of the mounting plate, and the brush is in contact with one side of the power receiving plate. The conductive rail is connected to the cathode, and the electric brush is transmitted to the electroplating clip via the brush, the power receiving plate and the mounting plate.

However, the above electroplating transmission system needs to be electrically transmitted to the electroplating clip through the mounting plate, and when installing the electroplating clip, it is necessary to first fix a plurality of mounting plates on the transmission belt, and then install mounting holes on the mounting plate, and the electroplating clips are one-to-one corresponding. When the grounding plate is mounted on the mounting hole of the mounting plate, when the plating clip is fixed on the driving belt in this way, when the mounting holes are opened in the plurality of mounting plates, it is difficult to ensure that the mounting holes of the plurality of mounting plates are consistent, resulting in fixing The height of the plating clip on the mounting hole is also inconsistent, and the height of the plating clip holding the wiring board is also inconsistent. At the same time, since at least two electroplating clips are required to fix the two ends of the circuit board on the transmission belt, there must be a gap between two adjacent mounting plates of the electroplating clip, and the circuit board between the two mounting boards is When the transmission belt runs forward, under the gravity of the circuit board, the downward force is inevitably generated, so that the height of the circuit board is inconsistent at the position between the plating clip and the two mounting plates, and finally the circuit board cannot be in the Running at the same height, in addition, the transmission belt itself is not electrically conductive, and the electroplating transmission system has low electrical conductivity, so that the working efficiency during electroplating is far from the actual need, and the thickness of the plating on both sides of the circuit board is largely different.

Summary of the invention

The present disclosure proposes an electroplating transmission system to ensure that the circuit board of the electroplating transmission system is operated at the same height when the steel strip clamp clamps the circuit board, and the electroplating transmission system is improved in electrical conductivity and the plating on both sides of the circuit board is reduced. The difference in thickness.

The present disclosure provides an electroplating transmission system comprising:

Fixed bracket

Two steel wheels rotatably mounted on both sides of the fixing bracket;

a conveyor belt, made of a conductive material, surrounding the outer sides of the two steel wheels, and forming oppositely disposed first straight conveying regions and second straight conveying regions and oppositely disposed first curved conveying regions and second arcs Shape transfer area;

a plurality of connecting plates, the first set distance of the interval is fixedly disposed on the upper side of the conveyor belt;

a plurality of pairs of conductive heads, each pair of said conductive heads being disposed on opposite sides of each of said connecting plates;

a plurality of steel strip line clamps are fixedly disposed on a lower side of the conveyor belt at intervals of a second set distance, and each of the steel strip line clamps is disposed to clamp a circuit board;

Two rows of conductive copper bars are mounted on the fixing bracket and disposed on two sides of the first straight line conveying region;

a plurality of pairs of steel strip line conductive brushes, each pair of the strip line conductive brushes are oppositely mounted on the two rows of conductive copper strips and each of the strip line conductive brushes is electrically connected to the corresponding conductive copper strip;

a cathode copper row electrically connected to the two rows of conductive copper rows;

When the conveyor belt drives the plurality of connecting plates and the plurality of steel strip line clamps to move, the conductive heads moving to both sides of the connecting plate of the first straight-line conveying region respectively and the two The steel strip wire conductive brush on the row of conductive copper strips is in sliding contact, so that the cathode copper strip, the two rows of conductive copper strips, the plurality of pairs of conductive strips on the two rows of conductive copper strips are located The conductive head of the first straight-line transfer region and the connecting plate, the conveyor belt, and the plurality of steel strip line clamps are sequentially electrically connected to plate the circuit board.

In an embodiment, the electroplating transmission system further includes: a plurality of steel strip line drive track roller shafts, and each of the two steel strip line drive track roller shafts are mounted on one of the connecting plates in a vertical direction;

a plurality of steel strip line drive track rollers are respectively mounted on the plurality of steel strip line drive track roller shafts in one-to-one correspondence;

The rail plate is fixedly connected to the fixed bracket;

a track plate fixed on the fixed rail of the track plate;

When the conveyor belt drives the plurality of connecting plates to move, the steel belt wire drive track rollers of a part of the plurality of connecting plates roll along the track plate to guide the conveyor to transmit direction.

In an embodiment, the electroplating transmission system further includes: a cover, the cover is mounted on the fixing bracket, and the rail plate fixing side is fixed to the fixing bracket by the cover.

In an embodiment, the plurality of pairs of conductive heads on the top of the plurality of connecting plates are equal in level and the plurality of pairs of steel strip line conductive brushes mounted on the two rows of conductive copper bars are equal in level.

In one embodiment, each of the strip conductor brushes has an oblique angle in the range of 30° to 60° at the connection position with the conductive head and a length of 3 m per row of the conductive copper strips.

In one embodiment, each row of the conductive copper strips comprises a plurality of sub-conductive copper strips of a predetermined length, and the distance between adjacent two sub-conductive copper strips is in the range of 0 to 1.5 cm.

In an embodiment, in a vertical direction, a top of each of the connecting plates protrudes from a top of the driving belt, and opposite portions of each of the connecting plates project from the driving belt are respectively mounted with the Conductive head.

In an embodiment, the shape of each of the connecting plates is designed as a "T" type structure.

In an embodiment, the number of the rail plate fixing squares and the number of the rail plates are two, and the two rail plate fixing squares are respectively disposed in the first straight line transmitting region and Two sides of the second linear transmission area are respectively fixed to the two rail plate fixing squares in a one-to-one correspondence.

The electroplating transmission system of the present disclosure is novel in design and simple in structure, and has the following advantages: the electroplating transmission system provided by the present disclosure is provided with conductive heads on opposite sides of the top of the connecting plate to pass the conductive heads on both sides of the connecting plate. The steel strip wire conductive brush on the two rows of conductive copper strips is in sliding contact, thereby achieving electrical conduction through the two sides of the connecting board, and the present invention is achieved by electroplating by contacting one side of the receiving board with the brush in the related art. The difference in current between the two sides of the steel strip clamp can be reduced, thereby reducing the difference in the thickness of the electroplated plating on both sides of the circuit board; in addition, in the present disclosure, the transmission belt is made of a conductive material instead of the mounting board in the related art. The steel strip clamp can be directly fixed on the transmission belt, and the flatness of the transmission belt itself can be used to easily install the installation holes at the same height on the transmission belt, thereby installing the steel belt clamps at the same height; at the same time, no installation is required. After the board, the second set distance can be set on the lower side of the belt to set the strip line clamp, thus making the board different. The set can be clamped by the steel strip clamp, and the steel strip clamp can keep the circuit board running at the same height as the belt moves forward; in addition, the power supply component transmits the electric power directly to the steel strip clamp through the transmission belt. It does not need to be electroplated transmission system like the related art, but also through the mounting plate to transmit electricity to the steel strip clamp, thereby reducing loop resistance, reducing energy consumption and improving electrical conductivity.

DRAWINGS

1 is a cross-sectional view of an electroplating transmission system according to an embodiment of the present disclosure;

2a is a front elevational view of a conductive copper bar of an electroplating transmission system according to an embodiment of the present disclosure;

Figure 2b is a top plan view of the conductive copper row of Figure 2a;

Figure 2c is a side view of the conductive copper row of Figure 2a;

3a is a front elevational view of a conductive copper bar of an electroplating transmission system according to another embodiment of the present disclosure;

Figure 3b is a top plan view of the conductive copper row of Figure 3a;

Figure 3c is a side view of the conductive copper row of Figure 3a;

4a is a schematic structural view of a portion of a steel strip wire conductive brush of an electroplating transmission system according to an embodiment of the present disclosure;

Figure 4b is a schematic view showing the structure of the torsion spring of Figure 4a at a first viewing angle;

Figure 4c is a schematic view showing the structure of the torsion spring of Figure 4a at a second viewing angle;

4d is a schematic structural view of the torsion spring of FIG. 4a at a third viewing angle;

5 is a schematic diagram of an internal connection structure of a steel strip wire conductive brush of an electroplating transmission system according to an embodiment of the present disclosure;

6a is a front elevational view of a steel strip line clamp of an electroplating transmission system according to an embodiment of the present disclosure;

Figure 6b is a side view of the steel strip line clamp of Figure 6a;

7a is a cross-sectional view of a connecting plate portion of an electroplating transmission system according to an embodiment of the present disclosure;

Figure 7b is a plan view of the portion of the web of Figure 7a;

Figure 7c is a front elevational view of the portion of the web of Figure 7a;

8a is a cross-sectional view of a steel belt wire drive track roller of an electroplating transmission system according to an embodiment of the present disclosure;

Figure 8b is a front elevational view of the steel belt wire drive track roller of Figure 8a;

9 is a schematic structural view of a steel belt wire drive track roller shaft of an electroplating transmission system according to an embodiment of the present disclosure;

10a is a front elevational view of a connecting plate of an electroplating transmission system according to an embodiment of the present disclosure;

Figure 10b is a side view of the web of Figure 10a.

In the figure: 1-cover; 2-steel strip conductive brush; 3-conductive copper row; 4-cathode copper row; 5-steel belt line drive track roller; 6-steel strip line drive track roller shaft; 7-track Plate fixing square pass; 8- steel strip line clamp; 9-belt; 10-track plate; 11-connecting plate; 12-conducting head; 13-steel wheel; 14-circuit board; 15--fixing bracket; 16-torsion spring ; 17 - first wire; 18 - second wire.

Detailed ways

The technical solutions in the embodiments of the present disclosure will be described in conjunction with the drawings in the embodiments of the present disclosure. It is obvious that the described embodiments are only a part of the embodiments of the present disclosure, and not all of the embodiments.

Example 1

Referring to FIG. 1-10b, an electroplating transmission system according to an embodiment of the present disclosure includes a cover 1, a strip wire conductive brush 2, a conductive copper strip 3, a cathode copper strip 4, a steel strip wire drive track roller 5, and a steel. With the line drive track roller shaft 6, the track plate fixed square pass 7, the steel strip line clamp 8, the conveyor belt 9, the track plate 10, the connecting plate 11, the conductive head 12, the steel wheel 13 and the fixed bracket 15, the electroplating transmission system is The steel wheel 13 is driven to operate. The upper left portion of the steel wheel 13 is vertically installed with two rows of conductive copper bars 3, and the top of the conductive copper bars 3 is mounted with a steel strip wire conductive brush 2, and two steel strip wire conductive brushes 2 A connecting plate 11 is vertically installed between the middle and lower portions of the connecting plate 11 , and a steel belt wire drive track roller shaft 6 is mounted through the middle and lower portions thereof. The steel belt wire drive track roller shaft 6 is mounted with a steel belt wire drive track roller 5 . A rail plate 10 is disposed between the steel belt line transmission track rollers 5, and a rail plate fixing square 7 is mounted on the outer side of the rail plate 10, and the rail plate 10 is fixed on the rail plate fixing square pass 7, the track plate The organic cover 1 is attached to the outside of the fixed square 7 , and the fixed cover is arranged above the cover 1 and the steel wheel 13 15, the rail plate 7 on the fixed side fixed to the fixing bracket 15.

In one embodiment, the top of the conductive copper strip 3 is mounted with a cathode copper strip 4, wherein a square tube is disposed between the conductive copper strip 3 and the rail plate fixing square 7 and the conductive copper strip 3 is fixed to the square tube on.

In an embodiment, the connecting plate 11 on the inner side of the rail plate 10 is mounted on the outer side of the upper portion of the conveyor belt 9, and the conductive head 12 is mounted on both sides of the upper end of the connecting plate 11.

In an embodiment, the drive track roller 5 is mounted on the upper and lower ends of the connecting plate 11 by a steel belt wire drive track roller shaft 6, wherein the drive track roller 5 meshes with the track plate 10.

In an embodiment, the lower end of the conveyor belt 9 is connected to a steel strip line clamp 8 in which the steel strip line clamp 8 is mounted on the outside of the lower portion of the conveyor belt 9, and the steel strip line clamp 8 is disposed to sandwich the top of the wiring board 14.

In an embodiment, a conductive head 12 is connected between the steel strip wire conductive brush 2 and the connecting plate 11, and the conveyor belt 9 drives the conductive head 12 to slide and frictionally connect the steel strip wire conductive brush 2, wherein is fixed on the top of the connecting plate 11. The conductive head 12 is equal in level to the strip-wire conductive brush 2.

In an embodiment, the steel wheel 13 is provided in a cylindrical configuration in which the conveyor belt 9 forms a semi-annular structure around the outer side of the steel drum 13 and is circulated between the two steel wheels 13.

In an embodiment, the steel strip wire conductive brush 2 is provided at an oblique angle within a range of 30 to 60 degrees at a connection position with the conductive head 12. In one embodiment, the length of each row of conductive copper bars 3 is designed to be 3 m.

In one embodiment, at least one strip of conductive strip 2 is mounted on the top of each row of the conductive copper strips 3, and the distance between the two adjacent conductive strips 3 adjacent to each other is in the range of 0 to 1.5 cm. .

In an embodiment, the connecting plate 11 has a "T" shape. In an embodiment, the conductive heads 12 mounted on the top of the connecting plate 11 are in one-to-one correspondence with the connecting plates 11.

When the electric drive system is in operation, the steel belt wire drive track roller 5 mounted on the steel belt wire drive track roller shaft 6 circulates on the outer ring of the cylindrical structure formed by the steel wheel 13, and the current passes through the cathode copper bar 4 , entering the inside of the conductive copper strip 3, and then the current passes through the steel strip wire conductive brush 2, enters the connecting plate 11 through the conductive head 12, and is then supplied by the conveyor belt 9 to the steel strip wire clamp 8, and the steel strip wire clamp 8 is clamped and plated. The parts are plated, the track plate is fixed, and the track belt 10 is fixed, and the cover 1 comprehensively protects the entire system.

1 is a cross-sectional view of an electroplating transmission system provided by an embodiment of the present disclosure. Referring to FIG. 1, the electroplating transmission system provided in this embodiment includes: a fixing bracket 15; two steel wheels 13 rotatably mounted on both sides of the fixing bracket 15; and a conveyor belt 9 made of a conductive material and surrounded by two An outer side of the steel wheel 13 and forming a first linear conveying area and a second straight conveying area disposed opposite to each other and a first curved conveying area and a second curved conveying area disposed opposite to each other; a plurality of connecting plates 11 spaced first The set distance is fixedly disposed on the upper side of the conveyor belt 9; the plurality of pairs of the conductive heads 12, each pair of the conductive heads 12 are disposed on opposite sides of each of the connecting plates 11; the plurality of steel strip line clamps 8 are spaced apart from each other The fixed distance is fixedly disposed on the lower side of the conveyor belt 9, and each of the steel strip wire clamps 8 is disposed to clamp the circuit board 14; the two rows of conductive copper bars 3 are mounted on the fixed bracket 15 and disposed in the first straight line transmission area. Two pairs of steel strip wire conductive brushes 2, each pair of steel strip wire conductive brushes 2 are oppositely mounted on two rows of conductive copper bars 3 and each steel strip wire conductive brush 2 is electrically connected with a corresponding conductive copper bar 3; The cathode copper strip 4 is electrically connected to the two rows of conductive copper strips 3.

When the electroplating transmission system is in operation, a plating tank may be disposed under the first straight conveying region, and a plating solution is stored in the plating tank. When the conveyor belt 9 drives the plurality of connecting plates 11 and the plurality of steel strip wire clamps 8 to move, the movement The conductive heads 12 on both sides of the connecting plate 11 to the first straight-line transfer area are in sliding contact with the strip-shaped conductive brushes 2 on the two rows of conductive copper strips 3, thereby making the cathode copper strips 4 and the two rows of conductive copper strips 3 a plurality of pairs of steel strip wire conductive brushes 2 on the two rows of conductive copper bars 3, a conductive head 12 and a connecting plate 11 located in the first straight line transfer region, a conveyor belt 9 and a plurality of steel strip wire clamps 8 are sequentially electrically connected to each other for electroplating Circuit board 14.

2a is a front view of a conductive copper strip according to an embodiment of the present disclosure, FIG. 2b is a top view of the conductive copper strip of FIG. 2a, and FIG. 2c is a side view of the conductive copper strip of FIG. 2a; FIG. A front view of a conductive copper strip provided by another embodiment is disclosed, FIG. 3b is a top view of the conductive copper strip of FIG. 3a, and FIG. 3c is a side view of the conductive copper strip of FIG. 3a. The conductive copper row in Figure 2a differs from the conductive copper row in Figure 3a in that it is fixed in a different manner.

4a is a schematic structural view of a position portion of a steel strip wire conductive brush in an electroplating transmission system according to an embodiment of the present disclosure, and FIG. 4b is a structural schematic view of the torsion spring of FIG. 4a at a first viewing angle, and FIG. 4c is a schematic view of FIG. 4a. FIG. 4d is a schematic structural view of the torsion spring in a second viewing angle, and FIG. 4d is a structural schematic view of the torsion spring in FIG. 4a at a third viewing angle. As shown in FIGS. 4a-4d, the steel strip wire conductive brush 2 can be electrically connected to the conductive copper strip 3 through the first wire 17, and the torsion spring 16 is fixed to the steel strip wire conductive brush 2 to make the conductive head 12 through the torsion spring 16. Good contact with the steel strip wire conductive brush 2.

FIG. 5 is a schematic diagram of an internal connection structure of a steel strip wire conductive brush according to an embodiment of the present disclosure. As shown in FIG. 5, the inside of the steel strip wire conductive brush 2 may be embedded with a second wire 18, and the second wire 18 is arranged to transmit an electrical signal to a Programmable Logic Controller (PLC), due to the steel strip line. When the conductive brush 2 is worn and the conductive head 12 is in contact with and connected to the second wire 18, the PLC alarms to remind the maintenance personnel to replace the steel strip wire conductive brush 2.

In an embodiment, the steel strip wire conductive brush 2 may be a common steel strip wire conductive brush, that is, the second wire 18 may not be buried inside.

6a is a front view of a steel strip line clamp according to an embodiment of the present disclosure, and FIG. 6b is a side view of the steel strip line clamp of FIG. 6a. The steel strip line clamps of Figures 6a and 6b are arranged to clamp the circuit board.

In an embodiment, the first set distance and the second set distance may be the same or different. The smaller the second set distance, the more the steel strip wire clamp 8 can stably hold the circuit board 14, thereby reducing the jitter of the circuit board 14 during the plating process and improving the plating uniformity.

In an embodiment, one of the circuit boards 14 may be held by a plurality of steel strip line clamps 8, or one of the circuit boards 14 may be held by a steel strip line clamp 8. The clamping of one of the circuit boards 14 by the plurality of steel strip line clamps 8 enables a more stable clamping of the circuit boards. The electroplating transmission system provided by the present disclosure has novel design and simple structure. The continuous electroplating transmission system of the structure is provided with conductive heads on opposite sides of the top of the connecting plate to pass the conductive heads on both sides of the connecting plate and the two rows of conductive copper bars. The steel strip wire conductive brush is in sliding contact, thereby achieving electrical conduction through the two sides of the connecting plate, and the present disclosure can reduce the steel strip compared to the related art in which the plating is realized by the side of the power receiving plate contacting the brush. The difference in current between the two sides of the wire clamp, thereby reducing the difference in the thickness of the plating plating on both sides of the circuit board, and the friction between the conductive head and the steel strip wire conductive brush is small, thereby reducing the jitter of the conveyor belt and improving the uniform plating In addition, in the present disclosure, by utilizing the flatness of the belt itself, it is convenient to install mounting holes at the same height on the belt to install the steel strip clamps at the same height; at the same time, after the installation board is not required, The lower side of the drive belt is spaced apart by a second set distance to set the steel strip line clamp so that different positions of the circuit board can be clamped by the steel strip line Clamping, when the steel strip clamp moves forward with the belt, it can keep the circuit board running at the same height; in addition, the power supply component transmits the electric power directly to the steel strip fixture without the electroplating in related art. The transmission system must pass through the mounting plate to transfer electricity to the steel strip fixture, thereby reducing loop resistance, reducing energy consumption and improving electrical conductivity.

In an embodiment, the electroplating transmission system further includes: a plurality of steel strip line transmission track roller shafts 6, each of which is mounted on a connecting plate 11 in a vertical direction; The steel belt line transmission track rollers 5 are respectively mounted on the plurality of steel belt line transmission track roller shafts 6 in one-to-one correspondence; the rail plate fixing squares 7 are fixed on the fixed brackets 15; the rail plates 10 are fixed on the rail plates. Fangtong 7 on.

When the conveyor belt 9 drives the plurality of connecting plates 11 to move, the steel belt wire drive track rollers 5 on the partial connecting plates 11 of the plurality of connecting plates 11 roll along the track plate 10 to guide the direction in which the conveyor belt 9 is conveyed.

7a is a cross-sectional view of a portion of a connecting plate of an electroplating transmission system according to an embodiment of the present disclosure, FIG. 7b is a plan view of a portion of the connecting plate of FIG. 7a, and FIG. 7c is a front view of a portion of the connecting plate of FIG. 7a. In this embodiment, a strip space can be formed between the two steel strip line drive track rollers 5 of each connecting plate 11. When the conveyor belt 9 drives the plurality of connecting plates 11 to move, the track board 10 is inserted and moved to the track board 10. The two steel strip line drive track rollers 5 on the connecting plate 11 are positioned to move the two steel strip line drive track rollers 5 along the track plate 10, thereby guiding the direction in which the conveyor belt 9 is transported, reducing The jitter of the conveyor belt 9 during the movement increases the stability of the conveyor belt 9.

8a is a cross-sectional view of a steel belt wire drive track roller according to an embodiment of the present disclosure, and FIG. 8b is a front view of the steel belt wire drive track roller of FIG. 8a. Referring to Figures 8a and 8b, in one embodiment, the steel belt wire drive track roller 5 is an I-shaped roller.

FIG. 9 is a schematic structural view of a steel belt wire drive track roller shaft according to an embodiment of the present disclosure. The steel belt wire drive track roller 5 is fixed to the connecting plate 11 by a steel belt wire drive track roller shaft 6.

In an embodiment, the steel belt wire drive track roller shaft 6 can be fixed to the connecting plate 11 by rivets.

In an embodiment, the rail plate 10 is mounted laterally of the first straight conveying area to improve the stability of the conveyor belt 9 of the first straight conveying area.

In an embodiment, the number of the rail plate fixing squares 7 and the number of the rail plates 10 are two, and the two rail plate fixing squares 7 are respectively disposed in the first straight line transmitting region and the second straight line transmitting region. On the side of the two sides, the two rail plates 10 are fixed to the two rail plate fixing squares 7 in a one-to-one correspondence. Thereby, the stability of the conveyor belt 9 of the first straight conveying area and the second conveying area is improved.

In an embodiment, the electroplating transmission system further includes: a cover 1 , the cover 1 is mounted on the fixing bracket 15 , and the rail plate fixing rail 7 is fixed to the fixing bracket 15 through the cover 1 , and the cover 1 is used for Protect the plating drive system.

In an embodiment, the electroplating transmission system further includes: a square tube, wherein the two rows of conductive copper strips 3 are fixed on the fixing bracket 15 through the square tube.

In an embodiment, the plurality of pairs of the conductive heads 12 fixed on the top of the plurality of connecting plates 11 are equal in level and the plurality of pairs of the strip-shaped conductive brushes 2 mounted on the two rows of conductive copper strips 3 are equal in level to ensure The conductive head 12 that has moved to the first straight-line transfer area is in sliding contact with the steel strip wire conductive brush 2.

In an embodiment, the horizontal heights of the plurality of pairs of conductive heads 12 may be different from the horizontal heights of the plurality of pairs of steel strip conductive brushes 2, as long as the conductive heads 12 that are moved to the first straight-line transfer area are electrically conductive with the steel strip lines. Brush 2 can be sliding contact. For example, the level of the plurality of pairs of the conductive heads 12 may be higher or lower than the level of the plurality of pairs of the strip line conductive brushes 2.

In an embodiment, each of the steel strip wire conductive brushes 2 is provided with an oblique angle within a range of 30° to 60° at a connection position with the conductive head 12, and each row of the conductive copper strips 3 has a length of 3 meters ( m).

In one embodiment, each row of conductive copper rows comprises a plurality of sub-conductive copper rows of predetermined length, and the distance between adjacent two segments of conductive copper rows is in the range of 0 to 1.5 centimeters (cm). For example, a row of conductive copper busbars can be formed by two 1.5 m sub-conductive copper bars, and the two-segment conductive copper bars are arranged without a gap.

In one embodiment, the length of the gap between the two rows of conductive copper bars 3 is in the range of 40 to 60 cm.

In an embodiment, in the vertical direction, the top of each of the connecting plates 11 protrudes from the top of the transmission belt 9, and the opposite sides of each of the connecting plates 11 projecting from the belt 9 are respectively mounted with the conductive heads 12.

Fig. 10a is a front view of the connecting plate provided in the embodiment, and Fig. 10b is a side view of the connecting plate in Fig. 10a. Referring to Figures 10a and 10b, in one embodiment, each of the connecting plates 11 has a "T" configuration.

Claims (10)

1. An electroplating transmission system comprising: a fixing bracket (15);

   Two steel wheels (13) rotatably mounted on both sides of the fixing bracket (15);

   a conveyor belt (9) made of a conductive material, surrounding the outer sides of the two steel wheels (13), and forming oppositely disposed first straight conveying regions and second straight conveying regions and oppositely disposed first curved shapes a transfer area and a second curved transfer area;

   a plurality of connecting plates (11) fixed at a first set distance apart from an upper side of the conveyor belt (9);

   a plurality of pairs of conductive heads (12), each pair of said conductive heads (12) being disposed on opposite sides of each of said connecting plates (11);

   a plurality of steel strip line clamps (8) are fixedly disposed on a lower side of the conveyor belt (9) at intervals, and each of the steel strip line clamps (8) is disposed to clamp a circuit board (14) ;

   Two rows of conductive copper bars (3) are mounted on the fixing brackets (15) and disposed on both sides of the first straight line conveying region;

   a plurality of pairs of steel strip line conductive brushes (2), each pair of said strip line conductive brushes (2) are oppositely mounted on said two rows of conductive copper strips (3) and each of said strip line conductive brushes (2) ) electrically connected to the corresponding conductive copper row (3);

   a cathode copper busbar (4) electrically connected to the two rows of conductive copper bars (3);

   The conveyor belt (9) drives the plurality of connecting plates (11) and the plurality of steel strip line clamps (8) to move to the connecting plate (11) of the first straight conveying area The conductive heads (12) on both sides are in sliding contact with the steel strip wire conductive brushes (2) on the two rows of conductive copper bars (3), so that the cathode copper bars (4), the two rows a plurality of pairs of steel strip wire conductive brushes (2) on the conductive copper bars (3), the two rows of conductive copper bars (3), the conductive heads (12) located in the first straight line transfer region, and The connecting plate (11), the conveyor belt (9) and the plurality of steel strip line clamps (8) are sequentially electrically connected to plate the circuit board (14).
2. The electroplating transmission system of claim 1 further comprising:

   a plurality of steel strip line drive track roller shafts (6), each of the two steel strip line drive track roller shafts (6) are mounted on one of the connecting plates (11) in a vertical direction;

   a plurality of steel strip line drive track rollers (5) are respectively mounted on the plurality of steel strip line drive track roller shafts (6) in one-to-one correspondence;

   a rail plate fixing square (7) fixed to the fixing bracket (15);

   a rail plate (10) fixed to the rail plate fixing square passage (7);

   When the conveyor belt (9) drives the plurality of connecting plates (11) to move, the steel belt wire drive track rollers (5) on a part of the connecting plates (11) of the plurality of connecting plates (11) Rolling along the track plate (10) to guide the direction in which the conveyor belt (9) is transported.
3. The electroplating transmission system according to claim 2, further comprising: a cover (1), the cover (1) is mounted on the fixing bracket (15), and the rail plate is fixed to the square passage (7) The cover (1) is fixed to the fixing bracket (15).
4. The electroplating transmission system according to claim 3, further comprising a square tube, wherein said two rows of conductive copper bars (3) are fixed to said fixing bracket (15) by said square tube.
5. The electroplating transmission system according to any one of claims 1 to 4, wherein said plurality of pairs of conductive heads (12) fixed to the top of said plurality of connecting plates (11) are equal in level and mounted on said two The plurality of pairs of steel strip wire conductive brushes (2) on the row of conductive copper bars (3) are equal in level.
6. The electroplating transmission system according to any one of claims 1 to 5, wherein each of the steel strip wire conductive brushes (2) is provided at an angle of 30 to 60 at a connection position with the conductive head (12). An oblique angle in the range of °, and the length of the conductive copper strip (3) per row is 3 m.
7. The electroplating transmission system according to any one of claims 1 to 6, wherein each of the rows of the conductive copper strips (3) comprises a plurality of sub-conductive copper strips of a predetermined length, and the adjacent two sections of the sub-conductive copper The distance between the rows is in the range of 0 to 1.5 cm.
8. An electroplating transmission system according to any one of claims 1 to 7, wherein, in the vertical direction, the top of each of said connecting plates (11) projects from the top of said belt (9), each of said connections The opposite ends of the plate (11) projecting from the belt (9) are respectively mounted with the conductive heads (12).
9. The electroplating transmission system according to any one of claims 1-8, wherein each of the connecting plates (11) has a "T"-shaped configuration.
10. The electroplating transmission system according to claim 2, wherein the number of the rail plate fixing squares (7) and the number of the rail plates (10) are two, and the two rail plates are fixed. The passages (7) are respectively disposed on the sides of the first straight conveying area and the second straight conveying area, and the two rail plates (10) are respectively fixed in one-to-one correspondence to the two rail plates. Fangtong (7).

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