CN220335342U - Novel electroplating bath and vertical electroplating device - Google Patents

Abstract

In one aspect, the present utility model provides a novel electroplating tank in the technical field of electroplating, including: the electroplating device comprises an electroplating bath body, wherein a plurality of grooves are formed in the groove walls at two sides of the electroplating bath body; the groove opening faces to the inside of the electroplating bath body. In another aspect, there is provided a vertical plating apparatus, comprising: a novel electroplating bath and an electroplating anode arranged in the electroplating bath body; at least two annular travelling conductive belts which are stacked from top to bottom are stacked at set intervals between two adjacent conductive belts; and the material to be electroplated is arranged in the interval between the two adjacent conductive strips, and the material to be electroplated is electrically conductive and drives the film to move by the upper and lower adjacent conductive strips. The embodiment of the utility model can solve the problems that the electroplating bath body is in a vertical state, the belt pulleys of the conductive belt are all in the electroplating bath body, the conductive belt is difficult to electrify the cathode, and electroplating cannot be realized.

Description

Novel electroplating bath and vertical electroplating device

Technical Field

The utility model relates to the technical field of electroplating, in particular to a novel electroplating tank and a vertical electroplating device.

Background

Electroplating refers to a process in which a substance as an anode is electrolyzed in the presence of a plating solution and is laminated on a cathode by an electric field. At present, the electroplating line is a multi-time horizontal line, a plurality of electroplating baths are horizontally arranged in series, more horizontal space is occupied, and if the electroplating baths are arranged in a vertical state, the occupied horizontal space can be reduced. However, if the plating tank body is a regular cuboid plating tank, when the conductive belt is used as the cathode conductive mechanism, the belt pulleys of the conductive belt are all positioned in the plating tank body, and the plating solution is contained in the plating tank body, so that the conductive belt is difficult to be electrified in a cathode manner, and the electroplating cannot be realized.

In carrying out the present utility model, the applicant has found that at least the following problems exist in the prior art: the electroplating bath body is in a vertical state, and the belt pulleys of the conductive belt are all in the electroplating bath body, so that the conductive belt is difficult to electrify the cathode, and electroplating cannot be realized.

Disclosure of Invention

The embodiment of the utility model provides a novel electroplating tank and a vertical electroplating device, which are used for solving the problem that the electroplating cannot be realized due to the fact that a conductive belt in a vertically arranged electroplating tank is difficult to electrify a cathode.

In one aspect, an embodiment of the present utility model provides a novel plating cell, including:

the electroplating bath body 30, a plurality of grooves 301 are arranged on the two side bath walls of the electroplating bath body 30;

the recess 301 is opened toward the inside of the plating tank body 30.

Further, a plurality of grooves 301 are uniformly formed in the left side wall of the plating tank body 30, a plurality of grooves 301 are uniformly formed in the right side wall of the plating tank body 30, and the grooves 301 on the left side and the grooves 301 on the right side are staggered in the height direction.

Further, the groove 301 is square with a side length of 1.5m-2 m.

In another aspect, an embodiment of the present utility model provides a vertical plating apparatus, including:

a new plating tank and a plating anode disposed in the plating tank body 30;

at least two annular traveling conductive belts 10 which are stacked from top to bottom, wherein two adjacent conductive belts 10 are stacked at set intervals;

the material to be electroplated 90 is arranged in the interval between two adjacent conductive strips 10, and the material to be electroplated 90 is electrically conductive and drives the film to move by the upper and lower adjacent conductive strips 10.

Further, the conductive tape 10 is positioned in a plating tank 30, and the conductive tape 10 passes through the groove 301 and is electrically conductive at the groove 301.

Further, one conductive wheel 20 is disposed in each groove 301, and the conductive wheel 20 is in contact with the outer surface of the conductive strip 10, and the conductive wheel 20 electrically cathodes the conductive strip 10.

Further, one pulley 50 is provided at four corners of the inside of the loop of each conductive belt 10, and the four pulleys 50 drive the conductive belt 10.

Further, a winding wheel 801 and an unwinding wheel 802 are arranged outside the electroplating tank body 30, the winding wheel 801 is connected with one end of the material 90 to be electroplated, and the unwinding wheel 802 is connected with the other end of the material 90 to be electroplated.

Further, a plurality of pressing wheels 60 are arranged in the plating tank body 30, and the pressing wheels 60 are in contact with the conductive belt 10 in the plating tank body 30 and are used for pressing the conductive belt 10 to the material 90 to be plated.

Further, the plating anode includes:

the first electroplating anodes 401 are arranged at intervals up and down and positioned at two sides of the horizontal section of the material 90 to be electroplated;

and second plating anodes 402 disposed at left and right sides of the opposite sides of the recess 301 at intervals and located at both sides of the vertical section of the material 90 to be plated.

The technical scheme has the following beneficial effects: because the groove is added on the groove wall of the electroplating groove, the conductive wheel is arranged in the groove, and meanwhile, the technical means of the roller wiping mechanism is configured, the technical effect that the belt pulley of the conductive belt is arranged in the vertical electroplating groove can be achieved.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic view showing the structure of a novel plating tank and a vertical plating apparatus according to an embodiment of the utility model;

FIG. 2 is a left side view of a recess in a side tank wall of a novel plating tank and vertical plating apparatus according to an embodiment of the utility model;

FIG. 3 is a schematic diagram of the positions of pulleys, pinch rollers, and conductive rollers in an embodiment of the utility model.

The reference numerals are expressed as:

10. a conductive tape; 20. a conductive wheel; 30. a plating bath body; 301. a groove; 401. a first electroplating anode; 402. a second electroplating anode; 50. a belt pulley; 60. a pinch roller; 801. a winding wheel; 802. unreeling wheel; 90. and (5) material to be electroplated.

Detailed Description

The present utility model will now be described for a clearer understanding of technical features, objects, and effects of the present utility model.

As shown in fig. 1, in one aspect, an embodiment of the present utility model provides a novel plating tank, including:

the electroplating bath body 30, a plurality of grooves 301 are arranged on the two side bath walls of the electroplating bath body 30;

the recess 301 is opened toward the inside of the plating tank body 30.

A plurality of grooves 301 are arranged on the two side groove walls of the electroplating groove body 30 of the novel electroplating groove, the grooves 301 are provided with conductive wheels 20, a cathode power supply supplies cathode electricity to the conductive wheels 20, the conductive wheels 20 conduct the cathode electricity to the conductive belt 10, and the conductive belt conducts the cathode electricity to the material 90 to be electroplated.

Further, a plurality of grooves 301 are uniformly formed in the left side wall of the plating tank body 30, a plurality of grooves 301 are uniformly formed in the right side wall of the plating tank body 30, and the grooves 301 on the left side and the grooves 301 on the right side are staggered in the height direction.

A plurality of grooves 301 are uniformly formed in the groove walls on two sides of the plating tank body 30 in the horizontal direction, as shown in fig. 2, wherein the grooves 301 are formed in the groove 301 in the left view of the groove 301 on one side, and the grooves 301 are formed in the left side and the right side of the plating tank body 30 in a staggered manner, so that one end surface of the vertical section of the conductive belt 10 of the annular travelling belt can be ensured to be in contact with the conductive wheels 20, and smooth cathode electricity conduction of the conductive belt 10 can be ensured.

Further, the groove 301 is square with a side length of 1.5m-2 m. According to practical production experience, the grooves 301 are arranged into squares with the side length of 1.5m-2m, so that the conductive wheels 20 are conveniently arranged, and meanwhile, the material 90 to be electroplated is also conveniently subjected to film feeding.

In another aspect, an embodiment of the present utility model provides a vertical plating apparatus, including:

a new plating tank and a plating anode disposed in the plating tank body 30;

at least two annular traveling conductive belts 10 which are stacked from top to bottom, wherein two adjacent conductive belts 10 are stacked at set intervals;

the material to be electroplated 90 is arranged in the interval between two adjacent conductive strips 10, and the material to be electroplated 90 is electrically conductive and drives the film to move by the upper and lower adjacent conductive strips 10.

The cathode conductive mechanisms comprising the conductive belt 10 are respectively arranged on two sides of the material 90 to be electroplated in the width direction, and the conductive belt 10 of the annular travelling belt in the cathode conductive mechanisms conducts electricity on two sides of the material 90 to be electroplated in the width direction. The cathode power supply is used for electrifying the cathode of the conductive wheel 20 arranged in the groove 301, one conductive wheel 20 is electrified for electrifying the cathode of the conductive belt 10, the conductive belts 10 are respectively arranged on two sides of the material to be electroplated 90 in the width direction, the material to be electroplated 90 is in contact with the conductive belts 10, the conductive belts 10 conduct the cathode electricity to the material to be electroplated 90, and the annular conductive belts 10 drive the material to be electroplated 90 to move. In the electroplating process, the material to be electroplated 90 cannot contact with air, so that oxidation of the product of the material to be electroplated 90 is avoided, and the product quality is effectively ensured.

Further, the conductive tape 10 is positioned in a plating tank 30, and the conductive tape 10 passes through the groove 301 and is electrically conductive at the groove 301. The conductive strip 10 is cathodically energized by the conductive wheel 20 at the recess 301.

Further, one conductive wheel 20 is disposed in each groove 301, and the conductive wheel 20 is in contact with the outer surface of the conductive strip 10, and the conductive wheel 20 electrically cathodes the conductive strip 10. Each groove 301 is provided with a conductive wheel 20, and grooves 301 are arranged on the left side and the right side of the electroplating bath body 30 in a staggered manner, so that the vertical section of the annular conductive belt 10 can uniformly obtain cathode electricity.

Further, one pulley 50 is provided at four corners of the inside of the loop of each conductive belt 10, and the four pulleys 50 drive the conductive belt 10. One of the pulleys 50 acts as a driving pulley and the other as a driven pulley. Four pulleys 50 support the endless traveling conductive belt 10 and are also one of the components of the drive mechanism that drives the conductive belt 10.

Further, a winding wheel 801 and an unwinding wheel 802 are arranged outside the electroplating tank body 30, the winding wheel 801 is connected with one end of the material 90 to be electroplated, and the unwinding wheel 802 is connected with the other end of the material 90 to be electroplated. The take-up reel 801 and the pay-off reel 802 can ensure that a long length of the material 90 to be plated is continuously and completely plated.

Further, as shown in fig. 3, a plurality of pressing wheels 60 are disposed in the plating tank 30, and the pressing wheels 60 are in contact with the conductive strip 10 in the plating tank 30, so as to press the conductive strip 10 to the material 90 to be plated, and play a role in limiting the material 90 to be plated.

Further, the plating anode includes:

the first electroplating anodes 401 are arranged at intervals up and down and positioned at two sides of the horizontal section of the material 90 to be electroplated;

and second plating anodes 402 disposed at left and right sides of the opposite sides of the recess 301 at intervals and located at both sides of the vertical section of the material 90 to be plated.

As shown in fig. 1, plating anodes are provided at both the horizontal section and the one-end vertical section of the material to be plated 90 so that the material to be plated 90 is sufficiently plated.

The plating bath body 30 is filled with a plating solution, and since the conductive tape 10 passes through the plating bath body 30, the conductive tape 10 positioned in the groove 301 has the plating solution, the conductive wheel 20 will contact with the plating solution on the conductive tape 10, and after the conductive wheel 20 contacts with the plating solution, a metal plating layer will be formed on the surface of the conductive wheel 20, and therefore, a wiping roller mechanism is disposed near the conductive wheel 20, and is used for cleaning metals and impurities laminated on the conductive wheel 20. In the case of a good sealing of the position of the conductive strip which passes out of the plating tank, only a small amount of plating solution can flow out of the gap of the plating tank.

A plurality of grooves 301 are arranged on the groove walls on two sides of the plating tank body 30, a conductive wheel 20 can be arranged right above the grooves 301. A cathode power supply supplies cathode electricity to the conductive wheel 20, the conductive wheel 20 is in contact with the conductive belt 10 to conduct the cathode electricity to the conductive belt 10, two annular conductive belts 10 are arranged on the width direction of the material to be plated 90, the material to be plated 90 is in contact with the conductive belt 10, and then the conductive belt 10 conducts the cathode electricity to the material to be plated 90. The design of the groove 301 can solve the problem that the belt pulley 50 of the conductive belt 10 is in the electroplating bath, so that the conductive belt is difficult to electrify the cathode and cannot realize electroplating.

The foregoing is illustrative of the present utility model and is not to be construed as limiting the scope of the utility model. In order that the components of the utility model may be combined without conflict, any person skilled in the art shall make equivalent changes and modifications without departing from the spirit and principles of the utility model.

Claims (10)

1. A novel plating bath, comprising:

the electroplating device comprises an electroplating bath body (30), wherein a plurality of grooves (301) are formed in the two side bath walls of the electroplating bath body (30);

the opening of the groove (301) faces to the inside of the plating bath body (30).

2. The novel electroplating bath according to claim 1, wherein a left side wall of the electroplating bath body (30) is uniformly provided with a plurality of grooves (301), a right side wall of the electroplating bath body (30) is uniformly provided with a plurality of grooves (301), and the grooves (301) on the left side and the grooves (301) on the right side are staggered in the height direction.

3. The novel plating cell according to claim 1, characterized in that the recess (301) is square with a side length of 1.5m-2 m.

4. A vertical plating apparatus, comprising:

a novel electroplating cell as claimed in any one of claims 1 to 3 and an electroplating anode disposed in said electroplating cell body (30);

at least two annular travelling conductive belts (10) which are arranged in a stacked manner from top to bottom, wherein the adjacent two conductive belts (10) are arranged in a stacked manner at set intervals;

and materials (90) to be electroplated are arranged in the interval between two adjacent conductive belts (10), and the materials (90) to be electroplated are electrically conductive and drive the film to move by the upper and lower adjacent conductive belts (10).

5. The vertical plating apparatus according to claim 4, wherein the conductive strip (10) is located in one of the plating tanks (30), and the conductive strip (10) passes through the recess (301) and is electrically conductive at the recess (301).

6. The vertical plating device according to claim 4, wherein one conductive wheel (20) is provided in each of the grooves (301), and the conductive wheel (20) is in contact with the outer surface of the conductive belt (10), and the conductive wheel (20) electrifies the conductive belt (10) with a cathode.

7. The vertical plating device according to claim 4, wherein four corners of the inside of the ring of each of the conductive strips (10) are provided with a pulley (50), and four pulleys (50) drive the conductive strips (10) to drive.

8. The vertical plating apparatus according to claim 4, wherein a take-up reel (801) and an unreeling reel (802) are provided outside the plating tank body (30), the take-up reel (801) is connected to one end of the material (90) to be plated, and the unreeling reel (802) is connected to the other end of the material (90) to be plated.

9. The vertical plating apparatus according to claim 4, wherein a plurality of pressing wheels (60) are provided in the plating tank body (30), and the pressing wheels (60) are in contact with the conductive strip (10) in the plating tank body (30) for pressing the conductive strip (10) against the material (90) to be plated.

10. The vertical plating apparatus according to claim 4, wherein said plating anode comprises:

the first electroplating anodes (401) are arranged at intervals up and down and are positioned at two sides of the horizontal section of the material (90) to be electroplated;

and second electroplating anodes (402) which are arranged on one side opposite to the grooves (301) at intervals left and right and are positioned on two sides of the vertical section of the material (90) to be electroplated.