CN216688357U - Close formula crude foil machine anode plate connection structure and crude foil machine - Google Patents

Abstract

The utility model relates to a foil machine anode plate connection structure and foil machine are given birth to close cloth formula, belong to the electronic copper foil field, give birth to the foil machine and include connection structure, connection structure includes electrically conductive row and the soft copper bar that links to each other with the positive pole groove of giving birth to the foil machine, the positive pole groove includes anode plate and positive pole mother board, polylith anode plate sets up side by side along positive pole mother board inner wall circumference, threaded connection has the bolt between anode plate and the positive pole mother board, bolt tip wears out the positive pole mother board and threaded connection has the anode plate nut, electrically conductive row includes the installation department and is used for connecting the connecting portion of soft copper bar, the installation department is fixed and is deviated from anode plate one side and set up along positive pole mother board circumference at the positive pole mother board, the installation department is fixed between two adjacent rows of bolts, connecting portion are fixed at the tip along circumference of installation department, connecting portion are located different planes with the installation department, soft copper bar keeps away from installation department one end with connecting portion and links to each other, soft copper bar is connected with external power source. The application has the effect of being convenient for dismounting the nut on the back of the anode mother board.

Description

Close formula crude foil machine anode plate connection structure and crude foil machine

Technical Field

The application relates to the field of electronic copper foil, in particular to a densely-distributed anode plate connecting structure of a foil generating machine and the foil generating machine.

Background

The structure is mainly used for a lithium electric foil generation all-in-one machine and an electronic circuit copper foil generation machine (special key equipment for producing copper foil), and has the main function of conducting and connecting the anode plate of an anode tank.

Referring to fig. 1 and 2, the conventional foil forming machine includes an anode tank including an anode plate 1 and an anode mother plate 2, and a connection structure, the anode plate 1 being provided with a plurality of blocks for generating cations. The anode mother plate 2 is semi-cylindrical for connection with the connection structure. The connecting structure comprises a conductive bar 3 and a soft copper bar (not shown in the figure), a plurality of anode plates 1 are arranged on the inner wall of an anode mother plate 2 side by side, one side of the anode plate 1 close to the anode mother plate 2 is in threaded connection with a bolt, the bolt is in threaded fixation with the anode mother plate 2, one end of the bolt far away from the anode plate 1 is in threaded connection with an anode plate nut 11, and therefore the anode plate 1 is fixed on the anode mother plate 2.

Referring to fig. 2 and 3, a plurality of conductive bars 3 are symmetrically arranged along the circumferential direction of the anode mother plate 2, the conductive bars 3 are rectangular plates and are located between the anode plate nuts 11, because the conductive bars 3 are generally made of titanium materials and are welded on the anode mother plate 2, but too many welding points can cause deformation of the anode mother plate 1, thereby affecting the precision of the anode mother plate 2, therefore, the number of the conductive bars 3 cannot be too large, and 2-3 conductive bars are generally arranged on one side. The soft copper bar (not shown in the figure) is fixed on the conductive bar 3 through a bolt, the other end of the soft copper bar (not shown in the figure) is connected with the rectifier and used for supplying power to the anode mother board 2, and the anode mother board 2 is conductive, so that the anode plate 1 is electrified.

In view of the above-mentioned related technologies, the inventor believes that the soft copper bar is directly fixed to the conductive bar by screws, and the nut (used for fixing the anode plate and needing to be periodically disassembled) on the back of the anode mother plate is shielded in space, and the soft copper bar needs to be disassembled first when the bolt is disassembled every time, which is inconvenient.

SUMMERY OF THE UTILITY MODEL

In order to facilitate the disassembly of a nut on the back of an anode mother plate, the application provides a densely-distributed anode plate connecting structure of a crude foil machine and the crude foil machine.

In a first aspect, the present application provides a connection structure for a dense foil generator anode plate, which adopts the following technical scheme:

a densely-distributed anode plate connecting structure of a foil forming machine comprises a conductive bar connected with an anode tank of the foil forming machine and a soft copper bar connected with an external power supply, wherein the anode tank comprises an anode plate and an anode mother plate, the anode mother plate is arc-shaped, a plurality of anode plates are arranged side by side along the circumferential direction of the inner wall of the anode mother plate, a bolt is connected between the anode plate and the anode mother plate in a threaded manner, the end part of the bolt penetrates out of the anode mother plate and is connected with an anode plate nut in a threaded manner, the conducting bar comprises an installation part and a connecting part used for connecting the soft copper bar, the installation part is fixed on one side of the anode plate away from the anode plate and is arranged along the circumferential direction of the anode plate, the installation part is fixed between two adjacent rows of bolts, the connecting part is fixed on the end part of the installation part along the circumferential direction, the connecting part and the installation part are located on different planes, the soft copper bar is connected with the connecting part far away from one end of the installation part, and the soft copper bar is connected with an external power supply.

By adopting the technical scheme, when the anode is used, the current of the anode part passes through the external power supply rectifier: the soft copper bar, the conductive bar and the anode mother board are transmitted to the anode plate, the anode tank works after being connected with a power supply and forms a loop with the cathode, and the copper foil is produced. Because connecting portion are bent from installation department both ends and are stretched out, do not occupy the space of anode plate nut after the soft copper bar is installed, can not shelter from the anode plate nut to can not influence the dismantlement of anode plate nut.

Optionally, at least one conductive bar is arranged between every two adjacent anode plate nuts.

By adopting the technical scheme, the plurality of conductive bars are uniformly distributed on the anode mother board at intervals, so that the anode mother board is more uniform in conduction. In the prior art, only 2-3 conductive bars can be arranged on one side, so that the anode plate is not uniform in conductivity and has certain influence on the quality of a finished product.

Optionally, the conducting bar is a tinned copper bar.

Through adopting above-mentioned technical scheme, tin-plating can prevent that copper from exposing in the air and the oxidation from forming one deck copper green film, and the electric conductivity of aeruginosa can increase the resistance very poorly, therefore tin-plated copper bar electric conductivity is better.

Optionally, still include the cylinder manifold, the installation department links to each other with same connecting portion of one side and same piece cylinder manifold, and soft copper bar is connected on the cylinder manifold.

Through adopting above-mentioned technical scheme, the busbar converges to the polylith busbar for the electric current can be transmitted to different busbars simultaneously through the busbar on, makes the structure more simple.

Optionally, the anode plate is provided with 16-20 blocks.

By adopting the technical scheme, the uniformity of the produced copper foil is not good easily caused by too few anode plates; too many anode plates result in high cost, and 16-20 copper plates can maintain the uniformity of the copper foil and keep the cost low.

Optionally, a plane for abutting against the mounting portion is arranged on one side, away from the anode plate, of the anode mother plate, and the plane is located between two adjacent rows of anode plate nuts.

Through adopting above-mentioned technical scheme, mill the face at curved positive pole motherboard outer wall and form the platform, be favorable to the installation department steadily to install on the plane to the contact is laminated more.

In a second aspect, the present application provides a foil forming machine comprising any one of the anode plate connection structures described above.

Through adopting above-mentioned technical scheme, during the use, the electric current of positive pole part is followed external power supply rectifier and is passed: the soft copper bar, the bus bar, the conductive bar and the anode mother board are transmitted to the anode plate, the anode groove works after being connected with a power supply and forms a loop with the cathode, and copper foil is produced. Because connecting portion are bent from installation department both ends and are stretched out, do not occupy the space of anode plate nut after the soft copper bar is installed, can not shelter from the anode plate nut to can not influence the dismantlement of anode plate nut.

Drawings

FIG. 1 is a schematic cross-sectional view of a connection structure for illustrating the prior art;

FIG. 2 is an enlarged view of portion A of FIG. 1;

FIG. 3 is a left side view for showing a prior art connection structure;

FIG. 4 is a schematic sectional view showing a connection structure according to an embodiment of the present application;

FIG. 5 is a schematic view for showing the installation state of an anode plate according to an embodiment of the present application;

fig. 6 is a schematic view for showing an installation state of the connection structure according to the embodiment of the present application.

Description of reference numerals: 1. an anode plate; 11. an anode plate nut; 2. an anode mother board; 3. a conductive bar; 31. an installation part; 32. a connecting portion; 4. soft copper bars; 5. a bus board.

Detailed Description

The present application is described in further detail below with reference to figures 4-6.

The embodiment of the application discloses a densely-distributed anode plate connecting structure of a foil forming machine and the foil forming machine.

Referring to fig. 4, a foil forming machine comprises a densely distributed anode plate connecting structure of the foil forming machine, the densely distributed anode plate connecting structure of the foil forming machine comprises a conductive bar 3 connected with an anode tank of the foil forming machine and a soft copper bar 4 connected with an external power supply, the anode tank comprises an anode plate 1 and two anode mother plates 2, the anode mother plates 2 are arc-shaped, a plurality of anode plates 1 are arranged side by side along the circumferential direction of the inner wall of the anode mother plate 2, a bolt is connected between the anode plate 1 and the anode mother plate 2 in a threaded manner, the end part of the bolt penetrates out of the anode mother plate 2 and is connected with an anode plate nut 11 in a threaded manner, the conductive bar 3 comprises a mounting part 31 and a connecting part 32 connected with the soft copper bar, the mounting part 31 is fixed on one side of the anode mother plate 2 departing from the anode plate 1 and is arranged along the circumferential direction of the anode mother plate 2, the mounting part 31 is fixed between two adjacent rows of the anode plate nuts 11, the connecting part 32 is fixed on the circumferential end part of the mounting part 31, the connecting part 32 and the mounting part 31 are located on different planes, the soft copper bar 4 and one end of the connecting part 32 far away from the mounting part 31 are connected, and the soft copper bar 4 is connected with an external power supply. Because the connecting part 32 is bent and extended from the two ends of the mounting part 31, the soft copper bar 4 does not occupy the space of the anode plate nut 11 after being mounted, and the dismounting of the anode plate nut 11 is not influenced.

Referring to fig. 5, the anode plate 1 is a rectangular plate, one side of the anode plate 1 close to the anode mother plate 2 is in threaded connection with a row of bolts, and one end of each bolt far away from the anode plate 1 penetrates through the anode mother plate 2 and is in threaded connection with the anode plate nut 11, so that the anode plate 1 is fixed on the anode mother plate 2. Since the anode plate 1 needs to be replaced periodically, the anode plate nut 11 needs to be removed periodically.

16-20 anode plates 1 can be arranged, and poor uniformity of the produced copper foil is easily caused by too few anode plates 1; the cost is high due to too many anode plates 1, and 18 anode plates are selected in the embodiment, so that the uniformity of the copper foil can be maintained, and the cost is kept low. The anode plates 1 are densely distributed on the inner wall of the anode mother plate 2, so that the inner wall of the anode mother plate 2 is completely covered by the anode plates 1. The two anode mother plates 2 are mutually encircled to form a hollow cylindrical shape, so that reactants can be accommodated conveniently. The outer wall of the anode mother board 2 on the side departing from the anode plate 1 is milled at multiple positions to form multiple rectangular planes, and the planes are located between two adjacent rows of anode plate nuts 11 and used for mounting the conductive rows 3. The plurality of conductive bars 3 are uniformly distributed on the anode mother board 2 at intervals, so that the anode mother board 2 is more uniformly conductive.

Referring to fig. 4 and 6, the mounting portion 31 is a rectangular plate, and the mounting portion 31 abuts against the plane and is then fixed by screws, so that the mounting portion 31 is smoothly mounted on the plane, and the mounting portion 31 is contacted with the anode mother plate 2 and is more attached. Connecting portion 32 is the rectangle, and connecting portion 32 integrated into one piece is at the tip of installation department 31 and perpendicular with installation department 31 for connecting portion 32 bends from installation department 31 both ends and stretches out, does not occupy the space of anode plate nut 11, can not shelter from anode plate nut 11, thereby can not influence the dismantlement of anode plate nut 11. The conducting bar 3 can be a tinned copper bar, tinning can prevent that copper from exposing in the air and being formed a layer of copper green film by oxidation, and the electric conductivity of aeruginosa can increase resistance very poorly, and consequently the electric conductivity of tinned copper bar is better.

The connecting portion 32 of the same side of the mounting portion 31 is fixed with the same bus bar 5 through screws, the bus bar 5 is in a C shape, and the bus bar 5 is a copper bar and has excellent conductivity. The busbar 3 that converges is led to the polylith to the cylinder manifold 5 for the electric current can be transmitted to different conductive row 3 simultaneously through the busbar 5 on, the structure is simpler. A plurality of soft copper bars 4 pass through the bolt fastening and keep away from connecting portion 32 one side at cylinder manifold 5, do not occupy the space of anode plate nut 11 after 4 dress of soft copper bars to can not influence the dismantlement of anode plate nut 11. The soft copper bar 4 is electrically connected with an external power supply, and the external power supply can be a rectifier and can lead in stable current to the soft copper bar 4.

The implementation principle of the connection structure of the anode plate of the densely-distributed crude foil machine in the embodiment of the application is as follows: when in use, the current of the anode part sequentially flows from an external power supply rectifier: the soft copper bar 4, the bus bar 5, the conducting bar 3 and the anode mother board 2 are transmitted to the anode plate 1, and the anode groove works after being connected with a power supply and forms a loop with the cathode to produce copper foil. Because the connecting part 32 is bent and extended from the two ends of the mounting part 31, the soft copper bar 4 does not occupy the space of the anode plate nut 11 after being mounted, and the dismounting of the anode plate nut 11 is not influenced.

The foregoing embodiments are merely illustrative of the principles and utilities of the present invention and are not intended to limit the invention. Any person skilled in the art can modify or change the above-mentioned embodiments without departing from the spirit and scope of the present invention. Accordingly, it is intended that all equivalent modifications or changes which can be made by those skilled in the art without departing from the spirit and technical spirit of the present invention be covered by the claims of the present invention.

Claims (7)

1. The utility model provides a foil quick-witted anode plate connection structure is given birth to densely covered formula, including be used for with the soft copper bar (4) of leading electrical drainage (3) and being used for connecting external power source that the positive pole groove that gives birth to the foil machine links to each other, the positive pole groove includes anode plate (1) and positive pole mother board (2), positive pole mother board (2) are arc, polylith anode plate (1) sets up side by side along positive pole mother board (2) inner wall circumference, threaded connection has the bolt between anode plate (1) and positive pole mother board (2), positive pole mother board (2) and threaded connection have anode plate nut (11) are worn out to the tip of bolt, its characterized in that: electrically conductive row (3) are including installation department (31) and connecting portion (32) that are used for connecting soft copper bar, installation department (31) are fixed and are deviated from anode plate (1) one side and set up along anode plate (2) circumference in anode plate (2), installation department (31) are fixed between two adjacent rows of anode plate nuts (11), connecting portion (32) are fixed at installation department (31) along the tip of circumference, connecting portion (32) are located different planes with installation department (31), soft copper bar is kept away from installation department (31) one end with connecting portion (32) and is linked to each other, soft copper bar (4) are connected with external power source.

2. The connection structure of an anode plate of a dense-distribution type crude foil machine according to claim 1, wherein: at least one conductive bar (3) is arranged between every two adjacent rows of the anode plate nuts (11).

3. The connection structure of an anode plate of a dense-distribution type crude foil machine according to claim 1, wherein: the conductive bar (3) is a tinned copper bar.

4. The connection structure of an anode plate of a dense-distribution type crude foil machine according to claim 1, wherein: still include cylinder manifold (5), installation department (31) link to each other with same one side connecting portion (32) and same block of cylinder manifold (5), and soft copper bar (4) are connected on cylinder manifold (5).

5. The connection structure of an anode plate of a dense-distribution type crude foil machine according to claim 1, wherein: 16-20 pieces of the anode plate (1) are arranged.

6. The connection structure of an anode plate of a dense-distribution green-foil machine according to any one of claims 1 to 5, wherein: one side of the anode mother board (2) departing from the anode plate (1) is provided with a plane for abutting against the mounting part (31), and the plane is positioned between two adjacent rows of anode plate nuts (11).

7. A green foil machine characterized by: comprising the anode plate connection structure of any one of claims 1 to 6.

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