CN113981493A - Copper-clad plate copper foil production electrolysis equipment - Google Patents

Abstract

The invention relates to the technical field of copper foil production, in particular to copper clad laminate copper foil production electrolysis equipment, which comprises a copper dissolving tank, a feeding mechanism, a water inlet mechanism, a conveying mechanism and a stirring mechanism, wherein the feeding mechanism is installed in the copper dissolving tank, the water inlet mechanism is installed on the left side of the copper dissolving tank, and the conveying mechanism and the stirring mechanism are installed on the right side of the copper dissolving tank; secondly, the copper material cannot be uniformly added into the sulfuric acid manually, the contact area between the copper material and the sulfuric acid is reduced, the reaction speed between the sulfuric acid and the copper material is influenced, the labor intensity of manually adding the copper material into the sulfuric acid is high, the efficiency of conveying the copper material is low, and the reaction efficiency of a copper sulfate solution is influenced.

Description

Copper-clad plate copper foil production electrolysis equipment

Technical Field

The invention relates to the technical field of copper foil production, in particular to copper clad laminate copper foil production electrolysis equipment.

Background

The electrolytic copper foil is an important material for manufacturing Copper Clad Laminate (CCL), Printed Circuit Board (PCB) and lithium ion battery. In the rapid development of the electronic information industry, the electrolytic copper foil is called a "neural network" for signal and power transmission and communication of electronic products. The production process of the copper clad laminate copper foil is simple, and the main processes comprise three steps: solution foil generation, surface treatment and product slitting, wherein the solution foil generation is to convey a copper material into sulfuric acid for chemical reaction to obtain a copper sulfate solution, and then to electrolyze to obtain the copper clad laminate copper foil.

However, the prior art has the following problems in the preparation of copper sulfate solution, namely, the sulfuric acid splashes during dilution and needs to be stirred by a tool manually, so that the danger of manually diluting the sulfuric acid is high; secondly, the copper material cannot be uniformly added into the sulfuric acid manually, the contact area between the copper material and the sulfuric acid is reduced, the reaction speed between the sulfuric acid and the copper material is influenced, the labor intensity of manually adding the copper material into the sulfuric acid is high, the efficiency of conveying the copper material is low, and the reaction efficiency of a copper sulfate solution is influenced.

Disclosure of Invention

In order to solve the technical problem, the invention provides copper clad laminate copper foil production electrolysis equipment which comprises a copper dissolving box, a feeding mechanism, a water inlet mechanism, a conveying mechanism and a stirring mechanism, wherein the feeding mechanism is installed in the copper dissolving box, the water inlet mechanism is installed on the left side of the copper dissolving box, and the conveying mechanism and the stirring mechanism are installed on the right side of the copper dissolving box.

The feeding mechanism comprises a sealing plate, square blocks, a feeding plate, a feeding pipe, a material distributing plate, a discharging pipe, a flat plate, a feeding motor, an elliptical plate, a sliding plate and a sliding round rod, wherein the sealing plate is arranged in the middle of the inner wall of the copper dissolving box, the square blocks are symmetrically arranged in the middle of the inner walls of the front end and the rear end of the copper dissolving box and positioned on the upper side of the sealing plate, the square blocks are connected through the feeding plate, the feeding pipe is arranged in the middle of the upper end of the feeding plate, the material distributing groove is formed in the middle of the upper side of the feeding plate, a through hole is formed in the central position of the inner wall on the left side of the material distributing groove, the feeding grooves are symmetrically formed in the left side and the right side of the material distributing plate, the material distributing plate is provided with through grooves in a sliding fit manner, the sliding plate is arranged in the central position of the left end of the material distributing plate, and is arranged in the through hole in a sliding fit manner, the sliding round bar is installed in sliding plate upper end left side, and the feed plate lower extreme is located feed chute position department and installs the discharging pipe, and the discharging pipe all runs through the closing plate, divides the feed plate left end and is located logical groove upside and installs the flat board, installs the feeding motor on the flat board, and the feeding motor output runs through the flat board and installs the elliptical plate, and the elliptical trough has been seted up to the elliptical plate lower extreme, and installs the sliding round bar through sliding fit's mode in the elliptical trough, can carry out the operation of carrying in batches to the copper material.

Conveying mechanism including carrying return bend, funnel pipe, dome sheet, branch liquid pipe, fluid-discharge tube and splashproof bent plate, the copper case right side of dissolving install and carry the return bend, carry the return bend upper end and be located and dissolve the copper case outside and install the funnel pipe, the dome sheet is installed through screw-thread fit's mode to funnel pipe upper end, carry the return bend lower extreme and be located and dissolve copper case internally mounted and have the branch liquid pipe of semicircle form, divide liquid pipe right-hand member outer wall downside and evenly install a plurality of fluid-discharge tubes to the back in the past, and the fluid-discharge tube supports tightly on dissolving copper case right-hand member inner wall, the splashproof bent plate is installed to the fluid-discharge tube lower extreme, can carry out stable transport operation to sulphuric acid.

As a preferred technical scheme of the invention, the water inlet mechanism comprises a bearing plate, a water tank, a water pump and a U-shaped water inlet pipe, wherein the bearing plate is arranged on the lower side of the outer wall of the left end of the copper dissolving tank, the water tank is arranged on the bearing plate, the water pump is arranged in the water tank, the U-shaped water inlet pipe with a downward opening is jointly arranged at the left end of the copper dissolving tank and the right side of the water tank, the output end of the water pump is connected to the left end of the U-shaped water inlet pipe, the right end of the U-shaped water inlet pipe penetrates through the sealing plate, and a proper amount of clear water can be added into the copper dissolving tank.

As a preferred technical scheme of the invention, the stirring mechanism comprises a top plate, a stirring motor, a transmission round rod and stirring plates, wherein the top plate is arranged on the upper side of the inner wall of the right end of the copper dissolving box, the stirring motor is arranged at the lower end of the top plate, the transmission round rod is arranged on the sealing plate in a rotating fit mode, the upper end of the transmission round rod is connected to the output end of the stirring motor, and a plurality of stirring plates are uniformly arranged on the lower side of the outer wall of the stirring round rod along the circumferential direction of the stirring round rod from top to bottom, so that stirring operation can be carried out during the reaction of sulfuric acid and clear water, and the dilution rate of the sulfuric acid is improved.

As a preferable technical scheme of the invention, a liquid outlet pipe is arranged at the lower side of the rear end of the copper dissolving box, so that the copper sulfate solution can be discharged.

As a preferred technical scheme, the positioning block is arranged on the upper side of the outer wall of the right end of the copper dissolving box, the right side of the positioning block is connected to the outer wall of the left side of the circular funnel pipe, and the circular funnel pipe can be reinforced.

As a preferred technical scheme of the invention, the backing plate is fixedly arranged on the outer wall of the front end of the copper dissolving box, the existing air compressor is arranged on the backing plate, the air outlet end of the air compressor is connected with the L-shaped air inlet pipe, and the L-shaped air inlet pipe penetrates through the front end of the copper dissolving box and the sealing plate, so that compressed air can be conveyed into the copper dissolving box, and the reaction rate of sulfuric acid and copper materials is improved.

As a preferred technical scheme of the invention, two layered sieve plates are arranged on the inner wall of the left side of the copper dissolving box and positioned on the lower side of the sealing plate, the two layered sieve plates are arranged in a vertically staggered manner, the layered sieve plates are integrally V-shaped, and the right sides of the layered sieve plates are connected through baffles, so that the copper materials can be layered.

As a preferable technical scheme of the invention, the discharge pipe positioned on the left side of the material distribution plate is aligned to the corner of the layered sieve plate positioned on the upper side in the copper melting tank, and the discharge pipe positioned on the right side of the material distribution plate penetrates through the layered sieve plate positioned on the upper side in the copper melting tank and is aligned to the corner of the layered sieve plate positioned on the lower side in the copper melting tank, so that copper materials can be conveyed onto the layered sieve plate.

Has the advantages that: 1. the feeding mechanism designed by the invention can convey the copper material to the layered sieve plate in batches through the reciprocating material distributing plate, and the copper material is separated through the layered sieve plate, so that the contact area of the copper material and sulfuric acid is increased, the reaction rate of the copper material and sulfuric acid is improved, and the reaction rate of the copper material and sulfuric acid is further improved by conveying compressed air into the copper dissolving box through the air compressor.

2. The water inlet mechanism, the conveying mechanism and the stirring mechanism are designed to convey clean water into the copper dissolving box through the water pump, sulfuric acid is slowly added into the clean water through the funnel circular tube, the conveying bent tube, the liquid dividing tube and the liquid discharging tube, the sulfuric acid can be divided through the uniformly designed liquid discharging tube, the sulfuric acid can slowly flow into the clean water along the inner wall of the copper dissolving box, the sulfuric acid and the clean water are prevented from reacting excessively, the clean water and the sulfuric acid can be stirred through the rotation of the stirring plate, and the sulfuric acid dilution efficiency is improved.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a perspective view of the present invention;

FIG. 2 is a top plan view of FIG. 1 of the present invention;

FIG. 3 is a cross-sectional view taken along line A-A of FIG. 2 in accordance with the present invention;

FIG. 4 is an enlarged view of a portion of the invention at K of FIG. 3;

FIG. 5 is a cross-sectional view taken along line B-B of FIG. 2 in accordance with the present invention;

FIG. 6 is a cross-sectional view taken along line C-C of FIG. 2 in accordance with the present invention;

FIG. 7 is a schematic view of a first perspective of the feed mechanism of the present invention;

FIG. 8 is a partial schematic structural view of a second perspective of the feed mechanism of the present invention;

FIG. 9 is a cross-sectional view of the feed mechanism of the present invention;

fig. 10 is a partial structural schematic view of the conveying mechanism of the present invention.

In the figure: 1. a copper dissolving box; 11. a liquid outlet pipe; 12. a base plate; 13. an air compressor; 14. an L-shaped air inlet pipe; 15. layering sieve plates; 16. a baffle plate; 2. a feeding mechanism; 21. a sealing plate; 22. a square block; 23. a feeding plate; 231. a material distributing groove; 232. a through hole; 233. a feed chute; 24. a feed pipe; 25. a material distributing plate; 251. a through groove; 26. a discharge pipe; 27. a flat plate; 28. a feeding motor; 29. an elliptical plate; 291. an elliptical trough; 210. a sliding plate; 211. a sliding round bar; 3. a water inlet mechanism; 31. a support plate; 32. a water tank; 33. a water pump; 34. a U-shaped water inlet pipe; 4. a conveying mechanism; 41. conveying bent pipes; 42. a funnel circular tube; 43. a round cover plate; 44. a liquid separating pipe; 45. a liquid discharge pipe; 46. a splash-proof bending plate; 5. a stirring mechanism; 51. a top plate; 52. a stirring motor; 53. a drive round bar; 54. and (4) stirring the plate.

Detailed Description

The embodiments of the invention will be described in detail below with reference to the drawings, but the invention can be implemented in many different ways as defined and covered by the claims.

Referring to fig. 1, fig. 2 and fig. 3, an electrolysis device for copper foil production of copper clad laminates comprises a copper dissolving tank 1, a feeding mechanism 2, a water inlet mechanism 3, a conveying mechanism 4 and a stirring mechanism 5, wherein the feeding mechanism 2 is installed in the copper dissolving tank 1, the water inlet mechanism 3 is installed on the left side of the copper dissolving tank 1, the conveying mechanism 4 and the stirring mechanism 5 are installed on the right side of the copper dissolving tank 1, and a liquid outlet pipe 11 is arranged on the lower side of the rear end of the copper dissolving tank 1.

Referring to fig. 3, 7, 8 and 9, the feeding mechanism 2 includes a sealing plate 21, a block 22, a feeding plate 23, a feeding pipe 24, a material distributing plate 25, a discharging pipe 26, a flat plate 27, a feeding motor 28, an elliptical plate 29, a sliding plate 210 and a sliding round bar 211, the sealing plate 21 is installed in the middle of the inner wall of the copper dissolving box 1, the blocks 22 are symmetrically installed in the middle of the inner wall of the front and rear ends of the copper dissolving box 1 and located on the upper side of the sealing plate 21, the blocks 22 are connected with each other through the feeding plate 23, the feeding pipe 24 is installed in the middle of the upper end of the feeding plate 23, a material distributing groove 231 is installed in the middle of the upper side of the feeding plate 23, a through hole 232 is installed in the center position of the inner wall of the left side of the material distributing groove 231, feeding grooves 233 are symmetrically installed on the left and right sides of the lower end of the material distributing groove 231, the material distributing plate 25 is symmetrically installed with a through-sliding fit, through groove 251 is installed on the left and right sides of the material distributing plate 25, and the feeding groove 233 and the through groove 251 are matched with each other, divide flitch 25 left end central point to put and install sliding plate 210, and sliding plate 210 installs in through-hole 232 through sliding fit's mode, sliding plate 210 upper end left side is installed and is slided round bar 211, feeding plate 23 lower extreme is located feeding chute 233 position department and installs discharging pipe 26, and discharging pipe 26 all runs through sealing plate 21, divide flitch 25 left end and be located logical groove 251 upside and install dull and stereotyped 27, install feeding motor 28 on the dull and stereotyped 27, feeding motor 28 output runs through dull and stereotyped 27 and installs elliptical plate 29, elliptical plate 291 has been seted up to elliptical plate 29 lower extreme, and install slip round bar 211 through sliding fit's mode in the elliptical groove 291.

Referring to fig. 3, two layered sieve plates 15 are installed on the inner wall of the left side of the copper melting tank 1 and on the lower side of the sealing plate 21, the two layered sieve plates 15 are arranged in a vertically staggered manner, the layered sieve plates 15 are integrally V-shaped, and the right sides of the layered sieve plates 15 are connected through a baffle 16.

Referring to fig. 3, the discharging pipe 26 located at the left side of the material distributing plate 25 is aligned with the corner of the layered sieve plate 15 located at the inner upper side of the copper melting tank 1, and the discharging pipe 26 located at the right side of the material distributing plate 25 penetrates through the layered sieve plate 15 located at the inner upper side of the copper melting tank 1 and is aligned with the corner of the layered sieve plate 15 located at the inner lower side of the copper melting tank 1.

Referring to fig. 1 and 3, the water inlet mechanism 3 includes a supporting plate 31, a water tank 32, a water pump 33 and a U-shaped water inlet pipe 34, the supporting plate 31 is installed on the lower side of the outer wall of the left end of the copper dissolving tank 1, the water tank 32 is installed on the supporting plate 31, the water pump 33 is installed in the water tank 32, the U-shaped water inlet pipe 34 with a downward opening is installed on the left end of the copper dissolving tank 1 and the right side of the water tank 32, the output end of the water pump 33 is connected to the left end of the U-shaped water inlet pipe 34, and the right end of the U-shaped water inlet pipe 34 penetrates through the sealing plate 21.

When the copper dissolving tank works specifically, the water pump 33 is started to convey clean water in the water tank 32 into the copper dissolving tank 1 through the U-shaped water inlet pipe 34, and after a proper amount of clean water is filled in the copper dissolving tank 1, the water pump is closed.

Please refer to fig. 1, fig. 3, fig. 4 and fig. 10, conveying mechanism 4 including carry return bend 41, funnel pipe 42, dome sheet 43, divide liquid pipe 44, fluid-discharge tube 45 and splashproof bent plate 46, dissolve 1 right side of copper case and install and carry return bend 41, carry return bend 41 upper end and be located and dissolve copper case 1 outside and install funnel pipe 42, dissolve 1 right-hand member outer wall upside of copper case and be provided with locating piece 47, locating piece 47 right side is connected on funnel pipe 42 left side outer wall, dome sheet 43 is installed through screw-thread fit's mode to funnel pipe 42 upper end, carry return bend 41 lower extreme and be located and dissolve copper case 1 internally mounted and have the branch liquid pipe 44 of semicircle form, divide liquid pipe 44 right-hand member outer wall downside from the past to the back evenly to install a plurality of fluid-discharge tubes 45, and fluid-discharge tube 45 supports tightly on dissolving 1 right-hand member inner wall of copper case, splashproof bent plate 46 is installed to fluid-discharge tube 45 lower extreme.

Referring to fig. 3 and 6, the stirring mechanism 5 includes a top plate 51, a stirring motor 52, a transmission round bar 53 and stirring plates 54, the top plate 51 is installed on the upper side of the inner wall of the right end of the copper dissolving tank 1, the stirring motor 52 is installed at the lower end of the top plate 51, the transmission round bar 53 is installed on the sealing plate 21 in a rotating fit manner, the upper end of the transmission round bar 53 is connected to the output end of the stirring motor 52, and a plurality of stirring plates 54 are evenly installed on the lower side of the outer wall of the stirring round bar from top to bottom along the circumferential direction.

During specific work, artifical round cover plate 43 that rotates, open funnel pipe 42, artifical present sulphuric acid input mechanism of using slowly carries sulphuric acid funnel pipe 42, sulphuric acid in funnel pipe 42 flows to branch liquid pipe 44 in through carrying return bend 41, sulphuric acid in branch liquid pipe 44 flows to dissolving on the copper case 1 right side inner wall through a plurality of fluid-discharge tubes 45, sulphuric acid slowly flows to the clear water in dissolving copper case 1 right side inner wall, and simultaneously, start agitator motor 52 and make it drive transmission round bar 53 and rotate, transmission round bar 53 drives the stirring board 54 and rotates, stirring board 54 stirs the processing to clear water and sulphuric acid of dissolving in copper case 1, after adding appropriate amount sulphuric acid, sulphuric acid input mechanism stops the input to sulphuric acid.

Referring to fig. 6, a backing plate 12 is fixedly installed on the outer wall of the front end of the copper melting tank 1, an existing air compressor 13 is installed on the backing plate 12, an air outlet end of the air compressor 13 is connected with an L-shaped air inlet pipe 14, and the L-shaped air inlet pipe 14 penetrates through the front end of the copper melting tank 1 and a sealing plate 21.

During specific work, after sulphuric acid and clear water stirring, close agitator motor 52, in artifical current feeding equipment that uses carried the copper material to divide silo 231 through inlet pipe 24, start feeding motor 28 and make it drive elliptical plate 29 and rotate, elliptical plate 29 drives the motion of slip round bar 211 through elliptical groove 291, make slip round bar 211 drive sliding plate 210 and carry out reciprocating motion about in through-hole 232, sliding plate 210 drives and divides flitch 25 to carry out reciprocating motion about in dividing silo 231.

When the material distributing plate 25 slides to the rightmost end in the material distributing groove 231, the copper material in the feeding pipe 24 falls into the through groove 251 on the left side of the material distributing plate 25, the material distributing plate 25 slides to the left side in the material distributing groove 231, the copper material in the through groove 251 on the left side of the material distributing plate 25 moves to the left side, so that the copper material in the through groove 251 on the left side of the material distributing plate 25 falls onto the layered sieve plate 15 on the upper side of the internally dissolved copper box 1 from the feeding groove 233 on the left side of the feeding plate 23 and the discharging pipe 26, the material distributing plate 25 slides to the right side in the material distributing groove 231, the copper material in the through groove 251 on the right side of the material distributing plate 25 moves to the right side, so that the copper material in the through groove 251 on the right side of the material distributing plate 25 falls onto the layered sieve plate 15 on the lower side of the internally dissolved copper box 1 from the feeding groove 233 on the right side of the feeding plate 23 and the discharging pipe 26, so that the copper material and the uniformly stirred sulfuric acid perform chemical reaction, and simultaneously, and starting the air compressor 13 to convey compressed air into the copper dissolving box 1, increasing the reaction speed of the copper material and sulfuric acid to obtain a copper sulfate solution, closing the feeding motor 28 and the air compressor 13, opening the switch of the liquid outlet pipe 11, manually collecting the copper sulfate solution, and continuously mixing the copper material and the sulfuric acid by repeating the operation.

When in work: the first step is as follows: the water pump 33 is started to convey the clean water in the water tank 32 to the copper dissolving tank 1 through the U-shaped water inlet pipe 34, and the water pump is closed after a proper amount of clean water is filled in the copper dissolving tank 1.

The second step is that: the round cover plate 43 is manually rotated, the funnel round pipe 42 is opened, the existing sulfuric acid feeding mechanism is manually used for slowly conveying sulfuric acid to the funnel round pipe 42, and the sulfuric acid in the funnel round pipe 42 slowly flows into clear water from the inner wall of the right side of the copper dissolving box 1 through the conveying bent pipe 41 and the liquid separating pipe 44.

The third step: the stirring motor 52 drives the stirring plate 54 to stir the clean water and the sulfuric acid in the copper dissolving tank 1 through the transmission round rod 53, and after a proper amount of sulfuric acid is added, the sulfuric acid adding mechanism stops adding the sulfuric acid.

The fourth step: copper materials are manually conveyed into the material distribution groove 231 through the feeding pipe 24 by using existing feeding equipment, and the feeding motor 28 drives the sliding plate 210 and the material distribution plate 25 to reciprocate left and right in the material distribution groove 231 through the elliptical plate 29 and the sliding round rod 211.

The fifth step: when the material distributing plate 25 slides to the rightmost end in the material distributing groove 231, the copper material in the feeding pipe 24 falls into the through groove 251 on the left side of the material distributing plate 25, and the material distributing plate 25 slides to the left in the material distributing groove 231, so that the copper material in the through groove 251 on the left side of the material distributing plate 25 falls onto the layered sieve plate 15 on the upper side of the internally-dissolved copper box 1 from the feeding groove 233 on the left side of the feeding plate 23 and the discharging pipe 26.

And a sixth step: copper material in the feeding pipe 24 falls into the through groove 251 on the right side of the material distributing plate 25, the material distributing plate 25 slides to the right in the material distributing groove 231, and copper material in the through groove 251 on the right side of the material distributing plate 25 falls onto the layered sieve plate 15 on the lower side of the internally-dissolved copper tank 1 from the feeding groove 233 on the right side of the feeding plate 23 and the discharging pipe 26, so that the copper material and sulfuric acid uniformly stirred perform chemical reaction.

The seventh step: and starting an air compressor 13 to convey compressed air into the copper dissolving box 1, improving the reaction speed of the copper material and sulfuric acid to obtain a copper sulfate solution, opening a switch of the liquid outlet pipe 11, manually collecting the copper sulfate solution, repeating the operation, continuously mixing the copper material and the sulfuric acid, and finally electrolyzing to obtain the copper clad laminate copper foil.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (8)

1. The utility model provides a copper-clad plate copper foil production electrolysis equipment, includes copper dissolving box (1), feed mechanism (2), mechanism (3) of intaking, conveying mechanism (4) and rabbling mechanism (5), its characterized in that: a feeding mechanism (2) is installed in the copper dissolving box (1), a water inlet mechanism (3) is installed on the left side of the copper dissolving box (1), and a conveying mechanism (4) and a stirring mechanism (5) are installed on the right side of the copper dissolving box (1); wherein:

the feeding mechanism (2) comprises a sealing plate (21), square blocks (22), a feeding plate (23), a feeding pipe (24), a material distributing plate (25), a discharging pipe (26), a flat plate (27), a feeding motor (28), an elliptical plate (29), a sliding plate (210) and a sliding round rod (211), wherein the sealing plate (21) is arranged in the middle of the inner wall of the copper dissolving box (1), the square blocks (22) are symmetrically arranged in the middle of the inner wall of the front end and the rear end of the copper dissolving box (1) and are positioned on the upper side of the sealing plate (21), the square blocks (22) are connected through the feeding plate (23), the feeding pipe (24) is arranged in the middle of the upper end of the feeding plate (23), the material distributing groove (231) is arranged in the middle of the upper side of the feeding plate (23), a through hole (232) is arranged in the center position of the inner wall of the left side of the material distributing groove (231), the feeding grooves (233) are symmetrically arranged on the left side and the right side of the lower end of the material distributing groove (231), the material distributing plate (25) is arranged in a sliding fit mode, the left side and the right side of the material distributing plate (25) are symmetrically provided with through grooves (251), the feeding grooves (233) and the through grooves (251) are mutually matched for use, the center position of the left end of the material distributing plate (25) is provided with a sliding plate (210), the sliding plate (210) is arranged in the through hole (232) in a sliding fit mode, the sliding round rod (211) is arranged on the left side of the upper end of the sliding plate (210), the discharging pipe (26) is arranged at the position, located on the feeding groove (233), of the lower end of the feeding plate (23), the discharging pipes (26) penetrate through the sealing plate (21), the flat plate (27) is arranged at the left end of the material distributing plate (25) and positioned on the upper side of the through groove (251), the feeding motor (28) is arranged on the flat plate (27), the elliptical plate (29) is arranged at the output end of the feeding motor (28) in a penetrating mode through the flat plate (27), the elliptical groove (291) is formed in the lower end of the elliptical plate (29), a sliding round rod (211) is arranged in the oval groove (291) in a sliding fit manner;

conveying mechanism (4) including carrying return bend (41), funnel pipe (42), dome board (43), branch liquid pipe (44), fluid-discharge tube (45) and splashproof bent plate (46), copper dissolving case (1) right side install and carry return bend (41), carry return bend (41) upper end and be located copper dissolving case (1) outside and install funnel pipe (42), dome board (43) are installed through screw-thread fit's mode to funnel pipe (42) upper end, carry return bend (41) lower extreme and be located copper dissolving case (1) internally mounted and have branch liquid pipe (44) of semicircle form, divide liquid pipe (44) right-hand member outer wall downside to evenly install a plurality of fluid-discharge tubes (45) after from the front, and fluid-discharge tube (45) support tightly on copper dissolving case (1) right-hand member inner wall, splashproof bent plate (46) are installed to fluid-discharge tube (45) lower extreme.

2. The copper clad laminate copper foil production electrolysis equipment of claim 1, which is characterized in that: intake mechanism (3) including bearing board (31), water tank (32), water pump (33) and U form inlet tube (34), copper dissolving box (1) left end outer wall downside install bearing board (31), install water tank (32) on bearing board (31), install water pump (33) in water tank (32), copper dissolving box (1) left end and water tank (32) right side install U form inlet tube (34) that open side down jointly, water pump (33) output is connected at U form inlet tube (34) left end, U form inlet tube (34) right-hand member just runs through closing plate (21).

3. The copper clad laminate copper foil production electrolysis equipment of claim 1, which is characterized in that: rabbling mechanism (5) including roof (51), agitator motor (52), transmission round bar (53) and stirring board (54), copper melting box (1) right-hand member inner wall upside install roof (51), agitator motor (52) are installed to roof (51) lower extreme, install transmission round bar (53) through normal running fit's mode on closing plate (21), connection is in agitator motor (52) output in transmission round bar (53) upper end, stirring round bar outer wall downside is from last to evenly installing a plurality of stirring boards (54) down along its circumferential direction.

4. The copper clad laminate copper foil production electrolysis equipment of claim 1, which is characterized in that: a liquid outlet pipe (11) is arranged at the lower side of the rear end of the copper dissolving box (1).

5. The copper clad laminate copper foil production electrolysis equipment of claim 1, which is characterized in that: and a positioning block (47) is arranged on the upper side of the outer wall of the right end of the copper dissolving box (1), and the right side of the positioning block (47) is connected to the outer wall of the left side of the funnel circular tube (42).

6. The copper clad laminate copper foil production electrolysis equipment of claim 1, which is characterized in that: dissolve copper case (1) front end outer wall on fixed mounting have backing plate (12), install current air compressor (13) on backing plate (12), air compressor (13) give vent to anger the end and be connected with L type intake pipe (14), and L type intake pipe (14) run through and dissolve copper case (1) front end and closing plate (21).

7. The copper clad laminate copper foil production electrolysis equipment of claim 1, which is characterized in that: dissolve copper case (1) left side inner wall and be located sealing plate (21) downside and install two layering sieve (15), two layering sieve (15) are dislocation set from top to bottom, and layering sieve (15) are whole to be the V type, layering sieve (15) right side is connected through baffle (16).

8. The copper clad laminate copper foil production electrolysis equipment of claim 7, which is characterized in that: be located left discharging pipe (26) of tripper board (25) aim at the bent angle department that is located the layering sieve (15) of upside in dissolving copper case (1), be located discharging pipe (26) on tripper board (25) right side run through and be located the layering sieve (15) of upside in dissolving copper case (1) and aim at the bent angle department that is located the layering sieve (15) of downside in dissolving copper case (1).

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