CN114628168B

CN114628168B - Quantitative vacuum impregnation mechanism

Info

Publication number: CN114628168B
Application number: CN202011452378.7A
Authority: CN
Inventors: 陈启瑞; 林薏竹
Original assignee: Fengbin Electronic Technology Co ltd
Current assignee: Fengbin Electronic Technology Co ltd
Priority date: 2020-12-12
Filing date: 2020-12-12
Publication date: 2023-06-30
Anticipated expiration: 2040-12-12
Also published as: CN114628168A

Abstract

The invention relates to a quantitative vacuum impregnation mechanism, which comprises an impregnation tank, a piston supporting plate, a liquid inlet guide pipe, a liquid outlet guide pipe, a cover plate, a liquid storage tank, a vacuum reflux barrel, a first fixing plate, a second fixing plate, a third fixing plate, a supporting column, a transmission module, a first transmission rod and a second transmission rod, wherein the first transmission rod is arranged on the first transmission rod; the impregnating tank is provided with a piston cylinder; grooves are formed in two sides of the piston cylinder; a piston is arranged in the piston cylinder; the middle part of the piston cylinder is provided with a through hole. The quantitative vacuum impregnation mechanism is simple in structure and reasonable in design, the liquid storage amount of the piston cylinder is changed by pushing the piston to achieve quantitative liquid control, and the vacuum reflux barrel absorbs liquid, so that quantitative liquid storage amount control, liquid recycling and liquid recycling reliability are good, and production cost is reduced. Solves the problems that the traditional capacitor element impregnation cannot accurately control the liquid amount and the liquid can be recycled, and has great popularization value and practicability.

Description

Quantitative vacuum impregnation mechanism

Technical Field

The invention belongs to the field of capacitor manufacturing instruments, and particularly relates to a quantitative vacuum impregnation mechanism.

Background

In the manufacture of aluminum electrolytic capacitors, electrolyte in the capacitor enters into a capacitor element in an impregnation process, firstly, a monomer solution is impregnated to enable the monomer to enter into the capacitor element, then, an oxidant is impregnated to enable the oxidant to enter into the capacitor element, no automatic vacuum impregnating machine can realize quantitative automatic liquid feeding of thicker impregnating liquid in production at present, liquid quantity injected in the existing liquid injection mode (higher concentration of the thicker impregnating liquid) cannot be supplied to a capacitor element core of the aluminum electrolytic capacitor for carrying out process treatment of the impregnating liquid, recycling of the liquid cannot be recycled again, the defect that liquid quantity cannot be accurately controlled exists, liquid quantity shortage can be generated, the service life of products is short, and the products are directly defective products in serious cases.

Disclosure of Invention

The invention aims to overcome the defects of the prior art, provides a quantitative vacuum impregnation mechanism, changes the liquid storage amount of a piston cylinder by pushing a piston to achieve liquid quantitative control, and sucks liquid by a vacuum reflux barrel to realize quantitative control of the liquid storage amount and liquid recycling, thereby solving the problem that the liquid storage amount and the liquid recycling cannot be accurately controlled by traditional capacitor element impregnation.

The invention solves the technical problems by adopting the following technical scheme:

a quantitative vacuum impregnation mechanism is characterized in that: the device comprises an impregnation tank, a piston supporting plate, a liquid inlet guide pipe, a liquid outlet guide pipe, a cover plate, a liquid storage tank, a vacuum reflux barrel, a first fixing plate, a second fixing plate, a third fixing plate, a supporting column, a transmission module, a first transmission rod and a second transmission rod; the impregnating tank is provided with a piston cylinder; grooves are formed in two sides of the piston cylinder; a piston is arranged in the piston cylinder; the middle part of the piston cylinder is provided with a through hole; the piston cylinders are communicated with each other and are respectively communicated with the liquid inlet guide pipe and the liquid outlet guide pipe through the through holes; the liquid inlet conduit is connected with the liquid storage tank; the liquid outlet pipe is connected with the vacuum reflux barrel; the middle part of the first fixed plate is provided with a hollowed-out groove; the first transmission rod penetrates through the first fixing plate and is fixedly connected with the bottom of the impregnation tank; the second transmission rod penetrates through the first fixed plate and is fixedly connected with the bottom of the piston supporting plate; the first transmission rod and the second transmission rod are respectively connected with the transmission module.

Further, the groove on the upper surface of the impregnation tank is communicated with the liquid outlet conduit.

Further, the piston cylinders in the impregnation tank are distributed in an array mode, the piston cylinders distributed in the same row are communicated with each other, and the impregnation tank is composed of a plurality of piston cylinders in a row.

Further, the number of the piston cylinders corresponds to that of the pistons, a piston is arranged in each piston cylinder, and the bottom of each piston is fixedly connected with the piston supporting plate.

Further, the piston moves up and down in the piston cylinder, the movement of the piston controls the conduction and closure of the through hole, the piston moves to a position where the piston passes through the through hole, and the piston cylinder stores liquid.

Further, the impregnating tank is arranged below the cover plate, the joint end surfaces of the impregnating tank and the cover plate are provided with sealant, and the impregnating tank is lifted to be jointed with the cover plate under the pushing of the first transmission rod.

Further, a clamp is arranged in the cover plate, the distribution of the clamp corresponds to that of a piston cylinder in the impregnation tank, and the capacitor element is clamped in the clamp.

The invention has the advantages and positive effects that:

1. according to the quantitative vacuum impregnation mechanism, the liquid storage amount of the piston cylinder is changed by pushing the piston to achieve quantitative liquid control, and the vacuum reflux barrel absorbs liquid, so that the quantitative liquid control of the impregnation liquid amount, the liquid recycling and the reliability of liquid recycling are good, and the production cost is reduced. Solves the problems that the traditional capacitor element impregnation cannot accurately control the liquid amount and the liquid can be recycled, and has great popularization value and practicability.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

FIG. 2 is a schematic cross-sectional perspective view of an impregnation tank according to the present invention.

FIG. 3 is a schematic cross-sectional front view of an impregnation tank according to the present invention.

FIG. 4 is a schematic perspective view of an impregnation tank according to the present invention.

FIG. 5 is a schematic perspective view of a piston of an impregnation tank according to the present invention.

FIG. 6 is a schematic view showing the perspective view of the bottom of the impregnation tank of the present invention.

Fig. 7 is a schematic perspective view of a cover plate of the present invention.

Reference numerals illustrate: 1. an impregnation tank; 2. a piston; 3. a piston pallet; 4. a liquid inlet conduit; 5. a liquid outlet conduit; 6. a cover plate; 7. a liquid storage tank; 8. a vacuum reflux drum; 9. a first fixing plate; 10. a second fixing plate; 11. a third fixing plate; 12. a support column; 13 a transmission module; 14. a first transmission rod; 15. a second transmission rod; 16. a piston cylinder; 17. a through hole; 18. a groove; 19. a clamp; 20. sealing glue; 21. and (5) a capacitor element.

Detailed Description

Embodiments of the present invention will be described in further detail with reference to the accompanying drawings:

as shown in fig. 1 to 7, the quantitative vacuum impregnation mechanism of the present invention is characterized in that: the device comprises an impregnation tank 1, a piston 2, a piston supporting plate 3, a liquid inlet guide pipe 4, a liquid outlet guide pipe 5, a cover plate 6, a liquid storage tank 7, a vacuum reflux barrel 8, a first fixing plate 9, a second fixing plate 10, a third fixing plate 11, a supporting column 12, a transmission module 13, a first transmission rod 14 and a second transmission rod 15; the impregnating tank 1 is provided with a piston cylinder 16; grooves 18 are formed in two sides of the piston cylinder 16; a piston 2 is arranged in the piston cylinder 16; the middle part of the piston cylinder 16 is provided with a through hole 17; the through holes 17 are communicated with the piston cylinders 16 and respectively communicated with the liquid inlet guide pipe 4 and the liquid outlet guide pipe 5; the liquid inlet conduit 4 is connected with the liquid storage tank 7; the liquid outlet pipe 5 is connected with the vacuum reflux barrel 8; the middle part of the first fixing plate 9 is provided with a hollow groove; the first transmission rod 14 passes through the first fixing plate 9 and is fixedly connected with the bottom of the impregnation tank 1; the second transmission rod 15 passes through the first fixed plate 9 and is fixedly connected with the bottom of the piston supporting plate 3; the first transmission rod 14 and the second transmission rod 15 are respectively connected with the transmission module 13.

The impregnating tank 1 is provided with piston cylinders 16, the piston cylinders 16 in the impregnating tank 1 are distributed in an array mode, the piston cylinders 16 distributed in the same row are communicated with each other, and the impregnating tank 1 is composed of a plurality of rows of piston cylinders 16. The diameter of the piston cylinder 16 is larger than the diameter of the capacitor 21, and the depth of the piston cylinder 16 is consistent with the thickness of the impregnation tank 1, so that the piston cylinder 16 can accommodate the capacitor 21 and can completely impregnate the capacitor 21 in liquid. The piston cylinders 16 in the impregnation tank 1 are distributed in an array. The piston cylinders 16 distributed in each row are distributed in an array at the same pitch, and the number of rows and columns of the array distribution are not limited. The array of pistons 2 corresponds to the array of piston cylinders 16, with each piston 2 corresponding to a piston cylinder 16.

The number of the piston cylinders 16 corresponds to that of the pistons 2, one piston 2 is arranged in each piston cylinder 16, and the bottom of each piston 2 is fixedly connected with the piston supporting plate 3. Each piston 2 is movably sleeved in a piston cylinder 16, the piston cylinder 16 and the piston 2 have air tightness, the penetration of liquid is blocked, and the specific volume of the liquid is controlled by changing the volume of the piston cylinder 16 through the pushing of the piston 2 in the piston cylinder 16.

The piston 2 moves up and down in the piston cylinder 16, the movement of the piston 2 controls the conduction and closure of the through hole 17, the piston 2 moves to a position of passing through the through hole 17, and the piston cylinder 16 stores liquid. Since the middle portion of each piston cylinder 16 of the same column is provided with the through-hole 17, each piston cylinder 16 of the same column is communicated with each other, and when liquid is filled, the liquid flows into the piston cylinder 16 from the liquid inlet pipe 4, and since each piston cylinder 16 of the same column is communicated, the liquid capacity of the flowing liquid is distributed to each piston cylinder 16 is the same.

The second transmission rod 15 passes through the first fixed plate 9 and is fixedly connected with the bottom of the piston supporting plate 3; the first transmission rod 14 and the second transmission rod 15 are respectively connected with the transmission module 13. The pushing of the piston 2 is provided with pushing force by the transmission module 13, the pushing force is provided to the piston supporting plate 3 by the transmission module 13 through the second transmission rod 15, and the piston supporting plate 3 obtains upward pushing force or downward pulling force to control the lifting or descending of the piston 2. When the piston moves upwards and exceeds the through hole 17 in the middle part of the piston cylinder 16, the piston 2 blocks the through hole 17, the upper end part of the piston cylinder 16 forms a closed-bottom groove, liquid can be contained, the capacity of the formed closed-bottom groove is controlled by the pushing amount of the piston 2, and the larger the pushing amount is, the smaller the capacity is. When the piston 2 is subjected to a downward pulling force by the second transmission rod 15, the piston 2 moves downward, and when the piston 2 moves lower than the through hole 17, the through hole 17 in the middle part of the piston cylinders 16 is in a conducting state, and each piston cylinder 16 in the same column is conducted mutually, so that liquid flows from the through hole 17 to the liquid outlet pipe 5. Grooves 18 are formed in two sides of the piston cylinder 16; a piston 2 is arranged in the piston cylinder 16; the middle part of the piston cylinder 16 is provided with a through hole 17; the through holes 17 are communicated with the piston cylinders 16 and respectively communicated with the liquid inlet guide pipe 4 and the liquid outlet guide pipe 5; the liquid inlet conduit 4 is connected with the liquid storage tank 7; the liquid outlet pipe 5 is connected with a vacuum reflux barrel 8. Liquid enters the vacuum reflux drum 8 from the liquid outlet pipe 5 under the suction action of the vacuum reflux drum 8 to recover the liquid. The liquid fluid groove 18 overflows from the top of the piston cylinder 16, and the groove 18 on the upper surface of the soaking groove 1 is communicated with the liquid outlet pipe 5. The spilled liquid enters the liquid outlet conduit 5 via the channel 18 and returns the recovered liquid to the reservoir 7. And (3) completing the impregnation period and recycling the recovered liquid.

The middle part of the first fixing plate 9 is provided with a hollow groove; the first transmission rod 14 passes through the first fixing plate 9 and is fixedly connected with the bottom of the impregnation tank 1. The second fixing plate 10 and the third fixing plate 11 are respectively arranged below the first fixing plate 9, and the supporting columns 12 are respectively fixed on four corners of the first fixing plate 9, the second fixing plate 10 and the third fixing plate 11 to play a role in fixing. The transmission module 13 is disposed in the second fixing plate 10.

The impregnation tank 1 is arranged below the cover plate 6, the joint end surfaces of the impregnation tank 1 and the cover plate 6 are provided with sealant 20, and the impregnation tank 1 is lifted to be jointed with the cover plate 6 under the pushing of the first transmission rod 14. The impregnation tank 1 and the cover plate 6 are joined to form a closed impregnation space. The cover plate 6 is internally provided with clamps 19, the clamps 20 are distributed corresponding to the piston cylinders 16 in the impregnation tank 1, and the clamps 20 are used for clamping capacitor elements 21.

The impregnation process of the capacitor element 21 is that the clamp 19 in the cover plate 6 clamps the capacitor element 21 first, and the number of the clamped capacitor elements 21 is consistent with the number of the piston cylinders 16 in the impregnation tank 1. The transmission module 13 drives the first transmission rod 14, and applies upward pushing force to the first transmission rod 14, the first transmission rod 14 pushes the impregnation tank 1 upward, and the impregnation tank 1 is lifted to be jointed with the cover plate 6 under the pushing of the first transmission rod 14. The impregnation tank 1 and the cover plate 6 are joined to form a closed impregnation space. The liquid is then fed from the liquid reservoir 7 via the liquid feed line 4 to the piston cylinder 16 in the impregnation tank 1 until the piston cylinder 16 is filled with liquid. When the piston cylinder 16 is filled with liquid, the transmission module 13 drives the second transmission rod 15, the second transmission rod 15 receives upward pushing force to push the piston supporting plate 3 and the piston 2 together until the piston 2 passes through the position of the through hole 17, at this time, the piston 2 blocks the through hole 17, the upper end part of the piston cylinder 16 forms a closed-bottom groove, the capacity of the formed closed-bottom groove is controlled by the pushing amount of the piston 2, and the larger the pushing amount is, the smaller the capacity is. The quantitative control of the liquid is achieved, and the overflowed liquid enters the liquid outlet conduit 5 through the groove 18 on the upper surface of the impregnating tank 1. The capacitor 21 is impregnated in the impregnation tank 1. When the impregnation is finished, the piston 2 is driven by the transmission module 13 to apply downward pulling force to the second transmission rod 15, the piston 2 moves downwards, when the piston 2 moves lower than the through hole 17, the through hole 17 in the middle part of the piston cylinder 16 is in a conducting state, each piston cylinder 16 in the same column is conducted mutually, and liquid flows from the through hole 17 to the liquid outlet conduit 5. The liquid was refluxed to the liquid tank 7 under suction from the vacuum reflux drum 8. The impregnated capacitor element 21 in the cover plate 6 goes to the next step. The liquid storage tank 7 is again used for delivering liquid to the impregnation tank 1 to complete the impregnation process of the capacitor element 21 for one cycle. After one period of impregnation is completed, redundant liquid in the impregnation tank 1 is sucked out through the vacuum reflux barrel 8 for recycling, the impregnation cost can be reduced, and the new liquid in the impregnation process of the next period can be ensured to change the liquid storage amount of the impregnation tank 1 through the up-and-down pushing of the piston 2 so as to achieve the liquid quantification. Realizes the quantitative control of the liquid in the impregnation tank 1.

It should be emphasized that the examples described herein are illustrative rather than limiting, and therefore the invention is not limited to the examples described in the detailed description, but rather falls within the scope of the invention as defined by other embodiments derived from the technical solutions of the invention by those skilled in the art.

Claims

1. A quantitative vacuum impregnation mechanism is characterized in that: the device comprises an impregnating tank (1), a piston (2), a piston supporting plate (3), a liquid inlet pipe (4), a liquid outlet pipe (5), a cover plate (6), a liquid storage tank (7), a vacuum reflux barrel (8), a first fixing plate (9), a second fixing plate (10), a third fixing plate (11), a support column (12), a transmission module (13), a first transmission rod (14) and a second transmission rod (15); the impregnating tank (1) is provided with a piston cylinder (16); the piston cylinders (16) are distributed in an array mode, the piston cylinders (16) distributed in the same row are communicated with each other, and the impregnating tank (1) is composed of a plurality of arranged piston cylinders (16); grooves (18) are formed in two sides of the piston cylinder (16); the groove (18) on the upper surface of the impregnation tank (1) is communicated with the liquid outlet conduit (5); a piston (2) is arranged in the piston cylinder (16); the middle part of the piston cylinder (16) is provided with a through hole (17); the piston cylinders (16) are communicated with each other and are respectively communicated with the liquid inlet guide pipe (4) and the liquid outlet guide pipe (5) through the through holes (17); the liquid inlet conduit (4) is connected with the liquid storage tank (7); the liquid outlet conduit (5) is connected with the vacuum reflux barrel (8); the middle part of the first fixing plate (9) is provided with a hollowed-out groove; the first transmission rod (14) passes through the first fixing plate (9) and is fixedly connected with the bottom of the impregnation tank (1); the second transmission rod (15) passes through the first fixing plate (9) and is fixedly connected with the bottom of the piston supporting plate (3); the first transmission rod (14) and the second transmission rod (15) are respectively connected with the transmission module (13).

2. The quantitative vacuum impregnation mechanism of claim 1, wherein: the number of the piston cylinders (16) corresponds to that of the pistons (2), one piston (2) is arranged in each piston cylinder (16), and the bottom of each piston (2) is fixedly connected with the piston supporting plate (3).

3. The quantitative vacuum impregnation mechanism of claim 1, wherein: the piston (2) moves up and down in the piston cylinder (16), the movement of the piston (2) controls the conduction and closure of the through hole (17), the piston (2) moves to a position of passing through the through hole (17), and the piston cylinder (16) stores liquid.

4. The quantitative vacuum impregnation mechanism of claim 1, wherein: the impregnating tank (1) is arranged below the cover plate (6), the joint end surfaces of the impregnating tank (1) and the cover plate (6) are provided with sealant (20), and the impregnating tank (1) is lifted to be jointed with the cover plate (6) under the pushing of the first transmission rod (14).

5. The quantitative vacuum impregnation mechanism of claim 1, wherein: the cover plate (6) is internally provided with clamps (19), the distribution of the clamps (20) corresponds to the piston cylinders (16) in the impregnation tank (1), and the clamps (20) are used for clamping the capacitor elements (21).