CN117029435A

CN117029435A - Drying equipment is used in aluminium electrolytic capacitor production and processing

Info

Publication number: CN117029435A
Application number: CN202311296812.0A
Authority: CN
Inventors: 薛瑄武; 包伟; 陆少游
Original assignee: Nantong Ruitai Electronic Co ltd
Current assignee: Nantong Ruitai Electronic Co ltd
Priority date: 2023-10-09
Filing date: 2023-10-09
Publication date: 2023-11-10

Abstract

The invention discloses drying equipment for producing and processing an aluminum electrolytic capacitor, which comprises a supporting seat, wherein two supporting columns are fixed on the supporting seat, a drying rectangular frame is arranged at the upper ends of the supporting columns, a dust removing box and three heat supply boxes for providing different drying temperatures are arranged in the drying rectangular frame, four hollow plates are arranged in the drying rectangular frame, the hollow plates are communicated with the heat supply boxes and the dust removing boxes, and a plurality of air outlet pipes are arranged at the bottoms of the hollow plates in a penetrating manner. The invention heats the clean water by using the induction current of the alternating magnetic field to generate water vapor, the water vapor not only provides heat for drying the capacitor shell, but also can remove dust in the air, thereby reducing the influence on the capacitor shell, avoiding the vibration and water removal conditions in the prior art without causing shell collision damage by the air blowing treatment of the capacitor shell and the cooperation of the mesh conveyor belt, and further reducing the defective rate.

Description

Drying equipment is used in aluminium electrolytic capacitor production and processing

Technical Field

The invention relates to the technical field of aluminum electrolytic capacitors, in particular to drying equipment for producing and processing an aluminum electrolytic capacitor.

Background

A capacitor is an energy storage element used in circuits for tuning, filtering, coupling, bypassing, energy conversion and delay; the core is formed by overlapping and winding anode aluminum foil, lining paper immersed with electrolyte, cathode aluminum foil, natural oxide film and the like, and the core is sealed by an aluminum shell and a rubber cover after being immersed with the electrolyte to form an electrolytic capacitor. At present, in the production process of the aluminum electrolytic capacitor, the shell of the aluminum electrolytic capacitor can be cleaned for ensuring the cleaning effect of the aluminum electrolytic capacitor, the shell needs to be dried for ensuring the drying effect after cleaning, and the shell can waste longer time in the drying process, so that the production efficiency of the aluminum electrolytic capacitor can be reduced, and longer time is required in the drying process and the process is required to be recovered to the production line.

The prior art discloses drying equipment for aluminum electrolytic capacitor production and processing with application number of CN202110577692.6, the middle part of box is provided with middle conduction subassembly, the bottom of box inner chamber is provided with water guide assembly, middle conduction subassembly includes the slope filter, the leak has been seted up to the slope filter right-hand member, the equidistant rubber arc board that is connected with in top of slope filter, the gas blow hole has been seted up in the left side of rubber arc board, the equidistant piston hole that is equipped with the gas blow hole communicating in bottom of slope filter, the inboard sliding connection in piston hole has rubber piston, the bottom fixedly connected with fine rod of rubber piston, the bottom fixedly connected with horizontal pole of fine rod, and the back of horizontal pole is connected with the back of box inner wall through branch, the bottom of slope filter is connected with the suction component.

In the prior art, through the use of the middle conduction component, the shell of the aluminum electrolytic capacitor can vibrate under the action of the inclined filter plate of the middle conduction component in the drying process of the aluminum electrolytic capacitor, so that the drying efficiency is improved; because the shell is mostly aluminum alloy material and thinner, vibration can easily lead to the shell to collide and appear sunken condition, so can increase the defective rate, can not effectually remove dust, and the dust in the air blows to the shell along with hot-blast, because the shell is moist in addition to the stoving, can lead to the dust to adhere to on the shell, has increased the circumstances that follow-up processing working procedure and dust take out the back probably have the vestige, needs further improvement.

Disclosure of Invention

The invention aims to solve the technical problems and provides drying equipment for producing and processing an aluminum electrolytic capacitor.

In order to achieve the above purpose, the present invention adopts the following technical scheme:

the utility model provides an aluminium electrolytic capacitor production and processing is with drying equipment, includes the supporting seat, be fixed with two support columns on the supporting seat, the stoving rectangle frame is installed to the upper end of support column, run through on the stoving rectangle frame and be equipped with the observation window, install the dust removal case in the stoving rectangle frame and provide the three heat supply case of different stoving temperatures, install four cavity boards in the stoving rectangle frame, cavity board is linked together with heat supply case, dust removal case, just the bottom of cavity board runs through and installs a plurality of tuber pipes, all install the apron on heat supply case, the dust removal case, install the first fan that is connected with the dust removal case on the apron on the heat supply case, install driven pivoted plectane on the supporting seat, be fixed with a plurality of first magnetic path and the second magnetic path that are annular distribution on the plectane, be fixed with the mounting panel on the stoving rectangle frame, run through on the mounting panel and install the heat supply section of thick bamboo, the bottom of thick bamboo is fixed with the first magnetic path and the metal sheet, install the heat supply case on the relative heat supply case, install the heat supply section of thick bamboo in the heat supply case.

Preferably, the drying device further comprises a conveying mechanism, the conveying mechanism comprises two supports fixed on the supporting seat, driving rollers are rotatably connected to the supports, the two driving rollers are connected through a conveying belt, the conveying belt penetrates through the drying rectangular frame, and the conveying belt is in a net-shaped arrangement.

Preferably, the three heat supply boxes are internally provided with the snake-shaped heat exchange tubes, the dust removal box is internally provided with the snake-shaped air inlet tube, and the adjacent snake-shaped heat exchange tubes and the snake-shaped air inlet tube are communicated through connecting tubes.

Preferably, the air outlet end of the first fan penetrates through the cover plate, and the three air inlet ends of the first fans are provided with conveying pipes which penetrate through the cover plate and are connected with the dust removal box.

Preferably, a fixed plate is fixed on the bracket, a motor is installed at the bottom of the fixed plate, the output end of the motor is fixedly connected with a rotating rod, and the circular plate is coaxially and fixedly connected with the rotating rod.

Preferably, the device further comprises a transmission mechanism for driving the transmission roller to rotate, wherein a coaxial worm is fixed on the rotating rod, a short rod which is coaxially arranged is fixed on the transmission roller, a worm wheel is fixed on the short rod, and the worm wheel is in meshed connection with the worm.

Preferably, the cylinder cover is in threaded connection with the heating cylinder, and an air inlet hole is formed in the cylinder cover in a penetrating mode.

Preferably, an air inlet pipe is arranged at the air inlet end of the second fan, the air inlet pipe penetrates through the cylinder cover, an air outlet pipe is arranged at the air outlet end of the second fan, and the air outlet pipe is connected with a similar snake-shaped heat exchange pipe.

Compared with the prior art, the invention has the beneficial effects that:

1. can carry the shell, because the conveyer belt is netted can play the effect to the shell waterlogging caused by excessive rainfall, because the conveyer belt has the stable transportation of transmission, avoided the condition of prior art vibration dewatering, can not lead to the shell collision damage to can reduce the defective rate.

2. Because the magnetic poles of the upper end surfaces of the first magnetic block and the second magnetic block are opposite, the magnetic field is alternately changed through the metal plate during rotation, so that the alternating magnetic field is utilized to induce current to generate heat, the metal plate is heated, clear water in the heat supply cylinder can be heated and boiled to generate steam through heat transfer, and heat can be provided for drying of the shell.

3. In the air and steam conveying process, dust in the air can be removed due to the fact that steam is moist, so that in the air and steam conveying process, the serpentine heat exchange tube which is bent and arranged is conveyed to be in contact with the inner wall of the serpentine heat exchange tube, and therefore the dust which is partly moist can be directly adhered to the inside of the serpentine heat exchange tube, the dust removing effect is achieved, and the dust cannot influence the capacitor shell.

4. The heat exchange is carried out to the hot air after the heat transfer by the snakelike heat exchange tube of rear side, therefore the heat after the heat transfer reduces gradually, and in addition, the hot air is liquefied through heat transfer condensation and depends on at snakelike heat exchange tube inner wall, so when dust and vapor and snakelike heat exchange tube inner wall contact, can further clear up the dust, improves the effect to dust treatment.

5. Air in the overvoltage condition dust removal box is conveyed into the hollow plate and is rapidly sprayed out through the air outlet pipe and blown onto the capacitor shell, moisture on the capacitor shell can be blown away, clear water can be rapidly removed, and dust can not be attached to the shell when the shell is more in moisture due to the fact that the air is subjected to dust removal treatment.

6. Then the air with the temperature gradually increased at the rear side is dried step by step, so that the drying treatment can be effectively and more specifically carried out on the outer shell, and the air blown by drying is purified, so that the outer shell is not influenced.

7. When the snakelike heat exchange tube is provided with water drops, the water drops flow to drive dust on the inner wall of the snakelike heat exchange tube to flow to the inner bottom of the snakelike heat exchange tube, and along with the increase of moisture, the air flow can drive water to flow, so that the water and the dust flow to the ponding tube, the collection of the water and the dust is realized, and the cleaning of the dust on the inner wall of the snakelike heat exchange tube is also realized.

In summary, the alternating magnetic field induction current is utilized to heat clean water to generate water vapor, the water vapor not only provides heat for drying the capacitor shell, but also can carry out dust removal treatment on dust in the air, so that the influence on the capacitor shell is reduced, the air blowing treatment on the capacitor shell and the matching of the mesh conveyor belt are realized, the situation of vibration water removal in the prior art is avoided, the shell collision damage is avoided, the defective rate is reduced, and meanwhile, dust in the serpentine heat exchange tube can be cleaned and collected.

Drawings

FIG. 1 is a schematic diagram of a drying apparatus for producing and processing an aluminum electrolytic capacitor according to the present invention;

FIG. 2 is a top view of a drying apparatus for manufacturing and processing an aluminum electrolytic capacitor according to the present invention;

FIG. 3 is a bottom view of a drying apparatus for manufacturing and processing an aluminum electrolytic capacitor according to the present invention;

FIG. 4 is a side view of a drying apparatus for manufacturing and processing an aluminum electrolytic capacitor according to the present invention;

FIG. 5 is a schematic diagram of a motor in a drying apparatus for manufacturing and processing an aluminum electrolytic capacitor according to the present invention;

fig. 6 is a bottom view of a heating cylinder in a drying apparatus for manufacturing and processing an aluminum electrolytic capacitor according to the present invention.

In the figure: 1 supporting seat, 2 brackets, 3 conveyer belt, 4 drying rectangular frame, 5 observation window, 6 heat supply box, 7 cover plate, 8 conveying pipe, 9 first fan, 10 connecting pipe, 11 mounting panel, 12 air inlet pipe, 13 second fan, 14 outlet pipe, 15 heat supply cylinder, 16 cylinder cover, 17 inlet hole, 18 fixed plate, 19S-shaped heat exchange pipe, 20S-shaped air inlet pipe, 21 support column, 22 hollow plate, 23 air outlet pipe, 24 driving roller, 25 short rod, 26 rotating rod, 27 dust removal box, 28 worm wheel, 29 worm, 30 circular plate, 31 first magnetic block, 32 second magnetic block, 33 metal plate, 34 motor.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments.

Referring to fig. 1-6, a drying device for producing and processing an aluminum electrolytic capacitor comprises a supporting seat 1, wherein two supporting columns 21 are fixed on the supporting seat 1, a drying rectangular frame 4 is installed at the upper ends of the supporting columns 21, an observation window 5 is penetrated and arranged on the drying rectangular frame 4, and the observation window 5 is made of glass materials, so that a worker can know the drying condition of a shell; the conveying mechanism comprises two brackets 2 fixed on the supporting seat 1, the brackets 2 are rotationally connected with driving rollers 24, the two driving rollers 24 are connected through a conveying belt 3, and the conveying belt 3 conveys towards a motor 34; the conveyer belt 3 penetrates through the drying rectangular frame 4, the conveyer belt 3 is in a net shape, and the conveyer belt 3 and the driving roller 24 are matched to convey the shell, wherein the edge part of the conveyer belt 3 can be provided with a bulge to place the shell to drop or a baffle plate is arranged on the supporting seat 1;

the drying rectangular frame 4 is internally provided with a dust removing box 27 and three heat supply boxes 6 for providing different drying temperatures, the three heat supply boxes 6 are internally provided with serpentine heat exchange tubes 19, the dust removing box 27 is internally provided with a serpentine air inlet tube 20, the adjacent serpentine heat exchange tubes 19 and the serpentine air inlet tube 20 are communicated through a connecting tube 10, the bottom of each serpentine heat exchange tube 19 is provided with a water accumulation tube which is provided with a valve and is communicated with the water accumulation tube, the water accumulation tube can be used for collecting water generated by liquefying water vapor, when the serpentine heat exchange tubes 19 are formed with water drops, the water drops flow can drive dust on the inner wall of each serpentine heat exchange tube 19 to flow to the inner bottom of each serpentine heat exchange tube 19, and along with the increase of the water, the air flow can drive water to flow to the water accumulation tube, so that the water and the dust are collected, and the dust on the inner wall of each serpentine heat exchange tube 19 are cleaned;

four hollow plates 22 are arranged in the drying rectangular frame 4, the hollow plates 22 are communicated with the heat supply box 6 and the dust removal box 27, a plurality of air outlet pipes 23 are arranged at the bottoms of the hollow plates 22 in a penetrating manner, cover plates 7 are arranged on the heat supply box 6 and the dust removal box 27, first fans 9 connected with the dust removal box 27 are arranged on the cover plates 7 on the heat supply box 6, air outlet ends of the first fans 9 are arranged through the cover plates 7, conveying pipes 8 are arranged at air inlet ends of the three first fans 9, and the conveying pipes 8 are connected with the dust removal box 27 through the cover plates 7, wherein the air supply quantity of the first fans 9 is small, and only the purpose of conveying heat into the hollow plates 22 is achieved without a large air speed; wherein the communicating part of the dust removing box 27 and the hollow plate 22 is communicated through a vertical pipe, a one-way valve is arranged on the vertical pipe, the one-way valve only allows the dust removing box 27 to flow into the hollow plate 22, the air is prevented from flowing back into the dust removing box 27, and the upper end of the vertical pipe is higher than the inner bottom of the dust removing box 27;

the support seat 1 is provided with a driven and rotated circular plate 30, the support 2 is fixedly provided with a fixed plate 18, the bottom of the fixed plate 18 is provided with a motor 34, the output end of the motor 34 is fixedly connected with a rotating rod 26, and the circular plate 30 is coaxially and fixedly connected with the rotating rod 26; in addition, the device also comprises a transmission mechanism for driving the transmission roller 24 to rotate, a coaxial worm 29 is fixed on the rotating rod 26, a short rod 25 coaxially arranged is fixed on the transmission roller 24, a worm wheel 28 is fixed on the short rod 25, the worm wheel 28 is meshed with the worm 29, so that the conveyor belt 3 can be driven to move, the shell can be conveyed, the worm wheel 28 and the worm 29 are arranged for conveying the shell at a low speed, the drying time of the shell can be increased, and meanwhile, the rotating speed of the circular plate 30 can be ensured;

a plurality of first magnetic blocks 31 and second magnetic blocks 32 which are distributed in an annular manner are fixed on the circular plate 30, the first magnetic blocks 31 and the second magnetic blocks 32 are arranged in a staggered manner, a mounting plate 11 is fixed on the drying rectangular frame 4, a heating cylinder 15 is arranged on the mounting plate 11 in a penetrating manner, and clear water is contained in the heating cylinder 15;

a metal plate 33 opposite to the first magnetic block 31 is fixed at the bottom of the heating cylinder 15; the circumferences of the first magnetic block 31 and the second magnetic block 32 which are distributed in an annular shape are overlapped with the vertical projection of the axis of the metal plate 33, the circular plate 30 rotates to drive the first magnetic block 31 and the second magnetic block 32 to rotate, and the magnetic poles of the upper end surfaces of the first magnetic block 31 and the second magnetic block 32 are opposite, so that the magnetic field is alternately changed through the metal plate 33 during rotation, thereby heating by using alternating magnetic field induced current, heating the metal plate 33, heating clear water in the heat supply cylinder 15 and boiling to generate steam through heat transfer, and providing heat for drying the shell;

the heat supply cylinder 15 is provided with the cylinder cover 16, the cylinder cover 16 is in threaded connection with the heat supply cylinder 15, and the cylinder cover 16 is provided with the air inlet hole 17 in a penetrating way, so that external air can enter the heat supply cylinder 15 through the air inlet hole 17, and negative pressure in the heat supply cylinder 15 can not be caused; the drying rectangular frame 4 is provided with a second fan 13 for conveying heat in the heat supply cylinder 15 into the heat supply box 6, an air inlet pipe 12 is arranged at the air inlet end of the second fan 13, the air inlet pipe 12 penetrates through a cylinder cover 16, an air outlet pipe 14 is arranged at the air outlet end of the second fan 13, and the air outlet pipe 14 is connected with a similar snake-shaped heat exchange pipe 19.

When the invention is used, the shell is conveyed onto the conveying belt 3 through conveying equipment, and then the motor 34, the first fan 9 and the second fan 13 are started;

the motor 34 works to drive the rotating rod 26 and the worm 29 to rotate, the worm 29 rotates to drive the worm wheel 28 and the short rod 25 to rotate, so that the rotation of the driving roller 24 can be realized, the movement of the conveying belt 3 can be realized, the conveying belt 3 can convey the shell, and the effect of draining the shell can be realized due to the net shape of the conveying belt 3;

the rotating rod 26 rotates to drive the round rod 30, the first magnetic block 31 and the second magnetic block 32 to rotate, and because the magnetic poles of the upper end surfaces of the first magnetic block 31 and the second magnetic block 32 are opposite, the magnetic field is alternately changed through the metal plate 33 during rotation, so that the alternating magnetic field induces current to generate heat, the metal plate 33 is heated, clear water in the heat supply cylinder 15 can be heated and boiled to generate steam through heat transfer, and heat can be provided for drying of the shell;

the second fan 13 works to enable external air to enter the heat supply cylinder 15 through the air inlet hole 17, finally air and water vapor are conveyed into the serpentine heat exchange tube 19 through the air inlet tube 12 and the air outlet tube 14, then conveyed into the rear serpentine heat exchange tube 19 through the connecting tube 10, finally conveyed into the serpentine air inlet tube 20 and conveyed into the dust removal box 27;

among them, further explanation is needed: in the air and steam conveying process, dust in the air can be removed due to the fact that steam is moist, in the air and steam conveying process, the serpentine heat exchange tube 19 which is arranged in a bending mode is conveyed to be in contact with the inner wall of the serpentine heat exchange tube, therefore, part of moist dust can be directly stuck in the serpentine heat exchange tube 19, the dust removing effect is achieved, the dust cannot influence the capacitor shell, the air after dust removal can be conveyed into the dust removal box 27, and the inside of the dust removal box 27 is in an overpressure state;

the direction from the second fan 13 to the dust box 27 is described as follows: the first fan 9 can suck air into the dust removal box 27 in an overpressure state, the air exchanges heat after passing through the serpentine heat exchange tube 19 to generate hot air, and the like, the serpentine heat exchange tube 19 at the rear side exchanges heat with the hot air after heat exchange, so that the heat after heat exchange is gradually reduced;

when the shell is conveyed on the conveying belt 3, air in the dust removing box 27 in an overpressure state is conveyed into the hollow plate 22 and is rapidly sprayed out through the air outlet pipe 23 and blown onto the shell of the capacitor, so that moisture on the shell of the capacitor can be blown away, clear water can be rapidly removed, dust cannot adhere to the shell when the moisture of the shell is more due to dust removing treatment, the effect of drying treatment of the shell can be ensured, and the condition that the shell is damaged due to collision in the prior art is avoided due to stable conveying of the conveying belt 3, so that the defective rate can be reduced;

then the air with the temperature gradually increased at the rear side is dried step by step, so that the drying treatment can be effectively and more specifically carried out on the outer shell, and the air blown by drying is purified, so that the outer shell is not influenced.

The foregoing is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art, who is within the scope of the present invention, should make equivalent substitutions or modifications according to the technical scheme of the present invention and the inventive concept thereof, and should be covered by the scope of the present invention.

Claims

1. Drying equipment for aluminum electrolytic capacitor production and processing, including supporting seat (1), its characterized in that, be fixed with two support columns (21) on supporting seat (1), stoving rectangle frame (4) are installed to the upper end of support column (21), run through on stoving rectangle frame (4) and be equipped with observation window (5), install dust removal case (27) and provide three heating case (6) of different stoving temperatures in stoving rectangle frame (4), install four cavity board (22) in stoving rectangle frame (4), cavity board (22) are linked together with heating case (6), dust removal case (27), just the bottom of cavity board (22) is run through and is installed a plurality of tuber pipes (23), all install apron (7) on heating case (6), on apron (7) on heating case (6) install first fan (9) that are connected with dust removal case (27), install by drive pivoted (30) on supporting seat (1), on drying rectangle frame (1) are fixed circular plate (30) and are first circular plate (31) and second circular plate (32) are fixed with first circular plate (31), the heat supply device is characterized in that a heat supply cylinder (15) is arranged on the mounting plate (11) in a penetrating mode, a metal plate (33) opposite to the first magnetic block (31) is fixed at the bottom of the heat supply cylinder (15), a cylinder cover (16) is arranged on the heat supply cylinder (15), and a second fan (13) for conveying heat in the heat supply cylinder (15) into the heat supply box (6) is arranged on the drying rectangular frame (4).

2. The drying equipment for aluminum electrolytic capacitor production and processing according to claim 1, further comprising a conveying mechanism, wherein the conveying mechanism comprises two supports (2) fixed on a supporting seat (1), driving rollers (24) are rotationally connected to the supports (2), the two driving rollers (24) are connected through a conveying belt (3), the conveying belt (3) penetrates through a drying rectangular frame (4), and the conveying belt (3) is in a net-shaped arrangement.

3. The drying equipment for aluminum electrolytic capacitor production and processing according to claim 1, wherein serpentine heat exchange tubes (19) are arranged in three heat supply boxes (6), a serpentine air inlet tube (20) is arranged in the dust removal box (27), and adjacent serpentine heat exchange tubes (19) and serpentine air inlet tubes (20) are communicated through connecting tubes (10).

4. The drying equipment for aluminum electrolytic capacitor production and processing according to claim 1, wherein the air outlet ends of the first fans (9) are arranged through the cover plate (7), the air inlet ends of the three first fans (9) are provided with conveying pipes (8), and the conveying pipes (8) are connected with the dust removal box (27) through the cover plate (7).

5. The drying equipment for aluminum electrolytic capacitor production and processing according to claim 2, wherein a fixing plate (18) is fixed on the bracket (2), a motor (34) is installed at the bottom of the fixing plate (18), the output end of the motor (34) is fixedly connected with a rotating rod (26), and the circular plate (30) is coaxially and fixedly connected with the rotating rod (26).

6. The drying equipment for aluminum electrolytic capacitor production and processing according to claim 5, further comprising a transmission mechanism for driving the transmission roller (24) to rotate, wherein a coaxial worm (29) is fixed on the rotation rod (26), a coaxially arranged short rod (25) is fixed on the transmission roller (24), a worm wheel (28) is fixed on the short rod (25), and the worm wheel (28) is in meshed connection with the worm (29).

7. The drying equipment for aluminum electrolytic capacitor production and processing according to claim 1, wherein the cylinder cover (16) is in threaded connection with the heat supply cylinder (15), and an air inlet hole (17) is formed in the cylinder cover (16) in a penetrating manner.

8. A drying device for producing and processing an aluminum electrolytic capacitor according to claim 3, wherein an air inlet pipe (12) is installed at an air inlet end of the second fan (13), the air inlet pipe (12) penetrates through a cylinder cover (16), an air outlet pipe (14) is installed at an air outlet end of the second fan (13), and the air outlet pipe (14) is connected with a similar serpentine heat exchange pipe (19).