CN221744587U - A high-efficiency drying equipment for electrolytic capacitor processing - Google Patents

Abstract

The utility model relates to the technical field of drying equipment, in particular to efficient drying equipment for electrolytic capacitor processing, which solves the technical problems: when using drying equipment for electrolytic capacitor processing, generally adopt the fan to carry out drying treatment to electrolytic capacitor, but when handling, unable effectual circulation is dried electrolytic capacitor, not only inefficiency and the not thorough that leads to the stoving easily, technical scheme: compared with the traditional drying equipment for electrolytic capacitor processing, the efficient drying equipment for electrolytic capacitor processing provided by the utility model cannot effectively and circularly dry the electrolytic capacitor, is low in efficiency and easy to cause incomplete drying, and can uniformly dry the electrolytic capacitor by injecting hot air into the drying equipment and circulating the hot air.

Description

A high-efficiency drying equipment for electrolytic capacitor processing

Technical Field

The utility model relates to the technical field of drying equipment, in particular to a high-efficiency drying equipment for electrolytic capacitor processing.

Background Art

Electrolytic capacitors are devices used to store electric charge and are commonly used in electronic devices. The processing of electrolytic capacitors may involve the use of high-efficiency drying equipment to speed up the production cycle. High-efficiency drying equipment usually uses hot air circulation systems or infrared heating technologies to quickly evaporate moisture or residual solvents in electrolytic capacitors to ensure product quality and production efficiency. The use of these devices can effectively shorten the production cycle and improve production efficiency. However, when using drying equipment for electrolytic capacitor processing, fans are generally used to dry the electrolytic capacitors. However, during the processing, the electrolytic capacitors cannot be effectively circulated to dry, which is not only inefficient but also easily leads to incomplete drying.

Utility Model Content

In order to overcome the problem that when using drying equipment for electrolytic capacitor processing, fans are generally used to dry the electrolytic capacitors. However, during the process, the electrolytic capacitors cannot be effectively circulated to dry them, which is not only inefficient but also easily leads to incomplete drying.

The technical solution of the utility model is: a high-efficiency drying equipment for electrolytic capacitor processing, including a drying equipment main body, a functional component, a heating component, a blowing component, a charge removal component, a supporting component and a drainage component. The top surface of the drying equipment main body is provided with the functional component, the bottom surface of the functional component is provided with the heating component, the inner side of the drying equipment main body is provided with the blowing component, the bottom surface of the functional component is provided with the charge removal component, the inner bottom surface of the drying equipment main body is provided with the supporting component, and the inner bottom surface of the drying equipment main body is provided with the drainage component.

Preferably, the drying equipment body is sealed by functional components, hot air is added into the drying equipment body by heating components, hot air inside the drying equipment body is blown by blowing components, the electrolytic capacitor is circulated and dried, the charge involved in the electrolytic capacitor is diluted by the charge removal component, the electrolytic capacitor is supported by the support component, and the condensed water generated by drying is discharged by the drainage component.

Preferably, the functional components include a cover plate, a rotating shaft and a support rod. The top surface of the drying equipment body is provided with a cover plate, a rotating shaft is provided on one side of the cover plate, the cover plate is connected to the drying equipment body through the rotating shaft, the bottom surface of the drying equipment body is provided with a support rod, and multiple groups of support rods are provided. When in use, the drying equipment body is sealed by the cover plate, the cover plate and the drying equipment body are connected by the rotating shaft, and the drying equipment body is supported by the support rod.

Preferably, the heating assembly includes a fan and a heater. The top surface of the cover is provided with a fan, and the bottom surface of the cover is provided with a heater. The fan and the heater are connected. When in use, air is drawn into the heater by the fan, and the air is heated by the heater.

Preferably, the blowing assembly includes a mounting block, an air outlet, an air suction device, a dustproof plate and a circulating air duct. A mounting block is arranged on the inner side of the drying equipment body, an air outlet is provided on the surface of the mounting block, and multiple groups of air outlets are provided. An air suction device is arranged on the outer side of the drying equipment body, and a dustproof plate is provided on one side of the air suction device. A circulating air duct is provided on the inner wall of the drying equipment body, and multiple groups of circulating air ducts are provided. When in use, air is drawn into the air outlet through the air suction device, and air is injected into the interior of the drying equipment body through the air outlet. The dustproof plate prevents dust from entering the interior of the air suction device, and hot air is circulated in the drying equipment body through the circulating air duct to dry the electrolytic capacitor.

Preferably, the charge removal component includes a mounting base and a negative ion generator. The bottom surface of the cover plate is provided with a mounting base, and multiple groups of mounting bases are provided. The bottom surface of the mounting base is provided with a negative ion generator. When in use, the negative ion generator is installed through the mounting base, and the residual charge of the electrolytic capacitor is eliminated through the negative ion generator.

Preferably, the supporting assembly includes a rotating base, a supporting platform and a motor. The inner bottom surface of the drying equipment body is provided with a rotating base, and the top surface of the rotating base is provided with a supporting platform. When in use, the electrolytic capacitor is stored through the supporting platform, and the rotating base is driven to rotate by the motor, and the supporting platform is driven to rotate by the rotating base.

Preferably, the drainage component includes a water collecting channel and a drainage valve. A water collecting channel is opened on the inner bottom surface of the drying equipment body, and a drainage valve is arranged on the outer side of the drying equipment body. The drainage valve is connected to the water collecting channel. When in use, the condensed water generated by drying is collected through the water collecting channel, and the condensed water in the water collecting channel is discharged through the drainage valve.

Beneficial effects of the utility model:

1. Compared with the traditional drying equipment for electrolytic capacitor processing, the fan is generally used to dry the electrolytic capacitor. However, during the processing, the electrolytic capacitor cannot be effectively circulated to dry it, which is not only inefficient but also easy to cause incomplete drying. The high-efficiency drying equipment for electrolytic capacitor processing injects hot air into the drying equipment, and can make the hot air circulate evenly to dry the electrolytic capacitor, which is more convenient;

2. The air is drawn into the heater through the fan, the air is heated by the heater, the air is drawn into the air outlet through the air suction device, the air is injected into the main body of the drying equipment through the air outlet, the dust-proof plate is used to prevent dust from entering the inside of the air suction device, and the hot air is circulated in the main body of the drying equipment through the circulating air duct to dry the electrolytic capacitor, so that the hot air can circulate evenly to dry the electrolytic capacitor;

3. Install the negative ion generator through the installation base, eliminate the residual charge of the electrolytic capacitor through the negative ion generator, store the electrolytic capacitor through the support table, drive the rotating base to rotate through the motor, drive the supporting table to rotate through the rotating base, collect the condensed water generated by drying through the water collection channel, and discharge the condensed water in the water collection channel through the drain valve, so as to effectively discharge the condensed water generated during drying.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG1 is a schematic diagram showing a first three-dimensional structure of a high-efficiency drying device for electrolytic capacitor processing according to the present invention;

FIG2 is a schematic diagram showing a second three-dimensional structure of the high-efficiency drying equipment for electrolytic capacitor processing of the present invention;

FIG3 is a schematic diagram showing the internal three-dimensional structure of the high-efficiency drying equipment for electrolytic capacitor processing of the present invention;

FIG4 is a schematic diagram of a partial three-dimensional structure of a high-efficiency drying device for electrolytic capacitor processing according to the present invention;

Explanation of the accompanying drawings: 1. Drying equipment body; 2. Functional component; 3. Heating component; 4. Blowing component; 5. De-charge component; 6. Support component; 7. Drainage component; 201. Cover plate; 202. Rotating shaft; 203. Support rod; 301. Fan; 302. Heater; 401. Mounting block; 402. Air outlet; 403. Air suction device; 404. Dustproof plate; 405. Circulating air duct; 501. Mounting base; 502. Negative ion generator; 601. Rotating base; 602. Support table; 603. Motor; 701. Water collection channel; 702. Drainage valve.

DETAILED DESCRIPTION

The utility model is further described below in conjunction with the accompanying drawings and embodiments.

Please refer to Figure 1. The utility model provides an embodiment: a high-efficiency drying equipment for electrolytic capacitor processing, including a drying equipment body 1, a functional component 2, a heating component 3, a blowing component 4, a charge removal component 5, a supporting component 6 and a drainage component 7. The top surface of the drying equipment body 1 is provided with the functional component 2, the bottom surface of the functional component 2 is provided with the heating component 3, the inner side of the drying equipment body 1 is provided with the blowing component 4, the bottom surface of the functional component 2 is provided with the charge removal component 5, the inner bottom surface of the drying equipment body 1 is provided with the supporting component 6, and the inner bottom surface of the drying equipment body 1 is provided with the drainage component 7.

Please refer to Figures 2-4. In this embodiment, the functional component 2 includes a cover plate 201, a rotating shaft 202 and a support rod 203. The top surface of the drying device body 1 is provided with a cover plate 201, and a rotating shaft 202 is provided on one side of the cover plate 201. The cover plate 201 is connected to the drying device body 1 through the rotating shaft 202. The bottom surface of the drying device body 1 is provided with a support rod 203. The support rod 203 is provided with multiple groups. When in use, the drying device body 1 is sealed by the cover plate 201, the cover plate 201 and the drying device body 1 are connected by the rotating shaft 202, and the drying device body 1 is supported by the support rod 203. The heating component 3 includes a fan 301 and a heater 302. The top surface of the cover plate 201 is provided with a fan 301, and the bottom surface of the cover plate 201 is provided with a heater 302. The fan 301 and the heater 302 are connected. When in use, air is drawn into the heater through the fan 301. In the heater 302, the air is heated by the heater 302, and the blowing component 4 includes a mounting block 401, an air outlet 402, an air suction device 403, a dustproof plate 404 and a circulating air duct 405. A mounting block 401 is arranged on the inner side of the drying device body 1, and an air outlet 402 is provided on the surface of the mounting block 401, and the air outlet 402 is provided in multiple groups. An air suction device 403 is arranged on the outer side of the drying device body 1, and a dustproof plate 404 is arranged on one side of the air suction device 403. A circulating air duct 405 is provided on the inner wall of the drying device body 1, and the circulating air duct 405 is provided in multiple groups. When in use, air is drawn into the air outlet 402 by the air suction device 403, and air is injected into the interior of the drying device body 1 through the air outlet 402. The dustproof plate 404 prevents dust from entering the interior of the air suction device 403, and the hot air is circulated in the drying device body 1 through the circulating air duct 405 to dry the electrolytic capacitor.

The charge removal component 5 includes a mounting base 501 and a negative ion generator 502. The bottom surface of the cover plate 201 is provided with a mounting base 501. The mounting base 501 is provided with multiple groups. The bottom surface of the mounting base 501 is provided with a negative ion generator 502. When in use, the negative ion generator 502 is installed through the mounting base 501, and the residual charge of the electrolytic capacitor is eliminated through the negative ion generator 502. The support component 6 includes a rotating base 601, a support table 602 and a motor 603. The inner bottom surface of the drying device body 1 is provided with a rotating base 601, and the top surface of the rotating base 601 is provided with a support table 603. 02. When in use, the electrolytic capacitor is stored by the support platform 602, the rotating base 601 is driven to rotate by the motor 603, and the supporting platform 602 is driven to rotate by the rotating base 601. The drainage component 7 includes a water collection channel 701 and a drainage valve 702. The inner bottom surface of the drying equipment body 1 is provided with a water collection channel 701, and the outer side of the drying equipment body 1 is provided with a drainage valve 702. The drainage valve 702 is connected to the water collection channel 701. When in use, the condensed water generated by drying is collected through the water collection channel 701, and the condensed water in the water collection channel 701 is discharged through the drainage valve 702.

When working, the electrolytic capacitor is stored through the support platform 602, the rotating base 601 is driven to rotate by the motor 603, the supporting platform 602 is driven to rotate by the rotating base 601, the drying device body 1 is sealed by the cover plate 201, the cover plate 201 and the drying device body 1 are connected by the rotating shaft 202, and the drying device body 1 is supported by the support rod 203;

Air is drawn into the heater 302 through the fan 301, the air is heated by the heater 302, the air is drawn into the air outlet 402 through the air suction device 403, the air is injected into the drying device body 1 through the air outlet 402, the dust is prevented from entering the air suction device 403 through the dustproof plate 404, and the hot air is circulated in the drying device body 1 through the circulating air duct 405 to dry the electrolytic capacitor;

At the same time, the negative ion generator 502 is installed through the installation base 501, the residual charge of the electrolytic capacitor is eliminated through the negative ion generator 502, the condensed water generated by drying is collected through the water collection channel 701, and the condensed water in the water collection channel 701 is discharged through the drain valve 702.

Through the above steps, the drying equipment body 1 is sealed through the functional component 2, hot air is added to the drying equipment body 1 through the heating component 3, the hot air inside the drying equipment body 1 is blown by the blowing component 4, the electrolytic capacitor is circulated and dried, the charge involved in the electrolytic capacitor is diluted by the charge removal component 5, the electrolytic capacitor is supported by the support component 6, and the condensed water generated by drying is discharged by the drainage component 7.

The embodiments of the present invention are described in detail above in conjunction with the accompanying drawings, but the present invention is not limited to the above embodiments, and various changes can be made within the knowledge scope of those skilled in the art without departing from the purpose of the present invention.

Claims (7)

1. An efficient drying device for electrolytic capacitor processing comprises a drying device main body (1); the method is characterized in that: still including functional module (2), heating element (3), blast module (4), remove charge subassembly (5), supporting component (6) and drainage subassembly (7), the top surface of drying equipment main part (1) is provided with functional module (2), the bottom surface of functional module (2) is provided with heating element (3), the inboard of drying equipment main part (1) is provided with blast module (4), the bottom surface of functional module (2) is provided with removes charge subassembly (5), the inside bottom surface of drying equipment main part (1) is provided with supporting component (6), the inside bottom surface of drying equipment main part (1) is provided with drainage subassembly (7).

2. The efficient drying equipment for electrolytic capacitor processing according to claim 1, wherein: the functional component (2) comprises a cover plate (201), a rotating shaft (202) and a supporting rod (203), wherein the cover plate (201) is arranged on the top surface of the drying equipment main body (1), the rotating shaft (202) is arranged on one side of the cover plate (201), the cover plate (201) is connected with the drying equipment main body (1) through the rotating shaft (202), the supporting rod (203) is arranged on the bottom surface of the drying equipment main body (1), and a plurality of groups of supporting rods (203) are arranged.

3. The efficient drying equipment for electrolytic capacitor processing according to claim 2, wherein: the heating assembly (3) comprises a fan (301) and a heater (302), the fan (301) is arranged on the top surface of the cover plate (201), the heater (302) is arranged on the bottom surface of the cover plate (201), and the fan (301) is connected with the heater (302).

4. The efficient drying equipment for electrolytic capacitor processing according to claim 1, wherein: the air blowing component (4) comprises a mounting block (401), an air outlet (402), an air suction device (403), a dust-proof plate (404) and a circulating air duct (405), the inner side of the drying equipment main body (1) is provided with the mounting block (401),

An air outlet (402) is formed in the surface of the mounting block (401), a plurality of groups of air outlets (402) are formed in the outer side of the drying equipment main body (1), an air suction device (403) is arranged on the outer side of the drying equipment main body (1), a dust-proof plate (404) is arranged on one side of the air suction device (403), a circulating air channel (405) is formed in the inner wall of the drying equipment main body (1), and a plurality of groups of circulating air channels (405) are formed in the inner wall of the drying equipment main body.

5. The efficient drying equipment for electrolytic capacitor processing according to claim 2, wherein: the charge removing assembly (5) comprises a mounting base (501) and a negative ion generator (502), wherein the mounting base (501) is arranged on the bottom surface of the cover plate (201), a plurality of groups of mounting bases (501) are arranged, and the negative ion generator (502) is arranged on the bottom surface of the mounting base (501).

6. The efficient drying equipment for electrolytic capacitor processing according to claim 1, wherein: the support assembly (6) comprises a rotating base (601), a supporting table (602) and a motor (603), wherein the rotating base (601) is arranged on the inner bottom surface of the drying equipment main body (1), and the supporting table (602) is arranged on the top surface of the rotating base (601).

7. The efficient drying equipment for electrolytic capacitor processing according to claim 1, wherein: the drainage assembly (7) comprises a water collecting channel (701) and a drainage valve (702), the water collecting channel (701) is formed in the inner bottom surface of the drying equipment main body (1), the drainage valve (702) is arranged on the outer side of the drying equipment main body (1), and the drainage valve (702) is connected with the water collecting channel (701).