CN212253545U - Storage battery shell drying device - Google Patents

Abstract

The utility model discloses a battery case drying device, extend the air-blast cover of the other end by its axial one end including the conveyer belt, in the air-blast cover inner wall rotates and is connected with the pendulum wind section of thick bamboo rather than the axis coincidence, the air-blast cover has hollow wind chamber, is equipped with spiral electric heating wire in wind intracavity, the pitch of spiral electric heating wire reduces along the direction of delivery of battery gradually, opens the air outlet that has the bar evenly along its circumference on the inner wall of air-blast cover, and each air outlet extends to the other end by the axial one end of air-blast cover, in it has the pendulum wind gap to open evenly along its circumference on the pendulum wind section of thick bamboo, and the outer wall and the air feed system intercommunication of air-blast cover. The utility model has the characteristics of moisture on the abundant stoving battery case, it is long when effectively reducing the stoving. The utility model is suitable for a drying equipment technical field after battery case washs in the battery production.

Description

Storage battery shell drying device

Technical Field

The utility model belongs to the technical field of the drying equipment after battery case washs in the battery production, specifically speaking relates to a battery case drying device.

Background

At present, the shell of the storage battery needs to be dried after cleaning the residual acid liquor on the surface of the shell so as to avoid the influence of moisture on the subsequent ultrasonic sealing cover. Present stoving all is to carry the battery to drying chamber in and dries, because the wind direction of the hot-blast wind in the drying chamber is fixed, the defect of existence is: on one hand, the wind direction is single, the local part of the storage battery shell is not easily blown by hot wind, and the drying time is prolonged; on the other hand, the stoving process is the assembly line form, and partial battery case stoving insufficient phenomenon often can appear, however, does not dry abundant battery, and the manual work is difficult to detect out, and then has influenced subsequent closing cap process.

SUMMERY OF THE UTILITY MODEL

The utility model provides a can fully dry and go up moisture on the battery case, battery case drying device when effective reduction is dried.

In order to achieve the above object, the utility model adopts the following technical scheme:

the utility model provides a battery case drying device, includes that the conveyer belt extends the air-blast cover of the other end by its axial one end, in the air-blast cover inner wall rotates and is connected with the pendulum wind section of thick bamboo rather than the axis coincidence, the air-blast cover has hollow wind chamber, is equipped with spiral electric heating wire in wind intracavity, the pitch of spiral electric heating wire reduces along the direction of delivery of battery gradually, evenly opens along its circumference on the inner wall of air-blast cover has the air outlet of bar, and each air outlet extends to the other end by the axial one end of air-blast cover, in it has the pendulum wind gap to open evenly along its circumference on the pendulum wind section of thick bamboo, and the outer wall and the air feed system intercommunication of air-blast cover.

Furthermore, an outer gear ring is welded at one axial end of the air swinging cylinder, a driving motor is installed on the air blowing sleeve, and a gear meshed with the outer gear ring is installed on an output shaft of the driving motor.

Furthermore, each air swinging opening is an oblique cut along the radial section of the air swinging cylinder.

Furthermore, each air swinging opening extends from one end to the other end of the air swinging cylinder along the axial direction of the air swinging cylinder.

Furthermore, the air swinging ports are strip-shaped holes, and the air swinging ports are uniformly distributed on the air swinging cylinder.

Furthermore, the air blowing sleeve is of a sleeve-shaped structure with the radius of the inlet end of the storage battery larger than the radius of the outlet end of the storage battery, and the air swinging cylinder is adapted to the inner wall of the sleeve-shaped structure.

Furthermore, the air supply system comprises an air supply main pipe provided with a master control valve, and the air supply main pipe is communicated with an air cavity of the air blowing sleeve.

Furthermore, the air supply system further comprises a first annular air distribution pipe and a second annular air distribution pipe which are sleeved outside the air blowing sleeve and are close to the outlet end and the inlet end of the storage battery respectively, the first annular air distribution pipe and the second annular air distribution pipe are communicated with the air cavity respectively, the air supply main pipe is communicated with the first annular air distribution pipe and the second annular air distribution pipe through a communication pipe, and a first control valve and a second control valve which are used for controlling the air quantity entering the first annular air distribution pipe and the second annular air distribution pipe are installed on the communication pipe respectively.

Furthermore, a preheating wire is assembled in the first annular air distribution pipe.

Furthermore, a plurality of supporting platforms are arranged at the lower part of the air blowing sleeve, and the supporting platforms support the air blowing sleeve at intervals along the axial direction of the air blowing sleeve.

The utility model discloses owing to adopted foretell structure, it compares with prior art, and the technical progress who gains lies in: the screw pitch of the spiral electric heating wire arranged in the air cavity of the air blowing sleeve is gradually reduced along the conveying direction of the storage battery, so that the outlet end of the storage battery with heating strength is larger than the inlet end of the storage battery, the air supply system supplies air with pressure into the air cavity, the storage battery is conveyed into the air blowing sleeve by the conveyor belt, the air with less heat is blown to the storage battery by the air blowing sleeve near the inlet end of the air blowing sleeve, the aim is to blow off larger water drops on the shell of the storage battery, the air with higher heat is blown to the storage battery at the corresponding position by the air blowing sleeve near the outlet end of the air blowing sleeve, the residual moisture on the shell of the storage battery is evaporated, and the swinging cylinder is sleeved in the air blowing sleeve in a rotating way and driven by external force to rotate, the air is blown out by the air outlet and is cut by the rotating swinging air port, so that, and the occurrence of dead angles is avoided; therefore, the utility model has the characteristics of moisture on the fully drying battery case, it is long when effectively reducing the stoving.

Drawings

The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention, and together with the description serve to explain the invention and not to limit the invention.

In the drawings:

fig. 1 is a schematic structural diagram of an embodiment of the present invention;

fig. 2 is a sectional view of an axial structure of an embodiment of the present invention;

fig. 3 is a schematic structural view of the swing duct according to the embodiment of the present invention;

FIG. 4 is another schematic structural diagram of the blower sleeve according to the embodiment of the present invention;

fig. 5 is a schematic structural view of a swinging air cylinder according to an embodiment of the present invention;

fig. 6 is another schematic structural diagram of the swinging air cylinder according to the embodiment of the present invention;

fig. 7 is a radial structure sectional view of the swing cylinder according to the embodiment of the present invention;

fig. 8 is an enlarged view of a portion a in fig. 7.

Labeling components: 200-a conveyor belt, 500-an air blowing sleeve, 501-an air cavity, 502-an air outlet, 503-a spiral electric heating wire, 504-an air swinging cylinder, 505-an outer gear ring, 506-an air supply main pipe, 507-a main control valve, 508-a communicating pipe, 509-a first control valve, 510-a second control valve, 511-a first annular air distribution pipe, 512-a second annular air distribution pipe, 513-a pre-heating wire, 514-a support table and 515-an air swinging cylinder.

Detailed Description

The preferred embodiments of the present invention will be described below with reference to the accompanying drawings. It should be understood that the preferred embodiments described herein are for purposes of illustration and explanation only and are not intended to limit the invention.

The utility model discloses a battery case drying device, as shown in fig. 1-8, including a blast sleeve 500, a pendulum wind section of thick bamboo 504 and air feed system. A plurality of support bases 514 are provided at a lower portion of the windband 500, and the plurality of support bases 514 support the windband 500 at intervals in an axial direction of the windband 500. The conveyor belt 200 extends out of the other end of the blowing sleeve 500 from one axial end thereof, the air swing cylinder 504 is sleeved on the inner wall of the blowing sleeve 500, the axial lines of the blowing sleeve 500 and the air swing cylinder 504 are overlapped, and the air swing cylinder 504 is rotatably connected with the blowing sleeve 500. The air blowing sleeve 500 is provided with a hollow air cavity 501, a spiral electric heating wire 503 is assembled in the air cavity 501, the pitch of the spiral electric heating wire 503 is gradually reduced along the conveying direction of the storage battery, the pitch of the spiral electric heating wire 503 can also be selected to be the smallest in the middle of the air blowing sleeve 500, and the pitch of the spiral electric heating wire 503 gradually increases along the axial line of the air blowing sleeve 500 towards the two sides of the air blowing sleeve 500. Strip-shaped air outlets 502 are uniformly formed in the inner wall of the air blowing sleeve 500 along the circumferential direction of the air blowing sleeve, each air outlet 502 extends from one end to the other end of the air blowing sleeve 500 in the axial direction, air swinging openings 515 are uniformly formed in the air swinging barrel 504 along the circumferential direction of the air swinging barrel, and the outer wall of the air blowing sleeve 500 is communicated with an air supply system. The utility model discloses a theory of operation does: the screw pitch of the spiral electric heating wire 503 arranged in the air cavity 501 of the air blowing sleeve 500 is gradually reduced along the conveying direction of the storage battery, so that the outlet end of the storage battery with heating intensity is larger than the inlet end of the storage battery, an air supply system supplies air with pressure into the air cavity 501, the storage battery is conveyed into the air blowing sleeve 500 by the conveyor belt 200, the air with less heat is blown to the storage battery by the air blowing sleeve 500 near the inlet end of the air blowing sleeve, the aim is to blow off larger water drops on the outer shell of the storage battery, the air with higher heat is blown to the storage battery at the corresponding position by the air blowing sleeve 500 near the outlet end of the air blowing sleeve 500 for evaporating residual moisture on the outer shell of the storage battery, and the air swinging cylinder 504 is rotationally sleeved in the air blowing sleeve 500 under the driving of external force, the air is blown out by the air outlet 502 and is cut through the rotating air swinging port 515, so that the air direction swings to evaporate moisture on, and the occurrence of dead angles is avoided.

As a preferred embodiment of the present invention, as shown in fig. 1 and fig. 5 to 6, the specific driven rotation mode of the swing air cylinder 504 is that an outer gear ring 505 is welded at one axial end of the swing air cylinder 504, the outer gear ring 505 coincides with the axis of the swing air cylinder 504, a driving motor is installed on the air blowing sleeve 500, and a gear meshed with the outer gear ring 505 is installed on the output shaft of the driving motor. The assembly of the driving motor and the gear and the matching of the gear and the outer gear ring 505 in this embodiment are not shown, and are conventional and need not be described herein. The driving motor drives the air swinging cylinder 504 to rotate along the axis of the air swinging cylinder through the matching of the gear and the outer gear ring 505, so that the air swinging cylinder 504 cuts and swings the air with pressure blown out by the air blowing sleeve 500, and the air blown to the battery shell is swinging air.

As a preferred embodiment of the present invention, as shown in fig. 7-8, each of the swinging air ports 515 is a bevel cut along the radial section of the swinging air cylinder 504, so that the air coming out from the swinging air ports 515 has a certain angle, forms a rotational flow, and forms a superposition stagger with the rotation of the swinging air cylinder 504, so that the angle range of the air is increased, thereby effectively avoiding the occurrence of dead angles, and improving the drying efficiency.

As a preferred embodiment of the present invention, the pendulum air cylinder 504 is divided into two types. First, as shown in fig. 5, each of the pendulum air outlets 515 extends from one end to the other end of the pendulum air cylinder 504 in the axial direction thereof; secondly, as shown in fig. 6, the swinging air ports 515 are strip-shaped holes, and the swinging air ports 515 are uniformly distributed on the swinging air cylinder 504. The first plurality of storage batteries have strong integrity blown by wind in the air blowing sleeve 500; the second same-direction wind is divided into a plurality of wind by the wind swinging opening 515 and blows the wind to the storage battery, and the interference among the wind is dispersed, so that the range of the wind blowing to the storage battery shell is enlarged.

As a preferred embodiment of the present invention, as shown in fig. 4, the air blowing sleeve 500 is a sleeve structure with a radius of the inlet end of the storage battery larger than that of the outlet end of the storage battery, the air swinging cylinder 504 is adapted to the inner wall of the sleeve structure, so that the drying air has an inclined angle to the inlet end of the storage battery when blown out by the air swinging cylinder 504, and the dried steam is discharged from the outlet end of the storage battery along with the air, thereby preventing the steam from gathering at the outlet end of the storage battery and wetting the dried storage battery.

As a preferred embodiment of the present invention, as shown in fig. 1 to 3, the air supply system includes an air supply main pipe 506, a communicating pipe 508, a first annular air distribution pipe 511, and a second annular air distribution pipe 512. Wherein, the air supply main pipe 506 is provided with a master control valve 507, the first annular air distribution pipe 511 and the second annular air distribution pipe 512 are respectively sleeved outside the air blowing sleeve 500, the first annular air distribution pipe 511 and the second annular air distribution pipe 512 are respectively close to the outlet end and the inlet end of the storage battery, the first annular air distribution pipe 511 and the second annular air distribution pipe 512 are respectively communicated with the air cavity 501, the air supply main pipe 506 is communicated with the first annular air distribution pipe 511 and the second annular air distribution pipe 512 through a communicating pipe 508, and the communicating pipe 508 is respectively provided with a first control valve 509 and a second control valve 510 for controlling the air volume entering the first annular air distribution pipe 511 and the second annular air distribution pipe 512. Air with pressure enters the first annular air distribution pipe 511 and the second annular air distribution pipe 512 through the air supply main pipe 506 through the communicating pipe 508 respectively, the two air flows enter the air cavity 501 to interact with each other and are blown into a space surrounded by the air blowing sleeve 500 through the air outlet 502 and the air swinging port 515, the two air flows interfere with each other in the middle of the air blowing sleeve 500, so that the air at the position densely covered by the spiral electric heating wire 503 is heated more fully, the time of the part of the air staying in the space surrounded by the air cavity 501 and the air blowing sleeve 500 is prolonged, the storage battery shell is dried fully and effectively, the other air flow is interfered, and the principle of the air flow is the same as that of the air flow heated at higher temperature, and water drops and the like on the surface of the storage battery are effectively blown away. In order to heat the wind for drying sufficiently and take away the moisture effectively, the first annular air distribution pipe 511 is provided with a pre-heating wire 513.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described in the foregoing embodiments, or equivalents may be substituted for elements thereof. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the scope of the protection of the claims of the present invention.

Claims (10)

1. The utility model provides a battery case drying device which characterized in that: the air blowing sleeve is characterized by comprising a conveying belt, wherein the axial end of the conveying belt extends out of the air blowing sleeve at the other end, the inner wall of the air blowing sleeve is rotatably connected with an air swinging cylinder coincident with the axis of the air blowing sleeve, the air blowing sleeve is provided with a hollow air cavity, a spiral electric heating wire is assembled in the air cavity, the pitch of the spiral electric heating wire is gradually reduced along the conveying direction of a storage battery, strip-shaped air outlets are uniformly formed in the inner wall of the air blowing sleeve along the circumferential direction of the air blowing sleeve, each air outlet is extended to the other end from the axial end of the air blowing sleeve, an air swinging opening is uniformly formed in the air swinging cylinder along the circumferential direction of the air swinging cylinder.

2. The battery case drying device according to claim 1, characterized in that: an outer gear ring is welded at one axial end of the air swinging cylinder, a driving motor is installed on the air blowing sleeve, and a gear meshed with the outer gear ring is installed on an output shaft of the driving motor.

3. The battery case drying device according to claim 1, characterized in that: each air swinging opening is an oblique cut along the radial section of the air swinging cylinder.

4. The battery case drying device according to claim 1, characterized in that: each air swinging opening extends from one end to the other end of the air swinging cylinder along the axial direction of the air swinging cylinder.

5. The battery case drying device according to claim 1, characterized in that: the air swinging holes are strip-shaped holes, and the air swinging holes are uniformly distributed on the air swinging cylinder.

6. The battery case drying device according to claim 1, characterized in that: the air blowing sleeve is of a sleeve structure with the radius of the inlet end of the storage battery larger than the radius of the outlet end of the storage battery, and the air swinging cylinder is adapted to the inner wall of the sleeve structure.

7. The battery case drying device according to claim 1, characterized in that: the air supply system comprises an air supply main pipe provided with a main control valve, and the air supply main pipe is communicated with an air cavity of the air blowing sleeve.

8. The battery case drying apparatus according to claim 7, wherein: the air supply system further comprises a first annular air distribution pipe and a second annular air distribution pipe which are sleeved outside the air blowing sleeve and are close to the outlet end and the inlet end of the storage battery respectively, the first annular air distribution pipe and the second annular air distribution pipe are communicated with the air cavity respectively, the air supply main pipe is communicated with the first annular air distribution pipe and the second annular air distribution pipe through a communication pipe, and a first control valve and a second control valve which are used for controlling the air quantity entering the first annular air distribution pipe and the second annular air distribution pipe are installed on the communication pipe respectively.

9. The battery case drying device according to claim 8, wherein: and a pre-heating wire is arranged in the first annular air distribution pipe.

10. The battery case drying device according to claim 1, characterized in that: and a plurality of supporting tables are arranged at the lower part of the air blowing sleeve, and the plurality of supporting tables support the air blowing sleeve at intervals along the axial direction of the air blowing sleeve.

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