CN216150171U

CN216150171U - Full-automatic graphite spraying device

Info

Publication number: CN216150171U
Application number: CN202122118528.7U
Authority: CN
Inventors: 焦志斌
Original assignee: Dongguan Weisman New Energy Technology Co ltd
Current assignee: Dongguan Weisman New Energy Technology Co ltd
Priority date: 2021-09-03
Filing date: 2021-09-03
Publication date: 2022-04-01
Anticipated expiration: 2031-09-03

Abstract

The utility model relates to a full-automatic graphite spraying device, which is sequentially provided with a hopper, a material lifting mechanism, a guide chute, a spraying mechanism, a conveying mechanism, a drying furnace, a cooling furnace and a discharge chute along the conveying direction of a material; the hopper is used for containing materials, and a discharge hole is formed in one side of the lower part of the hopper; the material lifting mechanism is used for lifting materials, the lower part of the material lifting mechanism corresponds to the discharge hole, and the upper part of the material lifting mechanism corresponds to the guide chute; the guide chute is used for receiving and conveying the materials lifted by the material lifting mechanism; the utility model has the advantages that: the problems of low production efficiency and poor quality of the vibration disc type arrangement in the prior art are effectively solved, the assembly line operation is realized, and the working efficiency is greatly improved.

Description

Full-automatic graphite spraying device

Technical Field

The utility model relates to a full-automatic graphite spraying device, and relates to the field of alkaline battery steel shell processing equipment.

Background

With the rapid development of science and technology, the productivity is greatly improved, and a plurality of devices realize automatic production. At present, the graphite spraying processing of the inner wall of the steel shell in the market generally adopts the traditional vibration disc array sequencing and spraying. Because the feeding device occupies a larger space and the array speed is very slow, the speed is greatly limited, and the production efficiency is difficult to improve on the premise of not changing the arrangement mode; the possibility of improving efficiency is limited due to the problems of arrangement mode and steering mode, and deformation is easy to generate due to the complex mechanical mechanism, so that the production efficiency and the product quality are low, the large mechanical mechanism occupies large area, the structure is complex, and the speed cannot be improved.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects of the prior art, the utility model provides a full-automatic graphite spraying device, and the technical scheme of the utility model is as follows:

a full-automatic graphite spraying device is sequentially provided with a hopper, a material lifting mechanism, a guide chute, a spraying mechanism, a conveying mechanism, a drying furnace, a cooling furnace and a discharge chute along the conveying direction of materials; the hopper is used for containing materials, and a discharge hole is formed in one side of the lower part of the hopper; the material lifting mechanism is used for lifting materials, the lower part of the material lifting mechanism corresponds to the discharge hole, and the upper part of the material lifting mechanism corresponds to the guide chute; the guide chute is used for receiving and conveying the materials lifted by the material lifting mechanism; the spraying mechanism is used for spraying materials and is arranged at a discharge port of the guide chute; the conveying mechanism is arranged at a discharge port of the spraying mechanism and is used for conveying the sprayed materials to the drying furnace; the drying furnace is used for drying materials; the cooling furnace is arranged at a discharge port of the drying furnace and is used for cooling materials; the discharge chute is arranged at a discharge port of the cooling furnace and used for outputting materials; the material lifting mechanism, the spraying mechanism, the conveying mechanism, the drying furnace and the cooling furnace are all connected into a main control box; the material lifting mechanism comprises at least two lifting units, each lifting unit comprises a lifting frame and a magnetic conveying belt arranged on the lifting frame, the lifting frames are arranged in a 7-shaped manner, and the magnetic conveying belts are driven by a lifting motor to rotate back and forth along the lifting frames; the lower part of the magnetic conveyor belt corresponds to the discharge hole of the hopper, and the upper part of the magnetic conveyor belt forms a blanking area which is close to the guide chute.

And a material returning mechanism is also arranged between the guide chute and the hopper and is used for recovering redundant materials.

An arc blanking frame for guiding and outputting the materials is further arranged between the discharge port of the guide chute and the spraying mechanism.

The guide chute is obliquely arranged and fixedly arranged on the guide chute bracket; and a roller is rotatably arranged in the guide chute along the length direction of the guide chute, is driven by a roller motor, and forms a material stirring space with the guide chute.

The conveying mechanism comprises a horizontal conveying belt and an inclined conveying belt which is arranged adjacent to the horizontal conveying belt, one side of the horizontal conveying belt corresponds to a discharge port of the spraying mechanism, and the other side of the horizontal conveying belt corresponds to the inclined conveying belt; the lower end of the inclined conveying belt is close to the blanking end of the horizontal conveying belt, and the high end of the inclined conveying belt extends to the feeding hole of the drying furnace.

The feed-back mechanism comprises a feed-back groove and a feed-back conveying belt, the feed port of the feed-back groove is communicated with the guide groove, and the discharge port of the feed-back groove corresponds to the feed-back conveying belt; the blanking end of the feed back conveying belt extends to the upper part of the hopper, and the feed back conveying belt is used for receiving materials falling from the feed back groove and conveying the materials to the hopper.

The utility model has the advantages that: because at least two sets of lifting units are additionally arranged, compared with the existing spraying device, the spraying efficiency is improved by at least one time, the technical effect of double spraying is realized, the problems of low production efficiency and poor quality of the vibration disc type arrangement in the prior art are effectively solved, the assembly line operation is realized, and the working efficiency is greatly improved.

Drawings

Fig. 1 is a schematic view of the main structure of the present invention.

Fig. 2 is a front view of fig. 1.

Detailed Description

The utility model will be further described with reference to specific embodiments, and the advantages and features of the utility model will become apparent as the description proceeds. These examples are illustrative only and do not limit the scope of the present invention in any way. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the utility model, and that such changes and modifications may be made without departing from the spirit and scope of the utility model.

Referring to fig. 1 and 2, the utility model relates to a full-automatic graphite spraying device, which is sequentially provided with a hopper 1, a material lifting mechanism 2, a material guide chute 3, a spraying mechanism 8, a conveying mechanism, a drying furnace 12, a cooling furnace 13 and a discharge chute 14 along the conveying direction of a material; the hopper 1 is used for containing materials, and a discharge hole is formed in one side of the lower part of the hopper 1; the material lifting mechanism 2 is used for lifting materials, the lower part of the material lifting mechanism 2 corresponds to the discharge hole, and the upper part of the material lifting mechanism 2 corresponds to the guide chute 3; the material guide groove 3 is used for receiving and conveying materials lifted by the material lifting mechanism; the spraying mechanism 8 (in the prior art) is used for spraying materials, and the spraying mechanism 8 is arranged at the discharge port of the guide chute 3; the conveying mechanism 11 is arranged at a discharge port of the spraying mechanism and used for conveying the sprayed materials to the drying furnace 12; the drying oven 12 is used for drying materials; the cooling furnace 13 is arranged at a discharge port of the drying furnace and is used for cooling materials; the discharge chute 14 is arranged at a discharge port of the cooling furnace 13 and used for outputting materials; the material lifting mechanism 2, the spraying mechanism 8, the conveying mechanism 11, the drying furnace 12 and the cooling furnace 13 are all connected into a main control box 10.

A material returning mechanism 5 is also arranged between the guide chute 3 and the hopper 1, and the material returning mechanism 5 is used for recovering redundant materials.

An arc blanking frame 7 for guiding and outputting the materials is further arranged between the discharge port of the guide chute 3 and the spraying mechanism 8 for arc guiding.

The material lifting mechanism 2 comprises at least two lifting units, each lifting unit comprises a lifting frame 16 and a magnetic conveyor belt 15 arranged on the lifting frame 16, the lifting frames 16 are arranged in a 7-shaped manner, and the magnetic conveyor belts 15 are driven by a lifting motor to rotate in a reciprocating manner along the lifting frames 16; the lower part of the magnetic conveyor belt 15 corresponds to the discharge hole of the hopper 1, and the upper part of the magnetic conveyor belt 15 forms a blanking area which is close to the material guide groove 3.

The guide chute 3 is obliquely arranged and fixedly arranged on the guide chute bracket 9; in the material guide chute 3, a roller 4 is rotatably installed along the length direction of the material guide chute 3, the roller is driven by a roller motor, and a material stirring space is formed between the roller and the material guide chute 3 and used for guiding and outputting materials.

The conveying mechanism comprises a horizontal conveying belt 17 and an inclined conveying belt 11 which is arranged adjacent to the horizontal conveying belt 17, one side of the horizontal conveying belt 17 corresponds to a discharge port of the spraying mechanism 8, and the other side of the horizontal conveying belt 17 corresponds to the inclined conveying belt 11; the lower end of the inclined conveyer belt 11 is close to the blanking end of the horizontal conveyer belt 17, and the upper end of the inclined conveyer belt 11 extends to the feeding hole of the drying oven 12.

The feed back mechanism comprises a feed back groove 18 and a feed back conveying belt 5, a feed inlet of the feed back groove 18 is communicated with the guide chute 3, and a discharge outlet of the feed back groove 18 corresponds to the feed back conveying belt 5; the blanking end of the feed back conveying belt 5 extends to the upper part of the hopper 1, and the feed back conveying belt 5 is used for receiving materials falling from a feed back groove and conveying the materials to the hopper 1.

The working principle of the utility model is as follows:

the box hat is discharged in the discharge gate department of hopper, promote through two sets of hoisting units, the magnetism conveyer belt of each hoisting unit drives the box hat and accomplishes the promotion back, get into the baffle box, then accomplish the range under the rotatory effect of roller bearing through in the baffle box, get into arc blanking frame, then rely on the action of gravity to get into spraying mechanism department, carry out the inkjet, the completion spouts the graphite breast in the box hat, the box hat after the completion spraying loops through horizontal transport belt and slope conveyer belt and conveys and dry in the drying furnace, cool off through the cooling furnace again, unnecessary material gets back to on the feed back conveying belt through the feed back groove, get into the hopper and queue again, accomplish the spraying.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and equivalent alternatives or modifications according to the technical solution of the present invention and the inventive concept thereof should be covered by the scope of the present invention.

Claims

1. A full-automatic graphite spraying device is characterized in that a hopper, a material lifting mechanism, a guide chute, a spraying mechanism, a conveying mechanism, a drying furnace, a cooling furnace and a discharge chute are sequentially arranged along the conveying direction of a material; the hopper is used for containing materials, and a discharge hole is formed in one side of the lower part of the hopper; the material lifting mechanism is used for lifting materials, the lower part of the material lifting mechanism corresponds to the discharge hole, and the upper part of the material lifting mechanism corresponds to the guide chute; the guide chute is used for receiving and conveying the materials lifted by the material lifting mechanism; the spraying mechanism is used for spraying materials and is arranged at a discharge port of the guide chute; the conveying mechanism is arranged at a discharge port of the spraying mechanism and is used for conveying the sprayed materials to the drying furnace; the drying furnace is used for drying materials; the cooling furnace is arranged at a discharge port of the drying furnace and is used for cooling materials; the discharge chute is arranged at a discharge port of the cooling furnace and used for outputting materials; the material lifting mechanism, the spraying mechanism, the conveying mechanism, the drying furnace and the cooling furnace are all connected into a main control box;

the material lifting mechanism comprises at least two lifting units, each lifting unit comprises a lifting frame and a magnetic conveying belt arranged on the lifting frame, the lifting frames are arranged in a 7-shaped manner, and the magnetic conveying belts are driven by a lifting motor to rotate back and forth along the lifting frames; the lower part of the magnetic conveyor belt corresponds to the discharge hole of the hopper, and the upper part of the magnetic conveyor belt forms a blanking area which is close to the guide chute.

2. The automatic graphite spraying device as claimed in claim 1, wherein a material returning mechanism is further disposed between the material guiding chute and the material hopper, and the material returning mechanism is used for recovering excess material.

3. The automatic graphite spraying device of claim 1 or 2, wherein an arc-shaped blanking frame for guiding and outputting the materials is further installed between the discharge port of the material guide chute and the spraying mechanism.

4. The automatic graphite spraying device of claim 3, wherein the material guide chute is obliquely arranged and fixedly mounted on the material guide chute support; and a roller is rotatably arranged in the guide chute along the length direction of the guide chute, is driven by a roller motor, and forms a material stirring space with the guide chute.

5. The automatic graphite spraying device of claim 1, wherein the conveying mechanism comprises a horizontal conveying belt and an inclined conveying belt arranged adjacent to the horizontal conveying belt, one side of the horizontal conveying belt corresponds to a discharge port of the spraying mechanism, and the other side of the horizontal conveying belt corresponds to the inclined conveying belt; the lower end of the inclined conveying belt is close to the blanking end of the horizontal conveying belt, and the high end of the inclined conveying belt extends to the feeding hole of the drying furnace.

6. The automatic graphite spraying device of claim 2, wherein the feed back mechanism comprises a feed back tank and a feed back conveyor belt, a feed inlet of the feed back tank is communicated with the guide chute, and a discharge outlet of the feed back tank corresponds to the feed back conveyor belt; the blanking end of the feed back conveying belt extends to the upper part of the hopper, and the feed back conveying belt is used for receiving materials falling from the feed back groove and conveying the materials to the hopper.