CN219955986U - Drying equipment for battery manufacturing - Google Patents

Abstract

The utility model provides drying equipment for battery manufacturing, and relates to the technical field of battery manufacturing. The device comprises a base, a recovered hot air box body, an oxygen generator and an optical sensor, wherein the upper surface of the base is connected with a conveyor belt, two sides of the conveyor belt are connected with a working bin, the lower end of one side of the working bin is provided with a vent, and a display control panel is connected above the vent. Through retrieving hot gas box, heat energy conversion pipeline, heat energy transfer box, the hot gas that the hot gas box will produce in the stoving process absorbs then converts into heat energy through heat energy conversion pipeline, finally recycles these heat energies through heat energy transfer box, reduce the extravagant energy, and the oxygen generator of setting can accelerate the oxidation reaction of product, promote the drying and the shaping of product, thereby improve quality and the production efficiency of product, and optical sensor can real-time detection battery surface temperature, in order to prevent that the stoving from drying too much or the condition that stoving time is short takes place.

Description

Drying equipment for battery manufacturing

Technical Field

The utility model relates to the technical field of battery manufacturing, in particular to a drying device for battery manufacturing.

Background

The battery is a device for converting chemical energy into electric energy, has strong energy storage and output capacity, and is widely applied to various fields such as mobile phones, vehicles, power grids and the like. In battery manufacturing, various battery raw materials are mixed, molded, activated, packaged and the like according to a certain proportion to manufacture a final battery product, and the battery is required to be dried in the battery manufacturing process, so that a drying device for battery manufacturing is required.

Through retrieving, the patent with publication number CN108240748A discloses a drying equipment for battery manufacturing, this drying equipment for battery manufacturing is proposed herein, "the second pivot on the second motor drives the flabellum and rotates, make the drying equipment for battery manufacturing can dispel the heat fast, the effectual drying equipment that has solved for battery manufacturing is used for drying battery and raw and other materials, and current drying equipment for battery manufacturing can't make battery and raw and other materials cool down fast after the stoving, influence the problem to battery next step processing, this drying equipment for battery manufacturing, through having set up the dust screen, prevent that the dust from getting into the inside of second motor, play the guard action to the second motor, effectually solve the dust and get into the inside of second motor and cause the problem that the second motor damaged", but the stoving battery needs a large amount of energy in the course of working, if can not in time handle and will cause the waste of energy, and because the not enough of oxidation reaction in the course of working, the stoving is slower, the efficiency is lower, and can't the battery stoving degree in the course of drying, the battery stoving condition of drying process is easy, the condition of drying too first or drying time is short.

In view of the above, intensive studies have been conducted to solve the above problems.

Disclosure of Invention

The present utility model is directed to a drying apparatus for battery manufacturing, which solves the problems set forth in the background art described above.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a drying equipment for battery manufacturing, includes base, recovery hot air box, oxygen generator and optical sensor, the base upper surface is connected with the conveyer belt, the conveyer belt both sides are connected with the work storehouse, work storehouse one side lower extreme is provided with the vent, the vent top is connected with the display control panel, work storehouse upper surface is connected with recovery hot air box, recovery hot air box one side is connected with heat energy conversion pipeline, the heat energy conversion pipeline other end is connected with heat energy transmission box, the inside upper surface of work storehouse is provided with the recovery mouth, the inside left and right sides of work storehouse is connected with the heating pipe, the heating pipe top is provided with anion generator, heating pipe one side is connected with oxygen generator, oxygen generator one side is connected with the sensor, sensor one side is connected with optical sensor.

Preferably, the upper surface of the base is rotatably connected with a conveyor belt, and two sides of the conveyor belt are welded with a working bin.

Preferably, a vent is formed in the lower end of one side of the working bin, a display control panel is adhered above the vent, and a group of vents are formed in the left side and the right side of the outer surface of the working bin respectively.

Preferably, the upper surface of the working bin is welded with a recovered hot air box body, one side of the recovered hot air box body is sleeved with a heat energy conversion pipeline, and two groups of heat energy conversion pipelines are arranged in two groups.

Preferably, the other end of the heat energy conversion pipeline is sleeved with a heat energy transmission box body, and the upper surface of the inside of the working bin is provided with a recovery port.

Preferably, the left side and the right side of the inside of the working bin are connected with heating pipes in a threaded mode, and negative ion generators are embedded above the heating pipes.

Preferably, one side of the heating pipe is adhered with an oxygen generator, one side of the oxygen generator is connected with a sensor, and six oxygen generators are combined into a group and two groups.

Preferably, an optical sensor is adhered to one side of the sensor, and the optical sensor is made of quartz.

Compared with the prior art, the utility model has the beneficial effects that:

this a battery manufacturing installation for through base, conveyer belt, working bin, vent, display control panel, retrieve hot air box, heat energy conversion pipeline, heat energy transfer box, recovery mouth, heating pipe, anion generator, oxygen generator, sensor, optical sensor's setting, through retrieving hot air box, heat energy conversion pipeline, heat energy transfer box, retrieve the hot air box and absorb then through heat energy conversion pipeline conversion heat energy with the steam that produces in the stoving process, finally through heat energy transfer box with these heat energy reuse, reduce extravagant energy.

And the oxygen generator can accelerate the oxidation reaction of the product and promote the drying and forming of the product, thereby improving the quality and production efficiency of the product, and the optical sensor can detect the surface temperature of the battery in real time so as to prevent the condition of excessive drying or short drying time.

Drawings

FIG. 1 is a schematic view of the overall appearance structure of the present utility model;

FIG. 2 is a schematic diagram of the front state structure of the present utility model;

FIG. 3 is a right side internal structure diagram of the present utility model;

fig. 4 is a schematic view of the right side plan view structure of the present utility model.

Reference numerals in the drawings: 1. a base; 2. a conveyor belt; 3. a working bin; 4. a vent; 5. displaying a control panel; 6. recovering the hot gas box body; 7. a thermal energy conversion conduit; 8. a thermal energy transfer box; 9. recovering the mouth; 10. heating pipes; 11. a negative ion generator; 12. an oxygen generator; 13. a sensor; 14. an optical sensor.

Detailed Description

The following description of the embodiments of the present utility model 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 utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-4, the present utility model provides a technical solution: the utility model provides a drying equipment for battery manufacturing, including base 1, retrieve hot air box 6, oxygen generator 12 and optical sensor 14, base 1 upper surface is connected with conveyer belt 2, the conveyer belt 2 both sides are connected with work storehouse 3, work storehouse 3 one side lower extreme is provided with vent 4, the vent 4 top is connected with the display control panel 5, work storehouse 3 upper surface is connected with retrieves hot air box 6, retrieve hot air box 6 one side and be connected with heat energy conversion pipeline 7, the heat energy conversion pipeline 7 other end is connected with heat energy transfer box 8, the inside upper surface of work storehouse 3 is provided with retrieves mouth 9, the inside left and right sides of work storehouse 3 is connected with heating pipe 10, the heating pipe 10 top is provided with anion generator 11, heating pipe 10 one side is connected with oxygen generator 12, oxygen generator 12 one side is connected with sensor 13, sensor 13 one side is connected with optical sensor 14.

Further, the upper surface swivelling joint of base 1 has conveyer belt 2, and the welding of conveyer belt 2 both sides has connected work storehouse 3, and the inside main battery stoving work that carries out of work storehouse 3 collects all functions as an organic wholely, convenient high efficiency.

Further, vent 4 has been seted up to work bin 3 one side lower extreme, and the adhesion of vent 4 top has the demonstration to control panel 5, and vent 4 has respectively seted up a set of in the left and right sides of work bin 3 surface, controls panel 5 through the demonstration and can look over the stoving temperature extreme humidity at any time to can adjust at any time.

Further, the upper surface welding of work storehouse 3 has the recovered hot gas box 6, and recovered hot gas box 6 one side has cup jointed heat energy conversion pipeline 7, and two a set of altogether of heat energy conversion pipeline 7 are provided with two sets of, absorb the steam that produces in the stoving process through recovered hot gas box 6 to prevent that the wasting of resources is more.

Further, the other end of the heat energy conversion pipeline 7 is sleeved with the heat energy transmission box body 8, the upper surface inside the working bin 3 is provided with the recovery port 9, the collected hot air can be converted into heat energy through the heat energy transmission box body 8 through the heat energy conversion pipeline 7, and then the heat energy is reused through the heat energy transmission box body 8, so that energy waste is reduced.

Further, the left side and the right side of the inside of the working bin 3 are connected with heating pipes 10 in a threaded manner, negative ion generators 11 are embedded above the heating pipes 10, and negative ions of the negative ion generators 11 can adsorb harmful gases and particles in air and purify the air in the drying chamber, so that the quality and the sanitation and safety of products are improved.

Further, one side of the heating pipe 10 is adhered with the oxygen generator 12, one side of the oxygen generator 12 is connected with the sensor 13, two groups of six oxygen generators 12 are arranged in a group, oxygen of the oxygen generator 12 can accelerate oxidation reaction of products, drying and forming of the products are promoted, and accordingly quality and production efficiency of the products are improved.

Furthermore, an optical sensor 14 is adhered to one side of the sensor 13, and the optical sensor 14 is made of quartz material, so that the optical sensor 14 can detect the surface temperature of the battery in real time, and the battery is prevented from being damaged due to overhigh temperature.

Working principle: firstly, a drying device for battery manufacturing is installed to a working position, then a battery to be dried is placed on a conveyor belt 2, then the battery enters a working bin 3 under the drive of the conveyor belt 2, then a heating pipe 10 installed in the working bin 3 starts to raise the temperature to dry the battery, meanwhile, an anion generator 11 starts to work, harmful gas and particles in air are adsorbed, air in a drying chamber is purified, so that the quality and sanitation safety of products are improved, an oxygen generator 12 starts to accelerate the oxidation reaction of the products, drying and forming of the products are promoted, the quality and the production efficiency of the products are improved, then a sensor 13 senses the temperature in the bin and then displays the temperature on a display control panel 5, the temperature of the battery is conveniently adjusted in time, an optical sensor 14 detects the surface temperature of the battery in real time, the battery is sent out along with the conveyor belt 2 after drying, meanwhile, hot air generated in the working process of the device is absorbed by a recovery hot air box 6 through a recovery port 9, the hot air is converted into heat energy through a heat energy conversion pipeline 7, and finally the heat energy is transmitted to a heat energy transmission box 8 to be stored, and the next circulation is waited for use, and the battery is manufactured, and the drying device is used.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. Drying equipment for battery manufacturing, including base (1), recovery hot gas box (6), oxygen generator (12) and optical sensor (14), its characterized in that: the utility model discloses a solar energy collection device, including base (1), workstation, heating pipe (10), anion generator (11) are provided with in workstation (3), base (1) upper surface is connected with conveyer belt (2), conveyer belt (2) both sides are connected with workstation (3), workstation (3) one side lower extreme is provided with vent (4), vent (4) top is connected with shows and controls panel (5), workstation (3) upper surface is connected with retrieves hot gas box (6), retrieve hot gas box (6) one side and be connected with heat energy conversion pipeline (7), heat energy conversion pipeline (7) other end is connected with heat energy transfer box (8), workstation (3) inside upper surface is provided with retrieves mouth (9), workstation (3) inside left and right sides is connected with heating pipe (10), heating pipe (10) top is provided with anion generator (11), heating pipe (10) one side is connected with oxygen generator (12), oxygen generator (12) one side is connected with sensor (13), sensor (13) one side is connected with optical inductor (14).

2. The drying equipment for battery manufacturing according to claim 1, wherein the upper surface of the base (1) is rotatably connected with a conveyor belt (2), and two sides of the conveyor belt (2) are welded with a working bin (3).

3. The drying equipment for battery manufacturing according to claim 1, wherein a vent (4) is formed in the lower end of one side of the working bin (3), a display control panel (5) is adhered above the vent (4), and a group of vents (4) are formed in the left side and the right side of the outer surface of the working bin (3) respectively.

4. The drying equipment for battery manufacturing according to claim 1, wherein the upper surface of the working bin (3) is welded with a recovered hot air box body (6), one side of the recovered hot air box body (6) is sleeved with a heat energy conversion pipeline (7), and two groups of heat energy conversion pipelines (7) are arranged in two groups.

5. The drying equipment for battery manufacturing according to claim 1, wherein the other end of the heat energy conversion pipeline (7) is sleeved with a heat energy transmission box body (8), and the upper surface of the inside of the working bin (3) is provided with a recovery port (9).

6. The drying equipment for battery manufacturing according to claim 1, wherein a heating pipe (10) is connected to the left side and the right side of the inside of the working bin (3) in a threaded manner, and a negative ion generator (11) is embedded above the heating pipe (10).

7. The drying equipment for battery manufacturing according to claim 1, wherein an oxygen generator (12) is adhered to one side of the heating pipe (10), a sensor (13) is connected to one side of the oxygen generator (12), and six oxygen generators (12) are arranged in a group to form two groups.

8. The drying apparatus for battery manufacturing according to claim 1, wherein an optical sensor (14) is adhered to one side of the sensor (13), and the optical sensor (14) is made of quartz.