CN110861945A - Battery diaphragm vacuum conveying mechanism - Google Patents

Abstract

The invention discloses a vacuum conveying mechanism for a battery diaphragm, and belongs to the technical field of automatic conveying mechanisms. Battery diaphragm vacuum conveying mechanism includes the vacuum board subassembly, sets up main drive subassembly and driven wheel subassembly on the vacuum board subassembly and the belt of vacuum board subassembly outside is located to the cover, wherein: the driven wheel assembly is arranged at two ends of the vacuum plate assembly, the belt is sleeved on the vacuum plate assembly and the driven wheel assembly, the belt is tightly attached to the vacuum plate assembly, and the main driving assembly drives the belt to run; a first flat vacuum suction hole is formed in the belt, and a second vacuum suction hole is formed in the vacuum plate assembly; the second vacuum air suction hole is opposite to the first vacuum air suction hole, and the battery membrane is adsorbed on the surface of the belt. According to the invention, the flat belt with the vacuum suction holes is used for replacing the operation of directly sucking the battery diaphragm by the traditional vacuum sucker, so that the product yield and the production efficiency are improved.

Description

Battery diaphragm vacuum conveying mechanism

Technical Field

The invention relates to the technical field of automatic conveying mechanisms, in particular to a vacuum conveying mechanism for a battery diaphragm.

Background

At present, batteries are increasingly used, materials for producing the batteries are continuously updated, a novel flexible battery diaphragm is used as the battery diaphragm, the main components of the diaphragm are carbon, powder and adhesive, the thickness of the diaphragm is about 300-650 mu m, the diaphragm is thin and heavy, a group of diaphragms is easy to form, wrinkles, diaphragm deformation and diaphragm damage occur in the conveying process, a lot of troubles are brought to the conveying in the production process, and the rejection rate of the produced batteries is high. A new battery membrane conveying mechanism is needed to solve the conveying problem of the novel flexible battery membrane.

Disclosure of Invention

Based on the above, the invention provides a vacuum conveying mechanism for a battery diaphragm, which is suitable for conveying in the production process of a flexible battery diaphragm and aims to solve the problems of wrinkles, diaphragm deformation, diaphragm breakage and the like in the conventional battery diaphragm conveying process. According to the invention, the flat belt with the vacuum suction holes is used for replacing the operation of directly sucking the battery diaphragm by the traditional vacuum sucker, so that the product yield and the production efficiency are improved.

In order to achieve the purpose, the invention provides the following technical scheme: a battery membrane vacuum transport mechanism comprising: vacuum board subassembly, set up main drive assembly and driven wheel subassembly on the vacuum board subassembly and the belt in the vacuum board subassembly outside is located to the cover, wherein:

the driven wheel assembly is arranged at two ends of the vacuum plate assembly, the belt is sleeved on the vacuum plate assembly and the driven wheel assembly, the belt is tightly attached to the vacuum plate assembly, and the main driving assembly drives the belt to run; a first flat vacuum suction hole is formed in the belt, and a second vacuum suction hole is formed in the vacuum plate assembly; the second vacuum air suction hole is opposite to the first vacuum air suction hole, and the battery membrane is adsorbed on the surface of the belt.

The first vacuum suction hole absorbs the battery diaphragm on the surface of the belt; compared with the traditional vacuum chuck, the flexible battery diaphragm has high flatness, and is not easy to deform and damage in the adsorption process.

The first vacuum suction hole is preferably a vacuum suction hole having a diameter of 1 mm. The first vacuum suction holes are preferably arranged in six rows on the belt.

The main driving component is a structure for driving the belt to run; comprises a driving wheel, a driving motor, a driving wheel shaft and a driving wheel supporting plate; the driving wheel is fixedly arranged on a driving wheel shaft, one end of the driving wheel shaft is connected with a driving motor, and the driving wheel shaft is arranged on a driving wheel supporting plate.

The main driving assembly further comprises a main driving assembly bottom plate, and the main driving assembly bottom plate is connected with the two driving wheel supporting plates to form a support of the main driving assembly.

The vacuum plate assembly comprises a vacuum plate, and a second vacuum suction hole, a vacuum pipe connecting port and a vacuum plate fixing hole which are arranged on the vacuum plate; the second vacuum suction hole is communicated with the side vacuum connection pipe opening, and the vacuum plate fixing hole is used for fixing the vacuum plate.

The second vacuum suction holes are preferably arranged in six rows.

The vacuum plate assembly further comprises a discharging plate hole, and automatic discharging in the vacuum conveying process of the membrane is achieved through the discharging plate hole.

In a preferred embodiment, the belt is provided with a gear engaged with the driving wheel.

The belt is attached to the vacuum plate assembly.

In a preferred embodiment, the vacuum conveying mechanism for the battery membrane further comprises a tensioning assembly, and the tensioning assembly is arranged on the main driving assembly and used for adjusting the tightness state of the belt. The tensioning assembly is preferably a tensioner wheel structure.

According to the technical scheme provided by the invention, the belt with the smooth first vacuum air suction holes is matched with the vacuum plate assembly with the second vacuum air suction holes, so that the vacuum adsorption of the flexible battery membrane is realized; the vacuum sucking disc structure has replaced traditional vacuum chuck structure, has solved the phenomenon problems such as fold, diaphragm deformation, diaphragm damage that appear among the flexible battery diaphragm transportation process to the yields of product has been improved. Meanwhile, the vacuum plate assembly, the main driving assembly, the driven wheel assembly and the belt with the vacuum suction holes are arranged in a matched mode, the automation degree is high, and the conveying production efficiency is improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

FIG. 1 is a schematic structural diagram of a preferred embodiment of the present invention.

Fig. 2 is a schematic structural view of the main drive assembly of fig. 1.

Fig. 3 is a schematic structural view of the vacuum plate assembly of fig. 1.

The implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

At present, the defects of phenomena such as folds, membrane deformation, membrane breakage and the like exist in the conventional battery membrane conveying process. In order to solve the technical problems, the invention provides a vacuum conveying mechanism for a battery diaphragm, which is suitable for conveying in the production process of a flexible battery diaphragm.

As shown in fig. 1, the present invention provides a battery membrane vacuum conveying mechanism, comprising: the belt conveyor comprises a vacuum plate assembly 50, a main driving assembly 20 and a driven wheel assembly 40 which are arranged on the vacuum plate assembly 50, and a belt 10 which is sleeved outside the vacuum plate assembly 50, wherein:

the driven wheel assemblies 40 are arranged at two ends of the vacuum plate assembly 50, the belt 10 is sleeved on the vacuum plate assembly 50 and the driven wheel assemblies 40, the belt 10 is tightly attached to the vacuum plate assembly 50, and the main driving assembly 20 drives the belt 10 to run; a first vacuum suction hole 11 is formed in the belt 10, and a second vacuum suction hole 51 is formed in the vacuum plate assembly 50; the second vacuum suction hole 51 is opposite to the first vacuum suction hole 11, and a battery membrane is adsorbed on the surface of the belt 10.

The first vacuum suction holes 11 absorb the battery membrane on the surface of the belt 10; compared with the traditional vacuum chuck, the flexible battery diaphragm has high flatness, and is not easy to deform and damage in the adsorption process.

The first vacuum suction hole 11 is preferably a first vacuum suction hole having a diameter of 1 mm. The first vacuum suction holes 11 are preferably arranged in six rows on the belt 10.

As shown in fig. 1 and fig. 2, the main driving assembly 20 is a mechanism for driving the belt 10 to operate, and includes a driving wheel 21, a driving motor 22, a driving wheel shaft 23 and a driving wheel supporting plate 24; the driving wheel 21 is fixedly arranged on a driving wheel shaft 23, one end of the driving wheel shaft 23 is connected with a driving motor 22, and the driving wheel shaft 23 is arranged on a driving wheel supporting plate 24.

The main driving assembly 20 further comprises a main driving assembly bottom plate 25, and the main driving assembly bottom plate 25 is connected with the two driving wheel supporting plates 24 to form a support of the main driving assembly 20.

As shown in fig. 1 and 3, the vacuum plate assembly 50 includes a vacuum plate 55, and a second vacuum suction hole 51, a vacuum nozzle 52 and a vacuum plate fixing hole 54 provided on the vacuum plate 55; the second vacuum suction holes 51 are communicated with the side vacuum nozzle 52, and the vacuum plate fixing holes 54 are used for fixing a vacuum plate 55.

The vacuum plate assembly 50 further comprises a discharge plate hole 53, and the discharge plate hole 53 realizes automatic discharge in the vacuum conveying process of the membrane. The discharge plate openings 53 are preferably three discharge plate openings.

In a preferred embodiment, the belt 10 is provided with a gear (not shown) engaged with the driving wheel 21.

The belt 10 is attached to the vacuum plate assembly 50.

In a preferred embodiment, the battery membrane vacuum conveying mechanism further comprises a tensioning assembly 30, and the tensioning assembly 30 is arranged on the main driving assembly 20 and is used for adjusting the tightness state of the belt. The tension assembly 30 is of a tension pulley structure.

The vacuum adsorption device has the beneficial effects that in the technical scheme provided by the invention, the belt 10 with the smooth first vacuum air suction holes 11 is matched with the vacuum plate assembly 50 with the second vacuum air suction holes 51, so that the vacuum adsorption of the flexible battery membrane is realized; the vacuum sucking disc structure has replaced traditional vacuum chuck structure, has solved the phenomenon problems such as fold, diaphragm deformation, diaphragm damage that appear among the flexible battery diaphragm transportation process to the yields of product has been improved. Meanwhile, the vacuum plate assembly 50, the main driving assembly 20, the driven wheel assembly 40 and the belt 10 with the vacuum suction holes are arranged in a matched mode, the automation degree is high, and the conveying production efficiency is improved.

In conclusion, the structure and the combination thereof complete the structure of the vacuum conveying mechanism for the battery membrane. It is to be understood that the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the invention, as claimed, and are not restrictive of the invention, since various modifications may be made by those skilled in the art without departing from the spirit and scope of the invention, it is intended that all changes, equivalents and modifications to the foregoing detailed description be embraced therein without departing from the spirit and scope of the invention.

Claims (10)

1. The utility model provides a battery diaphragm vacuum conveying mechanism which characterized in that: including the vacuum board subassembly, set up main drive subassembly and driven wheel subassembly on the vacuum board subassembly and the belt in the vacuum board subassembly outside is located to the cover, wherein:

the driven wheel assembly is arranged at two ends of the vacuum plate assembly, the belt is sleeved on the vacuum plate assembly and the driven wheel assembly, the belt is tightly attached to the vacuum plate assembly, and the main driving assembly drives the belt to run; a first flat vacuum suction hole is formed in the belt, and a second vacuum suction hole is formed in the vacuum plate assembly; the second vacuum air suction hole is opposite to the first vacuum air suction hole, and the battery membrane is adsorbed on the surface of the belt.

2. The battery membrane vacuum transport mechanism of claim 1, wherein: the first vacuum suction hole is a vacuum suction hole with the diameter of 1 mm.

3. The battery membrane vacuum transport mechanism of claim 1, wherein: the main driving assembly comprises a driving wheel, a driving motor, a driving wheel shaft and a driving wheel supporting plate; the driving wheel is fixedly arranged on a driving wheel shaft, one end of the driving wheel shaft is connected with a driving motor, and the driving wheel shaft is arranged on a driving wheel supporting plate.

4. The battery membrane vacuum transport mechanism of claim 3, wherein: the main driving assembly further comprises a main driving assembly bottom plate, and the main driving assembly bottom plate is connected with the two driving wheel supporting plates to form a support of the main driving assembly.

5. The battery membrane vacuum transport mechanism of claim 1, wherein: the vacuum plate assembly comprises a vacuum plate, and a second vacuum suction hole, a vacuum pipe connecting port and a vacuum plate fixing hole which are arranged on the vacuum plate; the second vacuum suction hole is communicated with the side vacuum connection pipe opening, and the vacuum plate fixing hole is used for fixing the vacuum plate.

6. The battery membrane vacuum transport mechanism of claim 5, wherein: the vacuum plate assembly further comprises a discharging plate hole, and automatic discharging in the vacuum conveying process of the membrane is achieved through the discharging plate hole.

7. The battery membrane vacuum transport mechanism of claim 3, wherein: and a gear matched with the driving wheel is arranged on the belt.

8. The battery membrane vacuum transport mechanism of claim 1, wherein: the belt is attached to the vacuum plate assembly.

9. The battery membrane vacuum transport mechanism of claim 1, wherein: the belt tensioning device is characterized by further comprising a tensioning assembly, wherein the tensioning assembly is arranged on the main driving assembly and used for adjusting the tightness of the belt.

10. The battery membrane vacuum transport mechanism of claim 9, wherein: the tensioning assembly is preferably a tensioner wheel structure.

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