CN114802896B - Automatic film coating system for lead-acid storage battery box - Google Patents

Abstract

The invention discloses an automatic film coating system for a lead-acid storage battery box, which comprises a supporting component, a conveying component, an electric control component, a first film coating component, a second film coating component and a third film coating component. The transportation assembly comprises a chain, connecting plates and clamp plates, wherein the chain is provided with mounting holes, the two connecting plates are fixed with the chain, the clamp plates are fixed on the connecting plates, the distance between the two connecting plates is adjustable, and the distance between the clamp plates is also adjustable. The first film coating assembly is positioned at the left side and the right side of the transportation assembly, the second film coating assembly and the third film coating assembly are respectively positioned at the upper side and the lower side of the transportation assembly, and the first film coating assembly, the second film coating assembly and the third film coating assembly are respectively provided with a film coating mechanism. The automatic film pasting device has the function of secondary film pasting on the peripheral end faces of the lead-acid storage battery box, simplifies the structure under the condition of meeting the working efficiency, and has wide application range, and can be used for pasting films on the peripheral sides of the battery boxes with different specifications.

Description

Automatic film coating system for lead-acid storage battery box

Technical Field

The invention relates to a storage battery production technology, in particular to an automatic film coating system for a lead-acid storage battery box.

Background

After the lead-acid storage battery box is processed and molded, the surface of the lead-acid storage battery box is required to be coated with a film so as to prevent the lead-acid storage battery box from being scratched in the subsequent transportation and assembly processes. An automatic film coating device for a lead-acid storage battery box is disclosed in patent number CN202022785117.9, and the function of the film coating device and film coating details thereof are disclosed in the patent. The patent number CN201510310104.7 discloses an automatic film coating method for a lead-acid storage battery box, which improves and optimizes the complex structure of film coating equipment in the document, and mainly comprises the steps that a pair of film guide rollers which are arranged up and down are arranged at the front end of a lead-acid storage battery box conveying line, wherein the upper film guide roller is positioned above the conveying plane of the lead-acid storage battery box conveying line, the lower film guide roller is level with the conveying plane of the lead-acid storage battery box conveying line, and a gap between the upper film guide roller and the lower film guide roller is used for the lead-acid storage battery box to pass through so as to coat the lead-acid storage battery box.

The existing lead-acid storage battery box coating process does not meet the requirements of modern production. Therefore, the automatic equipment which has a simple structure and a wide application range and can be used for pasting films on the periphery of the battery boxes with different specifications becomes a research hot spot.

Disclosure of Invention

In order to solve the defects in the prior art, the invention provides an automatic film coating system for a lead-acid storage battery box, which adopts a modularized design, optimizes the structure of equipment and can be used for pasting films on the periphery of the battery boxes with different specifications.

The technical scheme of the invention is realized as follows:

an automatic film coating system of a lead-acid storage battery box comprises a supporting component, a transporting component, an electric control component, a first film coating component, a second film coating component and a third film coating component,

It is characterized in that the method comprises the steps of,

The transportation assembly is positioned in the middle of the supporting assembly, the electric control assembly is arranged on the supporting assembly, the transportation assembly comprises a gear shaft, a chain, connecting plates and clamp plates, the chain is provided with mounting holes, the two connecting plates are fixed with the chain, the clamp plates are fixed on the connecting plates, wherein the distance between the two connecting plates is adjustable, the distance between the clamp plates is also adjustable,

The first film coating component is positioned at the left side and the right side of the transportation component, the second film coating component and the third film coating component are respectively positioned at the upper side and the lower side of the transportation component, wherein, the first film coating component, the second film coating component and the third film coating component are respectively provided with a film coating mechanism which comprises a mounting plate, the mounting plate is provided with a guide roller and a roller rod, the film is sequentially connected with the guide roller through the roller rod,

The second coating assembly also comprises a guide frame, a first sliding frame and an adjusting screw rod, wherein the guide frame is fixedly connected to the supporting assembly, the first sliding frame is provided with the coating mechanism, the first sliding frame slides along the direction of the guide frame under the action of the adjusting screw rod,

The third film coating assembly further comprises a second sliding frame, a second sliding plate and a second sliding rod, wherein the second sliding frame is fixed with the guide frame, the second sliding plate is connected in the second sliding frame through the second sliding rod in a sliding mode, and the distance between the second sliding plate and the second sliding frame is adjustable.

In the automatic film coating system of the lead-acid storage battery box, the guide rollers mainly comprise a first guide roller, a second guide roller, a third guide roller, a fourth guide roller and a fifth guide roller, wherein three first guide rollers are arranged at the left front side of the mounting plate in an arc manner, the second guide roller and the third guide roller are positioned at the right lower side of the first guide roller, and the fourth guide roller and the fifth guide roller are horizontally distributed at the right side of the third guide roller.

In the automatic film coating system for the lead-acid storage battery box, the fifth guide roller is further provided with a positioning frame, the positioning frame is connected with the mounting frame, and a gap exists between the positioning frame and the fifth guide roller.

In the automatic film coating system of the lead-acid storage battery box, the film coating mechanism is further provided with a cutter, and the cutter is positioned between the second guide roller and the third guide roller and is connected to the mounting plate in a sliding manner.

In the automatic film coating system of the lead-acid storage battery box, the film coating mechanism further comprises a power motor, a belt pulley and a belt, wherein the power motor is positioned at the bottom of the mounting plate, an output shaft of the motor is connected with the fourth guide roller, the belt pulleys are respectively fixed on the fourth guide roller and the fifth guide roller, and the two belt pulleys are connected through the belt.

In the automatic film coating system of the lead-acid storage battery box, grooves are formed in the roller, and the grooves are distributed on the roller in an annular mode.

In the automatic film coating system of the lead-acid storage battery box, the film coating mechanism further comprises a disc and a metal sheet, wherein the disc is fixedly connected with a roller rod, and the metal sheet is fixedly connected at a groove of the roller rod.

In the automatic film coating system of the lead-acid storage battery box, the metal sheet is provided with the chute, and the installation angle of the metal sheet can be adjusted under the action of the chute.

In the automatic film coating system of the lead-acid storage battery box, the second film coating assembly further comprises a first sliding plate and a first sliding rod, wherein the first sliding plate is connected in the first sliding frame in a sliding mode, and the first sliding rod penetrates through the first sliding plate to be connected with the film coating mechanism.

The automatic film coating system for the lead-acid storage battery box has the following beneficial effects: the position between the two clamp plates on the conveying assembly in the automatic film coating system of the lead-acid storage battery box is adjustable, and the automatic film coating system of the lead-acid storage battery box has film coating assemblies on the left side and the right side, is attached to the two sides of the lead-acid storage battery box, and further has the function of secondarily film-attaching the upper end face and the lower end face of the lead-acid storage battery box. Under the condition of meeting the working efficiency, the structure is simplified, and the automatic equipment which has wide application range and can be used for pasting films on the periphery of the battery boxes with different specifications is provided.

Drawings

FIG. 1 is a schematic diagram of an automated film coating system for a lead-acid battery case of the present invention;

FIG. 2 is a schematic view of a portion of the automated film coating system for a lead acid battery case of the present invention;

FIG. 3 is a schematic diagram of the separation of the transport assembly in the automatic lead acid battery case coating system of the present invention;

FIG. 4 is a schematic diagram of the structure of the capsule mechanism in the automatic capsule system of the lead-acid battery case of the invention;

FIG. 5 is a schematic view of a portion of the automated film wrapping system for a lead acid battery case of the present invention;

FIG. 6 is a schematic view of a portion of the structure of FIG. 5, mainly showing the second and third membrane modules;

FIG. 7 is a schematic view of another angle configuration of FIG. 6;

fig. 8 is a top view of the capsule mechanism in the automatic capsule system of the lead-acid battery case of the present invention.

The reference numerals in the drawings are as follows: 1-support assembly, 11-support frame, 12-fixed plate, 13-pulley, 14-aluminum alloy door, 2-transport assembly, 21-drive motor, 22-support bar, 23-gear shaft, 24-chain, 25-stopper plate, 26-base plate, 27-connecting plate, 28-clamp plate, 3-first coating assembly, 30-coating mechanism, 31-mounting plate, 32-first guide roller, 33-first buckle plate, 34-second guide roller, 35-third guide roller, 36-second buckle plate, 37-power motor, 38-third buckle plate, 39-fourth guide roller, 310-fifth guide roller, 311-pulley, 312-belt, 313-disc, 314-roller bar, 315-sheet metal, 316-cutter, 4-electronic control assembly, 5-second coating assembly, 51-guide frame, 52-first slide frame, 53-adjusting screw, 54-first slide plate, 55-first slide bar, 6-first coating assembly, 61-second slide frame, 62-second slide plate, 63-second slide bar.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

As shown in fig. 1 to 7, the automatic film coating system of the lead-acid storage battery box comprises a supporting component 1, a conveying component 2, a first film coating component 3, an electric control component 4, a second film coating component 5 and a third film coating component 6. The support assembly 1 comprises a support frame 11, a fixed plate 12, pulleys 13 and an aluminum alloy door 14. The supporting frame 11 is fixedly connected with a fixing plate 12 through bolts, two pulleys 13 are arranged at the bottom of the supporting frame 11, an aluminum alloy door 14 is arranged on the side edge of the supporting frame 11, and the two supporting frames 11 are connected through the conveying assembly 2. As shown in fig. 3, the transport assembly 2 includes a driving motor 21, a supporting rod 22, a gear shaft 23, a chain 24, a limiting plate 25, a bottom plate 26, a connecting plate 27, and a clamp plate 28. The driving motor 21 is fixedly arranged on the supporting frame 11 at one side, the two supporting rods 22 are respectively and fixedly connected with the two supporting frames 11, the gear shafts 23 are connected to the supporting rods 22 through bearings, and a chain 24 is sleeved between the two gear shafts 23, wherein an output shaft of the driving motor 21 is connected with one of the gear shafts 23. The limiting plate 25 is installed on the inner side of the chain 24, and plays a certain limiting role on the chain 24, so that the chain 24 is prevented from transmitting deviation. The three bottom plates 26 are fixedly connected between the two limiting plates 25, and a distance of 1.5 lead-acid storage battery boxes exists between every two bottom plates 26. The chain 24 has mounting holes on both sides through which two connection plates 27 can be fixed to the chain 24. Wherein the distance between the two connecting plates 27 can be adjusted according to the lead-acid storage battery box needing to be coated. The fixture plate 28 is fixed on the connecting plate 27 through screws, and the distance between two sides of the fixture plate 28 can be adjusted according to the lead-acid storage battery box coated as required, so that the lead-acid storage battery box suitable for different specifications is achieved, and the application range is enlarged.

As shown in fig. 2 to 4, the first envelope assembly 3 is mounted on top of the support frame 11, and the first envelope assembly 3 is located at both sides of the transport assembly 2. As shown in fig. 4, the first capsule assembly 3 includes a capsule mechanism 30. The coating mechanism 30 mainly comprises a mounting plate 31, a first guide roller 32, a first buckle plate 33, a second guide roller 34, a third guide roller 35, a second buckle plate 36, a power motor 37, a third buckle plate 38, a fourth guide roller 39, a fifth guide roller 310, a belt pulley 311, a belt 312, a disc 313, a roller rod 314, a metal sheet 315 and a cutter 316. The mounting plate 31 is fixed on the support frame 11, and three first guide rollers 32 are rotatably connected to the mounting plate 31, and the first buckle plate 33 is used for fixedly connecting the three first guide rollers 32. The second guide roller 34 and the third guide roller 35 are both rotatably connected to the mounting plate 31, and the second buckle plate 36 fixes the second guide roller 34 and the third guide roller 35. The power motor 37 is fixedly arranged at the bottom of the mounting plate 31, an output shaft of the power motor 37 penetrates through the mounting plate 31 to be connected with the fourth guide roller 39, the third buckle plate 38 is used for fixing the fourth guide roller 39, and the fifth guide roller 310 is rotatably connected to the mounting plate 31. The disc 313 is fixedly connected with the roller 314, and the disc 313 is rotatably connected to the mounting plate 31.

As shown in fig. 8, the film is mounted on a roll bar 314 and is drawn out from a fifth guide roll 310 via a first guide roll 32, a second guide roll 34, a third guide roll 35, and a fourth guide roll 39. And the roller 314 is further provided with grooves which are annularly distributed on the roller 314, and the metal sheet 315 is fixed at the grooves on the roller 314 by screws. The metal sheet 315 also has a chute that is adjustable in angle to fit rolls 314 of film of different calibers.

In which a pulley 311 is installed at the bottom of the fourth guide roller 39 and the fifth guide roller 310, and the two pulleys 311 are connected by a belt 312. The cutter 316 is located between the second guide roller 34 and the third guide roller 35 and is slidably coupled to the mounting plate 31. As shown in fig. 2, an electric control assembly 4 is further connected to the support frame 11, and the electric control assembly 4 mainly controls the working states of the driving motor 21 and the power motor 37.

When film sticking is required, the lead-acid battery box is fixedly arranged on the connecting plate 27, and is fixed by using two clamp plates 28. The electric control assembly 4 controls the driving motor 21 to work, and the lead-acid storage battery box needing film pasting is transported to the first film coating assembly 3. The lead acid battery case will first come into contact with the film wound on the fifth guide roller 310 on both sides, and the transport assembly 2 continues to move the lead acid battery case in a direction approaching the drive motor 21. The power motor 37 is started to slowly rotate so as to drive the fourth guide roller 39 and the fifth guide roller 310 to slowly rotate. The film on the film roll is slowly pulled out and covered on the surface of the lead-acid storage battery box. When the lead-acid storage battery box moves to the position of the cutter 316, the films on the two sides are cut off under the action of the cutter 316, so that the peripheral film pasting work of the lead-acid storage battery box is completed.

The existing coating device can only coat two lead-acid storage battery boxes, and can not coat all the periphery of the lead-acid storage battery boxes. The lead-acid storage battery box needs to be prevented from being scratched in the subsequent transportation and assembly processes, and other surfaces of the lead-acid storage battery box are very necessary to be subjected to film pasting.

As shown in fig. 5 to 7, the second and third film coating assemblies 5 and 6 are both located at the gap between the two bottom plates 26. The second film wrapping assembly 5 includes a guide frame 51, a first slide frame 52, an adjusting screw 53, a first slide plate 54, and a first slide rod 55. The guide frame 51 penetrates the support rod 22 to be connected with the fixed plate 12, the first sliding frame 52 is slidably connected to the guide frame 51, and the adjusting screw 53 is rotatably connected with the first sliding frame 52. Wherein, adjusting screw 53 and the up end screw thread fit of leading truck 51, when rotating adjusting screw 53, first slip frame 52 can slide along the direction of leading truck 51. The first sliding plate 54 is slidably connected to the first sliding frame 52 via two limiting rods, and the first sliding rod 55 is slidably connected to the first sliding plate 54. The first sliding rod 55 is also connected with a coating mechanism 30, which is identical to the above-mentioned coating mechanism in structure, and will not be repeated here.

A third film wrapping assembly 6 is fixedly connected below the guide frame 51, and the third film wrapping assembly 6 comprises a second sliding frame 61, a second sliding plate 62 and a second sliding rod 63. The second sliding frame 61 is fixedly connected with the guide frame 51, the second sliding plate 62 is slidably connected in the second sliding frame 61 through two limiting rods, the second sliding rod 63 is slidably connected on the second sliding plate 62, and the second sliding rod 63 is connected with the coating mechanism 30.

Wherein the film coating mechanism 30 in the third film coating assembly 6 is always positioned at the bottom of the bottom plate 26 in the transport assembly 2, and the second film coating assembly 5 is positioned at the top of the lead-acid battery case. The position of the second film wrapping assembly 5 can be changed by adjusting the screw 53 when lead acid battery cartridges of different heights are encountered.

As shown in fig. 5, when the lead-acid storage battery box moves towards the direction approaching to the first film coating assembly 3, the upper and lower end surfaces of the right side of the lead-acid storage battery box are coated under the action of the second film coating assembly 5 and the third film coating assembly 6 (the working principle is the same as that of the film coating assembly); and after the continuous movement, coating the upper end face and the lower end face of the left side of the lead-acid storage battery box. And (3) performing secondary film pasting on the upper end surface and the lower end surface of the lead-acid storage battery box. Under the condition of meeting the working efficiency, the structure is simplified, and the automatic equipment which has wide application range and can be used for pasting films on the periphery of the battery boxes with different specifications is provided.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

Claims (6)

1. An automatic film coating system of a lead-acid storage battery box comprises a supporting component, a transporting component, an electric control component, a first film coating component, a second film coating component and a third film coating component,

It is characterized in that the method comprises the steps of,

The transportation assembly is positioned in the middle of the supporting assembly, the electric control assembly is arranged on the supporting assembly, the transportation assembly comprises a gear shaft, a chain, a connecting plate and a clamp plate, the chain is provided with a mounting hole, the connecting plate is fixed with the chain, the clamp plate is fixed on the connecting plate, wherein the distance between the connecting plates is adjustable, the distance between the clamp plates is also adjustable,

The first film coating component is positioned at the left side and the right side of the transportation component, the second film coating component and the third film coating component are respectively positioned at the upper side and the lower side of the transportation component, wherein, the first film coating component, the second film coating component and the third film coating component are respectively provided with a film coating mechanism which comprises a mounting plate, the mounting plate is provided with a guide roller and a roller rod, the film is sequentially connected with the guide roller through the roller rod,

The second coating assembly also comprises a guide frame, a first sliding frame and an adjusting screw rod, wherein the guide frame is fixedly connected to the supporting assembly, the first sliding frame is provided with the coating mechanism, the first sliding frame slides along the direction of the guide frame under the action of the adjusting screw rod,

The third film coating component also comprises a second sliding frame, a second sliding plate and a second sliding rod, wherein the second sliding frame is fixed with the guide frame, the second sliding plate is connected in the second sliding frame through the second sliding rod in a sliding way, the distance between the second sliding plate and the second sliding frame is adjustable,

The guide roller mainly comprises a first guide roller, a second guide roller, a third guide roller, a fourth guide roller and a fifth guide roller, the coating mechanism is also provided with a cutter which is positioned between the second guide roller and the third guide roller and is connected on the mounting plate in a sliding way,

The coating mechanism also comprises a power motor, belt pulleys and a belt, wherein the power motor is positioned at the bottom of the mounting plate, an output shaft of the motor is connected with the fourth guide roller, the belt pulleys are respectively fixed on the fourth guide roller and the fifth guide roller, the two belt pulleys are connected through the belt,

When the lead-acid storage battery box moves towards the direction close to the first coating assembly, the upper end face and the lower end face on the right side of the lead-acid storage battery box are coated under the action of the second coating assembly and the third coating assembly; and after the movement is continued, coating the upper and lower end surfaces of the left side of the lead-acid storage battery box, and secondarily coating the upper and lower end surfaces of the lead-acid storage battery box.

2. The automatic film coating system of a lead-acid storage battery box according to claim 1, wherein three first guide rollers are arranged on the left front side of the mounting plate in an arc shape, a second guide roller and a third guide roller are positioned on the right lower side of the first guide roller, and a fourth guide roller and a fifth guide roller are horizontally distributed on the right side of the third guide roller.

3. The automatic lead-acid battery case coating system of claim 1, wherein the roller bar further has grooves thereon, the grooves being annularly distributed on the roller bar.

4. The automatic film coating system of a lead-acid battery box according to claim 1, wherein the film coating mechanism further comprises a disc and a metal sheet, the disc is fixedly connected with a roller rod, and the metal sheet is fixedly connected at a groove of the roller rod.

5. The automatic film coating system of lead-acid battery case according to claim 4, wherein the metal sheet is provided with a chute, and the installation angle of the metal sheet is adjustable under the action of the chute.

6. The automatic film coating system of a lead-acid battery box according to claim 1, wherein the second film coating assembly further comprises a first sliding plate and a first sliding rod, the first sliding plate is slidably connected in the first sliding frame, and the first sliding rod penetrates through the first sliding plate and is connected with the film coating mechanism.