CN213033761U - Blade adjusting mechanism and battery slitting device - Google Patents

Abstract

The utility model discloses a blade adjusting mechanism and a battery slitting device, the knife rest structure can adapt to various machine types, the number of knife positions can be increased or decreased at will, and the knife rest can be used by direct installation without changing the original machine type structure; simultaneously, each blade is independently replaced, the upper blade and the lower blade of each group are independently used for tool setting, each group of blades do not influence each other in the tool setting process, the operation process is simple, and the operation space is improved. The device is used for tool setting, the occlusion depth and the adhesion force of the upper tool and the lower tool can be visually quantized and precisely adjusted through a measuring tool, the dependence on the experience and the technology of a tool exchanging person is reduced, and the crack of the tool in the debugging process is well avoided.

Description

Blade adjusting mechanism and battery slitting device

Technical Field

The utility model belongs to the battery field of cutting especially relates to a device is cut to blade adjustment mechanism, battery.

Background

The battery pole piece cutting process plays a vital role in the new energy industry, the main factor that limits the battery pole piece cutting process at present is that efficiency is still very low when changing and debugging on the slitting blade, the leading cause that leads to above-mentioned problem is current device, because upper and lower arbor adopts synchronous machine drive rotation respectively, so go up the structure that lower knife rest the same in all adopting and figure 1 of knife rest spare, this knife rest structure is complicated, the piece that arrives on the knife rest can not take the change alone, need dismantle whole upper knife rest when changing the blade, the tight structure of cover spring subsides in the cover of upper knife blade disc adoption causes easily that the upper knife terminal surface beats and the too big accumulative error of radial run-out, seriously influence the quality of cutting. Further upper and lower arbor adopts synchronous machine drive rotation respectively, can produce sliding friction all the time between the upper and lower blade because technical restriction, and the wearing and tearing blade reduces life and influences the quality of cutting.

Meanwhile, the upper cutter adopts an outer exposed thread to adjust the cutter, the thread is damaged, the maintenance is not in place, the rotation is not flexible, and the proper fitting force is difficult to ensure; the too small attaching force can cause collapse and edge drop, the too large blade is worn to aggravate the service life, and the knife tip is not easy to be detected if the too large blade is used to directly crack the knife.

Furthermore, the existing device has strong tolerance to the experience of operators, the cutter setting process is observed by naked eyes, and the relation and the influence between the cutting quality and the self precision of equipment, the self quality of a blade and the correct debugging of the cutter cannot be analyzed through effective data.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that a can realize that the blade independently changes, can not produce sliding friction, blade quick replacement and the convenient knife rest structure of tool setting process adjustment between the upper and lower blade.

In order to solve the problems, the technical proposal of the utility model is that,

a blade adjustment mechanism includes

A level adjustment assembly;

a first tool holder disposed on the horizontal adjustment assembly; the horizontal adjusting assembly controls the first cutter seat to move left and right;

the vertical adjusting assembly is arranged on the first tool apron;

a second tool holder disposed on the vertical adjustment assembly; and the vertical adjusting assembly controls the second tool apron to move up and down.

Furthermore, the first tool apron comprises a first connecting plate, a beam connecting slide block and a horizontal adjusting block; the first connecting plate comprises a horizontal part and a vertical part, and the beam connecting slide block is arranged on the vertical part; the horizontal adjusting block is arranged on the vertical part.

Further, the level adjustment assembly comprises a level adjustment plate; and a horizontal fine adjustment assembly is arranged on the horizontal adjusting plate.

Furthermore, the vertical adjusting component comprises a sliding upper and lower adjusting block, a fixed upper and lower adjusting block, an upper and lower adjusting component and an abutting block; the sliding upper and lower adjusting blocks and the fixed upper and lower adjusting blocks are overlapped together, and the sliding upper and lower adjusting blocks and the fixed upper and lower adjusting blocks can slide relatively; the upper and lower adjusting components are arranged on the sliding upper and lower adjusting blocks, and the abutting blocks are arranged on the fixed upper and lower adjusting blocks.

Further, the vertical adjusting component also comprises a fastening component; the fastening assembly comprises a fastening screw and a fastening connecting plate, and the fastening screw is arranged on the fixed upper and lower adjusting blocks; the fastening connecting plate is arranged on the sliding upper and lower adjusting blocks, and the fastening screw is matched with the fastening connecting plate.

Further, the up-down adjusting component is a differential head, and a contact of the differential head is abutted to the abutting block.

Furthermore, a U-shaped groove is arranged on the horizontal adjusting plate and matched with the horizontal adjusting block, and the horizontal fine adjusting components are arranged on the left and right vertical surfaces of the U-shaped groove.

A battery slitting device comprises

The cutter comprises a rack, an upper cutter frame, the blade adjusting mechanism, a lower cutter shaft and a lower cutter spacer bush; the upper tool rest and the lower tool shaft are arranged on the rack, and the upper tool rest is provided with a plurality of upper blade adjusting mechanisms; the upper blade adjusting mechanism is provided with a self-rotating upper blade, the lower cutter shaft is provided with a lower blade, and the upper blade and the lower blade are contacted to generate static friction force.

Furthermore, the lower cutter shaft is connected with the motor through a transmission coupling to rotate.

Further, the upper tool rest comprises a cross beam, a sliding groove is formed in the cross beam, and symmetrical protrusions are arranged on the inner wall of the sliding groove.

The utility model has the advantages that:

1. the tool rest structure can adapt to various machine types, the number of tool positions can be increased or decreased at will, and the tool rest can be used by being directly installed without changing the original machine type structure; simultaneously, each blade is independently replaced, the upper blade and the lower blade of each group are independently used for tool setting, each group of blades do not influence each other in the tool setting process, the operation process is simple, and the operation space is improved.

2. The device is used for tool setting, the occlusion depth and the adhesion force of the upper tool and the lower tool can be visually quantized and precisely adjusted through a measuring tool, the dependence on the experience and the technology of a tool exchanging person is reduced, and the crack of the tool in the debugging process is well avoided.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the invention without undue limitation to the invention.

Fig. 1 is a schematic structural diagram of a battery knife slitting mechanism according to an embodiment of the present invention;

fig. 2 is a schematic structural view of an upper tool holder of a battery knife slitting mechanism according to an embodiment of the present invention;

fig. 3 is a schematic structural diagram of another view angle of the upper tool holder of the battery knife slitting mechanism according to the embodiment of the present invention;

FIG. 4 is a partial enlarged view of A in FIG. 2;

fig. 5 is a schematic structural view of a single upper blade adjusting mechanism according to an embodiment of the present invention;

fig. 6 is a schematic structural view of another view angle of the single upper blade adjusting mechanism according to the embodiment of the present invention;

fig. 7 is a schematic structural view of another view angle of the single upper blade adjusting mechanism according to the embodiment of the present invention;

fig. 8 is a schematic structural view of another view angle of the single upper blade adjusting mechanism according to the embodiment of the present invention;

fig. 9 is an exploded view of the vertical adjustment assembly according to the embodiment of the present invention;

fig. 10 is a schematic structural view of an up-down knife assembly according to an embodiment of the present invention;

fig. 11 is a schematic structural view of another perspective of the explosive structure of the vertical adjustment knife assembly according to the embodiment of the present invention;

fig. 12 shows the change of the position of the upper and lower blades during the tool setting process.

The device comprises a frame 1, a transmission coupler 2, an upper tool rest 3, a cross beam 3.1, an upper blade adjusting mechanism 4, a horizontal adjusting plate 4.1, a first fastening screw 4.2, a horizontal fine-adjustment assembly 4.3, a first connecting plate 4.4, a second connecting plate 4.5, a cross beam connecting slide block 4.6, a horizontal adjusting block 4.7, an upper adjusting block 4.8, a lower adjusting block 4.8.1, an upper sliding adjusting block 4.8.1, a fixed upper adjusting block 4.8.2, an upper adjusting block 4.8.3, a butt block 4.8.4, a fastening assembly 4.8.5, a lower cutter shaft 5, a lower cutter spacer sleeve 6 and a lower blade 8.

Detailed Description

In order to make the technical solution of the present invention better understood, the technical solution of 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, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts shall belong to the protection scope of the present invention.

It should be noted that the terms "first," "second," and the like in the description and claims of the present invention and in the drawings described above are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the invention described herein are capable of operation in sequences other than those illustrated or otherwise described herein. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

As shown in fig. 1, a battery slitting device comprises a frame 1, a transmission coupler 2, an upper tool rest 3, an upper blade adjusting mechanism 4, a lower tool shaft 5, a lower tool spacer 6 and a lower blade 8; the U-shaped frame 1 is provided with an upper tool rest 3 and a lower tool shaft 5 on the frame 1, a plurality of independent upper blade adjusting mechanisms 4 are arranged on the upper tool rest 3, a plurality of lower tool spacers 6 are arranged on the lower tool shaft 5, the upper blade adjusting mechanisms 4 are provided with autorotation upper blades 7, lower blades 8 are arranged on the lower tool shaft 5, the upper blades 7 are contacted with the lower blades 8 to generate static friction, the lower tool shaft 5 is connected with a motor through a transmission coupling 2 to rotate, the lower tool shaft 5 drives the lower blades 8 to rotate, and the lower blades 8 drive the upper blades 7 to rotate simultaneously through the static friction generated by the contact of the upper blades 7 and the lower blades 8.

As shown in fig. 2-3, an upper blade holder for a battery slitting device comprises a cross beam 3.1 and an upper blade adjusting mechanism 4 arranged on the cross beam 3.1. The upper blade adjustment mechanism 4 moves horizontally along the cross beam 3.1. Further, be provided with spout 3.1.1 on the crossbeam 3.1, go up blade adjustment mechanism 4 and include with spout 3.1.1 complex crossbeam link block 4.6, crossbeam link block 4.6 can be in spout 3.1.1 internal level paddling, be provided with symmetrical protruding on the inner wall of spout 3.1.1, protruding being used for restricting crossbeam link block 4.6 spout 3.1.1 to fall down.

As shown in fig. 4-11, the upper blade adjustment mechanism 4 includes a first linkage plate 4.4; the first connecting plate 4.4 is "L" shaped including a horizontal portion and a vertical portion. As shown in fig. 5-8, the horizontal portion is provided with a beam connecting sliding block 4.6, and the beam connecting sliding block 4.6 is matched with a sliding groove 3.1.1 arranged on the beam 3.1. The horizontal part is also provided with a horizontal adjusting block 4.7, and the horizontal adjusting block 4.7 is matched with a horizontal adjusting plate 4.1. The level adjusting plate 4.1 is arranged on the cross beam 3.1 in a sliding mode, and when the level adjusting plate 4.1 is moved horizontally, the first connecting plate 4.4 is controlled through the level adjusting block 4.7 to drive the upper cutter shaft 4.9 and the upper blade 7 to move horizontally. The level adjustment plate 4.1 is further provided with a first fastening screw 4.2, and the first fastening screw 4.2 is screwed when the upper blade adjustment mechanism 4 moves horizontally to a preset position. Furthermore, as shown in fig. 8, a u-shaped groove is formed on the horizontal adjusting plate 4.1 to be engaged with the horizontal adjusting block 4.7, and horizontal fine-tuning elements 4.3 are formed on left and right vertical surfaces of the u-shaped groove, so that when the horizontal adjusting plate 4.1 is fixed at a predetermined position, the horizontal fine-tuning elements 4.3 are adjusted to control the horizontal adjusting block 4.7 to move horizontally in the u-shaped groove. Furthermore, the horizontal fine-tuning element 4.3 comprises a differential head and a butt head, which are simultaneously turned when adjusting the horizontal fine-tuning element 4.3, pushing and controlling the horizontal adjusting block 4.7 to move horizontally in the U-shaped groove to reach an ideal position.

As shown in fig. 5-8, the vertical part is provided with an up-and-down adjusting block 4.8 for adjusting the up-and-down movement of the upper blade 7; the up-down adjusting block 4.8 comprises a sliding up-down adjusting block 4.8.1, a fixed up-down adjusting block 4.8.2, an up-down adjusting assembly 4.8.3, an abutting block 4.8.4 and a fastening assembly 4.8.5. Fixed upper and lower regulating block 4.8.2 sets up on the vertical part, for better installation fixed upper and lower regulating block 4.8.2 on the vertical part, is provided with the gasket between fixed upper and lower regulating block 4.8.2 and the vertical part, simultaneously, for the data when the tool setting is more accurate, above-mentioned gasket is insulating gasket 4.10, all is insulating connection between each part, guarantees to go up blade 7 and bottom knife 8 contactless not electric UNICOM. A second connecting plate 4.5 is arranged on the sliding upper and lower adjusting block 4.8.1, and an upper cutter shaft 4.9 is arranged on the second connecting plate 4.5. The upper cutter shaft 4.9 is provided with an upper blade 7 capable of rotating. The fastening assembly 4.8.5 comprises a fastening screw and a fastening connection plate, wherein the fastening screw is arranged on the fixed upper and lower adjusting block 4.8.2; the fastening connecting plate is arranged on the sliding upper and lower adjusting block 4.8.1, the fastening screw is matched with the fastening connecting plate, and the fastening screw is tightened when the blade is adjusted to a preset position up and down.

As shown in fig. 9-11, the sliding up-down adjusting block 4.8.1 and the fixed up-down adjusting block 4.8.2 are overlapped together, and the sliding up-down adjusting block 4.8.1 and the fixed up-down adjusting block 4.8.2 can slide relatively. When the upper blade 7 is adjusted, the fixed upper and lower adjusting blocks 4.8.2 are fixed on the vertical part, and the upper and lower adjusting blocks 4.8.1 are slid to control the position of the upper blade 7 up and down. An upper adjusting component 4.8.3 is arranged on the sliding upper adjusting block 4.8.1, a butting block 4.8.4 is arranged on the fixed upper adjusting block 4.8.2, and a contact extending out of the rotating upper adjusting component 4.8.3 is butted with the butting block 4.8.4 to drive the first upper adjusting block 4.8.1 to move up and down. Further, in order to accurately adjust the contact position between the upper blade 7 and the lower blade 8, the upper and lower adjusting components 4.8.3 are differential heads, a contact of the differential heads is in contact with the abutting block 4.8.4, the differential heads are rotated to drive the first upper and lower adjusting blocks 4.8.1 to move up and down, and the first upper and lower adjusting blocks 4.8.1 drive the second connecting plate 4.5, the upper cutter shaft 4.9 and the upper blade 7 to move up and down.

It will be appreciated by those of ordinary skill in the art that the embodiments described herein are intended to assist the reader in understanding the principles of the invention, and it is to be understood that the scope of the invention is not limited to such specific statements and embodiments. Those skilled in the art can make various other specific modifications and combinations based on the teachings of the present invention without departing from the spirit of the invention, and such modifications and combinations are still within the scope of the invention.

Claims (10)

1. A blade adjustment mechanism, its characterized in that: comprises that

A level adjustment assembly;

a first tool holder disposed on the horizontal adjustment assembly; the horizontal adjusting assembly controls the first cutter seat to move left and right;

the vertical adjusting assembly is arranged on the first tool apron;

a second tool holder disposed on the vertical adjustment assembly; and the vertical adjusting assembly controls the second tool apron to move up and down.

2. The blade adjustment mechanism of claim 1, wherein: the first tool apron comprises a first connecting plate, a beam connecting sliding block and a horizontal adjusting block; the first connecting plate comprises a horizontal part and a vertical part, and the beam connecting slide block is arranged on the vertical part; the horizontal adjusting block is arranged on the vertical part.

3. A blade adjustment mechanism according to claim 1 or 2, wherein: the horizontal adjusting assembly comprises a horizontal adjusting plate; and a horizontal fine adjustment assembly is arranged on the horizontal adjusting plate.

4. The blade adjustment mechanism of claim 1, wherein: the vertical adjusting assembly comprises a sliding upper adjusting block, a sliding lower adjusting block, a fixed upper adjusting block, a fixed lower adjusting block, an upper adjusting assembly, a lower adjusting assembly and a butting block; the sliding upper and lower adjusting blocks and the fixed upper and lower adjusting blocks are overlapped together, and the sliding upper and lower adjusting blocks and the fixed upper and lower adjusting blocks can slide relatively; the upper and lower adjusting components are arranged on the sliding upper and lower adjusting blocks, and the abutting blocks are arranged on the fixed upper and lower adjusting blocks.

5. The blade adjustment mechanism of claim 4, wherein: the vertical adjustment assembly further comprises a fastening assembly; the fastening assembly comprises a fastening screw and a fastening connecting plate, and the fastening screw is arranged on the fixed upper and lower adjusting blocks; the fastening connecting plate is arranged on the sliding upper and lower adjusting blocks, and the fastening screw is matched with the fastening connecting plate.

6. The blade adjustment mechanism of claim 4, wherein: the upper and lower adjusting components are differential heads, and the contact of the differential heads is abutted to the abutting block.

7. The blade adjustment mechanism of claim 3, wherein: the U-shaped groove is arranged on the horizontal adjusting plate and matched with the horizontal adjusting block, and the horizontal fine adjusting components are arranged on the left and right vertical surfaces of the U-shaped groove.

8. The utility model provides a device is cut to battery which characterized in that: comprises that

A frame, an upper blade carrier, a blade adjustment mechanism as claimed in any one of claims 1 to 4, a lower blade shaft and a lower blade spacer; the upper tool rest and the lower tool shaft are arranged on the rack, and the upper tool rest is provided with a plurality of upper blade adjusting mechanisms; the upper blade adjusting mechanism is provided with a self-rotating upper blade, the lower cutter shaft is provided with a lower blade, and the upper blade and the lower blade are contacted to generate static friction force.

9. The battery slitting device according to claim 8, wherein: the lower cutter shaft is connected with the motor through a transmission coupler to rotate.

10. The battery slitting device according to claim 8, wherein: the upper tool rest comprises a cross beam, wherein a sliding groove is formed in the cross beam, and symmetrical protrusions are arranged on the inner wall of the sliding groove.

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