CN217599773U - Auxiliary battery cell conveying mechanism - Google Patents

Abstract

The utility model provides an auxiliary battery core conveying mechanism, include: the battery cell is arranged on the tray assembly, and the tray assembly is in contact with the first surface of the battery cell and limits the movement of the battery cell relative to the tray assembly in the horizontal direction; the pressing plate assembly covers the second surface of the battery cell, and is matched with the tray assembly to limit the movement of the battery cell relative to the tray assembly in the vertical direction; the pressing assembly is used for pressing the pressing plate assembly, so that the pressing plate assembly is connected with the tray assembly, and the battery cell is fixed between the pressing plate assembly and the tray assembly; and the clamping assembly is used for separating the pressing plate assembly from the tray assembly and clamping the pressing plate assembly to enable the pressing plate assembly to cover the second surface of the battery core. The utility model provides a problem that lithium ion battery cell is damaged easily in the transportation.

Description

Auxiliary battery cell conveying mechanism

Technical Field

The utility model relates to a battery production facility technical field particularly, relates to an auxiliary electrical core conveying mechanism.

Background

Compared with traditional lead-acid batteries, nickel-hydrogen batteries, nickel-cadmium batteries and the like, the lithium ion batteries have the advantages of high energy density, small volume, long service life, small self-discharge, no memory effect, zero environmental pollution and the like, and are widely applied to a plurality of mobile devices in the fields of national defense, industry and civilian use. However, with the continuous improvement of the performance requirements of high-end digital lithium batteries and power batteries, the manufacturing requirements of lithium batteries are more and more strict.

In the production process of the lithium ion battery, after the lithium ion battery cells are laminated in a lithium ion laminating machine, the lithium ion battery cells need to be conveyed to other processing stations through an automatic logistics conveying system so as to carry out the next production procedure. In the conveying process, the battery cell is easily damaged due to inertia collision impact, so that the product quality of the lithium battery is seriously influenced, and the safety and the service life of the lithium battery are seriously influenced.

SUMMERY OF THE UTILITY MODEL

The utility model discloses aim at solving the problem that lithium ion battery cell is easily damaged in current lithium ion battery's transportation.

In order to solve the above problem, the utility model provides an auxiliary battery cell conveying mechanism, include:

the battery cell is arranged on the tray assembly, and the tray assembly is in contact with the first surface of the battery cell and limits the movement of the battery cell relative to the tray assembly in the horizontal direction;

the pressing plate assembly covers the second surface of the battery cell, is matched with the tray assembly and can limit the movement of the battery cell relative to the tray assembly in the vertical direction;

the pressing assembly is used for pressing the pressing plate assembly, so that the pressing plate assembly is connected with the tray assembly, and the battery cell is fixed between the pressing plate assembly and the tray assembly;

and the clamping assembly is used for separating the pressing plate assembly from the tray assembly and clamping the pressing plate assembly to enable the pressing plate assembly to cover the second surface of the battery core.

Further, the tray assembly comprises a supporting plate and limiting blocks, the limiting blocks are arranged on the supporting plate, the limiting blocks are arranged on the periphery of the battery cell, and the limiting blocks limit the battery cell to move relative to the tray assembly in the horizontal direction.

Further, the tray assembly further comprises a locking member, at least one group of locking member is arranged on the supporting plate, and the locking member is used for locking the pressing plate assembly.

Further, the locking piece comprises a shell, a limiting cover, a clamping block and a guide shaft, wherein,

the shell is provided with a first waist-shaped hole arranged along the horizontal direction;

the limiting cover extends along the horizontal direction and is arranged on one side outside the shell, and the limiting cover and one side of the shell enclose to form an accommodating cavity with an upper opening;

one end of the fixture block is positioned in the shell, the other end of the fixture block penetrates out of the shell and is positioned in the accommodating cavity, and one end of the fixture block, which is positioned in the accommodating cavity, is provided with a first inclined surface;

one end of the guide shaft is positioned in the shell and connected with the fixture block, the other end of the guide shaft extends towards the direction far away from the accommodating cavity and penetrates out of the shell, and the guide shaft drives the fixture block to move along the horizontal direction;

the guide shaft is sleeved with a first spring, one end of the first spring is abutted to the fixture block, the other end of the first spring is abutted to the shell, and the first spring can generate elastic force for enabling the fixture block to move in the horizontal direction.

Furthermore, the locking assembly also comprises a telescopic block and a limiting pin, wherein,

the telescopic block penetrates through the shell and can move in the vertical direction, and an inclined second waist-shaped hole is formed in the telescopic block;

one end of the limiting pin is connected with the clamping block, and the other end of the limiting pin penetrates through the second waist-shaped hole in the telescopic block, penetrates out of the first waist-shaped hole and is arranged outside the shell.

Further, the pressure plate assembly comprises a pressure plate, a contact plate, a second spring and a buckling column, wherein,

the pressing plate is in contact with the pressing assembly;

the contact plate and the pressing plate are arranged in parallel, and the contact plate is used for being in contact with a second surface of the battery core;

the plurality of second springs are arranged between the pressing plate and the contact plate, one end of each second spring is connected with the pressing plate, the other end of each second spring is connected with the contact plate, and the second springs can generate elastic force for enabling the contact plate to press the battery cell;

the clamping buckle column is connected with the pressing plate, and the clamping buckle column and the clamping blocks are arranged in a one-to-one correspondence mode and used for locking the pressing plate assembly.

Furthermore, the buckling column extends downwards towards the vertical direction and protrudes out of the contact plate, a second inclined plane is arranged at one end, protruding out of the contact plate, of the buckling column, and the second inclined plane is matched with the first inclined plane.

Further, the gripping assembly comprises a gripping jaw, a contact post, and an adjustment assembly, wherein,

the clamping jaw is used for clamping the pressing plate assembly;

the contact columns are arranged in one-to-one correspondence with the telescopic blocks and are used for pressing the telescopic blocks to separate the clamping blocks from the pressing plate assembly;

the adjusting assembly is used for adjusting the height of the clamping jaw and the contact column in the vertical direction and adjusting the telescopic range of the clamping jaw in the horizontal direction.

Further, the pressing assembly comprises a pressing rod and a driving part;

the pressing rod is used for contacting with the pressure plate assembly;

the driving part is used for driving the pressing rod to be close to or far away from the pressing plate assembly, and acting force for enabling the clamping buckle column to be tightly abutted to the clamping block can be applied to the pressing plate assembly through the pressing rod.

Further, still include the slide rail, the slide rail with press from both sides and get subassembly sliding connection, make press from both sides and get the subassembly and can move along the horizontal direction.

The utility model provides an auxiliary electric core conveying mechanism compresses tightly each face of electric core through tray subassembly and clamp plate subassembly, adopts integral compact structure to electric core, makes the whole face of electric core all evenly atress, and the electric core is protected to all sides, guarantees that electric core does not have in the transportation and rocks, collides or damaged to can effectively guarantee that electric core is impaired in the transportation; in addition, press from both sides the subassembly clamp and get the clamp plate subassembly through getting, compress tightly the subassembly and compress tightly the clamp plate subassembly, be favorable to improving the efficiency that conveys and compress tightly, can realize efficient automated production, be favorable to improving production efficiency.

Drawings

Fig. 1 is a schematic structural view of an auxiliary battery cell conveying mechanism in an embodiment of the present invention;

FIG. 2 is a schematic cross-sectional view of a locking member according to an embodiment of the present invention;

FIG. 3 is a schematic side view of a locking member according to an embodiment of the present invention;

fig. 4 is a schematic structural view of unlocking the locking member in the embodiment of the present invention;

fig. 5 is a schematic structural view of a platen assembly according to an embodiment of the present invention;

fig. 6 is a schematic structural view of the clamping assembly according to the embodiment of the present invention;

fig. 7 is a schematic structural diagram of the compressing assembly according to the embodiment of the present invention.

Description of reference numerals:

1-electric core; 2-a tray assembly; 3-a platen assembly; 4-a gripping assembly; 5-a pressing component; 6-a slide rail;

21-a support plate; 22-a limiting block; 23-a locking member; 31-a platen; 32-a contact plate; 33-a second spring; 34-a snap post; 41-an adjustment assembly; 42-contact column; 43-a jaw; 51-a drive section; 52-a hold down bar;

231-a housing; 232-limit cover; 233-a fixture block; 234-a guide shaft; 235-a telescopic block; 236-a limit pin; 237-a first spring; 238-a containment cavity; 411-lifting floor; 412-linear guide rail; 413-a first cylinder; 414-gripper feed cylinder; 511-connecting plate; 512-guide bar; 513-a second cylinder;

2311-a first kidney-shaped hole; 2351-second kidney-shaped hole.

Detailed Description

The technical solution of the present invention is clearly and exhaustively described below with reference to the accompanying drawings. In the description of the present invention, it should be noted that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present invention. Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or to implicitly indicate the number of technical features indicated. Thus, features defined as "first", "second", may explicitly or implicitly include one or more of the described features. Furthermore, in the description of the present invention, "at least one" means one or more unless specifically limited otherwise.

In the description of the present specification, the description of the term "on the basis of the above-described embodiments" means that a specific feature, structure, material or characteristic described in connection with the embodiment or example is included in at least one preferred embodiment or preferred example of the present invention. Throughout this specification, the schematic representations of the terms used above do not necessarily refer to the same implementation or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

As shown in fig. 1, the present embodiment provides an auxiliary cell conveying mechanism, where a cell 1 includes a lower surface (i.e., a first surface) and an upper surface (i.e., a second surface) that are oppositely disposed, and the auxiliary cell conveying mechanism includes: tray subassembly 2, clamp plate subassembly 3, press from both sides subassembly 4 and compress tightly subassembly 5, wherein:

the battery cell 1 is arranged on the tray assembly 2, and the tray assembly 2 is in contact with the lower surface of the battery cell 1 and can limit the movement of the battery cell 1 relative to the tray assembly 2 in the horizontal direction;

the pressing plate component 3 is arranged above the tray component 2, the pressing plate component 3 covers the upper surface of the battery core 1, and the pressing plate component 3 is matched with the tray component 2 to tightly press the battery core 1 so as to limit the movement of the battery core 1 relative to the tray component 2 in the vertical direction;

the clamping assembly 4 is used for separating the pressing plate assembly 3 from the tray assembly 2 and clamping the pressing plate assembly 3 to enable the pressing plate assembly 3 to cover the upper surface of the battery core 1;

the pressing assembly 5 is used for pressing the pressing plate assembly 3, so that the pressing plate assembly 3 is connected with the tray assembly 2, and the battery cell 1 is fixed between the pressing plate assembly 3 and the tray assembly 2.

According to the auxiliary battery cell conveying mechanism provided by the embodiment, each surface of the battery cell is compressed through the tray assembly and the pressing plate assembly, and an integral type compression structure is adopted for the battery cell, so that the whole surface of the battery cell is uniformly stressed, the battery cell is protected in an all-dimensional manner, and the battery cell is ensured not to shake, collide or damage in the transportation process, so that the battery cell can be effectively ensured to be damaged in the transportation process; in addition, press plate assembly is got to the subassembly clamp through pressing from both sides, compresses tightly the subassembly and compresses tightly press plate assembly, is favorable to improving the efficiency that conveys and compress tightly, can realize efficient automated production, is favorable to improving production efficiency.

The tray assembly 2 comprises a supporting plate 21, limiting blocks 22 and locking pieces 23, wherein the limiting blocks 22 and the locking pieces 23 are arranged on the supporting plate 21, the limiting blocks 22 are arranged around the battery cell 1 and coat four side surfaces and the lower surface of the battery cell 1 so as to fix the position of the battery cell 1 and limit the movement of the battery cell 1 relative to the tray assembly 2 in the horizontal direction; two sets of retaining members 23 are fixed respectively on the relative both sides limit of electric core 1, and retaining member 23 is used for locking clamp plate assembly 3, fixes clamp plate assembly 3's position, and restriction clamp plate assembly 3 is relative tray assembly 2 in the activity of vertical direction to can fix electric core 1 between clamp plate assembly 3 and tray assembly 2, restriction electric core 1 is relative tray assembly 2 in the activity of vertical direction.

The periphery of the tray assembly 2 is also provided with guide wheels (not marked in the figure), and the guide wheels can enable the tray assembly 2 to be conveyed on the electric core conveying line more smoothly.

As shown in fig. 2 to 4, the locker 23 includes a housing 231, a position-limiting cover 232, a latch 233, a guide shaft 234, a telescopic block 235, and a position-limiting pin 236, wherein,

the housing 231 is provided with a first waist-shaped hole 2311, and the first waist-shaped hole 2311 is arranged along the horizontal direction.

The first waist-shaped hole 2311 is arranged along the horizontal direction, which means that the center line of the first waist-shaped hole 2311 is arranged in parallel with the horizontal direction.

The limiting cover 232 extends along a horizontal direction and is disposed at one side of the outer portion of the housing 231, and the limiting cover 232 and one side wall of the housing 231 enclose to form an accommodating cavity 238 with an opening at the upper portion.

The latch 233 is disposed through the housing 231, one end of the latch 233 is located inside the housing 231, the other end of the latch 233 horizontally penetrates out of the housing 231 and is located in the accommodating cavity 238, and one end of the latch 233 located in the accommodating cavity 238 has a first inclined surface, and the first inclined surface is matched with the pressing plate assembly 3.

The guide shaft 234 penetrates the housing 231, one end of the guide shaft 234 is located inside the housing 231 and is connected with the latch 233, the other end of the guide shaft 234 extends in a direction away from the accommodating cavity 238 and penetrates out of the housing 231, and the guide shaft 234 is used for guiding the moving direction of the latch 233, so that the latch 233 can only move in the horizontal direction; the guide shaft 234 is sleeved with a first spring 237, one end of the first spring 237 abuts against the latch 233, the other end of the first spring 237 abuts against the inner wall of the housing 231, and the first spring 237 can generate an elastic force for moving the latch 233 in the horizontal direction.

When compressing tightly subassembly 5 and applying the effort to clamp plate subassembly 3, make clamp plate subassembly 3 contact first inclined plane and when extrudeing fixture block 233, fixture block 233 removes and extrudeing first spring 237 along the horizontal direction, make first spring 237 produce elasticity, when clamp plate subassembly 3 stops to extrude fixture block 233, the elasticity that first spring 237 produced promotes fixture block 233 and moves left, and with clamp plate subassembly 3 joint between spacing cover 232 and fixture block 233, reach the effect of locking clamp plate subassembly 3, fix the position of clamp plate subassembly 3, thereby can fix electric core 1 between clamp plate subassembly 3 and tray subassembly 2, restriction electric core 1 is relative tray subassembly 2 at the activity of vertical direction.

The telescopic block 235 is arranged on the shell 231 in a penetrating mode, one end of the telescopic block 235 is located inside the shell 231, the other end of the telescopic block 235 penetrates out of the shell 231 in the vertical direction and is located outside the shell 231, the telescopic block 235 can move in the vertical direction, and the second waist-shaped hole 2351 inclined is formed in the telescopic block 235.

The inclined second waist-shaped hole 2351 means that the center line of the second waist-shaped hole 2351 is inclined to a certain angle in the vertical direction, that is, the center line of the second waist-shaped hole 2351 forms a certain angle with the vertical direction. The angle is not further limited in this embodiment, and those skilled in the art can set the angle according to actual situations.

One end of the stopper pin 236 is connected to the latch 233, and the other end of the stopper pin 236 passes through the second slotted hole 2351 obliquely disposed on the telescopic block 235, and passes through the first slotted hole 2311, and is disposed outside the housing 231. The limit pin 236 is connected with the latch 233, and the limit pin 236 is inserted into the first waist-shaped hole 2311 and the second waist-shaped hole 2351, so that the moving positions of the telescopic block 235 and the latch 233 can be limited, and the phenomenon that the moving amplitude of the telescopic block 235 or the latch 233 is too large is avoided.

When pressing from both sides and getting subassembly 4 contact flexible piece 235 and extrude flexible piece 235, flexible piece 235 moves down along vertical direction, drive spacer pin 236 and remove in first waist shape hole 2311 and second waist shape hole 2351, drive fixture block 233 and remove right and extrude first spring 237, make fixture block 233 and pressure plate assembly 3 separate, reach the effect of loosening pressure plate assembly 3, make to press from both sides and get subassembly 4 and can press from both sides and get pressure plate assembly 3, the pressure plate assembly 3 that covers on electric core 1 is taked away the back, electric core 1 can be relative tray subassembly 2 at the activity of vertical direction, and pressure plate assembly 3 is taked away the back, promote fixture block 233 under the spring action of first spring 237 and resume the normal position.

As shown in fig. 5, the pressure plate assembly 3 includes a pressure plate 31, a contact plate 32, a second spring 33 and a latch post 34, wherein,

the pressing plate 31 is used for contacting with the pressing assembly 5, and the pressing assembly 5 applies acting force to the pressing plate 31;

the contact plate 32 and the pressure plate 31 are arranged in parallel along the vertical direction, the contact plate 32 is arranged below the pressure plate 31, and the contact plate 31 is used for contacting with the upper surface of the battery core 1 and can cover the upper surface of the battery core 1;

a plurality of second springs 33 are arranged between the pressing plate 31 and the contact plate 32, one end of each second spring 33 is connected with the pressing plate 31, and the other end of each second spring 33 is connected with the contact plate 32, and can generate elastic force for pressing the contact plate 32 against the battery cell 1;

the buckling columns 34 and the blocking blocks 233 are arranged in a one-to-one correspondence manner, the buckling columns 34 are connected with the pressing plate 31, the buckling columns 34 extend downwards in the vertical direction and protrude out of the contact plate 32, namely, one ends of the buckling columns 34 are connected with the pressing plate 31, the other ends of the buckling columns 34 are located below the contact plate 32, second inclined planes are arranged at the ends, protruding out of the contact plate 32, of the buckling columns 34, the second inclined planes are matched with the first inclined planes and can push the blocking blocks 233 to move rightwards, the buckling columns 34 extend to the lower sides of the blocking blocks 233, then the blocking blocks 233 are pushed to move leftwards by elastic force generated by the first springs 237, the buckling columns 34 are abutted against the blocking blocks 233, the blocking blocks 233 and the limiting covers 232 can clamp the buckling columns 34, and accordingly the pressing plate assembly 3 is locked.

As shown in connection with fig. 6, gripping assembly 4 comprises an adjustment assembly 41, a contact post 42 and a gripping jaw 43, wherein,

the adjusting assembly 41 comprises a mounting base (not shown in the figure), a lifting bottom plate 411 which is horizontally placed and can move up and down to approach the battery cell 1 on the battery cell conveying line or be far away from the battery cell 1 on the battery cell conveying line is arranged on the mounting base, a linear guide rail 412 which is matched with the side surface of the lifting bottom plate 411 and is convenient for guiding the lifting bottom plate 411 is arranged on the mounting base, and a first air cylinder 413 which drives the lifting bottom plate 411 to move up and down along the linear guide rail 412 is arranged on the mounting base;

a clamping jaw mounting plate is arranged on the lifting bottom plate 411, the clamping jaw mounting plate can be driven by a first air cylinder 413 to ascend or descend along a linear guide rail 412, a clamping jaw 43 is mounted on the clamping jaw mounting plate, the clamping jaw 43 is used for clamping the pressing plate assembly 3, an air jaw air cylinder (not marked in the figure) for driving the clamping jaw 43 to open and close is mounted on the clamping jaw mounting plate, a clamping jaw feeding air cylinder 414 which is matched with each group of mutually connected clamping jaw 43 and air jaw air cylinder and pushes the clamping jaw 43 and the air jaw air cylinder to extend or retract is further mounted on the clamping jaw mounting plate, wherein the clamping jaw feeding air cylinder 414 can drive the clamping jaw to extend and retract along the horizontal direction, so that the clamping range of the clamping jaw 43 is adjusted, and the clamping plate assembly 3 can be more stably grabbed by the clamping jaw 43;

contact post 42 sets up the clamping jaw 43 all around, contact post 42 and flexible piece 235 one-to-one setting, contact post 42 and lifting bottom plate 411 fixed connection, contact post 42 is towards vertical direction downwardly extending, contact post 42 can rise or descend along linear guide 412 under the drive of first cylinder 413 to make contact post 42 can press flexible piece 235, and through driving spacer pin 236 and fixture block 233 with flexible piece 235 and remove, make fixture block 233 and clamp plate subassembly 3 separate, thereby reach the effect of unclamping clamp plate subassembly 3.

As shown in fig. 7, the pressing assembly 5 includes a driving part 51 and a pressing rod 52, wherein,

the driving part 51 comprises a bracket, the bracket is provided with a connecting plate 511 which is horizontally placed and can move up and down to approach the cell 1 or be far away from the cell 1, the bracket is provided with a guide rod 512 which is matched with the connecting plate 511 to facilitate the guide of the connecting plate 511, and the bracket is provided with a second cylinder 513 which drives the connecting plate 511 to move up or down along the guide rod 512;

four pressure poles 52 all set up in the below of connecting plate 511 along vertical direction, and every pressure pole 52 all is connected with connecting plate 511, when second cylinder 513 drive connecting plate 511 ascends or the descending movement, can make pressure pole 52 and clamp plate 31 contact, and exert decurrent effort to clamp plate 31, thereby make buckle post 34 and fixture block 233 looks butt, thereby reach the effect of locking clamp plate subassembly 3, fix electric core 1 between clamp plate subassembly 3 and tray subassembly 2, restrict the activity of electric core 1 relative tray subassembly 2 in vertical direction.

This supplementary electric core conveying mechanism still includes slide rail 6, and slide rail 6 sets up along the horizontal direction, presss from both sides the mount pad of getting subassembly 4 and slide rail 6 sliding connection, makes to press from both sides and gets subassembly 4 and can remove along the horizontal direction, transports clamp plate assembly 3, makes electric core 1 on electric core transfer chain all fix between clamp plate assembly 3 and tray assembly 2.

The following describes the working process of the auxiliary battery cell conveying mechanism in this embodiment:

the battery cell 1 is arranged on the tray assembly 2, the tray assembly 2 limits the movement of the battery cell 1 in the horizontal direction, when the tray assembly 2 only provided with the battery cell 1 is conveyed to the lower part of the slide rail 6, the clamping assembly 3 presses the telescopic block 235 on the tray assembly 2 locked with the battery cell 1, the clamping block 233 is separated from the clamping plate assembly 3, the clamping and pressing plate assembly 3 is loosened, the clamping plate assembly 3 can bounce the pressing plate 31 due to the elasticity of the second spring 33, the clamping jaw 43 of the clamping assembly 3 stretches out and draws back through the clamping jaw feeding cylinder 414, the pressing plate 31 is clamped, the clamping jaw 43 is driven by the first cylinder 413 to ascend along the linear guide 412, the clamped clamping plate assembly 3 is moved to the upper part of the tray assembly 2 only provided with the battery cell 1 through the guide rail 6, the pressing rod 52 is in contact with the pressing plate 31, a downward acting force is applied to the pressing plate 31 through the driving part 51, the clamping column 34 is abutted to the clamping block 233, the clamping assembly 3 is fixed to the lower part of the tray assembly 2 clamped with the battery cell assembly 3, the tray assembly 3, and the clamping assembly 3 is conveyed to the lower part of the pressing plate assembly 5, and the pressing plate assembly 1, and the clamping assembly 3 is obtained, and the locking process that the tray assembly 1 and the clamping assembly 1 is clamped with the battery cell 1, and the clamping assembly 3, and the clamping plate assembly 1, and the clamping assembly 3, and the locking process of the locking plate assembly 1 is moved, and the clamping assembly 1, and the locking plate assembly 3, and the locking plate assembly 1, and the locking process is obtained.

The pressing plate assembly 3 in this embodiment can be repeatedly used, and after the transportation of the previous batch of battery cells 1 is completed, the pressing plate assembly can be continuously used in the transportation process of the next batch of battery cells 1, so that the damage of the battery cells 1 in the transportation process can be effectively ensured, and the transportation cost of the battery cells 1 can be reduced.

Although the present disclosure has been described above, the scope of the present disclosure is not limited thereto. Various changes and modifications may be made by those skilled in the art without departing from the spirit and scope of the present disclosure, and these changes and modifications are intended to fall within the scope of the present disclosure.

Claims (10)

1. An auxiliary battery cell conveying mechanism, electric core include relative first surface and the second surface that sets up, its characterized in that includes:

the battery cell is arranged on the tray assembly, the tray assembly is in contact with the first surface of the battery cell and limits the movement of the battery cell relative to the tray assembly in the horizontal direction;

the pressing plate assembly covers the second surface of the battery cell, is matched with the tray assembly and can limit the movement of the battery cell relative to the tray assembly in the vertical direction;

the pressing assembly is used for pressing the pressing plate assembly, so that the pressing plate assembly is connected with the tray assembly, and the battery cell is fixed between the pressing plate assembly and the tray assembly;

and the clamping assembly is used for separating the pressing plate assembly from the tray assembly and clamping the pressing plate assembly to enable the pressing plate assembly to cover the second surface of the battery core.

2. The auxiliary cell conveying mechanism according to claim 1, wherein the tray assembly includes a support plate and a plurality of stoppers, the stoppers are disposed on the support plate, the plurality of stoppers are disposed around the cell, and the stoppers limit movement of the cell in a horizontal direction with respect to the tray assembly.

3. The auxiliary cell delivery mechanism of claim 2, wherein the tray assembly further comprises a locking member, at least one set of the locking member is disposed on the support plate, and the locking member is configured to lock the pressure plate assembly.

4. The auxiliary cell conveying mechanism according to claim 3, wherein the locking member comprises a housing, a limiting cover, a clamping block and a guiding shaft, wherein,

the shell is provided with a first waist-shaped hole arranged along the horizontal direction;

the limiting cover extends along the horizontal direction and is arranged on one side outside the shell, and the limiting cover and one side of the shell enclose to form an accommodating cavity with an upper opening;

one end of the fixture block is positioned in the shell, the other end of the fixture block penetrates out of the shell and is positioned in the accommodating cavity, and one end of the fixture block, which is positioned in the accommodating cavity, is provided with a first inclined surface;

one end of the guide shaft is positioned in the shell and connected with the fixture block, the other end of the guide shaft extends towards the direction far away from the accommodating cavity and penetrates out of the shell, and the guide shaft drives the fixture block to move along the horizontal direction;

the guide shaft is sleeved with a first spring, one end of the first spring is abutted to the fixture block, the other end of the first spring is abutted to the shell, and the first spring can generate elastic force for enabling the fixture block to move in the horizontal direction.

5. The auxiliary cell delivery mechanism of claim 4, wherein the locking member further comprises a telescoping block and a spacing pin, wherein,

the telescopic block penetrates through the shell and can move in the vertical direction, and an inclined second waist-shaped hole is formed in the telescopic block;

one end of the limiting pin is connected with the clamping block, and the other end of the limiting pin penetrates through the second waist-shaped hole in the telescopic block, penetrates out of the first waist-shaped hole and is arranged outside the shell.

6. The auxiliary cell delivery mechanism of claim 4, wherein the pressure plate assembly comprises a pressure plate, a contact plate, a second spring, and a snap-fit post, wherein,

the pressing plate is in contact with the pressing assembly;

the contact plate and the pressing plate are arranged in parallel, and the contact plate is used for being in contact with a second surface of the battery core;

the plurality of second springs are arranged between the pressing plate and the contact plate, one end of each second spring is connected with the pressing plate, the other end of each second spring is connected with the contact plate, and the second springs can generate elastic force for enabling the contact plate to press the battery core;

the clamping buckle column is connected with the pressing plate and is in one-to-one correspondence with the clamping blocks and used for locking the pressing plate assembly.

7. The auxiliary battery cell conveying mechanism according to claim 6, wherein the buckling column extends downward in the vertical direction and protrudes out of the contact plate, a second inclined plane is arranged at one end of the buckling column protruding out of the contact plate, and the second inclined plane is matched with the first inclined plane.

8. The auxiliary cell conveying mechanism according to claim 5, wherein the clamping assembly comprises a clamping jaw, a contact column and an adjusting assembly, wherein,

the clamping jaw is used for clamping the pressure plate assembly;

the contact columns are arranged in one-to-one correspondence with the telescopic blocks and are used for pressing the telescopic blocks to separate the clamping blocks from the pressing plate assembly;

the adjusting assembly is used for adjusting the heights of the clamping jaws and the contact columns in the vertical direction and adjusting the telescopic range of the clamping jaws in the horizontal direction.

9. The auxiliary cell delivery mechanism of claim 6, wherein the compression assembly comprises a compression rod and a drive portion;

the pressing rod is used for contacting with the pressure plate assembly;

the driving part is used for driving the pressing rod to be close to or far away from the pressing plate assembly, and acting force for enabling the clamping post to be tightly abutted against the clamping block can be applied to the pressing plate assembly through the pressing rod.

10. The auxiliary battery cell conveying mechanism according to claim 8, further comprising a slide rail, wherein the slide rail is slidably connected to the clamping assembly, so that the clamping assembly can move in the horizontal direction.

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