CN218939744U - Battery cell tooling device and battery cell conveying system - Google Patents

Abstract

The utility model discloses a battery core tooling device and a battery core conveying system, wherein the battery core tooling device is used for clamping a battery core shell and conveying the battery core shell on a flow line, the battery core shell is square, and the battery core tooling device comprises: a support plate; the clamping mechanism is used for clamping the battery cell shell; the horizontal guide assembly is arranged on the side wall of the supporting plate and used for guiding the supporting plate when the supporting plate is driven by the assembly line to move in the horizontal direction; and the lifting guide assembly is used for guiding the support plate when the support plate is driven by the assembly line to move in the vertical direction. The electric core tooling device is provided with the horizontal guide assembly to be matched with the horizontal conveying device, so that the horizontal conveying of the electric core shell in a clamping state is realized, and the manual conveying is avoided; the lifting guide assembly and the lifting mechanism are matched to control the lifting of the tool device, so that different procedures such as detection, gluing and the like are performed on the battery cell shell in different height states, product processing automation is realized, manual workload is reduced, and efficiency is improved.

Description

Battery cell tooling device and battery cell conveying system

Technical Field

The utility model relates to a battery cell tooling, in particular to a battery cell tooling device and a battery cell conveying system.

Background

Today, the competition for energy is becoming vigorous, and searching for products that replace petroleum energy has become a consensus. Among them, the great development of the battery industry will be a trend, which has wide application in industrial production, life, etc., and urban electric buses have been silently started. The battery cell is an important component unit of the battery, and the battery is formed by assembling the battery cell into a battery cell module and then packaging the battery cell module through a soft package.

With the continuous development of modern industrial technology, more and more factories adopt automatic machinery to replace manual operation, so that the labor intensity can be greatly reduced, and the processing efficiency is improved. At present, battery manufacturers also commonly adopt an automatic conveying line to produce batteries, and battery cores often need to be placed on a tooling plate to be fixed so as to be transported on the conveying line better. In the process of conveying the battery cell on the conveying line, the battery cell also needs to be subjected to detection, gluing and other working procedure operations.

The existing battery cell tooling plate is fixed on the assembly line, the tooling plate can move along with a machine and clamp the battery cell shell, and when the subsequent machine is switched, manual carrying and transferring are needed, so that the workload is large and the efficiency is low.

Disclosure of Invention

In order to overcome the disadvantages of the prior art, the present utility model aims to provide a solution to the technical problems pointed out in the background art.

The utility model is realized by the following technical measures, and the electric core tooling device is used for clamping an electric core shell for conveying, the electric core shell is square, and the electric core tooling device comprises:

a support plate for supporting;

the clamping mechanism is arranged on the surface of the supporting plate and used for clamping the battery cell shell;

the horizontal guide assembly is arranged on the side wall of the supporting plate and used for guiding the supporting plate and/or assisting the supporting plate to move horizontally when the supporting plate is driven by the assembly line to move horizontally;

and the lifting guide assembly is arranged on the upper surface and/or the lower surface of the supporting plate and is used for guiding the supporting plate and/or assisting the supporting plate to move vertically when the supporting plate is driven by the assembly line to move in the vertical direction.

As a preferable mode, a boss for placing the battery cell shell is arranged on the surface of the supporting plate, and the edge size of the boss is smaller than or equal to that of the battery cell shell.

As a preferred mode, the clamping mechanism comprises a first positioning piece used for being abutted against a first side edge of the battery cell shell and a second positioning piece used for being abutted against a second side edge of the battery cell shell, and the first side edge and the second side edge are adjacent edges; the clamping mechanism further comprises a first elastic clamping assembly and a second elastic clamping assembly, wherein the first elastic clamping assembly is arranged opposite to the first positioning piece, the second elastic clamping assembly is arranged opposite to the second positioning piece, the first elastic clamping assembly is used for being pressed on the third side edge of the battery cell shell so as to enable the first side edge of the battery cell shell to be fixed in the positioning mode of the first positioning piece, and the second elastic clamping assembly is used for being pressed on the fourth side edge of the battery cell shell so as to enable the second side edge of the battery cell shell to be fixed in the positioning mode of the second positioning piece.

As a preferable mode, the first elastic clamping assembly comprises a first mounting plate and a third positioning piece, the third positioning piece is fixedly connected with a first sliding rod which is connected with the first mounting plate in a sliding way, the first sliding rod is used for enabling the third positioning piece to move away from or close to the first mounting plate, and a spring sleeved on the first sliding rod is arranged between the first mounting plate and the third positioning piece; the second elastic clamping assembly comprises a second mounting plate and a fourth positioning piece, the fourth positioning piece is fixedly connected with a second sliding rod which is connected with the second mounting plate in a sliding mode, the first sliding rod is used for enabling the third positioning piece to move far away from or close to the first mounting plate relatively, and a spring sleeved on the first sliding rod is arranged between the first mounting plate and the third positioning piece.

As a preferred mode, the horizontal guiding assembly comprises a plurality of rolling elements uniformly arranged on the edge of the supporting plate; or, the backup pad is square, horizontal direction subassembly including set up in the rolling element in backup pad four corners.

Preferably, the lifting guide assembly comprises a plurality of guide blocks arranged on the lower surface of the supporting plate, and the guide blocks are formed with positioning depressions matched with lifting rods of the assembly line.

Preferably, the lifting guide assembly comprises a guide sleeve, and the guide sleeve is used for penetrating a guide rod to guide the vertical movement of the support plate.

As a preferred mode, the electric core tooling device further comprises a handle component which is arranged on the surface of the supporting plate and used for being held.

Preferably, the handle assembly comprises at least two handles hinged to the surface of the support plate, and each handle is uniformly distributed on the surface of the support plate.

On the other hand, still provide a electric core conveying system, carry electric core conveying system and include conveyor and any above electric core tool equipment.

According to the battery cell tooling device, the supporting plate of the battery cell tooling device is used for placing the battery cell shell, and then the side wall of the battery cell shell is positioned through the clamping mechanism so as to clamp the battery cell shell; the electric core tool device is provided with the horizontal guide assembly to be matched with the horizontal conveying devices such as the conveyor belt, the belt and the chute, so that the horizontal conveying of the electric core shell in a clamping state is realized, the manual conveying step between two machines is avoided, the efficiency is improved, and the cost is reduced; after being conveyed to the target position, the lifting guide assembly and the lifting mechanism are matched to control the lifting of the tool device, so that different procedures such as detection, gluing and the like are performed on the battery cell shell in different height states, product processing automation is realized, manual workload is reduced, and efficiency is improved.

Drawings

FIG. 1 is a schematic diagram of a first embodiment of the present utility model;

fig. 2 is a schematic structural diagram of a second embodiment of the present utility model.

1. A support plate; 11. a boss; 21. a first positioning member; 22. a second positioning member; 23. a third positioning member; 24. a fourth positioning member; 25. a first mounting plate; 26. a first slide bar; 27. a second mounting plate; 28. a second slide bar; 29. a spring; 3. a rolling member; 41. a guide block; 42. positioning the concave; 43. a guide sleeve; 5. handle assembly

Detailed Description

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

In the description of the present utility model, it should be noted that the directions or positional relationships indicated by the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

In addition, the technical features of the different embodiments of the present utility model described below may be combined with each other as long as they do not collide with each other.

As shown in fig. 1-2, a preferred embodiment of the present utility model provides a cell tooling device for clamping a cell housing and conveying the cell housing on a line, wherein the cell housing (not shown in the drawings) is square, and the cell tooling device comprises: a support plate 1 for supporting; the clamping mechanism is arranged on the surface of the supporting plate 1 and is used for clamping the battery cell shell; the horizontal guide assembly is arranged on the side wall of the support plate 1 and is used for guiding the support plate 1 and/or assisting the support plate 1 to horizontally move when the support plate 1 is driven by the assembly line to horizontally move; and the lifting guide assembly is arranged on the upper surface and/or the lower surface of the support plate 1 and is used for guiding the support plate 1 and/or assisting the support plate 1 to vertically move when the support plate 1 is driven by the assembly line to vertically move. The support plate 1 is used for placing the battery cell shell, and then the side wall of the battery cell shell is positioned through the clamping mechanism so as to clamp the battery cell shell; the electric core tool device is provided with the horizontal guide assembly to be matched with the horizontal conveying devices such as the conveyor belt, the belt and the chute, so that the horizontal conveying of the electric core shell in a clamping state is realized, the manual conveying step between two machines is avoided, the efficiency is improved, and the cost is reduced; after being conveyed to the target position, the lifting guide assembly and the lifting mechanism are matched to control the lifting of the tool device, so that different procedures such as detection, gluing and the like are performed on the battery cell shell in different height states, product processing automation is realized, manual workload is reduced, and efficiency is improved.

It can be understood that the conveying device such as a conveyor belt and a belt in this embodiment is a mature prior art (not shown in the figure), and this embodiment is not described in detail; the lifting jack mechanism (not shown in the figure) used can be a hydraulic cylinder or an air cylinder or other lifting mechanism;

further, the clamping mechanism comprises a first positioning piece 21 for being abutted against a first side edge of the battery cell shell and a second positioning piece 22 for being abutted against a second side edge of the battery cell shell, wherein the first side edge and the second side edge are adjacent edges; the clamping mechanism further comprises a first elastic clamping assembly and a second elastic clamping assembly, wherein the first elastic clamping assembly is arranged opposite to the first positioning piece 21, the second elastic clamping assembly is arranged opposite to the second positioning piece 22, the first elastic clamping assembly is used for pressing the third side of the battery cell shell so as to enable the first side of the battery cell shell to be positioned and fixed on the first positioning piece 21, the second elastic clamping assembly is used for pressing the fourth side of the battery cell shell so as to enable the second side of the battery cell shell to be positioned and fixed on the second positioning piece 22, when the battery cell shell is clamped, the first side of the battery cell shell is abutted against the first positioning piece 21, the second side of the battery cell shell is abutted against the second positioning piece 22 for initial positioning, and the battery cell shell is pressed and positioned on the first side and the second side through the first elastic clamping assembly and the second elastic clamping assembly to finish clamping, and meanwhile, the battery cell shells with different sizes can be matched in a certain range;

specifically, the first elastic clamping assembly comprises a first mounting plate 25 and a third positioning piece 23, the third positioning piece 23 is fixedly connected with a first slide bar 26 which is connected with the first mounting plate 25 in a sliding manner, the slide bar is used for enabling the third positioning piece 23 to move far away from or close to the first mounting plate 25, and a spring 29 sleeved on the first slide bar 26 is arranged between the first mounting plate 25 and the third positioning piece 23; the second elastic clamping assembly comprises a second mounting plate 27 and a fourth positioning piece 24, the fourth positioning piece 24 is fixedly connected with a second sliding rod 28 which is connected with the second mounting plate 27 in a sliding way, the second sliding rod 28 is used for enabling the fourth positioning piece 24 to move far away from or close to the second mounting plate 27, and a spring 29 sleeved on the second sliding rod 27 is arranged between the second mounting plate 27 and the fourth positioning piece 24; the third positioning piece 23 slides axially along the first slide bar 26 relative to the first mounting plate 25 through the first slide bar 26, the third positioning piece 23 keeps moving relatively far away from the first mounting plate 25 by the elastic force of a spring 29 sleeved on the first slide bar 26 so as to clamp a workpiece, and the second elastic clamping assembly is similar;

in some embodiments, the surface of the supporting plate 1 is provided with a boss 11 for placing the battery cell casing, the edge dimension of the boss 11 is smaller than or equal to the edge dimension of the battery cell casing, interference with the clamping mechanism is avoided, and meanwhile, the battery cell casing with multiple dimensions in a certain range is adapted; it can be understood that the edge dimension of the boss 11 in this embodiment is smaller than the edge dimension of the minimum specification cell case in the practical application scenario.

Furthermore, the supporting plate 1 of the embodiment is square, the horizontal guiding component comprises rolling elements 3 arranged at four corners of the supporting plate 1, the rolling elements 3 can be rollers, and when the tool device is placed on a belt or a conveyor belt, the rollers can be matched with baffles arranged at two sides of the belt or the conveyor belt to guide; on the other hand, the conveying device can also be two oppositely arranged sliding grooves arranged on the assembly line, two sides of the supporting plate 1 are respectively embedded into the two sliding grooves, and meanwhile, the rolling parts 3 are abutted against the inner walls of the sliding grooves, so that the supporting plate 1 can move in the sliding grooves along the extending direction of the sliding grooves, and an electric driving device is arranged on the rolling parts 3 or the pushing device is used for driving the supporting plate 1 to move in the horizontal direction;

in other embodiments, the rolling elements 3 may be uniformly distributed on the edge of the support plate 1.

In some embodiments, the elevation guide assembly includes a plurality of guide blocks 41 provided at the lower surface of the support plate 1, the guide blocks 41 being formed with positioning recesses 42 to be engaged with elevation rods of the production line; that is, the end parts of the lifting rods of the lifting jack mechanism in the production line can be abutted in the positioning depressions 42, the positioning depressions 42 are respectively matched with the lifting rods to radially position the lifting rods, and then the supporting plate 1 is positioned in the horizontal direction, meanwhile, the tool device can be separated from the horizontal direction conveying device and the lifting rods, so that the lifting jack mechanism can be fixedly arranged without moving along with the production line, and after the supporting plate 1 is horizontally conveyed to the target position, the lifting jack mechanism is matched with the lifting guide assembly to control the lifting and lifting height of the supporting plate 1.

Further, the lifting guide assembly comprises a guide sleeve 43 for penetrating the guide rod and guiding the vertical movement of the support plate 1, and it can be understood that when the tool device is only required to be applied to a machine with the lifting height changed, the guide rod fixedly arranged on the machine is penetrated in the guide sleeve 43, so that the positioning accuracy of the support plate 1 is improved.

Further, the battery cell tooling device further comprises a handle component 5 which is arranged on the surface of the supporting plate 1 and used for holding; the handle assembly 5 is used for being carried by an operator in a hand or by grabbing a handle by a manipulator, so that the carrying is convenient;

specifically, the handle assembly 5 includes at least two handles hinged to the surface of the support plate 1, and each handle is uniformly arranged on the surface of the support plate 1, and when the handle assembly is not required to be used, the handle assembly can rotate to be close to the surface of the support plate 1, so that interference in the working procedure is avoided.

On the other hand, the embodiment also provides a battery cell conveying system, which comprises a conveying device and the battery cell tooling device of the embodiment.

The foregoing describes a lifting structure for a wave absorbing box assembly according to the present utility model to help understand the present utility model, but the implementation of the present utility model is not limited by the foregoing examples, and any changes, modifications, substitutions, combinations, and simplifications that do not depart from the principles of the present utility model should be equivalent to the above described examples, and are included in the scope of the present utility model.

Claims (10)

1. The utility model provides a electric core tool equipment for clamping electric core casing is in order to carry on the assembly line, electric core casing is square, its characterized in that, electric core tool equipment includes:

a support plate (1) for supporting;

the clamping mechanism is arranged on the surface of the supporting plate (1) and is used for clamping the battery cell shell;

the horizontal guide assembly is arranged on the side wall of the supporting plate (1) and is used for guiding the supporting plate (1) and/or assisting the supporting plate (1) to move horizontally when the supporting plate (1) is driven by the assembly line to move horizontally;

the lifting guide assembly is arranged on the upper surface and/or the lower surface of the supporting plate (1) and is used for guiding the supporting plate (1) and/or assisting the supporting plate (1) to move vertically when the supporting plate (1) is driven by the assembly line to move vertically.

2. The cell tooling device according to claim 1, wherein a boss (11) for placing the cell housing is provided on the surface of the support plate (1), and the edge dimension of the boss (11) is smaller than or equal to the edge dimension of the cell housing.

3. The cell tooling device according to claim 2, wherein the clamping mechanism comprises a first positioning member (21) for abutting a first side of the cell housing, a second positioning member (22) for abutting a second side of the cell housing, the first side and the second side being adjacent sides; the clamping mechanism further comprises a first elastic clamping assembly and a second elastic clamping assembly, wherein the first elastic clamping assembly is arranged opposite to the first positioning piece (21) and the second elastic clamping assembly is arranged opposite to the second positioning piece (22), the first elastic clamping assembly is used for being pressed on the third side edge of the battery cell shell so as to enable the first side edge of the battery cell shell to be fixed on the first positioning piece (21), and the second elastic clamping assembly is used for being pressed on the fourth side edge of the battery cell shell so as to enable the second side edge of the battery cell shell to be fixed on the second positioning piece (22).

4. A cell tooling device according to claim 3, wherein the first elastic clamping assembly comprises a first mounting plate (25) and a third positioning piece (23), the third positioning piece (23) is fixedly connected with a first slide bar which is connected with the first mounting plate (25) in a sliding manner, the first slide bar (26) is used for enabling the third positioning piece (23) to move away from or close to the first mounting plate (25), and a spring (29) sleeved on the first slide bar (26) is arranged between the first mounting plate (25) and the third positioning piece (23); the second elastic clamping assembly comprises a second mounting plate (27) and a fourth positioning piece (24), the fourth positioning piece (24) is fixedly connected with a second sliding rod (28) which is connected with the second mounting plate (27) in a sliding mode, the second sliding rod (28) is used for enabling the fourth positioning piece (24) to move away from or close to the second mounting plate (27) relatively, and a spring (29) sleeved on the second sliding rod (28) is arranged between the second mounting plate (27) and the fourth positioning piece (24).

5. The cell tooling device according to claim 1, wherein the horizontal guiding assembly comprises a plurality of rolling elements (3) uniformly arranged on the edge of the supporting plate (1); or, the supporting plate (1) is square, and the horizontal guiding assembly comprises rolling elements (3) arranged at four corners of the supporting plate (1).

6. The cell tooling device according to claim 1, wherein the lifting guide assembly comprises a plurality of guide blocks (41) arranged on the lower surface of the supporting plate (1), and the guide blocks (41) are formed with positioning depressions (42) matched with lifting rods of the assembly line.

7. The cell tooling device according to claim 6, wherein the lifting guide assembly comprises a guide sleeve (43) for penetrating a guide rod to guide the vertical movement of the support plate (1).

8. The cell tooling device according to claim 1, further comprising a handle assembly (5) for holding provided on the surface of the support plate (1).

9. The cell tooling device according to claim 8, wherein the handle assembly (5) comprises at least two handles hinged to the surface of the support plate (1), and each handle is uniformly arranged on the surface of the support plate (1).

10. A cell delivery system, characterized in that the delivery cell delivery system comprises a delivery device and a cell tooling device according to any one of claims 1-9.

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