CN214988676U - Electricity core loading attachment - Google Patents

Abstract

The utility model discloses an electric core feeding device, which comprises a conveying device, wherein the conveying device forms a conveying groove which is obliquely arranged, one side of the conveying groove is provided with a material box for stacking electric cores, and the other side of the conveying groove is provided with an electric core extracting device; the opening of the material box faces to the electric core extracting device, and the electric core extracting device is used for extracting the electric core in the material box and enabling the electric core to fall into the conveying groove. The battery core feeding device in the embodiment does not need to be provided with a conveyor belt and a driving device used for driving the conveyor belt to rotate, and the cost of the battery core feeding device is effectively reduced.

Description

Electricity core loading attachment

Technical Field

The utility model relates to an electricity core production technical field especially relates to an electricity core loading attachment.

Background

With the development of science and technology, the application of cylindrical battery cells is more and more extensive, especially the application in electric vehicles is more and more popular, and the production capacity of the battery cells is gradually increased.

Electric core loading attachment among the prior art, the manipulator need earlier with snatch anchor clamps translation to the top of workbin, make again and snatch anchor clamps descend in order to snatch electric core, then rise anchor clamps and make anchor clamps rise to the top of conveyer belt, anchor clamps descend at last in order to place electric core on the drive belt, the drive belt drives electric core and moves to the ejection of compact position of settlement in order to accomplish electric core material loading.

The prior art has following problem, and the conveyer belt must be provided with drive arrangement and just can will carry electric core, and the drive arrangement of conveyer belt has increased electric core loading attachment's cost.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an electricity core loading attachment reduces electricity core loading attachment's cost.

To achieve the purpose, the utility model adopts the following technical proposal:

a battery cell feeding device comprises a conveying device, wherein the conveying device is provided with a conveying groove which is obliquely arranged, one side of the conveying groove is provided with a material box for stacking battery cells, and the other side of the conveying groove is provided with a battery cell extracting device;

the opening of the material box faces to the electric core extracting device, and the electric core extracting device is used for extracting the electric core in the material box and enabling the electric core to fall into the conveying groove.

Optionally, the battery cell extracting device includes a driving device and an adsorption block for adsorbing the battery cell;

the driving device comprises a body fixedly connected with the conveying device and a telescopic shaft connected with the adsorption block, and the telescopic shaft is perpendicular to the conveying groove;

the other side of the conveying groove is further provided with a baffle used for blocking the battery cell, the baffle is provided with a rectangular through hole for the adsorption block to pass through, and the width of the rectangular through hole is smaller than the diameter of the battery cell.

Optionally, an installation groove parallel to the conveying groove is formed in the adsorption block, and a plurality of magnets for adsorbing the battery cell are installed in the installation groove.

Optionally, the side box wall of the material box for carrying the battery cells is parallel to the bottom of the conveying groove, and the length of the mounting groove is equal to the width of the material box;

and the adsorption block extracts a row of electric cores closest to the side box wall of the bearing electric core and sends the electric cores into the conveying groove.

Optionally, a protection plate for preventing the battery cell in the material box from falling is arranged on one side of the conveying groove, and an opening for the adsorption block and the battery cell to pass through is formed in the protection plate.

Optionally, the conveying device comprises a support plate and a pushing assembly arranged on the support plate, and the pushing assembly comprises a body fixedly connected to the support plate and a telescopic rod for pushing the battery core to roll along the conveying groove;

the pushing assembly is arranged at the higher end of the supporting plate, the telescopic rod is arranged in the conveying groove, and the telescopic rod is parallel to the conveying groove.

Optionally, the battery cell feeding device further includes a stopping device for stopping the battery cell in the conveying chute, and the stopping device includes a first cylinder fixedly connected to the support plate, a first stopping block mounted on an output shaft of the first cylinder, a second cylinder fixedly connected to the support plate, and a second stopping block mounted on an output shaft of the second cylinder;

when the first stopping block is located at a preset first stopping position, the distance between the first stopping block and the bottom of the conveying groove is smaller than the diameter of the battery core; when the second stopping block is located at a preset second stopping position, the distance between the second stopping block and the bottom of the conveying groove is smaller than the diameter of the battery core;

the distance between the preset first stopping position and the preset second stopping position is equal to the diameter of the battery cell.

Optionally, the battery cell loading device further includes a voltage detection device, and the voltage detection device includes a first detection probe, a first moving device for driving the first detection probe to abut against one end of the battery cell, a second detection probe, and a second moving device for driving the second detection probe to abut against the other end of the battery cell;

the first detection probe and the second detection probe are oppositely arranged;

when the voltage detection device detects voltage, the first gear stop block is located at a preset first gear stop position.

Optionally, the first moving device and the second moving device are both fixedly connected to the supporting plate;

the first moving device and the second moving device are both air cylinders.

Optionally, the conveying device further comprises a support bracket, the support plate is fixedly connected with the support bracket, and the bin is arranged on the support bracket.

Compared with the prior art, the utility model discloses following beneficial effect has:

in this embodiment, conveyor forms the conveyer trough that an slope set up, and electric core in the workbin can fall into to the conveyer trough after being extracted by electric core extraction element, and then electric core can roll along the conveyer trough and fall, accomplishes the transport to electric core. The battery core feeding device in the embodiment does not need to be provided with a conveyor belt and a driving device used for driving the conveyor belt to rotate, and the cost of the battery core feeding device is effectively reduced.

Drawings

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

The structure, ratio, size and the like shown in the drawings of the present specification are only used for matching with the content disclosed in the specification, so as to be known and read by people familiar with the technology, and are not used for limiting the limit conditions which can be implemented by the present invention, so that the present invention does not have the substantial significance in the technology, and any structure modification, ratio relationship change or size adjustment should still fall within the scope which can be covered by the technical content disclosed by the present invention without affecting the efficacy which can be produced by the present invention and the achievable purpose.

Fig. 1 is a schematic structural diagram of an electrical core feeding device provided in an embodiment of the present invention;

fig. 2 is a schematic structural diagram of an electrical core feeding device with a hidden protection plate according to an embodiment of the present invention;

fig. 3 is a schematic structural view of another downward-looking cell loading device provided in an embodiment of the present invention;

fig. 4 is a schematic side view of a battery cell loading device provided in an embodiment of the present invention;

fig. 5 is a schematic top view of a battery cell loading device provided in an embodiment of the present invention;

fig. 6 is a schematic sectional view taken along line a-a in fig. 5.

Illustration of the drawings: 1. a conveying device; 11. a conveying trough; 12. a support plate; 13. a pushing assembly; 14. a support bracket; 2. a material box; 21. a protection plate; 3. a battery cell extracting device; 31. a drive device; 32. an adsorption block; 33. a baffle plate; 34. a rectangular through hole; 35. a magnet; 4. a gear stop device; 41. a first cylinder; 42. a first stop block; 43. a second cylinder; 44. a second stop block; 5. a voltage detection device; 51. a first detection probe; 52. a first mobile device; 53. a second detection probe; 54. a second moving means.

Detailed Description

In order to make the objects, features and advantages of the present invention more obvious and understandable, the drawings in the embodiments of the present invention are combined below to clearly and completely describe the technical solutions in the embodiments of the present invention, and obviously, the embodiments described below are only some embodiments of the present invention, but 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 belong to the protection scope of the present invention.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on those 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 therefore should not be construed as limiting the present invention. It should be noted that when one component is referred to as being "connected" to another component, it can be directly connected to the other component or intervening components may also be present.

The technical solution of the present invention is further explained by the following embodiments with reference to the accompanying drawings.

Referring to fig. 1 to 6, an embodiment of the present invention provides an electrical core loading device, which includes a conveying device 1, wherein the conveying device 1 forms a conveying trough 11 that is obliquely arranged, a material box 2 for stacking electrical cores is arranged on one side of the conveying trough 11, and an electrical core extracting device 3 is arranged on the other side of the conveying trough 11;

the opening of the material box 2 faces the electric core extracting device 3, and the electric core extracting device 3 is used for extracting the electric core in the material box 2 and enabling the electric core to fall into the conveying groove 11.

Specifically, in the present embodiment, the cell extracting device 3 is configured to transfer the cells in the magazine 2 to the conveying trough 11, and then the cells in the conveying trough 11 roll along the conveying trough 11, so as to complete the loading of the cells. In this embodiment, need not to set up the conveyer belt and be used for driving conveyer belt pivoted drive arrangement, effectively reduced electric core loading attachment's cost.

Optionally, the cell extracting device 3 includes a driving device 31 and an adsorbing block 32 for adsorbing the cell;

the driving device 31 comprises a body fixedly connected with the conveying device 1 and a telescopic shaft connected with the adsorption block 32, and the telescopic shaft is vertical to the conveying groove 11;

the other side of the conveying trough 11 is further provided with a baffle 33 for blocking the battery cell, the baffle 33 is provided with a rectangular through hole 34 for the adsorption block 32 to pass through, and the width of the rectangular through hole 34 is smaller than the diameter of the battery cell.

Specifically, adsorb the electric core in the workbin 2 by the piece 32, drive arrangement 31 drives through the telescopic shaft and adsorbs piece 32 and remove towards the direction of keeping away from workbin 2, and at the in-process that adsorbs piece 32 and pass rectangle through-hole 34 on the baffle 33, the electric core is stopped by baffle 33 and falls into conveyer trough 11. It should be noted that, the baffle 33 is provided to stop the cell, and the adsorbing block 32 only needs to move along a straight line, and there is no need to provide an action of throwing the cell down the conveying trough 11, so as to further simplify the structure of the adsorbing block 32 and reduce the cost well.

Optionally, an installation groove parallel to the conveying groove 11 is opened in the adsorption block 32, and a plurality of magnets 35 for adsorbing the battery cell are installed in the installation groove.

Specifically, one end of the battery cell is provided with a magnetic metal material, and the magnet 35 pulls out the battery cell from the material box through magnetic attraction.

Optionally, the side box wall of the material box 2 for carrying the battery cells is parallel to the bottom of the conveying groove 11, and the length of the conveying groove is equal to the width of the material box 2;

the suction block 32 extracts the row of cells closest to the side wall of the magazine 2 carrying the cells and feeds them into the feed chute.

It should be noted that, in order to improve the loading efficiency, each action of the adsorption block 32 can extract all the cells in a row close to the side wall carrying the cells, and then the cells in the row fall into the conveying trough 11 through the blocking action of the baffle 33.

Optionally, a protection plate 21 for preventing the battery cells in the material box 2 from falling is disposed on one side of the conveying groove 11, and the protection plate 21 is provided with an opening through which the adsorption block 32 and the battery cells pass.

Specifically, the columnar cells are stacked in rows, and each row of cells is parallel to the lowest side box wall of the magazine 2. Considering that the battery cell may slide down and be damaged or even explode when the stacking height is high, the protection plate 21 for blocking the box opening of the material box 2 is arranged, the battery cell stacked in the material box 2 is blocked by the protection plate 21, the condition of falling and damage cannot occur, and the safety of the battery cell feeding device is improved.

Optionally, the conveying device 1 includes a support plate 12 and a pushing assembly 13 disposed on the support plate 12, where the pushing assembly 13 includes a body fixedly connected to the support plate 12 and a telescopic rod for pushing the battery cell to roll along the conveying chute 11;

the pushing assembly 13 is arranged at the higher end of the supporting plate 12, the telescopic rod is arranged in the conveying groove 11, and the telescopic rod is parallel to the conveying groove 11.

Alternatively, considering the case where a part of the cells may be jammed in the conveyance slot 11, the pushing assembly 13 is particularly provided. Promote subassembly 13 and promote electric core downstream in the conveyer trough 11 through the telescopic link, make the ejection of compact that electric core can be better.

Optionally, the battery cell loading device further includes a stopping device 4 for stopping the battery cell in the conveying chute 11, where the stopping device 4 includes a first cylinder 41 fixedly connected to the support plate 12, a first stopping block 42 mounted on an output shaft of the first cylinder 41, a second cylinder 43 fixedly connected to the support plate 12, and a second stopping block 44 mounted on an output shaft of the second cylinder 43;

when the first stopping block 42 is at the preset first stopping position, the distance between the first stopping block 42 and the bottom of the conveying trough 11 is smaller than the diameter of the battery core; when the second stopping block 44 is at the preset second stopping position, the distance between the second stopping block 44 and the bottom of the conveying trough 11 is smaller than the diameter of the battery cell;

the distance between the preset first stopping position and the preset second stopping position is equal to the diameter of the battery cell.

It should be noted that the presence of the blocking device 4 allows the cells to be discharged one by one. The discharging step one by one is as follows:

firstly, stopping the first stopping block 42 to a preset first stopping position, and stopping the second stopping block 44 to a preset second stopping position;

secondly, the first stopping block 42 is lifted, and at the moment, one battery cell rolls into the space between the first stopping block 42 and the second stopping block 44 and is stopped by the second stopping block 44;

and thirdly, the first stopping block 42 returns to the preset first stopping position again, and the second stopping block 44 rises to enable the battery cell between the first stopping block 42 and the second stopping block 44 to roll and discharge.

Optionally, the battery cell loading device further includes a voltage detection device 5, where the voltage detection device 5 includes a first detection probe 51, a first moving device 52 for driving the first detection probe 51 to collide with one end of the battery cell, a second detection probe 53, and a second moving device 54 for driving the second detection probe 53 to collide with the other end of the battery cell;

the first detection probe 51 and the second detection probe 53 are oppositely arranged;

when the voltage detection device 5 detects a voltage, the first stop block 42 is in the preset first stop position.

Specifically, the voltage detection device 5 detects whether the voltage of the battery cell is normal, and distinguishes the battery cell with the voltage defect, thereby preventing the battery cell with the defect from flowing into the subsequent process.

Optionally, the first moving device 52 and the second moving device 54 are both fixedly connected to the support plate 12;

the first moving device 52 and the second moving device 54 are both air cylinders.

Particularly, the cylinders on the market are of multiple types and are easy to match.

Optionally, the conveying device 1 further comprises a support frame 14, the support plate 12 is fixedly connected to the support frame 14, and the bin 2 is arranged on the support frame 14.

The above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention in its corresponding aspects.

Claims (10)

1. The battery cell feeding device is characterized by comprising a conveying device (1), wherein the conveying device (1) is provided with a conveying groove (11) which is obliquely arranged, one side of the conveying groove (11) is provided with a material box (2) for stacking battery cells, and the other side of the conveying groove (11) is provided with a battery cell extracting device (3);

the opening of the material box (2) faces the battery cell extracting device (3), and the battery cell extracting device (3) is used for extracting the battery cells in the material box (2) and enabling the battery cells to fall into the conveying groove (11).

2. The cell loading device according to claim 1, wherein the cell extraction device (3) comprises a driving device (31) and an adsorption block (32) for adsorbing the cell;

the driving device (31) comprises a body fixedly connected with the conveying device (1) and a telescopic shaft connected with the adsorption block (32), and the telescopic shaft is perpendicular to the conveying groove (11);

the other side of the conveying groove (11) is further provided with a baffle (33) used for blocking the battery cell, a rectangular through hole (34) for the adsorption block (32) to pass through is formed in the baffle (33), and the width of the rectangular through hole (34) is smaller than the diameter of the battery cell.

3. The cell loading device according to claim 2, wherein an installation groove parallel to the conveying groove (11) is formed in the adsorption block (32), and a plurality of magnets (35) for adsorbing the cells are installed in the installation groove.

4. The cell loading device according to claim 3, characterized in that the side walls of the magazine (2) for carrying cells are parallel to the bottom of the transport trough (11), the length of the mounting trough being equal to the width of the magazine (2);

and the adsorption block (32) extracts a row of electric cores closest to the side box wall bearing the electric cores and sends the electric cores into the conveying groove.

5. The cell loading device according to claim 2, wherein a protection plate (21) for preventing the cells in the material box (2) from falling is arranged on one side of the conveying groove (11), and the protection plate (21) is provided with an opening for the adsorption block (32) and the cells to pass through.

6. The cell loading device according to claim 1, wherein the conveying device (1) comprises a support plate (12) and a pushing assembly (13) arranged on the support plate (12), and the pushing assembly (13) comprises a body fixedly connected to the support plate (12) and a telescopic rod for pushing the cells to roll along the conveying chute (11);

the pushing assembly (13) is arranged at the higher end of the supporting plate (12), the telescopic rod is arranged in the conveying groove (11), and the telescopic rod is parallel to the conveying groove (11).

7. The cell loading device according to claim 6, further comprising a stopping device (4) for stopping the cell at the conveying trough (11), wherein the stopping device (4) comprises a first cylinder (41) fixedly connected with the support plate (12), a first stopping block (42) mounted on an output shaft of the first cylinder (41), a second cylinder (43) fixedly connected with the support plate (12), and a second stopping block (44) mounted on an output shaft of the second cylinder (43);

when the first stopping block (42) is located at a preset first stopping position, the distance between the first stopping block (42) and the bottom of the conveying trough (11) is smaller than the diameter of the battery core; when the second stopping block (44) is located at a preset second stopping position, the distance between the second stopping block (44) and the bottom of the conveying groove (11) is smaller than the diameter of the battery cell;

the distance between the preset first stopping position and the preset second stopping position is equal to the diameter of the battery cell.

8. The battery cell loading device according to claim 7, further comprising a voltage detection device (5), wherein the voltage detection device (5) comprises a first detection probe (51), a first moving device (52) for driving the first detection probe (51) to abut against one end of the battery cell, a second detection probe (53), and a second moving device (54) for driving the second detection probe (53) to abut against the other end of the battery cell;

the first detection probe (51) and the second detection probe (53) are oppositely arranged;

when the voltage detection device (5) detects voltage, the first gear stop block (42) is at a preset first gear stop position.

9. The cell loading device according to claim 8, wherein the first moving device (52) and the second moving device (54) are both fixedly connected to the support plate (12);

the first moving device (52) and the second moving device (54) are both air cylinders.

10. The cell loading device according to claim 6, wherein the conveying device (1) further comprises a support bracket (14), the support plate (12) is fixedly connected with the support bracket (14), and the material box (2) is arranged on the support bracket (14).

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