CN216834560U - Battery core Mylar packaging equipment - Google Patents

Abstract

The utility model provides an electric core Mylar packaging device, which comprises a conveying mechanism, a film coating mechanism, a rubberizing mechanism and a hot melting mechanism; the conveying mechanism comprises a plurality of conveying platforms which are arranged in parallel and jig mechanisms which are in reciprocating translation along the length direction of each conveying platform, each jig mechanism is provided with a positioning bearing platform, and the positioning bearing platforms are used for bearing the battery cell and the Mylar film and the side plates which are combined together; the film coating mechanism is positioned on one side of each conveying platform and is used for coating the Mylar film and the side plates on the positioning bearing platform outside the battery cell; the adhesive sticking mechanism is positioned at the downstream of the film coating mechanism and is used for sticking the free edge of the coated Mylar film to the battery cell; the hot melting mechanisms are respectively arranged at two ends of the conveying platform and are used for hot melting the Mylar films at two ends of the battery core. Electric core Mylar equipment for packing, through setting up a plurality of conveying platform to and tool mechanism can accomplish the packing to electric core through the mode of reciprocal translation, make equipment for packing's overall arrangement simpler, and be convenient for maintain.

Description

Battery core Mylar packaging equipment

Technical Field

The utility model relates to an electricity core technical field, in particular to electricity core Mylar equipment for packing.

Background

And the battery cell packaging Mylar equipment is used for packaging the Mylar film, the side plates and the battery cell. The packaging rate of the power battery affects the production efficiency of the power battery. A battery core feeding mechanism, a Mylar film feeding mechanism and a side plate feeding mechanism in the existing battery core packaging Mylar equipment respectively feed a battery core, a Mylar film and a side plate.

The Mylar film and the side plates need to be firstly combined together through a hot melting mechanism in a hot melting mode, and then the Mylar film and the battery cell are placed on a supporting platform on the turntable. The Mylar film is wrapped outside the battery cell by using a film wrapping mechanism on a rotation path of the supporting platform, then the free edge of the Mylar film is pasted with glue by using a gluing mechanism, and finally the Mylar films at two ends of the battery cell are subjected to hot melting edge sealing by using a hot melting mechanism.

However, the conventional battery cell packaging Mylar equipment is complex in structure, inconvenient to maintain, high in production cost and low in packaging efficiency.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model aims at providing an electric core Mylar equipment for packing to improve the packing efficiency of electric core, and be convenient for maintain.

In order to achieve the above purpose, the technical scheme of the utility model is realized like this:

the electric core Mylar packaging equipment comprises a conveying mechanism, a film coating mechanism, a rubberizing mechanism and a hot melting mechanism;

the conveying mechanism comprises a plurality of conveying platforms which are arranged in parallel and jig mechanisms which can reciprocate and translate along the length direction of each conveying platform due to being driven, each jig mechanism is provided with a positioning bearing table, and the positioning bearing tables are used for bearing the battery cell and the Mylar film and the side plate which are combined together;

the film coating mechanism is positioned on one side of each conveying mechanism and used for coating the Mylar films and the side plates on the positioning bearing platform outside the battery cell;

the adhesive sticking mechanism is positioned at the downstream of the film coating mechanism and is used for sticking the free edge of the coated Mylar film to the battery cell;

the hot melting mechanisms are respectively arranged at two ends of the conveying platform and used for hot melting the Mylar films at two ends of the battery core.

Further, the jig mechanisms are two jig mechanisms which are arranged on the conveying platform side by side; the film coating mechanism and the jig mechanism are arranged in a one-to-one correspondence mode.

Furthermore, the hot melting platform of the hot melting mechanism at least spans two adjacent conveying platforms.

Further, the rubberizing mechanism can be driven to perform reciprocating translation along the direction orthogonal to the conveying platform.

Furthermore, a linear driving part for driving the jig mechanism to translate is arranged on the conveying platform.

Furthermore, the battery cell Mylar packaging equipment also comprises a first feeding platform and a second feeding platform which are orthogonally arranged with the conveying platform, wherein the first feeding platform is provided with a first feeding mechanism capable of moving on the first feeding platform in a reciprocating manner, and the second feeding platform is provided with a second feeding mechanism capable of moving on the second feeding platform in a reciprocating manner; the first feeding mechanism is used for conveying the battery cell to each positioning bearing platform respectively; the second feeding mechanism is used for conveying the Mylar films and the side plates which are jointed together to each positioning bearing platform respectively.

Further, the number of the first feeding mechanism and/or the second feeding mechanism is multiple.

Furthermore, the second feeding platform is also provided with the first feeding mechanism.

Furthermore, a blanking mechanism capable of moving in a reciprocating manner is further arranged on the first feeding platform and/or the second feeding platform; the blanking mechanism is used for taking down the battery cores which are packaged on the jig mechanisms.

Further, the battery cell Mylar packaging equipment further comprises a battery cell pitch changing mechanism, a battery cell transferring mechanism and a battery cell detecting mechanism which are sequentially arranged at the downstream of the blanking mechanism; the battery cell pitch-changing mechanism is used for receiving the battery cells taken down by the blanking mechanism and driving the battery cells to rotate and move so as to enable the orientation and the distance of each battery cell to be consistent; the battery cell detection mechanism is used for detecting the battery cell; the battery cell transferring mechanism is used for conveying the battery cells on the battery cell pitch changing mechanism to the battery cell detecting mechanism.

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

electric core Mylar equipment for packing, through setting up a plurality of conveying platform to and tool mechanism can carry through the mode of reciprocal translation, and can accomplish the packing to electric core through diolame mechanism, rubberizing mechanism and hot melt mechanism, make equipment for packing's overall arrangement simpler, and be convenient for maintain, still do benefit to the packing efficiency who improves electric core simultaneously.

In addition, set up two tool mechanisms on a conveying platform, and with the diolame mechanism of tool mechanism one-to-one, do benefit to the packing efficiency that further improves electric core. The hot melting platform on the hot melting mechanism at least spans the two conveying platforms which are connected, so that the hot melting efficiency is improved. The rubberizing mechanism rubberizes the free edge of the Mylar in a reciprocating translation mode, and the utilization rate of the rubberizing mechanism is improved. The linear driving part is beneficial to driving the jig mechanism to perform reciprocating translation.

In addition, the arrangement of the first feeding mechanism and the second feeding mechanism is beneficial to conveying the battery core, the Mylar film and the side plates to each positioning bearing platform. And first feed mechanism and/or second feed mechanism are a plurality of, do benefit to and improve material loading efficiency. Also be equipped with first feed mechanism on the second material loading platform, do benefit to the material loading efficiency who improves electric core. The blanking mechanism is beneficial to taking down the packaged battery core. The electric core pitch varying mechanism, the electric core transferring mechanism and the electric core detecting mechanism can respectively vary the pitch, transfer and detect the electric core, so that the packaging quality of the electric core is improved.

Drawings

The accompanying drawings, which form a part hereof, are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the invention without undue limitation. In the drawings:

fig. 1 is the whole layout of electric core Mylar equipment for packing of the embodiment of the present invention.

Description of reference numerals:

1. a conveying platform; 2. a fixed platform; 3. a film coating mechanism; 4. a first hot-melt mechanism; 5. a first feeding platform; 6. a second feeding platform; 7. a Mylar film feeding mechanism; 8. a second hot-melting mechanism; 9. a battery core loading and transferring mechanism; 10. preparing a glue maintenance area; 11. a glue preparing mechanism; 12. a gluing mechanism; 13. a cell pitch-changing mechanism; 14. a battery cell blanking transfer mechanism; 15. a battery cell blanking transfer mechanism; 16. a battery cell detection mechanism; 17. a side plate feeding mechanism;

101. a jig mechanism;

501. a first feeding mechanism; 502. a blanking mechanism;

601. a second feeding mechanism; 602. mylar film and side plate transfer mechanisms.

Detailed Description

It should be noted that, in the present invention, the embodiments and features of the embodiments may be combined with each other without conflict.

In the description of the present invention, it should be noted that, if terms indicating orientation or positional relationship such as "upper", "lower", "inner", "back", etc. appear, they are based on the orientation or positional relationship shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the appearances of the terms first, second, etc. in this specification are not necessarily all referring to the same order, but are to be construed as referring to the same order.

The present invention will be described in detail below with reference to the accompanying drawings in conjunction with embodiments.

The embodiment relates to an electric core Mylar packaging device which is used for packaging an electric core. On the whole constitution, this electric core Mylar equipment for packing includes conveying mechanism, diolame mechanism 3, rubberizing mechanism 12 and hot melt mechanism.

Conveying mechanism includes a plurality of conveying platform 1 of parallel arrangement to and because of being ordered about and can follow the tool mechanism 101 of the reciprocal translation of each conveying platform 1's length direction, all have the location plummer on each tool mechanism 101, the location plummer is used for bearing electric core and the Mylar membrane and the curb plate that combine together. The film coating mechanism 3 is located on one side of each conveying mechanism, and the film coating mechanism 3 is used for coating the Mylar film and the side plates on the positioning bearing platform outside the battery core.

The adhesive sticking mechanism 12 is located at the downstream of the film coating mechanism 3, and the adhesive sticking mechanism 12 is used for sticking the free edge of the coated Mylar film to the battery core. The hot melting mechanisms are respectively arranged at two ends of the conveying platform 1 and are used for hot melting Mylar films at two ends of the battery core.

Based on the above general description, an exemplary layout of the battery cell Mylar packaging apparatus described in this embodiment is shown in fig. 1. Conveying platforms 1 in the conveying mechanism are four in parallel arrangement, and jig mechanisms 101 are two in parallel arrangement on the conveying platforms 1. The film coating mechanism 3 and the jig mechanism 101 are arranged in a one-to-one correspondence manner to coat the Mylar films and the side plates on the positioning bearing tables outside the battery cell respectively. For the sake of distinction, the above-mentioned heat fusing mechanisms are referred to as first heat fusing mechanisms 4, the first heat fusing mechanisms 4 are respectively two ones disposed at two ends of the conveying platforms 1, and one heat fusing platform is disposed across the end portions of two conveying platforms 1, that is, the end portions of two adjacent conveying platforms 1 correspond to one first heat fusing mechanism 4. One first hot melting mechanism 4 can be used for simultaneously carrying out hot melting on the Mylar films at the two ends of the electric core on the four jig mechanisms 101 on the two conveying platforms 1.

Of course, the number of the conveying platforms 1 can be increased or decreased adaptively according to specific use and arrangement requirements. The number of the jig mechanisms 101 on each conveying platform 1 can be set to other numbers besides two, as long as the use requirements are met.

In order to drive each jig mechanism 101 to perform reciprocating translation on the corresponding conveying platform 1, in the embodiment, a linear driving portion for driving each jig mechanism 101 to perform reciprocating translation is disposed on the conveying platform 1. During specific implementation, linear driving portion is including locating the lead screw motor on conveying platform 1, and lead screw motor's lead screw extends along conveying platform 1's length direction, and links to each other with the base transmission of tool mechanism 101. The corresponding jig mechanism 101 can be driven to perform reciprocating translation on the conveying platform 1 by changing the rotating direction of the screw rod on the screw rod motor, and the stability is better. Of course, the linear driving portion may also be other linear driving portions capable of driving the jig mechanism 101 to translate in the prior art, besides the screw motor.

The rubberizing mechanism 12 is located between the first hot melting mechanism 4 and the film coating mechanism 3, and preferably, the rubberizing mechanism 12 can be driven to perform reciprocating translation along the direction orthogonal to the conveying platform 1. As shown in fig. 1, a fixed platform 2 orthogonally arranged with the conveying platform 1 is arranged between the film coating mechanism 3 and the first hot melting mechanism 4 at one end of the film coating mechanism, and the adhesive applying mechanism 12 is in reciprocating translation along the length direction of the fixed platform 2. A screw motor is also arranged on the fixed platform 2, and the adhesive sticking mechanism 12 is arranged on the fixed platform 2 through a screw on the screw motor. Here, the reciprocating translation of the rubberizing mechanism 12 is beneficial to adhering the free edges of the Mylar films on the jig mechanisms 101 to the battery core.

In order to further improve the rubberizing efficiency of the rubberizing mechanisms 12, in this embodiment, two rubberizing mechanisms 12 are disposed on the fixed platform 2, and both the two rubberizing mechanisms 12 can move in a reciprocating manner on the fixed platform 2, so as to cooperatively rubberize the Mylar films on all the jig mechanisms 101.

Correspondingly, two glue preparation mechanisms 11 which are arranged at intervals are respectively arranged on one side of the fixed platform 2, and glue on the glue sticking mechanism 12 is supplied by the glue preparation mechanisms 11. In addition, a glue preparation maintenance area 10 is formed between two adjacent glue preparation mechanisms 11, so that the glue preparation mechanisms 11 can be maintained conveniently. The jig mechanism 101, the film coating mechanism 3, the adhesive applying mechanism 12, and the adhesive preparing mechanism 11 in this embodiment can all adopt products matured in the prior art.

In this embodiment, electric core Mylar equipment for packing still includes first feeding platform 5 and second feeding platform 6 with conveying platform 1 quadrature arrangement, is equipped with first feed mechanism 501 that can reciprocate the translation on first feeding platform 5, is equipped with second feed mechanism 601 that can reciprocate the translation on second feeding platform 6. The first feeding mechanism 501 is used for conveying the battery cells to each positioning bearing table respectively; the second feeding mechanism 601 is used for conveying the Mylar film and the side plates which are jointed together to each positioning bearing platform respectively.

As shown in fig. 1, the first loading platform 5 is located between the second loading platform 6 and the fixed platform 2. First feed mechanism 501 is for locating two on first material loading platform 5 to place electric core respectively on two location plummer on the conveying platform 1 simultaneously, and then do benefit to and improve packing efficiency.

In addition, an electric core feeding area is formed at the end between the fixing platform 2 and the first feeding platform 5, an electric core feeding transfer mechanism 9 is arranged at the electric core feeding area, and the electric core feeding transfer mechanism 9 is respectively used for conveying electric cores in the electric core feeding area to the corresponding first feeding mechanism 501. Here first feed mechanism 501 and electric core material loading transfer mechanism 9 all can adopt ripe product among the prior art, and first feed mechanism 501 has the clamping jaw that can the centre gripping electric core.

The second loading platform 6 in this embodiment is located on the other side of the first loading platform 5 relative to the fixed platform 2. In order to improve the efficiency of feeding the battery cells, in this embodiment, there are two battery cell feeding transfer mechanisms 9, and two first feeding mechanisms 501 are also disposed on one side of the second feeding platform 6 facing the first feeding platform 5. The two first feeding mechanisms 501 are a group, and each cell feeding transfer mechanism 9 is used for feeding the cells by the group of first feeding mechanisms 501. Thereby can be with the quick material loading of electricity core to each location plummer through two sets of first feed mechanism 501's cooperation.

In order to improve the loading efficiency of the Mylar film and the side plates, the second loading mechanisms 601 in this embodiment are two on the second loading platform 6. For the side facing the first feeding platform 5, the two ends of the other side of the first feeding platform 5 are respectively provided with a second hot melting mechanism 8, and a side plate feeding mechanism 17 and a Mylar film feeding mechanism 7 which are arranged adjacent to the second hot melting mechanism 8.

Wherein, curb plate feed mechanism 17 and Mylar membrane feed mechanism 7 feed curb plate and Mylar membrane respectively, and second feed mechanism 601 shifts the curb plate on the curb plate feed mechanism 17 respectively to and the Mylar membrane on the Mylar membrane feed mechanism 7 to on the second hot melt mechanism 8, thereby carry out the hot melt to curb plate and Mylar membrane through second hot melt mechanism 8, thereby combine both together. Here, the packing efficiency can be improved by two feed mechanisms.

In order to facilitate the transfer of the side plates and the Mylar film combined together to the jig mechanisms 101, a Mylar film and side plate transfer mechanism 602 capable of translating back and forth on the second feeding platform 6 is further provided on the second feeding platform 6. The Mylar film and side plate transfer mechanisms 602 are also two in number, and both can transfer the Mylar film and the side plates through the suckers, so that the Mylar film and side plates have a good use effect.

In this embodiment, the first feeding platform 5 and/or the second feeding platform 6 are/is further provided with a blanking mechanism 502 capable of moving in a reciprocating manner; the blanking mechanism 502 is used for taking down the battery cell packaged on each jig mechanism 101. As shown in fig. 1, the blanking mechanisms 502 are preferably disposed on the first feeding platform 5, where there are also two blanking mechanisms 502, so as to simultaneously blank two battery cells packaged on one conveying platform 1.

In addition, the battery core Mylar packaging device further includes a battery core pitch varying mechanism 13, a battery core transferring mechanism and a battery core detecting mechanism 16, which are sequentially arranged at the downstream of the blanking mechanism 502. Electric core displacement mechanism 13 is used for accepting the electric core of being taken off by unloading mechanism 502, and can order about electric core rotation and make the orientation and the interval of each electric core all unanimous, and electric core detection mechanism 16 is used for detecting electric core, and electric core transfer mechanism is used for carrying the electric core on electric core displacement mechanism 13 to electric core detection mechanism 16.

Specifically, as shown in fig. 1, the cell pitch varying mechanism 13 is disposed between the other ends of the first feeding platform 5 and the second feeding platform 6 relative to the cell feeding transfer mechanism 9, where the number of the cell pitch varying mechanisms 13 is two, so as to respectively vary the pitch and adjust the direction of the cells taken down by the two blanking mechanisms 502 on the first feeding platform 5 and the second feeding platform 6, thereby making the orientations of the cells consistent, and making the distance between two adjacent cells meet the preset distance.

The battery cell transferring mechanism and the battery cell detecting mechanism 16 in this embodiment are both two, so that the two battery cells can be transferred and detected at the same time, and the detection efficiency is improved. In order to facilitate the transportation of the battery cell after the pitch change adjustment to the battery cell transferring mechanism, a battery cell blanking transferring mechanism 14 is further disposed between the battery cell pitch changing mechanism 13 and the battery cell blanking transferring mechanism 15 in this embodiment.

It should be noted that the cell pitch varying mechanism 13, the cell blanking transfer mechanism 14, the cell blanking transfer mechanism 15, and the cell detection mechanism 16 in this embodiment all refer to mature products in the prior art, and are not described herein again.

When the electric core Mylar packaging equipment in this embodiment is used, first, the second feeding mechanism 601 respectively translates on the second feeding platform 6, and conveys the side plates on the side plate feeding mechanism 17 and the Mylar film on the Mylar film feeding mechanism 7 to the second hot melting mechanism 8, and the second hot melting mechanism 8 hot melts the Mylar film and the side plates to combine them together; then, the Mylar film and side plate transferring mechanism 602 conveys the combined Mylar film and side plate to the positioning bearing tables of the jig mechanisms 101 respectively by translation on the second feeding platform 6, thereby completing feeding of the Mylar film and side plate.

Tool mechanism 101 is along conveying platform 1's length direction translation, and electric core material loading transfer mechanism 9 carries electric core to first feed mechanism 501 respectively on to carry electric core to the location brace table of placing Mylar membrane and curb plate through the translation of first feed mechanism 501 on first material loading platform 5 and second material loading platform 6, thereby accomplish the material loading of electric core.

And then the jig mechanism 101 continues to translate towards the coating mechanism 3 on the conveying platform 1 until the jig mechanism translates to the coating mechanism 3 and stops, and the coating mechanism 3 respectively coats the Mylar film and the side plates on the battery cell, so that the coating of the battery cell is completed. Then, the jig mechanism 101 continues to translate backwards on the conveying platform 1, and the adhesive applying mechanism 12 translates on the fixing platform 2 in the adhesive preparing mechanism 11, so as to further wrap the electric core in place by translation, and enable the free edges of the Mylar films to wrap the electric core.

Then, the jig mechanism 101 continues to translate on the conveying platform 1 until reaching the first hot-melting mechanism 4, and the Mylar film at one end of the battery core is subjected to hot-melting edge covering through the first hot-melting mechanism 4. Then, each jig mechanism 101 translates on the conveying platform 1 in the direction until the jig mechanism translates to the first hot-melting mechanism 4 at the other end of the conveying platform 1, and the Mylar film at the other end of the battery cell is hot-melted and wrapped by the first hot-melting mechanism 4, so that the battery cell is packaged.

Next, each blanking mechanism 502 translates on the first feeding platform 5 and the second feeding platform 6, so as to take down the packaged electric core on each jig mechanism 101. The taken-down battery cell is conveyed to the battery cell pitch varying mechanism 13, and the battery cell is subjected to pitch varying and direction adjusting, so that the battery cell is consistent in orientation, and the distance between every two adjacent battery cells is consistent. The battery core blanking transfer mechanism 14 conveys the battery core on the battery core pitch varying mechanism 13 to the battery core blanking transfer mechanism 15, and then conveys the battery core to the battery core detection mechanism 16 through the battery core blanking transfer mechanism 15 to perform battery core detection. After the detection of the battery core is finished, the battery core blanking transfer mechanism 15 translates the battery core to a blanking position, so that the packaging of the battery core Mylar film is finished.

Electric core Mylar equipment for packing, through setting up a plurality of conveying platform 1 to and tool mechanism 101 can carry through the mode of reciprocal translation, and can accomplish the packing to electric core through diolame mechanism 3, rubberizing mechanism 12 and hot melt mechanism, make equipment for packing's overall arrangement simpler, and be convenient for maintain, still do benefit to the packing efficiency who improves electric core simultaneously.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. The utility model provides an electricity core Mylar equipment for packing which characterized in that:

the battery core Mylar packaging equipment comprises a conveying mechanism, a film coating mechanism (3), a rubberizing mechanism (12) and a hot melting mechanism;

the conveying mechanism comprises a plurality of conveying platforms (1) which are arranged in parallel, and jig mechanisms (101) which can reciprocate and translate along the length direction of each conveying platform (1) due to being driven, wherein each jig mechanism (101) is provided with a positioning bearing table, and the positioning bearing tables are used for bearing electric cores and combined Mylar films and side plates;

the film coating mechanism (3) is positioned on one side of each conveying mechanism, and the film coating mechanism (3) is used for coating the Mylar film and the side plates on the positioning bearing table outside the battery cell;

the adhesive sticking mechanism (12) is positioned at the downstream of the coating mechanism (3), and the adhesive sticking mechanism (12) is used for sticking the free edge of the coated Mylar film to the battery cell;

the hot melting mechanisms are respectively arranged at two ends of the conveying platform (1) and are used for hot melting the Mylar films at two ends of the battery core.

2. The electric core Mylar packaging apparatus of claim 1, wherein:

the jig mechanisms (101) are arranged on the conveying platform (1) side by side;

the film coating mechanism (3) and the jig mechanism (101) are arranged in a one-to-one correspondence manner.

3. The electric core Mylar packaging apparatus of claim 1, wherein:

the hot melting platform of the hot melting mechanism at least spans two adjacent conveying platforms (1).

4. The electric core Mylar packaging apparatus of claim 1, wherein:

the rubberizing mechanism (12) can be driven to perform reciprocating translation along the direction orthogonal to the conveying platform (1).

5. The electric core Mylar packaging apparatus of claim 1, wherein:

the conveying platform (1) is provided with a linear driving part for driving the jig mechanism (101) to perform reciprocating translation.

6. The electric core Mylar packaging apparatus of any of claims 1-5, wherein:

the battery core Mylar packaging equipment further comprises a first feeding platform (5) and a second feeding platform (6) which are orthogonally arranged with the conveying platform (1), wherein a first feeding mechanism (501) capable of performing reciprocating translation on the first feeding platform (5) is arranged on the first feeding platform (5), and a second feeding mechanism (601) capable of performing reciprocating translation on the second feeding platform (6) is arranged on the second feeding platform (6);

the first feeding mechanism (501) is used for conveying the battery cells to the positioning bearing tables respectively;

the second feeding mechanism (601) is used for conveying the Mylar films and the side plates which are jointed together to each positioning bearing platform respectively.

7. The electric core Mylar packaging apparatus of claim 6, wherein:

the number of the first feeding mechanism (501) and/or the second feeding mechanism (601) is multiple.

8. The electric core Mylar packaging apparatus of claim 6, wherein:

the second feeding platform (6) is further provided with the first feeding mechanism (501).

9. The electric core Mylar packaging apparatus of claim 6, wherein:

a blanking mechanism (502) capable of moving in a reciprocating manner is further arranged on the first feeding platform (5) and/or the second feeding platform (6);

the blanking mechanism (502) is used for taking down the battery cell packaged on each jig mechanism (101).

10. The electric core Mylar packaging apparatus of claim 9, wherein:

the battery cell Mylar packaging equipment further comprises a battery cell pitch changing mechanism (13), a battery cell transferring mechanism and a battery cell detecting mechanism (16) which are sequentially arranged at the downstream of the blanking mechanism (502);

the cell pitch-changing mechanism (13) is used for receiving the cells taken down by the blanking mechanism (502), and can drive the cells to rotate and move so that the orientation and the distance of each cell are consistent;

the cell detection mechanism (16) is used for detecting the cell;

the battery cell transferring mechanism is used for conveying the battery cells on the battery cell pitch varying mechanism (13) to the battery cell detecting mechanism (16).

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