CN205039208U - Automatic mylar packing welding machine of power battery - Google Patents

Abstract

The utility model discloses an automatic mylar packing welding machine of power battery, it contains the frame, is provided with the mylar material loading subassembly and the insulating piece material loading subassembly that are used for placing mylar film and insulating piece in the frame, still be provided with mylar insulating piece material loading manipulator in the frame, the mylar weld assembly contains the welding graduated disk, welding graduated disk top sets up and is used for mylar film and insulating piece heat -seal welding welding machine mechanism together, welding machine mechanism contains the insulating piece bonding tool, still be provided with in the frame be used for by draw mylar packing piece to the robot subassembly of packing the weld assembly on the welding graduated disk, the packing weld assembly contains and is used for packing piece parcel to electric core outside surface's hem subassembly with mylar and packs the bonding tool subassembly of piece heat -seal welding at electric core outside surface with being used for with mylar, still contain the rubberizing subassembly for mylar electricity core bottom subsides dress L type adhesive tape.

Description

The automatic Mylar of electrokinetic cell packs bonding machine

Technical field

The utility model relates to a kind of electrokinetic cell production system, especially the battery core packaging welding production of design motivation battery.

Background technology

Mylar (Mai La or step draw), its tool is a kind of tough polyester family macromolecule thing; There is extraordinary profile pattern, transparency and mechanical flexibility; The Mylar film that we often say is polyester film, very extensive in packaging industry application; For our electrokinetic cell production system, we need for battery core parcel Mylar film, if after Mylar film heat-sealing is simultaneously welded on and insulating trip forms Mylar package panel, it considerably increases insulation property and the intensity of packaging material, can carry out positiver sealing and protection to battery core; Thus, the current production process of whole electrokinetic cell needs Mylar film and insulating trip heat-sealing to be welded into Mylar package panel, and needing packing, at battery core outer surface, needs package panel to be welded on battery core outer surface; The transfer of the whole process of prior art, the processes such as the transfer of material and some location are all manually complete, and efficiency is lower, there is potential safety hazard, and especially the frequency that contacts with battery core of the hand of operator is too many, easily causes the phenomenon that product rejection rate increases.

Utility model content

Technical problem to be solved in the utility model is for above-mentioned deficiency of the prior art, there is provided the automatic Mylar of a kind of electrokinetic cell to pack bonding machine, it can the packaging completing battery core of automation, the operations such as welding, improve efficiency, reduce the contact frequency of people's hand and battery core.

In order to achieve the above object, the utility model is achieved by the following technical solutions:

The automatic Mylar of electrokinetic cell packs bonding machine, comprising frame, frame being provided with the Mylar loading assemblies for placing Mylar film and insulating trip and insulating trip loading assemblies; Described frame is also provided with for capturing Mylar film and the insulating trip Mylar insulating trip feeding manipulator to Mylar weld assembly; Described Mylar weld assembly comprises welding index dial, arranges and be used for Mylar film and insulating trip to seal the welding machine mechanism welded together above described welding index dial, and described Mylar film and insulating trip heat-sealing are welded together to form Mylar package panel; Described welding machine mechanism comprises insulating trip soldering tip;

Described frame is also provided with for by described welding index dial is drawn Mylar package panel to packaging weld assembly robot assembly; Described robot assembly also comprises for capturing the gripping cylinder of battery core to described packaging weld assembly;

Described packaging weld assembly comprise for by Mylar package panel parcel to the flanging assembly of battery core outer surface be used for the heat-sealing of Mylar package panel to be welded on the soldering tip assembly of battery core outer surface; Battery core after welding via packaging weld assembly packaging is Mylar battery core;

Also be included as the rubberizing assembly mounting L-type gummed paper bottom Mylar battery core.

Preferred implementation of the present utility model and further improvement as follows:

(1) described Mylar weld assembly comprises two welding index dials be arranged side by side, two welding index dial centers are provided with rotary slicer, described rotary slicer comprises central rotating shaft, and described two are welded index dials with described center fixture for the rotation of 180 degree, rotating shaft; The central rotating shaft of described rotary slicer is driven by rotary feeding motor and rotates; The welding machine mechanism of described Mylar weld assembly is undertaken moving along close and away from described robot assembly direction by air cylinder driven.

(2) described packaging weld assembly comprises packaging jig; Described battery core is rectangular structure, comprises top cover surface, bottom, left and right side, above and below; Described Mylar wrapping paper is placed between battery core and sacker's station by described robot assembly, and described battery core is below sacker's station one side is; The flanging assembly of described packaging weld assembly comprises for Mylar wrapping paper being covered bottom flap plate bottom battery core and bottom flap cylinder; Described flanging assembly also comprises upper hem plate and upper hem cylinder for Mylar wrapping paper being covered battery core left and right side; Described flanging assembly also comprises the lower hem cylinder for described Mylar wrapping paper being covered side compression block above battery core and the lifting of driving side compact heap;

The soldering tip assembly of described packaging weld assembly comprises for welding upper soldering tip above Mylar battery core and upper weld cylinder, for welding lower weld cylinder below Mylar battery core and lower soldering tip, for welding upper weld cylinder above Mylar battery core and upper soldering tip, for welding side weld cylinder and the side soldering tip of Mylar battery core side;

Described packaging weld assembly comprise welding mechanism and drive upper welding mechanism near and away from the coating drive motors of described bottom flap plate; Described upper welding mechanism comprises Welding head mechanism and drives the binder drive motors of upper Welding head mechanism elevating movement; Described upper Welding head mechanism comprises described upper soldering tip and upper weld cylinder; Described upper Welding head mechanism is also provided with hold-down mechanism, described hold-down mechanism comprises described side compression block and drives the lower hem cylinder of described side compression block lifting, side compression block is two, parallel with the left and right side of described battery core respectively, and two side compression block bottoms arrange the pressure strip of level.

(3) described packaging weld assembly also comprises clearing up assembly and battery core top cover is welded on the top cover weld assembly in battery core top cover surface; Described clearing up assembly comprise be arranged on the side finishing plate in direction, battery core left and right side on packaging welding bench and driving side finishing plate near and side away from battery core left and right side arrange cylinder; Described clearing up assembly also comprises the battery core top cover locating piece and battery core top cover arrangement block that are arranged on battery core top cover surface both sides; Described battery core top cover both sides of the edge are placed on battery core top cover locating piece; Described top cover weld assembly comprises described upper weld cylinder and upper plumb joint.

Further: described Mylar loading assemblies comprises Mylar magazine, the bottom surface of Mylar magazine is slidably mounted on guide rail, described Mylar magazine is provided with four Mylar location-plates for clamping Mylar film four angles, four Mylar location-plate centers arrange two pilot pins; Described Mylar film is laminated structure, it offers the positioning through hole of corresponding described pilot pin position; Described Mylar loading assemblies also comprises for driving described Mylar magazine along the charging cylinder of described guide rail movement.

Further: described insulating trip loading assemblies comprises insulating trip magazine, the basal sliding of insulating trip magazine is arranged on slide rail, insulating trip magazine is arranged two notches insulating trip location notch in opposite directions, and the two ends of insulating trip are positioned at described insulating trip location notch; Described insulating trip loading assemblies also comprises for driving described insulating trip magazine along the insulating trip charging cylinder of described slide rail movement; Described insulating trip is discussed assembly and is also comprised the spacing regulating part of charging for controlling described insulating trip magazine mobile displacement.

Further: described Mylar insulating trip feeding manipulator comprises feeding sucker, feeding sucker and feeding drive motors composition Z-direction travel mechanism, described feeding sucker is driven by feeding drive motors and moves along bracket height direction; Described Z-direction travel mechanism is driven by pan drive motor and moves along close and away from Mylar weld assembly direction.

Further: described robot assembly comprises picking up assembly and drives the feeding robot of picking up assembly movement, the rotary components that described feeding robot comprises lifting assembly and drives lifting assembly to swing;

Described picking up assembly comprises the Mylar sucker for drawing Mylar film and insulating trip, arranges the gripping gap being used for gripping battery core above Mylar sucker, and described gripping gap increases gap value by gripping air cylinder driven or reduces gap value; Both sides, described gripping gap arrange top cover positioning cylinder for spacing battery core top cover surface and bottom and bottom positioning cylinder respectively.

(4) described rubberizing assembly comprises and puts film for what place gummed paper, and described gummed paper is adsorbed by suction offset plate via after gummed paper pressure strip; Described rubberizing assembly also comprises cuts glue blade for what cut gummed paper; Described rubberizing assembly also comprises the binder cylinder for compressing Mylar battery core, being the rubberizing platform for placing Mylar battery core, described rubberizing platform being provided with the arrangement cylinder for adjusting Mylar battery core position below described binder cylinder; Described rubberizing assembly also comprise for drive inhale offset plate near and away from the rubberizing cylinder bottom Mylar battery core; Described film, cuts glue blade and rubberizing cylinder is arranged on rubberizing support, and described rubberizing assembly also comprises the described rubberizing support of driving along the gummed paper flat-removing air cyclinder being parallel to the direction movement of Mylar battery core base plane.

The beneficial effects of the utility model are:

The utility model, when the production for electrokinetic cell, adopts full automatic production process:

One, Mylar loading assemblies is got the raw materials ready:

1, Mylar film is put into Mylar magazine, by Mylar location-plate and pilot pin, Mylar film is located;

2, by charging cylinder, Mylar magazine is delivered to wait feeding position again.

Two, insulating trip loading assemblies is got the raw materials ready:

1, place insulating trip to insulating trip magazine, by insulating trip location notch, insulating trip is located;

2, by charging cylinder, insulating trip magazine is delivered to wait feeding position again, feeding position precision is regulated by charging cylinder and the spacing regulating part of charging.

Three, Mylar insulating trip feeding manipulator action:

1, Mylar and insulating trip are drawn by feeding sucker respectively, are promoted by feeding drive motors, then move on on Mylar welding index dial by pan drive motor;

Four, Mylar weld assembly welding Mylar film and insulating trip:

1, respectively Mylar and insulating trip are moved on to Mylar by Mylar insulating trip feeding manipulator to weld on index dial, then rotated by rotary feeding motor driving rotary slicer, Mylar and insulating trip are delivered to welding position;

2, by flat-removing air cyclinder, welding machine mechanism is delivered to welding position, then by binder cylinder, Mylar and insulating trip are compressed;

3, promote insulating trip soldering tip by weld cylinder to weld.

Five, Mylar package panel and battery core are delivered to packaging weld assembly by robot assembly:

1, weld on index dial at Mylar, by Mylar sucker, Mylar is held, by feeding robot, Mylar is put into packaging welding position;

2, material level in battery core, locates by bottom the positioning cylinder of bottom, then is located by top cover positioning cylinder top, has good positioning and captures battery core by gripping cylinder again;

3, by feeding robot, battery core is delivered to packaging welding position again.

Six, pack weld assembly and carry out packaging welding:

1, put Mylar and battery core well, by ceiling hold locating piece by spacing for battery core top cover, arrange block by ceiling hold and battery core top cover is arranged, then put battery core in order through side finishing plate;

2, after battery core is had good positioning, drive upper welding mechanism to advance by coating drive motors, then drive upper Welding head mechanism to decline by binder drive motors, by the action of bottom flap cylinder, drive bottom flap plate to pack bottom battery core;

3, drive upper hem plate up to be packed battery core both sides by the action of upper hem cylinder again, then drive upper soldering tip down to be packed battery core both sides by the action of lower hem cylinder;

4, after having packed, by upper weld cylinder, lower weld cylinder, side weld cylinder action, welds up and down to battery core respectively;

Seven, rubberizing assembly is rubberizing bottom battery core:

1, putting gummed paper to putting on film, by the action of doubling cylinder, clamping gummed paper, gummed paper is pulled out;

2, by the action of gummed paper pressure strip, compress gummed paper, by suction offset plate, gummed paper is held, then by cutting glue blade, gummed paper is cut off;

3, by the action of binder cylinder, battery core is compressed, then put battery core in order by the action of arrangement cylinder;

4, again by the action of rubberizing cylinder, gummed paper is taken out, by the action of gummed paper flat-removing air cyclinder, gummed paper is delivered to rubberizing position, then action rubberizing cylinder, gummed paper is attached to bottom battery core.

Above-mentioned course of work automation is carried out, and efficiency is high, avoids the direct contact of operator to battery core, has packed the quality of production; The arrangement of each action component of whole device is compact, and transmitting procedure relies on robot to carry out, and improves speed, have compressed taking up room of equipment.

Accompanying drawing explanation

Fig. 1 is the overall structure schematic diagram of a kind of embodiment of the present utility model;

Fig. 2 is the structural representation of a kind of embodiment of Mylar loading assemblies of the present utility model;

Fig. 3 is the structural representation of a kind of embodiment of insulating trip loading assemblies of the present utility model;

Fig. 4 is the structural representation of a kind of embodiment of Mylar insulating trip feeding manipulator of the present utility model;

Fig. 5 is the structural representation of a kind of embodiment of Mylar weld assembly of the present utility model;

Fig. 6 is the structural representation of a kind of embodiment of robot assembly of the present utility model;

Fig. 7 is the structural representation of a kind of embodiment of packaging weld assembly of the present utility model;

Fig. 8 is the structural representation of a kind of embodiment of rubberizing assembly of the present utility model.

Description of reference numerals:

1-Mylar loading assemblies, 2-insulating trip loading assemblies, 3-Mylar weld assembly, 4-Mylar insulating trip feeding manipulator, 5-robot assembly, 6-packs weld assembly, 7-rubberizing assembly;

11-charging cylinder, 12-Mylar location-plate, 13-pilot pin, 14-Mylar magazine;

21-insulating trip location notch, 22-insulating trip charging cylinder, the spacing regulating part of 23-charging, 24-insulating trip magazine;

31-flat-removing air cyclinder, 32-rotary feeding motor, 33-rotates separator, 34-weld cylinder, 35-binder cylinder, 36-insulating trip soldering tip, 37-welding machine mechanism, and 38-welds index dial;

41-pan drive motor, 42-feeding drive motors, 43-feeding sucker;

51-top cover positioning cylinder, 52-gripping cylinder, positioning cylinder bottom 53-, 54-feeding robot, 55-Mylar sucker;

71-puts film, 72-gummed paper flat-removing air cyclinder, 73-rubberizing cylinder, and 74-cuts glue blade, 75-binder cylinder, and 76-arranges cylinder, 77-doubling cylinder, 78-gummed paper pressure strip, and 79-inhales offset plate;

601-binder drive motors, 602-lower hem cylinder, the upper weld cylinder of 603-, 604-side compression block, 605-coating drive motors, 606-side arranges cylinder, weld cylinder under 607-, and 608-rolls over bottomed cylinder, 609-side weld cylinder, 610-bottom flap plate, 611-upper hem plate, 612-side soldering tip, 613-battery core top cover locating piece, the upper soldering tip of 614-, 615-side finishing plate, 616-upper hem cylinder, 617-battery core top cover arranges block, the upper welding mechanism of 618-, the upper Welding head mechanism of 619-, 620-bottom flap cylinder.

Embodiment

Below in conjunction with drawings and Examples, the utility model embodiment is described:

As shown in Fig. 1 ~ 8, it illustrates embodiment of the present utility model, as shown in the figure, the automatic Mylar of electrokinetic cell packs bonding machine, comprising frame, frame being provided with the Mylar loading assemblies 1 for placing Mylar film and insulating trip and insulating trip loading assemblies 2; Described frame is also provided with for capturing Mylar film and the insulating trip Mylar insulating trip feeding manipulator 4 to Mylar weld assembly; Described Mylar weld assembly comprises welding index dial 38, arranges and be used for Mylar film and insulating trip to seal the welding machine mechanism 37 welded together above described welding index dial, and described Mylar film and insulating trip heat-sealing are welded together to form Mylar package panel; Described welding machine mechanism comprises insulating trip soldering tip 36; We adopt feeding manipulator to complete the crawl respectively of Mylar and insulating trip in the present embodiment, and capture efficiency high, precision is high, takes up space very little; Compare the transmission equipments such as transport tape, its advantage clearly;

As shown in the figure, described frame is also provided with for by described welding index dial is drawn Mylar package panel to packaging weld assembly robot assembly 5; Described robot assembly also comprises for capturing the gripping cylinder 52 of battery core to described packaging weld assembly; Battery core and Mylar package panel are delivered to packaging weld assembly 6 by robot assembly by us, achieve equally and accurately transmit efficiently, space is very little, the structure of the transference material of our design is used in this bonding machine and can greatly reduces taking up room of bonding machine, enhances productivity and the quality of production;

As shown in the figure, described packaging weld assembly comprise for by Mylar package panel parcel to the flanging assembly of battery core outer surface be used for the heat-sealing of Mylar package panel to be welded on the soldering tip assembly of battery core outer surface; Battery core after welding via packaging weld assembly packaging is Mylar battery core; Packaging weld assembly achieves the flanging of automation, and arrange and welding function, automation is carried out, and avoids the direct contact of operator;

As shown in the figure, the rubberizing assembly 7 mounting L-type gummed paper bottom Mylar battery core is also included as; Rubberizing assembly is set, can automation carry out rubberizing bottom battery core, improve the intensity of battery core, make battery core globality better effects if.

As shown in the figure, in some preferred embodiments: described Mylar weld assembly comprises two welding index dials be arranged side by side, two welding index dial centers are provided with rotary slicer 33, described rotary slicer comprises central rotating shaft, and described two are welded index dials with described center fixture for the rotation of 180 degree, rotating shaft; The central rotating shaft of described rotary slicer is driven by rotary feeding motor 32 and rotates; The welding machine mechanism of described Mylar weld assembly is undertaken moving along close and away from described robot assembly direction by air cylinder driven.

Mylar weld assembly is for welding Mylar film and insulating trip:

1, respectively Mylar and insulating trip are moved on to Mylar by Mylar insulating trip feeding manipulator to weld on index dial, then rotated by rotary feeding motor driving rotary slicer, Mylar and insulating trip are delivered to welding position;

2, by flat-removing air cyclinder, welding machine mechanism is delivered to welding position, then by binder cylinder, Mylar and insulating trip are compressed;

3, promote insulating trip soldering tip by weld cylinder to weld.

We achieve a welding function of getting the raw materials ready by the rotational structure design of two welding index dials, substantially increase efficiency.

As shown in the figure, in some preferred embodiments: described packaging weld assembly comprises packaging jig; Described battery core is rectangular structure, comprises top cover surface, bottom, left and right side, above and below; Described Mylar wrapping paper is placed between battery core and sacker's station by described robot assembly, and described battery core is below sacker's station one side is; The flanging assembly of described packaging weld assembly comprises for Mylar wrapping paper being covered bottom flap plate 610 bottom battery core and bottom flap cylinder 620; Described flanging assembly also comprises upper hem plate 611 and upper hem cylinder 616 for Mylar wrapping paper being covered battery core left and right side; Described flanging assembly also comprises the lower hem cylinder 602 for described Mylar wrapping paper being covered side compression block 604 above battery core and the lifting of driving side compact heap;

As shown in the figure, the soldering tip assembly of described packaging weld assembly comprises for welding upper soldering tip 614 above Mylar battery core and upper weld cylinder 603, for welding lower weld cylinder 607 below Mylar battery core and lower soldering tip (not shown), for welding upper weld cylinder 603 above Mylar battery core and upper soldering tip 614, for welding side weld cylinder 609 and the side soldering tip 612 of Mylar battery core side;

As shown in the figure, described packaging weld assembly comprise welding mechanism 618 and drive upper welding mechanism near and away from the coating drive motors 605 of described bottom flap plate; Described upper welding mechanism comprises Welding head mechanism and drives the binder drive motors 601 of upper Welding head mechanism elevating movement; Described upper Welding head mechanism comprises described upper soldering tip and upper weld cylinder; Described upper Welding head mechanism is also provided with hold-down mechanism, described hold-down mechanism comprises described side compression block and drives the lower hem cylinder of described side compression block lifting, side compression block is two, parallel with the left and right side of described battery core respectively, and two side compression block bottoms arrange the pressure strip of level.

As shown in the figure, as the further improvement of above preferred embodiment: described packaging weld assembly also comprises clearing up assembly and battery core top cover is welded on the top cover weld assembly in battery core top cover surface; Described clearing up assembly comprise be arranged on the side finishing plate 615 in direction, battery core left and right side on packaging welding bench and driving side finishing plate near and side away from battery core left and right side arrange cylinder 606; Described clearing up assembly also comprises the battery core top cover locating piece 613 and battery core top cover arrangement block 617 that are arranged on battery core top cover surface both sides; Described battery core top cover both sides of the edge are placed on battery core top cover locating piece; Described top cover weld assembly comprises described upper weld cylinder and upper plumb joint.

When the packaging weld assembly of above-described embodiment carries out packaging welding:

1, put Mylar and battery core well, by ceiling hold locating piece by spacing for battery core top cover, arrange block by ceiling hold and battery core top cover is arranged, then put battery core in order through side finishing plate;

2, after battery core is had good positioning, drive upper welding mechanism to advance by coating drive motors, then drive upper Welding head mechanism to decline by binder drive motors, by the action of bottom flap cylinder, drive bottom flap plate to pack bottom battery core;

3, drive upper hem plate up to be packed battery core both sides by the action of upper hem cylinder again, then drive upper soldering tip down to be packed battery core both sides by the action of lower hem cylinder;

4, after having packed, by upper weld cylinder, lower weld cylinder, side weld cylinder action, welds up and down to battery core respectively;

As shown in the figure, in some preferred embodiments: described Mylar loading assemblies comprises Mylar magazine 14, the bottom surface of Mylar magazine is slidably mounted on guide rail, four Mylar location-plates, 12, four the Mylar location-plate centers described Mylar magazine is provided with for clamping Mylar film four angles arrange two pilot pins 13; Described Mylar film is laminated structure, it offers the positioning through hole of corresponding described pilot pin position; Described Mylar loading assemblies also comprises for driving described Mylar magazine along the charging cylinder 11 of described guide rail movement.

We are got the raw materials ready by the Mylar loading assemblies of above-described embodiment:

1, Mylar film is put into Mylar magazine, by Mylar location-plate and pilot pin, Mylar film is located;

2, by charging cylinder, Mylar magazine is delivered to wait feeding position again.

Due to Mylar thin film standby reliable location and position limiting structure, therefore its follow-up crawl process also accurate quick more.

As shown in the figure, in some preferred embodiments: described insulating trip loading assemblies comprises insulating trip magazine 24, the basal sliding of insulating trip magazine is arranged on slide rail, insulating trip magazine is arranged two notches insulating trip location notch 21 in opposite directions, and the two ends of insulating trip are positioned at described insulating trip location notch; Described insulating trip loading assemblies also comprises for driving described insulating trip magazine along the insulating trip charging cylinder 22 of described slide rail movement; Described insulating trip is discussed assembly and is also comprised the spacing regulating part 23 of charging for controlling described insulating trip magazine mobile displacement.

We are got the raw materials ready by above-mentioned insulating trip loading assemblies:

1, place insulating trip to insulating trip magazine, by insulating trip location notch, insulating trip is located;

2, by charging cylinder, insulating trip magazine is delivered to wait feeding position again, feeding position precision is regulated by charging cylinder and the spacing regulating part of charging.

As shown in the figure, in some preferred embodiments: described Mylar insulating trip feeding manipulator comprises feeding sucker 43, feeding sucker and feeding drive motors 42 form Z-direction travel mechanism, and described feeding sucker is driven by feeding drive motors and moves along bracket height direction; Described Z-direction travel mechanism is driven by pan drive motor 41 and moves along close and away from Mylar weld assembly direction.

When the Mylar insulating trip feeding manipulator of above-described embodiment works: Mylar and insulating trip are drawn by feeding sucker respectively, are promoted by feeding drive motors, then move on on Mylar welding index dial by pan drive motor; On sucker, we can uniform multiple suction nozzle, ensure to draw steadily and reliability.

As shown in the figure, in some preferred embodiments: described robot assembly comprises picking up assembly and drives the feeding robot 54 of picking up assembly movement, the rotary components that described feeding robot comprises lifting assembly and drives lifting assembly to swing;

Described picking up assembly comprises the gripping gap arranging above Mylar sucker 55, the Mylar sucker for drawing Mylar film and insulating trip and be used for gripping battery core, and described gripping gap is driven by gripping cylinder 52 and increases gap value or reduce gap value; Both sides, described gripping gap arrange top cover positioning cylinder 51 for spacing battery core top cover surface and bottom and bottom positioning cylinder 53 respectively.

Mylar package panel and battery core are delivered to packaging weld assembly by the robot assembly in above-described embodiment by us:

1, weld on index dial at Mylar, by Mylar sucker, Mylar is held, by feeding robot, Mylar is put into packaging welding position;

2, material level in battery core, locates by bottom the positioning cylinder of bottom, then is located by top cover positioning cylinder top, has good positioning and captures battery core by gripping cylinder again;

3, by feeding robot, battery core is delivered to packaging welding position again.

Because robot assembly adopts the transfer process of swing and the absorption put procedure of lifting picking up assembly, its transfer process is very reliable, and overall structure takes up room less, can by setting compacter for other assemblies.

As shown in the figure, in some preferred embodiments: described rubberizing assembly comprises puts film 71 for what place gummed paper, and described gummed paper is adsorbed by suction offset plate via after gummed paper pressure strip 78; Described rubberizing assembly also comprises cuts glue blade 74 for what cut gummed paper; Described rubberizing assembly also comprises the binder cylinder 75 for compressing Mylar battery core, being the rubberizing platform for placing Mylar battery core, described rubberizing platform being provided with the arrangement cylinder 76 for adjusting Mylar battery core position below described binder cylinder; Described rubberizing assembly also comprise for drive inhale offset plate near and away from the rubberizing cylinder 73 bottom Mylar battery core; Described film, cuts glue blade and rubberizing cylinder is arranged on rubberizing support, and described rubberizing assembly also comprises the described rubberizing support of driving along the gummed paper flat-removing air cyclinder 72 being parallel to the direction movement of Mylar battery core base plane.

We are rubberizing bottom battery core by the rubberizing assembly in above-described embodiment:

1, putting gummed paper to putting on film, by the action of doubling cylinder, clamping gummed paper, gummed paper is pulled out;

2, by the action of gummed paper pressure strip, compress gummed paper, by suction offset plate, gummed paper is held, then by cutting glue blade, gummed paper is cut off;

3, by the action of binder cylinder, battery core is compressed, then put battery core in order by the action of arrangement cylinder;

4, again by the action of rubberizing cylinder, gummed paper is taken out, by the action of gummed paper flat-removing air cyclinder, gummed paper is delivered to rubberizing position, then action rubberizing cylinder, gummed paper is attached to bottom battery core.

Its gluing structure automatically carries out, and efficiency is high, avoids the direct contact to battery core equally.

By reference to the accompanying drawings the utility model preferred implementation is explained in detail above; but the utility model is not limited to above-mentioned execution mode; in the ken that those of ordinary skill in the art possess; can also make a variety of changes under the prerequisite not departing from the utility model aim; these changes relate to correlation technique well-known to those skilled in the art, and these all fall into the protection range of the utility model patent.

Do not depart from design of the present utility model and scope can make many other and change and remodeling.Should be appreciated that the utility model is not limited to specific execution mode, scope of the present utility model is defined by the following claims.

Claims (9)

1. the automatic Mylar of electrokinetic cell packs bonding machine, it is characterized in that: comprise frame, frame being provided with the Mylar loading assemblies for placing Mylar film and insulating trip and insulating trip loading assemblies; Described frame is also provided with for capturing Mylar film and the insulating trip Mylar insulating trip feeding manipulator to Mylar weld assembly; Described Mylar weld assembly comprises welding index dial, arranges and be used for Mylar film and insulating trip to seal the welding machine mechanism welded together above described welding index dial, and described Mylar film and insulating trip heat-sealing are welded together to form Mylar package panel; Described welding machine mechanism comprises insulating trip soldering tip;

Described frame is also provided with for by described welding index dial is drawn Mylar package panel to packaging weld assembly robot assembly; Described robot assembly also comprises for capturing the gripping cylinder of battery core to described packaging weld assembly;

Described packaging weld assembly comprise for by Mylar package panel parcel to the flanging assembly of battery core outer surface be used for the heat-sealing of Mylar package panel to be welded on the soldering tip assembly of battery core outer surface; Battery core after welding via packaging weld assembly packaging is Mylar battery core;

Also be included as the rubberizing assembly mounting L-type gummed paper bottom Mylar battery core.

2. the automatic Mylar of electrokinetic cell as claimed in claim 1 packs bonding machine, it is characterized in that: described Mylar weld assembly comprises two welding index dials be arranged side by side, two welding index dial centers are provided with rotary slicer, described rotary slicer comprises central rotating shaft, and described two are welded index dials with described center fixture for the rotation of 180 degree, rotating shaft; The central rotating shaft of described rotary slicer is driven by rotary feeding motor and rotates; The welding machine mechanism of described Mylar weld assembly is undertaken moving along close and away from described robot assembly direction by air cylinder driven.

3. the automatic Mylar of electrokinetic cell as claimed in claim 2 packs bonding machine, it is characterized in that: described packaging weld assembly comprises packaging jig; Described battery core is rectangular structure, comprises top cover surface, bottom, left and right side, above and below; Described Mylar wrapping paper is placed between battery core and sacker's station by described robot assembly, and described battery core is below sacker's station one side is; The flanging assembly of described packaging weld assembly comprises for Mylar wrapping paper being covered bottom flap plate bottom battery core and bottom flap cylinder; Described flanging assembly also comprises upper hem plate and upper hem cylinder for Mylar wrapping paper being covered battery core left and right side; Described flanging assembly also comprises the lower hem cylinder for described Mylar wrapping paper being covered side compression block above battery core and the lifting of driving side compact heap;

The soldering tip assembly of described packaging weld assembly comprises for welding upper soldering tip above Mylar battery core and upper weld cylinder, for welding lower weld cylinder below Mylar battery core and lower soldering tip, for welding upper weld cylinder above Mylar battery core and upper soldering tip, for welding side weld cylinder and the side soldering tip of Mylar battery core side;

Described packaging weld assembly comprise welding mechanism and drive upper welding mechanism near and away from the coating drive motors of described bottom flap plate; Described upper welding mechanism comprises Welding head mechanism and drives the binder drive motors of upper Welding head mechanism elevating movement; Described upper Welding head mechanism comprises described upper soldering tip and upper weld cylinder; Described upper Welding head mechanism is also provided with hold-down mechanism, described hold-down mechanism comprises described side compression block and drives the lower hem cylinder of described side compression block lifting, side compression block is two, parallel with the left and right side of described battery core respectively, and two side compression block bottoms arrange the pressure strip of level.

4. the automatic Mylar of the electrokinetic cell as described in as arbitrary in claim 3 packs bonding machine, it is characterized in that: described packaging weld assembly also comprises clearing up assembly and battery core top cover is welded on the top cover weld assembly in battery core top cover surface; Described clearing up assembly comprise be arranged on the side finishing plate in direction, battery core left and right side on packaging welding bench and driving side finishing plate near and side away from battery core left and right side arrange cylinder; Described clearing up assembly also comprises the battery core top cover locating piece and battery core top cover arrangement block that are arranged on battery core top cover surface both sides; Described battery core top cover both sides of the edge are placed on battery core top cover locating piece; Described top cover weld assembly comprises described upper weld cylinder and upper plumb joint.

5. the automatic Mylar of electrokinetic cell as claimed in claim 4 packs bonding machine, it is characterized in that: described Mylar loading assemblies comprises Mylar magazine, the bottom surface of Mylar magazine is slidably mounted on guide rail, described Mylar magazine is provided with four Mylar location-plates for clamping Mylar film four angles, four Mylar location-plate centers arrange two pilot pins; Described Mylar film is laminated structure, it offers the positioning through hole of corresponding described pilot pin position; Described Mylar loading assemblies also comprises for driving described Mylar magazine along the charging cylinder of described guide rail movement.

6. the automatic Mylar of electrokinetic cell as claimed in claim 4 packs bonding machine, it is characterized in that: described insulating trip loading assemblies comprises insulating trip magazine, the basal sliding of insulating trip magazine is arranged on slide rail, insulating trip magazine is arranged two notches insulating trip location notch in opposite directions, the two ends of insulating trip are positioned at described insulating trip location notch; Described insulating trip loading assemblies also comprises for driving described insulating trip magazine along the insulating trip charging cylinder of described slide rail movement; Described insulating trip is discussed assembly and is also comprised the spacing regulating part of charging for controlling described insulating trip magazine mobile displacement.

7. the automatic Mylar of electrokinetic cell as claimed in claim 4 packs bonding machine, it is characterized in that: described Mylar insulating trip feeding manipulator comprises feeding sucker, feeding sucker and feeding drive motors composition Z-direction travel mechanism, described feeding sucker is driven by feeding drive motors and moves along bracket height direction; Described Z-direction travel mechanism is driven by pan drive motor and moves along close and away from Mylar weld assembly direction.

8. the automatic Mylar of electrokinetic cell as claimed in claim 4 packs bonding machine, it is characterized in that: described robot assembly comprises picking up assembly and drives the feeding robot of picking up assembly movement, the rotary components that described feeding robot comprises lifting assembly and drives lifting assembly to swing;

Described picking up assembly comprises the Mylar sucker for drawing Mylar film and insulating trip, arranges the gripping gap being used for gripping battery core above Mylar sucker, and described gripping gap increases gap value by gripping air cylinder driven or reduces gap value; Both sides, described gripping gap arrange top cover positioning cylinder for spacing battery core top cover surface and bottom and bottom positioning cylinder respectively.

9. the automatic Mylar of the electrokinetic cell as described in as arbitrary in claim 1 ~ 8 packs bonding machine, it is characterized in that: described rubberizing assembly comprises puts film for what place gummed paper, and described gummed paper is adsorbed by suction offset plate via after gummed paper pressure strip; Described rubberizing assembly also comprises cuts glue blade for what cut gummed paper; Described rubberizing assembly also comprises the binder cylinder for compressing Mylar battery core, being the rubberizing platform for placing Mylar battery core, described rubberizing platform being provided with the arrangement cylinder for adjusting Mylar battery core position below described binder cylinder; Described rubberizing assembly also comprise for drive inhale offset plate near and away from the rubberizing cylinder bottom Mylar battery core; Described film, cuts glue blade and rubberizing cylinder is arranged on rubberizing support, and described rubberizing assembly also comprises the described rubberizing support of driving along the gummed paper flat-removing air cyclinder being parallel to the direction movement of Mylar battery core base plane.