CN118160991A - Atomizing core equipment - Google Patents

Abstract

The application discloses atomization core assembly equipment. According to the application, a plurality of forming jigs are arranged on the turntable through the rotation of the turntable, the oil-guiding cotton feeding level, the heating net material level, the net cotton forming position and the bracket assembly position are sequentially passed through, the oil-guiding cotton feeding module, the heating net supply module, the net cotton forming module and the bracket supply module are arranged on the outer side of the turntable, and the pin fixing seat assembly module for assembling pins is arranged behind the bracket supply module, so that each module is arranged by taking the turntable as the center, the atomization core assembly equipment is reasonable in layout, and can realize the automatic assembly of all components of the atomization core.

Description

Atomizing core equipment

Technical Field

The application relates to the technical field of atomization core assembly, in particular to atomization core assembly equipment.

Background

The atomizing core is the core component of atomizer, and its effect is used for heating atomized liquid (tobacco tar, tobacco juice) so that atomized liquid is heated atomizing and for the user to inhale.

The atomizing cores are generally classified into cotton core atomizing cores and ceramic core atomizing cores. For cotton core atomizing core, generally include support, lead oily cotton, heating wire and pin fixing base. Wherein, the support is open structure, and this opening is used for leading oily cotton closed end to wear out the support. Therefore, based on the bracket structure, when the existing atomization core is automatically assembled, the oil guide cotton in an unfolded state is normally paved on the forming jig in a vertical direction; then the heating net is flatly paved on the oil guiding cotton in the unfolding state along the vertical direction; then, pressing the shaping rod from one side of the heating net to one side of the oil guiding cotton until the heating net and the oil guiding cotton are pressed into a shaping groove of the shaping jig together and shaped to an annular structure; then, the heating net and the oil guide cotton with the annular structures comprising the shaping bars are inserted into the bracket with the open structure; and finally, cutting the redundant oil guide cotton extending out of the bracket, thereby completing the assembly of the atomization core of the open bracket structure.

This automatic equipment of atomizing core does not realize the assembly of pin fixing base, and consequently degree of automation is lower, and leads oily cotton and the net that generates heat all is tiling in vertical direction and set up, consequently, the positioning accuracy requirement to leading oily cotton and the net that generates heat is higher, is unfavorable for the high-efficient equipment of atomizing core.

Disclosure of Invention

The application mainly aims to provide atomization core assembling equipment so as to solve the problem of low assembling efficiency of the existing atomization core assembling equipment.

The application provides an atomizing core assembly device, comprising:

the turntable is rotatably arranged on the workbench along the rotation center;

The device comprises a rotary table, a plurality of forming jigs, a plurality of heating net material levels, a plurality of net cotton forming positions and a bracket assembly position, wherein the rotary table is provided with a plurality of forming jigs, the forming jigs are arranged on the rotary table at the same angle with the rotary center at intervals, each forming jig is provided with a placing groove and a forming groove, the forming groove is positioned below the placing groove, and the rotary table rotates to drive each forming jig to sequentially pass through the oil guide cotton material level, the heating net material level, the net cotton forming positions and the bracket assembly position;

the oil guide cotton feeding module is arranged on the outer side of the turntable and corresponds to the oil guide cotton feeding level, and is used for horizontally spreading the oil guide cotton in the placing groove;

The heating net supply module is arranged on the outer side of the turntable and positioned behind the oil-guiding cotton feeding module, corresponds to the material level on the heating net and is used for stacking a heating net on the oil-guiding cotton positioned in the placing groove along the horizontal direction;

The net cotton forming module is arranged on the outer side of the rotary table and positioned at the rear of the heating net supply module, corresponds to the net cotton forming position and is used for pressing the heating net and the oil guide cotton which are stacked together into the forming groove together so that the heating net and the oil guide cotton are curled into a ring shape at the same time, and the outer side of the heating net is coated with the oil guide cotton to form a first assembly body;

The bracket supply module is arranged on the outer side of the turntable and positioned at the rear of the net cotton forming module, corresponds to the bracket assembly position and is used for supplying brackets and assembling a first assembly body with a bracket to form a second assembly body;

The pin fixing seat assembly module is arranged at the rear of the support supply module and is used for assembling a pin fixing seat in the support of the second assembly body and fixing pins of the heating net in the second assembly body.

According to the application, a plurality of forming jigs are arranged on the turntable through the oil guide cotton feeding level, the heating net feeding level, the net cotton forming level and the bracket assembly position sequentially, the oil guide cotton feeding module is arranged at the outer side of the turntable corresponding to the oil guide cotton feeding level, the heating net supply module is arranged at the outer side of the turntable corresponding to the heating net feeding level, the net cotton forming module is arranged at the net cotton forming level, the bracket supply module is arranged at the bracket assembly position corresponding to the bracket assembly position, and the pin fixing seat assembly module for assembling pins is arranged at the rear of the bracket supply module, so that each module is arranged with the turntable as the center, the atomization core assembly equipment is reasonable in layout, and automatic assembly of all components of the atomization core can be realized.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this specification, illustrate embodiments of the application and together with the description serve to explain the application and do not constitute a limitation on the application. In the drawings:

FIG. 1 is an overall schematic of an atomized core assembly apparatus according to an embodiment of the disclosure.

FIG. 2 is a partial schematic view of a misting core assembly apparatus in an embodiment of the disclosure.

FIG. 3 is another schematic partial exploded view of a misting core assembly apparatus in an embodiment of the disclosure.

Fig. 4 is a schematic diagram of an oil-guiding cotton feeding module according to an embodiment of the disclosure.

Fig. 5 is a schematic diagram of a heating grid supply module according to an embodiment of the disclosure.

Fig. 6 is a schematic partial view of a heating grid supply module according to an embodiment of the disclosure.

Fig. 7 (a) is a schematic diagram of a pitch mechanism according to an embodiment of the disclosure.

FIG. 7 (B) is a schematic diagram illustrating another perspective view of the variable pitch mechanism according to an embodiment of the present disclosure.

Fig. 8 is a schematic diagram of a rack supply module according to an embodiment of the disclosure.

Fig. 9 is a schematic view of a partial explosion of a rack supply module according to an embodiment of the present disclosure.

Fig. 10 is another schematic view of a partial explosion of a rack supply module according to an embodiment of the present disclosure.

FIG. 11 is an exploded view of a pin holder assembly module according to an embodiment of the present disclosure.

Detailed Description

It should be noted that, without conflict, the embodiments of the present application and features of the embodiments may be combined with each other. The application will be described in detail below with reference to the drawings in connection with embodiments.

It is noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of exemplary embodiments according to the present application. As used herein, the singular is also intended to include the plural unless the context clearly indicates otherwise, and furthermore, it is to be understood that the terms "comprises" and/or "comprising" when used in this specification are taken to specify the presence of stated features, steps, operations, devices, components, and/or combinations thereof.

The relative arrangement of the components and steps, numerical expressions and numerical values set forth in these embodiments do not limit the scope of the present application unless it is specifically stated otherwise. Meanwhile, it should be understood that the sizes of the respective parts shown in the drawings are not drawn in actual scale for convenience of description. Techniques, methods, and apparatus known to one of ordinary skill in the relevant art may not be discussed in detail, but should be considered part of the authorization specification where appropriate. In all examples shown and discussed herein, any specific values should be construed as merely illustrative, and not a limitation. Thus, other examples of the exemplary embodiments may have different values. It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further discussion thereof is necessary in subsequent figures.

Referring to fig. 1 to 11, the present application provides an atomization core assembling apparatus, which includes a turntable, a plurality of forming tools 20, an oil-guiding cotton feeding module 200, a heating net supply module 300, a net cotton forming module 400, a bracket supply module 600 and a pin fixing base assembling module 700.

Further, the turntable is rotatably provided on the table 30 along a rotation center. The forming jigs 20 are arranged on the turntable at the same angle with the interval of the rotation center, and the turntable rotates to drive each forming jig 20 to sequentially pass through the feeding position of the oil guiding cotton 1, the feeding position of the heating net 2, the forming position of the net cotton and the assembling position of the bracket 3.

Further, each of the forming jigs 20 is configured with a placement groove 21. The placing groove 21 is used for placing an oil guide cotton 1 when the oil guide cotton 1 is placed at the feeding position. When the forming jig 20 with the oil guiding cotton 1 is moved to the feeding position of the heating net 2, the forming jig is used for placing the oil guiding cotton 1 and the heating net 2 stacked on the oil guiding cotton 1.

The forming jig 20 further includes a forming groove 22. The forming groove 22 is located below the placing groove 21. The forming groove 22 is used for forming the heating net 2 and the oil guide cotton 1 which are pressed down and stacked from the placing groove 21 to form a first assembly.

Further, the oil guide cotton feeding module 200 is disposed at the outer side of the turntable and corresponds to the feeding position of the oil guide cotton 1. The oil guide cotton feeding module 200 is used for horizontally spreading the oil guide cotton 1 in the placement groove 21.

The heating net supply module 300 is disposed at the outer side of the turntable and behind the oil-guiding cotton feeding module 200, and the heating net supply module 300 corresponds to the feeding level of the heating net 2 and is used for stacking the heating net 2 on the oil-guiding cotton 1 in the placement groove 21 along the horizontal direction.

The net cotton forming module 400 is disposed at the outer side of the turntable and located at the rear of the heating net supply module 300, the net cotton forming module 400 corresponds to the net cotton forming position, and is used for pressing the heating net 2 and the oil guide cotton 1 stacked together into the forming groove 22 together, so that the heating net 2 and the oil guide cotton 1 are curled into a ring shape at the same time, and the oil guide cotton 1 is wrapped at the outer side of the heating net 2 to form a first assembly body.

The bracket supply module 600 is disposed at the outer side of the turntable and located at the rear of the net cotton forming module 400, and the bracket supply module 600 corresponds to the assembly position of the bracket 3, and is used for assembling a first assembly body with a bracket 3 to form a second assembly body.

The pin fixing base assembly module 700 is disposed at the rear of the support supply module 600, and the pin fixing base assembly module 700 is configured to assemble a pin fixing base 4 in the support 3 of the second assembly and fix pins of the heating grid 2 in the second assembly.

Referring to fig. 2-3, each of the forming tools 20 includes a base, a placement portion 24, and a pressing assembly 25. The placement portion 24 is located above the base, and the placement portion 24 is configured in a horizontal direction to form the placement groove 21. The base is located directly below the placement groove 21 and is configured to form the molding groove 22. The pressing component 25 is disposed above the placement portion 24, and is used for pressing the oil guiding cotton 1 horizontally placed in the placement groove 21, or pressing the oil guiding cotton 1 horizontally placed and stacked with the heating net 2.

Further, the base includes a base body 231 and a mold core 232, the base is detachably provided on the turntable, the mold core 232 is detachably provided on the base body 231, and the mold core 232 is configured with the molding groove 22.

By providing the shaping groove 22 detachably connected to the base body 231, the mold core 232 with the adapted shaping groove 22 can be replaced according to the structure and specification of the atomizing core to be assembled at the time of wire replacement.

Further, the base body 231 is provided with a dovetail groove 2311, and the mold core 232 is adapted to the dovetail groove 2311 and detachably mounted in the dovetail groove 2311.

The dovetail groove 2311 includes a first groove 2312 and a second groove 2313 which are communicated with each other, a first stepped surface 2314 is formed between the first groove 2312 and the second groove 2313 in a direction in which the mold core 232 is inserted, and a screw hole 2315 is formed in the first stepped surface 2314 in a direction in which the mold core 232 is inserted.

The mold core 232 includes a first segment 2321 and a second segment 2322 that are connected to each other, the first segment 2321 is adapted to the first slot 2312, the second segment 2322 is adapted to the second slot 2313, along the direction in which the mold core 232 is inserted, a second step surface is formed between the first segment 2321 and the second segment 2322, and the first segment 2321 is provided with a fixing hole 2324 corresponding to the threaded hole 2315.

When the mold core 232 is inserted into the dovetail groove 2311, the first segment 2321 is limited in the first groove 2312, the second segment 2322 is limited in the second groove 2313, the first step surface 2314 abuts against the second step surface, the fixing hole 2324 faces the threaded hole 2315, and a fixing piece passes through the fixing hole 2324 and is locked in the threaded hole 2315, so that the mold core 232 is limited and fixed on the base main body 231.

Further, the molding groove 22 includes a first molding sub-groove 221 and a second molding sub-groove 222, the first molding sub-groove 221 communicates with the second molding sub-groove 222, and the second molding sub-groove 222 is located right under the placement groove 21.

The first notch angle of the first molding sub-slot 221 is smaller than 180 degrees, the second notch angle of the second molding sub-slot 222 is also smaller than 180 degrees, and the second notch angle is larger than the first notch angle, so that after the first assembly body molded by the net cotton molding module 400 moves from the second molding sub-slot 222 to the first molding sub-slot 221, the oil guide cotton 1 extending out of the first molding sub-slot 221 can be further tightened, so that the subsequent oil guide cotton trimming module 500 can be sheared.

In one embodiment, each of the forming jigs 20 is configured with a plurality of placing grooves 21, and each of the placing grooves 21 may be used for placing one of the oil-guiding cottons 1 or may be used for placing one of the oil-guiding cottons 1 and the heating net 2 stacked on the oil-guiding cottons 1.

Further, each forming jig 20 is configured to form a forming groove 22 corresponding to each placement groove 21, and the forming grooves 22 are used for forming the heating net 2 and the oil guide cotton 1 stacked together in cooperation with the corresponding placement groove 21.

In one embodiment, each of the jigs is provided with four placement slots 21 and forming slots 22 corresponding to the four placement slots 21 one by one.

In other embodiments, other numbers of placement slots 21 and forming slots 22 may be provided on each forming jig 20, for example, only one placement slot 21 and one forming slot 22 may be provided; alternatively, two placement grooves 21, two molding grooves 22, and the like may be provided, and are not exemplified here.

Further, the pressing assembly 25 includes a first pressing member 251 and a second pressing member 252, where the first pressing member 251 and the second pressing member 252 may respectively press the oil cotton 1 in the placement groove 21 of the forming jig 20 located at the feeding position of the oil cotton 1; or the first pressing member 251 and the second pressing member 252 may be respectively pressed in the placement groove 21 of the forming jig 20at the feeding position of the heating net 2 and stacked on the heating net 2 on the oil guide cotton 1.

Further, the first pressing member 251 and the second pressing member 252 have the same structure and are symmetrically disposed at two sides of the placement groove 21. Taking the first pressing member 251 as an example, the first pressing member 251 includes a pressing portion 2511, a rotating portion 2512 and a driving portion 2513, the rotating portion 2512 is located between the pressing portion 2511 and the driving portion 2513, the placing portion 24 is provided with an elastic driving member 2514 corresponding to the pressing portion 2511, and the elastic driving member 2514 is used for driving the pressing member to keep pressing down in the placing groove 21.

Further, the elastic driving member 2514 may be a compression spring, a tower spring, a disc spring, a metal spring plate, an elastic silica gel member, or the like, which may be used to drive the first pressing member 251 and the second pressing member 252 to respectively keep pressing down in the corresponding placement groove 21.

Further, the first pressing member 251 and the second pressing member 252 corresponding to each placement groove 21 are pressed on the oil-guiding cotton 1 or on the heating net 2 stacked on the oil-guiding cotton 1 at a certain distance, so as to reserve a space for pressing the heating net 2 and the oil-guiding cotton 1 stacked together down to the second molding subslot 222.

Further, a first mounting plate 11 is further arranged above the turntable, and the first mounting plate 11 does not rotate along with the turntable. I.e. the first mounting plate 11 remains stationary all the time above the turntable.

Further, the first mounting plate 11 is disc-shaped, and the diameter of the first mounting plate 11 is smaller than the diameter of the turntable. The first mounting plate 11 is provided with a first pressing component 12, the first pressing component 12 is located at the feeding position of the oil guide cotton 1, and the first pressing component 12 is used for driving the first pressing component 251 and the second pressing component 252 to open, so that the oil guide cotton feeding module 200 is used for placing the oil guide cotton 1 in the placing groove 21 in a flat manner.

Further, the first pressing assembly 12 includes a first pressing driving device 121, a first pressing arm 122, and a second pressing arm 123. The first pressing arm 122 and the second pressing arm 123 are respectively disposed at the output end of the first pressing driving device 121, the first pressing arm 122 corresponds to the first pressing member 251, and the second pressing arm 123 corresponds to the second pressing member 252.

The first pressing driving device 121 may drive the first pressing arm 122 and the second pressing arm 123 to move synchronously and press the driving portion 2513 of the first pressing member 251 and the driving portion 2513 of the second pressing member 252, so that the pressing portion 2511 of the first pressing member 251 and the pressing portion 2511 of the second pressing member 252 are not pressed in the placement groove 21 any more, thereby facilitating the placement of the oil-guiding cotton 1 in the placement groove 21 by the oil-guiding cotton feeding module 200.

After the oil-guiding cotton feeding module 200 places the oil-guiding cotton 1 in the placement groove 21, the first pressing driving device 121 drives the first pressing arm 122 and the second pressing arm 123 to move upwards respectively to release the first pressing member 251 and the second pressing member 252, so that the pressing portion 2511 of the first pressing member 251 and the pressing portion 2511 of the second pressing member 252 are pressed on the oil-guiding cotton 1 respectively.

Further, the first mounting plate 11 is provided with a second pressing component 13, the second pressing component 13 is located at a feeding position of the heating net 2, the second pressing component 13 includes a second pressing driving device, a third pressing arm and a fourth pressing arm, the third pressing arm and the fourth pressing arm are respectively disposed at an output end of the second pressing driving device, the third pressing arm corresponds to the first pressing member 251, the fourth pressing arm corresponds to the second pressing member 252, and the second pressing driving device can drive the third pressing arm and the fourth pressing arm to synchronously move and respectively press the corresponding first pressing member 251 and the second pressing member 252, so that the first pressing member 251 and the second pressing member are not pressed on the oil guide cotton 1 any more.

The second pressing assembly 13 has the same structure as the first pressing assembly 12, that is, the second pressing driving device is the same as the first pressing driving device 121, and the third pressing arm and the fourth pressing arm have the same structure as the first pressing arm 122 and the second pressing arm 123, which are not described herein.

Referring to fig. 4, the oil-guiding cotton feeding module 200 is independently disposed at the outer side of the workbench 30, so that the oil-guiding cotton 1 module can be detachably disposed according to actual requirements. When the oil guiding cotton feeding module 200 is required to be used for feeding the oil guiding cotton 1, the oil guiding cotton feeding module 200 can be arranged at the outer side of the workbench 30 and corresponds to the feeding level of the oil guiding cotton 1. When the oil guide cotton feeding module 200 is not required to be arranged or the oil guide cotton feeding module 200 cannot be placed due to the limitation of the installation space, the oil guide cotton feeding module 200 can be not installed.

Further, the oil guide cotton feeding module 200, which is independently and detachably arranged, has the advantage of being convenient for overhauling the oil guide cotton feeding module 200 and/or other modules installed on the workbench 30. That is, when maintenance is required, the oil guide cotton feeding module 200 can be shifted so as to reserve a larger maintenance space.

Further, the oil guide cotton feeding module 200 includes a first mounting frame 210, a tray limiting frame 220, a tray recycling device 230 and a mechanical arm 240. The tray limiting frame 220 is disposed on the first mounting frame 210, and the tray limiting frame 220 may be used to limit one or a plurality of stacked trays. Wherein, the tray is internally provided with the oil guide cotton 1. The tray recycling device 230 is disposed below the tray limiting frame 220, and is used for recycling empty trays.

The first end of the mechanical arm 240 is disposed on the first mounting frame 210 and located at one side of the tray limiting frame 220, and the second end of the mechanical arm 240 is connected with a second mounting plate 250. The second mounting plate 250 is provided with a suction nozzle 260 and a suction cup 270. The suction nozzle 260 is configured to suck the oil-guiding cotton 1 in the tray, and lay the sucked oil-guiding cotton 1 in the placement groove 21 of the forming tool 20 located at the feeding position of the oil-guiding cotton 1 along a horizontal plane under the driving of the mechanical arm 240. The suction cup 270 is used for sucking an empty tray, and transferring the sucked empty tray from the tray limiting frame 220 to the tray recycling device 230 under the driving of the mechanical arm 240.

The suction nozzles 260 are arranged on the second mounting plate 250 and used for sucking the oil guide cotton 1, and the suction discs 270 are arranged and used for sucking the empty trays, so that after the oil guide cotton 1 in each tray is fed, the empty trays can be transferred to the tray recycling device 230 for recycling through the suction discs 270 and the mechanical arm 240. Therefore, the suction disc 270 and the suction nozzle 260 are simultaneously arranged on the second mounting plate 250, so that the oil guide cotton feeding module 200 is multifunctional, automatic transfer of an empty tray can be realized, workers can be prevented from taking the empty tray, labor reduction can be realized, and production cost is reasonably reduced.

In one embodiment, two suction cups 270 are disposed on the second mounting plate 250, and eight suction nozzles 260 are disposed between two suction cups 270, where each two adjacent suction nozzles 260 are a group to suck one oil guide cotton 1 together to transfer the oil guide cotton 1.

Referring to fig. 5-7, the heating net supply module 300 includes a support frame 310, a traction mechanism 320, a cutting mechanism 330, and a transfer mechanism 340. The support frame 310 is arranged on the mounting seat 350, the mounting seat 350 is arranged on the workbench 30, a coiled heating net material belt 360 is arranged on the support frame 310, and a plurality of heating nets 2 are formed on the heating net material belt 360. The traction mechanism 320 is disposed on the mounting base 350, and is configured to draw the heating mesh material belt 360 along a first direction, and thereby drive the heating mesh material belt 360 to move on the mounting base 350 along the first direction. The cutting mechanism 330 is disposed on the mounting base 350 and between the supporting frame 310 and the traction mechanism 320, and is configured to move along a vertical direction to perform blanking and cutting on the heating net 2 on the heating net material belt 360, so as to obtain an independent heating net 2. The transfer mechanism 340 is disposed at one side of the cutting mechanism 330, and is used for transferring the cut heating net 2 to the forming jig 20 of the atomization core assembling device for assembling.

In this embodiment, the coiled heating net material belt 360 is disposed on the supporting frame 310 and is pulled by the traction mechanism 320, so that the heating net material belt 360 can be conveyed along the first direction, the heating net 2 on the heating net material belt 360 is blanked by the cutting mechanism 330 disposed between the supporting frame 310 and the traction mechanism 320, and the blanked independent heating net 2 is transferred to the forming jig 20 of the atomization core assembling device for assembly by the transfer mechanism 340, so that the heating net material belt 360 is pulled by the traction mechanism 320, so that each heating net 2 sequentially passes through the cutting mechanism 330 for cutting, the cutting mechanism 330 only needs to blanking the heating net 2 along the vertical direction in the cutting process, thereby realizing continuous cutting and efficient supply of the heating net 2 to the forming jig 20, and avoiding the inefficiency and low supply efficiency of blanking of the heating net 2 caused by cutting the heating net 2 vertically and horizontally distributed on the heating net 2 plates in different positions.

Further, the cutting mechanism 330 includes a cutting driving device 331, an upper punch 332, and a lower punch 333. The cutting driving device 331 is disposed above the mounting base 350. The lower punch 333 is disposed on the mounting base 350 and extends out of the mounting base 350, and is used for positioning and ejecting the heating net 2 on the heating net material belt 360. The upper punch 332 is disposed at the output end of the cutting driving device 331, and is driven by the cutting driving device 331 to move towards the lower punch 333, and the heating net 2 located on the lower punch 333 is lowered by the cooperation of the lower punch 333, so that the independent heating net 2 is punched from the heating net material belt 360.

Further, the lower punch 333 is provided with a plurality of punching positions 3331, and the upper punch 332 has an adapted punching portion 3321 corresponding to each punching position 3331. When the traction mechanism 320 pulls the heating net material belt 360 onto the lower punch 333 and a heating net 2 is placed corresponding to each punching position 3331, the cutting driving device 331 drives the upper punch 332 to move toward the lower punch 333 until each punching portion 3321 is pressed down on the corresponding punching position 3331 to complete punching and cutting of a plurality of heating nets 2.

In one embodiment, four punching positions 3331 are provided on the lower punch 333, each punching position 3331 may place one heating net 2, and the four punching positions 3331 may be arranged along the first direction, and may position and eject four adjacent heating nets 2 on the heating net material belt 360 out of the mounting base 350.

In other embodiments, other numbers of the punching sites 3331 may be provided on the lower punch 333, so as to facilitate more efficient and rapid assembly of the atomizing core in cooperation with the forming jig 20. For example, the other number may be one, two, three, or five or more.

Further, the mounting base 350 is provided with a guide groove 351, and the heating net material belt 360 moves in the guide groove 351 along the first direction. Preferably, a cover plate 352 is further disposed on the guide groove 351, and the cover plate 352 cooperates with the guide groove 351 to limit the heating net material belt 360 on the mounting seat 350, so that the heating net material belt 360 is accurately conveyed along the first direction, and limit of the heating net material belt 360 is achieved, so that the heating net material belt 360 can accurately pass through the lower punch 333.

Further, a traction groove 353 is provided in the guide groove 351 along the first direction. The heating net material belt 360 is provided with a plurality of traction holes 361 at intervals along the length direction thereof, and the heating net material belt 360 moves in the guide chute 351 so that a plurality of traction holes 361 sequentially pass through the traction chute 353.

The traction mechanism 320 includes a first traction drive 321, a second traction drive 322, and a traction arm 323. The traction arm 323 is disposed at an output end of the first traction driving device 321, and the traction arm 323 may pass through one of the traction holes 361 in a vertical direction and extend into the traction groove 353 or leave from the traction hole 361 under the driving of the first traction driving device 321. The first traction driving device 321 is disposed at an output end of the second traction driving device 322, and the first traction driving device 321 can move along the first direction and pull the heating net material belt 360 to move in the guide groove 351 through the traction arm 323 under the driving of the second traction driving device 322.

Further, the plurality of traction holes 361 are uniformly distributed on the heating net material belt 360, so that the distances between the adjacent traction holes 361 are the same, and the traction mechanism 320 is convenient for traction of the heating net material belt 360, so that the heating net material belt 360 can accurately move in the guide groove 351 and sequentially reach and stay at the punching position 3331 for punching.

Preferably, the heating net material belt 360 is provided with a traction hole 361 corresponding to each heating net 2.

Through setting up baffle box 351 traction groove 353 with traction mechanism 320, and will apron 352 detachably lid is established on the baffle box 351, and set up on the net material area 360 that generates heat with traction hole 361 of traction arm 323 looks adaptation, thereby can make traction mechanism 320 will generate heat net material area 360 is followed the first direction is accurately pulled and is fixed a position, with the cooperation cutting mechanism 330 is efficient will generate heat net 2 on the net material area 360 and carry out blanking and form a plurality of independent net 2 that generates heat.

In one embodiment, the forming jig 20 is configured with a plurality of placing grooves 21 and a plurality of forming grooves 22, and one forming groove 22 corresponds to one placing groove 21 and is located below the corresponding placing groove 21. Therefore, the molding jig 20 may place a plurality of the heating nets 2 at a time and mold the plurality of the heating nets 2.

Further, since the distance between the adjacent placement grooves 21 on the forming jig 20 is greater than the distance between the adjacent placement grooves 21 on the heating net material belt 360 and the adjacent heating nets 2, when the punched and cut independent heating nets 2 are transferred to the forming jig 20, the independent heating nets 2 need to be subjected to distance changing, so that the independent heating nets can be placed in the placement grooves 21 corresponding to the forming jig 20.

In one embodiment, the heating net supply module 300 further includes a distance-changing mechanism 370, where the distance-changing mechanism 370 is disposed between the cutting mechanism 330 and the transferring mechanism 340, and is used for changing distances of a plurality of heating nets 2 cut at the same time, so that the transferring mechanism 340 transfers the plurality of heating nets 2 after distance changing into each placement groove 21 of the forming jig 20.

Further, the pitch mechanism 370 comprises a first pitch drive 371, a pitch carriage 372, a plurality of pitch jaws 373. The distance-varying slide 372 has a plurality of distance-varying slide rails 375, and a plurality of distance-varying clamping jaws 373 are slidably disposed on the plurality of distance-varying slide rails 375, respectively.

The plurality of pitch jaws 373 have a first operating position and a second operating position, driven by the first pitch drive 371. When the plurality of gage jaws 373 are in the first operating position, the plurality of gage jaws 373 are positioned adjacent to each other and each clamp a heat generating net 2 from the respective die cut positions 3331.

After the heating net 2 is clamped, when the first distance-changing driving device 371 changes the distance between the first working positions and the second working positions of the plurality of distance-changing clamping jaws 373, a preset distance is formed between the adjacent distance-changing clamping jaws 373, so that the transferring mechanism 340 transfers the plurality of distance-changed heating nets 2 into the placing grooves 21 on the forming jig 20.

Further, the pitch-varying mechanism 370 further comprises a second pitch-varying drive 376 and a third pitch-varying drive 377. The variable-pitch slide 372 is disposed at an output end of the second variable-pitch driving device 376, and the second variable-pitch driving device 376 is used for driving the first variable-pitch device to move along a second direction so as to make the plurality of variable-pitch clamping jaws 373 approach to or separate from the cutting mechanism 330. That is, when it is required to clamp the plurality of independent heating nets 2 punched by the cutting mechanism 330, the second pitch-changing driving mechanism drives the pitch-changing slide 372 to move toward the cutting mechanism 330 until the plurality of pitch-changing clamping jaws 373 can clamp the corresponding heating nets 2, respectively.

When the plurality of pitch changing jaws 373 clamp the corresponding heating net 2, the second pitch changing driving mechanism drives the pitch changing slide seat 372 to move reversely so as to transfer the clamped plurality of heating nets 2 from the cutting mechanism 330, and at this time, the traction mechanism 320 may draw the heating net material belt 360 to move continuously along the first direction so as to facilitate the cutting mechanism 330 to cut other heating nets 2 on the heating net material belt 360; then, the first displacement driving device 371 will drive the plurality of displacement jaws 373 away from each other until the plurality of displacement jaws 373 are moved to the second working position. After the plurality of distance-changing jaws 373 are far away from each other, the transferring mechanism 340 clips and transfers the plurality of heat-generating nets 2 after distance-changing from the plurality of distance-changing mechanisms 370 located at the second working position into the placing groove 21 of the forming jig 20.

Further, the third variable-pitch driving device 377 is disposed on the workbench 30, and the second variable-pitch driving device 376 is disposed at an output end of the third variable-pitch driving device 377. The third pitch drive device 377 is configured to drive the second pitch drive device 376 to move along the first direction, so that the plurality of pitch changing jaws 373 are close to or far from the cutting mechanism 330 along the first direction. The first direction and the second direction are two directions which are mutually perpendicular on a horizontal plane. By providing the third distance changing driving device 377, the transferring mechanism 340 can be facilitated to clamp and transfer the plurality of heating nets 2 after distance changing together.

Further, the second distance-varying mechanism 370 is connected to the distance-varying slide 372 through an adjusting plate 380, and the position of the distance-varying slide 372 relative to the second distance-varying mechanism 370 in the vertical direction can be adjusted by setting the adjusting plate 380, so that the distance-varying mechanism 370 can be adjusted according to the specifications of the heating cores, and the distance-varying clamping jaws 373 can clamp the heating cores with different specifications.

Further, the adjustment plate 380 includes a connection plate portion 381 and an adjustment plate portion 382. The connecting plate 381 is provided at the output end of the second pitch drive 376. The adjusting plate 382 is provided with an adjusting groove 383 along the vertical direction, a lock hole 3721 is arranged on one side of the distance-changing slide 372 away from the cutting mechanism 330, and a locking piece passes through the adjusting groove 383 and is locked in the lock hole 3721.

When the height positions of the plurality of pitch changing clamping jaws 373 are required to be adjusted, the height adjustment of the plurality of pitch changing clamping jaws 373 is completed by releasing the locking member and adjusting the pitch changing slide 372 in the vertical direction relative to the adjusting plate 382, and locking the locking member in the locking hole 3721 after the adjustment to the required height position.

Further, a limiting guide groove 384 is further formed on a side, close to the distance-varying slide 372, of the adjusting plate 380, and the distance-varying slide 372 is at least partially limited in the limiting guide groove 384 in the vertical direction. Through setting up spacing guide slot 384 can make the displacement slide 372 is when adjusting along vertical direction, and adjustment efficiency is higher, and the regulation effect is better.

Further, the transfer mechanism 340 includes a plurality of first transfer jaws 341, where the plurality of first transfer jaws 341 are respectively configured to clamp and transfer the plurality of heat generating nets 2 after the distance is changed on the corresponding distance changing jaws 373 onto the forming fixture 20.

Further, the transfer mechanism 340 further includes a first transfer driving device 342 and a second transfer driving device 343, the first transfer driving device 342 is disposed at an output end of the second transfer driving device 343, and the plurality of first transfer clamping jaws 341 are disposed at an output end of the first transfer driving device 342. The first transferring driving device 342 may drive a plurality of the first transferring clamping jaws 341 to move along a vertical direction, so that the plurality of first transferring clamping jaws 341 respectively clamp and place the plurality of heating nets 2 clamped on the distance-changing clamping jaw 373, and the second transferring driving device 343 may drive the plurality of first transferring clamping jaws 341 to move along the second direction by driving the first transferring driving device 342, so as to cooperate with the first transferring driving device 342 to transfer and place the plurality of heating nets 2 in the placing groove 21.

Further, for the heating net 2 having two pins. Each first transfer jaw 341 includes two first transfer arms 3411 disposed in a staggered manner and a third transfer driving device 344 for driving the two first transfer arms to move relatively, each first transfer arm 3411 includes two first transfer clamping plates 3412 disposed at a certain distance, where one first transfer clamping plate 3412 of one first transfer clamping arm 3411 is disposed between the two first transfer clamping plates 3412 of the other first transfer clamping arm 3411 in a limited manner. Thus, by the two first transfer clamping plates 3412 of the two first transfer clamping arms 3411 being staggered and limited, not only the individual clamping of each pin of the heat generating net 2 can be realized, but also the separation of the two first transfer clamping arms 3411 can be avoided by utilizing the limitation of the first transfer clamping plates 3412.

In another embodiment, adjacent first transfer jaws 341 have a first spacing position and a second spacing position therebetween. When the first space position is spaced between adjacent first transfer jaws 341, the plurality of first transfer jaws 341 may respectively clamp one heating net 2 from the lower punch 333. The plurality of first transfer jaws 341 may place the heating mesh 2 sandwiched by each other on the forming jig 20 while the second spacing position is spaced between adjacent first transfer jaws 341.

In this embodiment, the distance between the plurality of heating nets 2 clamped from the cutting mechanism 330 and placed on the forming jig 20 is changed by controlling the distance between the plurality of first transferring jaws 341 of the transferring mechanism 340.

Further, the cotton molding module 400 includes a molding rod supply mechanism 410, a cotton molding mechanism 420, and an oil guide cotton finishing mechanism 430. The molding rod supply mechanism 410 is configured to convey a plurality of molding rods synchronously, so that the net cotton molding mechanism 420 clips a plurality of molding rods and presses the heating net 2 and the oil-guiding cotton 1 stacked in the placement groove 21 into the corresponding second molding sub-groove 222, and the oil-guiding cotton trimming mechanism 430 is configured to clamp and trim a portion of the oil-guiding cotton 1 extending out of the second molding sub-groove 222, so as to trim the oil-guiding cotton 1 extending out of the second molding sub-groove 222.

Further, the forming bar supply mechanism 410 includes a first oscillating device 411 and a first oscillating plate 412, the first oscillating plate 412 is disposed on the first oscillating device 411, and the first oscillating plate 412 is configured to form a plurality of first conveying grooves 413, one of the first conveying grooves 413 corresponds to one of the forming grooves 22.

The pledget forming mechanism 420 includes a plurality of forming bar jaws 421, a plurality of forming bar press arms 422, a first forming bar transfer drive 423, and a second forming bar transfer drive 424. The plurality of forming rod clamping jaws 421 and the plurality of forming rod pressing arms 422 are respectively disposed on the first forming rod transferring driving device 423, and one forming rod clamping jaw 421 corresponds to one forming rod pressing arm 422, and the first forming rod transferring driving device 423 may be used to drive the plurality of forming rod clamping jaws 421 and the plurality of forming rod pressing arms 422 to move along a vertical direction so as to respectively and simultaneously clamp a plurality of forming rods from the forming rod supplying mechanism 410, and simultaneously press the oil-guiding cotton 1 and the heating net 2 stacked together into the corresponding second forming sub-groove 222 corresponding to each of the placing grooves 21. Wherein, the molding rod clamping jaw 421 clamps on one end of the molding rod, and the molding rod pressing arm 422 is abutted against the other end of the molding rod.

Further, the first forming rod transferring driving device 423 belongs to an output end of the second forming rod driving device, and is driven by the second forming rod driving device to drive the first forming rod driving device to move from above the forming rod supplying mechanism 410 to above the cotton forming position, so that a plurality of forming rods clamped by the forming rod clamping jaws 421 move from above the forming rod supplying mechanism 410 to above the cotton forming position.

Further, the turntable rotates to drive each forming jig 20 to further pass through the trimming position of the oil guiding cotton 1, and the trimming position of the oil guiding cotton 1 is located between the net cotton forming position and the assembling position of the bracket 3.

The atomization core assembly equipment further comprises an oil guide cotton trimming module 500, wherein the oil guide cotton trimming module 500 is arranged on the outer side of the rotary table and located between the net cotton forming module 400 and the support supply module 600, and the oil guide cotton trimming module 500 corresponds to the trimming position of the oil guide cotton 1 and is used for trimming redundant oil guide cotton 1 on the first assembly.

Further, the oil-guiding cotton trimming module 500 includes a pair of scissors 510, a first scissors driving device 520 and a second scissors driving device 530, wherein one pair of scissors 510 is disposed corresponding to each molding slot 22, one pair of first scissors driving devices 520 is disposed corresponding to each pair of scissors 510, and the first scissors driving devices 520 are used for driving the corresponding pair of scissors 510 to be closed so as to trim the redundant oil-guiding cotton 1, or driving the corresponding pair of scissors 510 to be opened. The second scissors driving device 530 is configured to drive at least one of the first scissors driving devices 520 to move toward or away from the first molding slot 221, and drive at least one of the scissors 510 to synchronously move toward or away from the first molding slot 221.

Referring to fig. 8-10, the rack supply module 600 includes a carrier 610, a pulling mechanism 620, a welding mechanism 630, a pushing mechanism 640, a clamping mechanism 650, and a pushing assembly 660. The carrier 610 is disposed on the carrier 670, and a coiled carrier tape 680 is disposed on the carrier 610, and a plurality of unwelded carriers 3 are punched on the carrier tape 680. The pulling mechanism 620 is disposed on the carrier 670, and is configured to pull the support material belt 680 along a first direction, so that the support material belt 680 moves along the first direction, thereby facilitating welding of the unwelded support 3 on the support material belt 680, pushing and cutting of the welded support 3, and transferring and assembling the support 3 that is independent after pushing and cutting.

The welding mechanism 630 is disposed on the workbench 30 and between the carrier 610 and the pulling mechanism 620, and is used for welding each support 3 on the support material belt 680, so that the support supply module 600 has a function of welding the support 3, and the support supply module 600 is multifunctional in sequence.

The pushing and cutting mechanism 640 is disposed on the carrier 670 and between the welding mechanism 630 and the pulling mechanism 620, and is configured to move in a vertical direction to push and cut the welded support 3 on the support material belt 680, so as to obtain an independent support 3, so as to facilitate assembling the support 3.

The clamping mechanism 650 is used for clamping the cut support 3 and positioning the support 3 at a first opening end of the forming groove 22, the first opening end is provided with a limiting portion 223, the limiting portion 223 can limit the support 3, so that a portion, close to the first opening end, of the support 3 is embedded in the limiting portion 223, and therefore the limiting portion 223 can be used for limiting the support 3 to position the support 3.

The pushing component 660 is arranged on the first mounting plate 11 and is positioned at the second opening end of the forming groove 22, the pushing component 660 comprises a pushing tube 661 and a pushing device 662, the pushing tube 661 is arranged at the output end of the pushing device 662, and under the driving of the pushing device 662, the pushing tube 661 can enter the forming groove 22 from the second opening end to push the first assembly out of the forming groove 22 from the first opening end and enter the bracket 3 to form a second assembly.

Further, the welding mechanism 630 includes a welding device 631, a first welding drive 632, a second welding drive 633, a welding jaw, and a welding support plate 635. The welding jaw is arranged at the output end of the first welding driving device 632 and clamps the bracket 3 under the driving of the first welding driving device 632, so that the clamped areas to be welded of the bracket 3 are closed together, and welding is facilitated.

The first welding driving device 632 is arranged at the output end of the second welding driving device 633 and can move along the vertical direction under the driving of the second welding driving device 633, so that the second welding driving device 633 can simultaneously drive the first welding driving device 632 and the welding clamping jaw to synchronously move along the vertical direction, and the welding clamping jaw can pass through the bracket 3 corresponding to the bracket material belt 680 to clamp; or the welding jaw is caused to withdraw from the carrier web 680 in order to facilitate movement of the carrier web 680 in the first direction.

The second welding drive 633 is provided on the welding support plate 635, and the welding device 631 is provided above the welding jaws for welding the clamped support 3.

Further, the welding jaw includes a slide mount 6341, a slide 6342, a fixed clamp arm 6343, and a movable clamp arm 6344. The sliding groove seat 6341 is disposed on the welding support plate 635, the fixed clamping arm 6343 is disposed on the sliding groove seat 6341, the movable clamping arm 6344 is disposed on the sliding block 6342, and the sliding block 6342 is slidably disposed in the sliding groove seat 6341.

The sliding block 6342 is connected to the first welding driving device 632, and the sliding block 6342 may move to drive the movable clamping arm 6344 to approach or separate from the corresponding fixed clamping arm 6343 under the driving of the first welding driving device 632.

When the movable clamp arm 6344 approaches to the corresponding fixed clamp arm 6343, the movable clamp arm 6344 and the fixed clamp arm 6343 can cooperate to clamp one bracket 3, and when the movable clamp arm 6344 moves away from the fixed clamp arm 6343, the clamped bracket 3 is released.

Further, the sliding groove seat 6341 is provided with a plurality of fixed clamping arms 6343, and the sliding block 6342 is provided with an adaptive movable clamping arm 6344 corresponding to each fixed clamping arm 6343. By providing a plurality of movable clamp arms 6344 and a corresponding fixed clamp arm 6343 corresponding to each movable clamp arm 6344, the welding jaw can clamp a plurality of brackets 3 at a time, so that welding efficiency of the brackets 3 can be effectively improved.

In one embodiment, four fixed clamping arms 6343 are provided on the chute base 6341, four movable clamping arms 6344 are provided on the slide block 6342, and one fixed clamping arm 6343 corresponds to one movable clamping arm 6344, so that the welding jaw can clamp four brackets 3 at a time.

Further, the push-cut mechanism 640 includes a die holder 641, a push-cut driving device 642, and a push-cut block 643. The die holder 641 is configured with a limiting guide groove 384, and the limiting guide groove 384 is used for allowing the support material belt 680 to move and limiting the support material belt 680 in a vertical direction, so that the support material belt 680 can stably move in the first direction under the traction of the traction mechanism 620.

The push-cut driving device 642 is disposed below the die holder 641, the push-cut block 643 is disposed at an output end of the push-cut driving device 642 and is disposed through the limit guide groove 384 of the die holder 641, a push-cut groove 6431 is formed at a top end of the push-cut block 643, and the push-cut groove 6431 can accommodate the bracket 3.

The push-cut driving device 642 drives the push-cut block 643 to move along the vertical direction so that the push-cut block 643 extends out of the limit guide groove 384 to push-cut and separate the support 3 on the support material belt 680, thereby obtaining the independent and welded support 3; or back under the limit guide 384 so that the carrier strip 680 continues to move in the first direction under the pull of the pull mechanism 620.

In one embodiment, the output end of the push-cut driving device 642 is provided with a plurality of push-cut blocks 643, and each push-cut block 643 is respectively configured with at least one push-cut groove 6431.

In one embodiment, the stand supply module 600 further includes a distance adjusting mechanism 690 for adjusting the distance between adjacent and independent stands 3 cut from the stand tape 680, so as to facilitate assembly of the adjusted stand 3 with the first assembly.

The distance adjusting mechanism 690 includes a distance adjusting driving device 691, a distance adjusting slide 692, and a plurality of sliding blocks 693. The adjustment slide 692 has a plurality of adjustment rails 6921, and each of the slider blocks 693 is configured with a placement slot 6931. The sliding blocks 693 are slidably disposed on the distance-adjusting sliding rails 6921, and have a first working position and a second working position driven by the distance-adjusting driving device 691.

When the sliding blocks 693 are in the first working position, the distance between the adjacent sliding blocks 693 is equal to the distance between the adjacent brackets 3 on the bracket material belt 680, and at this time, the clamping mechanism 650 may simultaneously place the pushed and cut brackets 3 in the placing grooves 6931 corresponding to the sliding blocks 693 of the distance adjusting mechanism 690.

When the sliding blocks 693 are in the second working position, the distance between the adjacent sliding blocks 693 is equal to the distance between the adjacent forming grooves 22 on the forming jig 20, and at this time, the clamping mechanism 650 may place the multiple brackets 3 after the distance change on the limiting portion 223 of the forming jig 20 to limit and position, and cooperate with the pushing mechanism to push the first assembly into the brackets 3 to form the second assembly.

Further, the clamping mechanism 650 includes a first clamping drive 651, a second clamping drive 652, a third clamping drive 653, a first clamping assembly 654, and a second clamping assembly 655. The first clamping assembly 654 includes a plurality of first clamping claws 6541, the spacing between adjacent first clamping claws 6541 is equal to the spacing between adjacent brackets 3 on the bracket material belt 680, and the plurality of first clamping claws 6541 are respectively used for clamping an independent bracket 3 after punching.

The second clamping set includes a plurality of second clamping claws 6551, the spacing between adjacent second clamping claws 6551 is equal to the spacing between adjacent forming grooves 22 on the forming jig 20, and the second clamping claws 6551 are respectively used for clamping the adjusted bracket 3.

The first clamping component 654 is disposed at an output end of the first driving device and is capable of moving in a vertical direction under the driving of the first clamping driving device 651, so that the plurality of first clamping claws 6541 may move downward to clamp the die-cut support 3, or the clamped support 3 is placed in the placement groove 6931 corresponding to each of the plurality of sliding blocks 693 located at the first working position.

The first clamping driving device 651 and the second clamping assembly 655 are respectively disposed at the output end of the second clamping driving device 652, and can move in the vertical direction under the driving of the second clamping driving device 652. So that the first clamp assembly 654 and the second clamp assembly 655 can move in a vertical direction simultaneously.

The second clamping driving device 652 is disposed at an output end of the third clamping driving device 653, and is movable between the push-cutting mechanism 640 and the distance-adjusting mechanism 690 under the driving of the third clamping driving device 653. So that the first clamp assembly 654 and the second clamp assembly 655 move synchronously between the push-cut mechanism 640 and the adjustable distance mechanism 690.

The second clamping assembly 655 may be used to simultaneously clamp the stent 3 within the placement groove 6931 of the slider 693 in the second operational position while the first clamping assembly 654 clamps the stent 3 at the push-cut mechanism 640. When the first clamping component 654 places the clamped bracket 3 in the placing groove 6931 of the sliding block 693 at the first working position, the second clamping component 655 can simultaneously place the clamped bracket 3 in the limiting part 223 of the forming jig 20 for limiting and positioning.

Further, the pulling mechanism 620 includes a first pulling driving device 621, a second pulling driving device 622, and a pulling arm 623. The pulling arm 623 is disposed at the output end of the first pulling driving device 621, and the pulling arm 623 can vertically pass through the pulling hole 681 on the stent material belt 680 under the driving of the first pulling driving device 621, so as to budget the stent material belt 680 for connection, and can pull the stent material belt 680 under the driving of the second pulling driving device 622; or out of the pulling hole 681, thereby releasing the stent graft 680.

The first traction driving device 621 is disposed at an output end of the second traction driving device 622, and the first traction driving device 621 can move along the first direction and draw the support material belt 680 to move by the traction arm 623 under the driving of the second traction driving device 622.

After the second traction driving device 622 moves from the initial position to the preset position, the first traction driving device 621 drives the traction arm 623 to withdraw from the corresponding traction hole 681, then the second traction driving device 622 drives the first traction driving device 621 and the traction arm 623 to move together to the initial position, and then the first traction driving device 621 drives the traction arm 623 to insert into the corresponding other traction hole 681 again, so as to draw the support material tape 680.

Further, the rack supply module 600 further includes a scrap tape slitting mechanism 694 disposed behind the pulling mechanism 620. The scrap tape slitting mechanism 694 includes a guide frame 6941, a cutter 6942, and a slitting drive 6943.

The guide frame 6941 is provided with a perforation 6944 for the waste material belt to pass through, the cutting driving device 6943 is arranged on the guide frame 6941, the cutter 6942 is arranged at the output end of the cutting driving device 6943, and under the driving of the cutting driving device 6943, the cutter 6942 can be matched with the perforation 6944 to cut the waste material belt which extends out of the perforation 6944. The recycling of the scrap tape can be facilitated by slitting the scrap tape.

Referring to fig. 11, the turntable rotates to drive each molding jig 20 to pass through a blanking position, which is located at the rear of the assembling position of the bracket 3; the pin fixing base assembly module 700 is independently arranged on the outer side of the workbench 30 and is positioned on one side of the oil guide cotton feeding module 200.

Further, the pin holder assembly module 700 includes a second mounting frame 710, a second assembly transfer mechanism, a pin holder supply mechanism 730, and a pin holder mounting unit. The second assembly transferring mechanism is disposed on the second mounting frame 710 and is used for transferring the second assembly from the forming jig 20, and the forming jig 20 is used for forming the heating net 2, the bracket 3 and the oil guide cotton 1 to form the second assembly.

The pin holder supplying mechanism 730 is disposed on the second mounting frame 710, and is configured to vibrate the pin holders 4 to supply each of the pin holders 4 in a set direction.

The pin fixing base mounting unit is disposed on the second mounting frame 710, and includes a pin fixing base mounting mechanism 740 and a pressing mechanism 750. The holding mechanism 750 may be used to hold the second assembly, the pin holder mounting mechanism 740 is used to transfer the pin holder 4 with a set orientation supplied on the pin holder 4, and the pin corresponding to the heating net 2 is assembled in the bracket 3, so that the pin holder 4 is assembled in the bracket 3 and forms an atomization core with the second assembly.

Further, the pin holder mounting mechanism 740 includes a positioning suction head 741, a first mounting driver 742, a second mounting driver 743, and a third mounting driver 744. The positioning suction head 741 is disposed at an output end of the first mounting driving device 742 and is switchable between a suction position and a mounting position by the driving of the first mounting driving device 742. When the positioning suction head 741 is at the sucking position, the positioning suction head 741 can suck the pin fixing seat 4 supplied according to the set orientation on the pin fixing seat 4, and when the positioning suction head 741 is at the mounting position, the positioning suction head 741 can cooperate with the holding-down mechanism 750 to assemble the sucked pin fixing seat 4 in the bracket 3 of the second assembly body and fix the pins of the heating network 2.

The first installation driving device 742 is disposed at an output end of the second installation driving device 743, and can move in a vertical direction under the driving of the second installation driving device 743, so as to drive the positioning suction head 741 to move in the vertical direction. The second installation driving device 743 is disposed at an output end of the third installation driving device 744, and can be close to or far from the pressing mechanism 750 under the driving of the third installation driving device 744. Thereby driving the positioning suction head 741 to realize the transfer of the sucked pin fixing seat 4.

Further, the pin fixing seat 4 is of a hollow ring structure, and the positioning suction head 741 includes a positioning portion 7411 and a suction surface 7412, the positioning portion 7411 is adapted to the hollow portion of the pin fixing seat 4 and can be inserted into the hollow portion, so as to position the pin fixing seat 4, and the suction surface 7412 is used for sucking one side surface of the pin fixing seat 4, so as to suck the pin fixing seat 4.

Further, the outer ring surface of the pin fixing seat 4 is provided with a plurality of avoidance grooves, and any one of the avoidance grooves can accommodate one pin, so that the pin fixing seat 4 is in a toothed ring structure.

In one embodiment, the pressing mechanism 750 is provided with a plurality of pressing positions, a certain distance is arranged between adjacent pressing positions, and each pressing position can press and hold one second assembly. The output end of the first installation driving device 742 is provided with a plurality of positioning suction heads 741, and each positioning suction head 741 corresponds to one pressing position, so that a plurality of pin fixing seats 4 can be assembled at the same time.

In one embodiment, the holding mechanism 750 includes four holding positions, and the output end of the first installation driving device 742 is provided with four positioning suction heads 741, so that four pin fixing bases 4 can be assembled at the same time.

Further, the second assembly is disposed on the forming jig 20 in a limited manner, the turntable rotates to drive the forming jig 20 to pass through the discharging position, and the second assembly transferring mechanism is used for transferring the second assembly from the discharging position to the pressing mechanism 750.

Further, the second assembly transfer mechanism includes a first movement drive 721, a second movement drive 722, a third movement drive 723, and a first movement jaw 724. The first moving jaw 724 is disposed at an output end of the first moving driving device 721 and is driven by the first moving driving device 721 to rotate along a rotation axis in a vertical direction, so that the first moving jaw 724 can clamp the second assembly at the discharging position.

Further, the first moving driving device 721 is disposed at an output end of the second moving driving device 722, and can move in a vertical direction under the driving of the second moving driving device 722, so as to drive the first moving clamping jaw 724 to perform lifting motion. The second moving driving device 722 is disposed at the output end of the third moving driving device 723, and can move between the discharging position and the pressing mechanism 750 under the driving of the third moving driving device 723, so as to drive the first moving clamping jaw 724 to move to transfer the clamped second assembly.

Further, the pin fixing base assembly module 700 further includes a pin shaping mechanism 760, where the pin shaping mechanism 760 is configured to shape the pins of the heating net 2 in the second assembly body, and the pin fixing base mounting mechanism 740 can be convenient to mount the sucked pin fixing base 4 in the second assembly body after shaping the pins.

Further, the pin shaping mechanism 760 includes a shaping driving device 761 and a pushing head 762, the pushing head 762 is disposed at an output end of the shaping driving device 761, and the pushing head 762 can shape the second assembly clamped in the first clamping unit 751 under the driving of the shaping driving device 761, so that the first assembly is located at a designated position in the bracket 3, and pins of the heat generating net 2 deviate outwards relative to a center line of the bracket 3, so that the pin fixing base mounting mechanism 740 can conveniently mount the pin fixing base 4 in the second assembly and fix the pins of the heat generating net 2 of the second assembly.

Further, the holding mechanism 750 includes a first holding unit 751 and a second holding unit 752 which are disposed at intervals. The first pressing unit 751 is configured to press the second assembly transferred by the second assembly transferring mechanism, so that the pin shaping mechanism 760 shapes pins of the second assembly, so as to facilitate subsequent assembly of the pin fixing base 4. The second pressing unit 752 is configured to press the shaped second assembly to facilitate the fixed mounting of the pin fixing base mounting mechanism 740.

Further, the first pressing unit 751 includes a plurality of first sub-pressing bits 7511, and the second pressing unit 752 includes a plurality of second sub-pressing bits 7511. The shaping mechanism includes a plurality of pushing heads 762, one pushing head 762 corresponds to one first sub-holding position 7511, and one positioning suction head 741 corresponds to one second sub-holding position 7511.

Further, the second assembly transfer mechanism is also included as well as a fourth motion drive 725, a fifth motion drive 726, a second motion jaw 727, and a third motion jaw 728. The second moving jaw 727 and the third moving jaw 728 are respectively disposed at an output end of the fourth moving driving device 725 at a certain distance, and the second moving jaw 727 and the third moving jaw 728 can move in a vertical direction under the driving of the fourth moving driving device 725. Thus, a synchronous movement of the second moving jaw 727 and the third moving jaw 728 in the vertical direction can be achieved only by the fourth moving drive 725.

The fourth moving driving device 725 is disposed at an output end of the fifth moving driving device 726, and the second moving jaw 727 is capable of moving between the first holding unit 751 and the second holding unit 752, and the third moving jaw 728 is capable of moving between the second holding unit 752 and a receiving position under the driving of the fifth moving driving device 726. Thus, a synchronous movement of the second moving jaw 727 and the third moving jaw 728 between the second clamping unit 752 and the first clamping unit 751 can be achieved only by the fifth moving drive 726.

Further, when the second moving jaw 727 is at the first holding unit 751, the third moving jaw 728 is at the second holding unit 752. At this time, the second moving jaw 727 may clamp the second assembly after the integral shape, and the third moving jaw 728 may clamp the second assembly (and the atomizing core) to which the pin holder 4 is mounted.

When the second moving jaw 727 is at the second holding unit 752, the third moving jaw 728 is at the receiving level. At this time, the shaped second assembly body clamped by the second moving clamping jaw 727 is located on the second pressing unit 752, so that the pin fixing seat mounting mechanism 740 mounts the pin fixing seat 4, and the third moving clamping jaw 728 performs blanking on the clamped atomized core from the receiving position.

Spatially relative terms, such as "above … …," "above … …," "upper surface on … …," "above," and the like, may be used herein for ease of description to describe one device or feature's spatial location relative to another device or feature as illustrated in the figures. It will be understood that the spatially relative terms are intended to encompass different orientations in use or operation in addition to the orientation depicted in the figures. For example, if the device in the figures is turned over, elements described as "above" or "over" other devices or structures would then be oriented "below" or "beneath" the other devices or structures. Thus, the exemplary term "above … …" may include both orientations "above … …" and "below … …". The device may also be positioned in other different ways (rotated 90 degrees or at other orientations) and the spatially relative descriptors used herein interpreted accordingly.

In addition, the terms "first", "second", etc. are used to define the components, and are only for convenience of distinguishing the corresponding components, and the terms have no special meaning unless otherwise stated, and therefore should not be construed as limiting the scope of the present application.

The above is only a preferred embodiment of the present application, and is not intended to limit the present application, but various modifications and variations can be made to the present application by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present application should be included in the protection scope of the present application.

Claims (10)

1. An atomizing core assembly apparatus, comprising:

the turntable is rotatably arranged on the workbench along the rotation center;

The device comprises a rotary table, a plurality of forming jigs, a plurality of heating net material levels, a plurality of net cotton forming positions and a bracket assembly position, wherein the rotary table is provided with a plurality of forming jigs, the forming jigs are arranged on the rotary table at the same angle with the rotary center at intervals, each forming jig is provided with a placing groove and a forming groove, the forming groove is positioned below the placing groove, and the rotary table rotates to drive each forming jig to sequentially pass through the oil guide cotton material level, the heating net material level, the net cotton forming positions and the bracket assembly position;

the oil guide cotton feeding module is arranged on the outer side of the turntable and corresponds to the oil guide cotton feeding level, and is used for horizontally spreading the oil guide cotton in the placing groove;

The heating net supply module is arranged on the outer side of the turntable and positioned behind the oil-guiding cotton feeding module, corresponds to the material level on the heating net and is used for stacking a heating net on the oil-guiding cotton positioned in the placing groove along the horizontal direction;

The net cotton forming module is arranged on the outer side of the rotary table and positioned at the rear of the heating net supply module, corresponds to the net cotton forming position and is used for pressing the heating net and the oil guide cotton which are stacked together into the forming groove together so that the heating net and the oil guide cotton are curled into a ring shape at the same time, and the outer side of the heating net is coated with the oil guide cotton to form a first assembly body;

The bracket supply module is arranged on the outer side of the turntable and positioned at the rear of the net cotton forming module, corresponds to the bracket assembly position and is used for supplying brackets and assembling a first assembly body with a bracket to form a second assembly body;

The pin fixing seat assembly module is arranged at the rear of the support supply module and is used for assembling a pin fixing seat in the support of the second assembly body and fixing pins of the heating net in the second assembly body.

2. The atomizing core assembly device of claim 1, wherein the forming jig comprises a base, a placement portion and a pressing assembly, the placement portion is located above the base, the placement portion is configured to form the placement groove along a horizontal direction, the base is located right below the placement groove to form the forming groove, and the pressing assembly is located above the placement portion and is used for pressing oil guiding cotton horizontally placed in the placement groove or the oil guiding cotton and the heating net horizontally stacked in a spreading mode.

3. The atomizing core assembly set forth in claim 2, wherein said base includes a base body and a mold core, said mold core being structured with said molding groove and said mold core being removably disposed on said base body.

4. The atomizing core assembly set forth in claim 2, wherein each of said forming jigs is structured with a plurality of said placement slots, and wherein each of said placement slots is structured with a said forming slot.

5. The atomizing core assembly set forth in claim 2, wherein said pressing assembly includes a first pressing member and a second pressing member, said first pressing member and said second pressing member respectively pressing on said oil-guiding cotton in said placement groove of said forming jig at said oil-guiding cotton feeding level, or said first pressing member and said second pressing member respectively pressing on said heating net in said placement groove of said forming jig at said heating net feeding level and superposed on said heating net on said oil-guiding cotton;

The rotary table is characterized in that a first mounting plate is further arranged above the rotary table, the first mounting plate does not rotate along with the rotary table, a first pressing component is arranged on the first mounting plate and located on the oil guiding cotton, the first pressing component comprises a first pressing driving device, a first pressing arm and a second pressing arm, the first pressing arm and the second pressing arm are respectively arranged at the output end of the first pressing driving device, the first pressing arm corresponds to the first pressing piece, the second pressing arm corresponds to the second pressing piece, and the first pressing driving device can drive the first pressing arm and the second pressing arm to synchronously move and respectively press the corresponding first pressing piece and the second pressing piece, so that the first pressing piece and the second pressing piece are not pressed in the placing groove any more.

6. The atomizing core assembly apparatus of claim 5, wherein a second pressing assembly is disposed on the first mounting plate, the second pressing assembly is located at a material level on the heating net, the second pressing assembly includes a second pressing driving device, a third pressing arm and a fourth pressing arm, the third pressing arm and the fourth pressing arm are respectively disposed at an output end of the second pressing driving device, the third pressing arm corresponds to the first pressing member, the fourth pressing arm corresponds to the second pressing member, and the second pressing driving device can drive the third pressing arm and the fourth pressing arm to synchronously move and respectively press the corresponding first pressing member and the second pressing member, so that the first pressing member and the second pressing member are not pressed on the oil guide cotton any more.

7. The atomizing core assembly set forth in claim 5, wherein said stand supply module includes:

the clamping mechanism is used for clamping the bracket and positioning the bracket at the first opening end of the forming groove;

The pushing assembly is arranged on the first mounting plate and located at the second opening end of the forming groove, the pushing assembly comprises a pushing tube and a pushing device, the pushing tube is arranged at the output end of the pushing device, and under the driving of the pushing device, the pushing tube can enter the forming groove from the second opening end to push the first assembly body out of the forming groove from the first opening end and enter the support.

8. The atomizing core assembly apparatus of claim 1, wherein rotation of the turntable drives each of the forming jigs to further pass through an oil guide cotton trimming station located between the mesh cotton forming station and the bracket assembly station;

The assembly equipment further comprises an oil guide cotton trimming module, wherein the oil guide cotton trimming module is arranged on the outer side of the rotary table and located between the net cotton forming module and the support supply module, and the oil guide cotton trimming module corresponds to the oil guide cotton trimming position and is used for trimming redundant oil guide cotton on the first assembly body.

9. The atomizing core assembly apparatus of claim 1, wherein the oil-guiding cotton feeding module is independently provided at an outer side of the table, the oil-guiding cotton feeding module comprising:

a first mounting frame;

The tray limiting frame is arranged on the first mounting frame and can be used for limiting one or a plurality of trays which are stacked, wherein the trays are loaded with oil guide cotton;

the tray recycling device is arranged below the tray limiting frame and is used for recycling empty trays;

The first end of the mechanical arm is arranged on the first mounting frame and is positioned on one side of the tray limiting frame, the second end of the mechanical arm is connected with a second mounting plate, a suction nozzle and a suction cup are arranged on the second mounting plate, the suction nozzle is used for sucking oil guiding cotton in the tray, the sucked oil guiding cotton is horizontally placed in the placing groove of the forming jig at the feeding position of the oil guiding cotton along a horizontal plane under the driving of the mechanical arm, and the suction cup is used for sucking an empty tray and transferring the sucked empty tray from the tray limiting frame to the tray recycling device under the driving of the mechanical arm.

10. The atomizing core assembly apparatus of claim 1, wherein rotation of the turntable drives each of the forming jigs to further pass through a blanking level located rearward of the rack assembly;

the pin fixing base assembly module is independently arranged on the outer side of the workbench and is positioned on one side of the oil guide cotton feeding module, and the pin fixing base assembly module comprises:

A second mounting frame;

The pin fixing seat mounting unit is arranged on the second mounting frame and is used for mounting a pin fixing seat in the bracket of the second assembly body and fixing pins of the heating net in the second assembly body to form an atomization core assembly;

the second assembly body transferring mechanism is arranged between the second mounting frame and the workbench and is used for transferring the second assembly body at the discharging position to the pin fixing seat mounting unit.