CN113876034A

CN113876034A - Atomizer, atomizing base, manufacturing device and manufacturing method

Info

Publication number: CN113876034A
Application number: CN202111263768.4A
Authority: CN
Inventors: 不公告发明人
Original assignee: Shenzhen Xinlinmei Technology Co ltd
Current assignee: Shenzhen Xinlinmei Technology Co ltd
Priority date: 2021-10-26
Filing date: 2021-10-26
Publication date: 2022-01-04

Abstract

The application provides an atomizer, an atomizing base, a manufacturing device and a manufacturing method. The manufacturing device of the atomizing base comprises a positioning, pressing and winding mechanism, an alignment and loosening mechanism and an assembly driving mechanism; the positioning, pressing and winding mechanism is used for positioning the heating wire, pressing and abutting the liquid guide piece on the heating wire, and enabling the liquid guide piece to rotate along with the heating wire and to be wound on the heating wire so as to form an atomizing core; the alignment elastic mechanism is used for clamping the atomization core; the assembly driving mechanism is used for clamping the mounting sleeve seat and sleeving and assembling the mounting sleeve seat on the atomizing core to obtain the atomizing seat. Foretell manufacturing installation realizes the automatic manufacturing of atomizing seat, and the centre need not artifical the intervention, has avoided traditional atomizing core to cup joint the elasticity inconsistent in the installation cover seat at the atomizing core in manufacturing process, even unable equipment, also need not to loosen again and twine once more, has avoided the equipment repeatedly, has solved the lower problem of packaging efficiency of atomizing seat.

Description

Atomizer, atomizing base, manufacturing device and manufacturing method

Technical Field

The invention relates to the technical field of electronic cigarette manufacturing, in particular to an atomizer, an atomizing base, a manufacturing device and a manufacturing method.

Background

The atomizing seat of electron cigarette includes atomizing core and installation cover seat, and the atomizing core includes the heater and leads oily cotton, leads oily cotton winding on the heater, and installation cover seat cup joints on the atomizing core. The inlet port has been seted up to the mount sleeve seat, and atomizing liquid flows in through the inlet port, leads oily cotton to absorb oil and lead oily effect to atomizing liquid, and the heater produces the heat when the circular telegram to atomizing liquid on leading oily cotton heats the atomizing.

During the equipment, earlier through the manual work with leading the cotton winding of oil in order to form the atomizing core in the heater, cup joint the installation cover seat in the atomizing core again, make the atomizing core install on the installation cover seat. However, because of the difference of manual operation skill and winding degree of progress, the volume size that makes the different atomizing cores that the equipment obtained is different, so make the atomizing core cup joint the not unanimous of the elasticity in the installation sleeve seat, even unable equipment, need loosen again and twine, so equipment repeatedly, make the packaging efficiency of atomizing seat lower.

Disclosure of Invention

The invention aims to overcome the defects in the prior art and provides an atomizer with higher assembly efficiency, an atomizing base, a manufacturing device and a manufacturing method.

The purpose of the invention is realized by the following technical scheme:

an atomizing base manufacturing device, comprising:

the positioning and pressing winding mechanism is used for positioning the heating wire, pressing and abutting the liquid guide piece on the heating wire, and enabling the liquid guide piece to rotate along with the heating wire and to be wound on the heating wire so as to form an atomizing core;

the alignment and tightening mechanism is used for clamping the atomization core;

the assembly driving mechanism is used for clamping the mounting sleeve seat and assembling the mounting sleeve seat on the atomizing core in a sleeved mode to obtain the atomizing seat; the alignment elastic mechanism is also used for loosening the atomizing core before the mounting sleeve seat is sleeved and assembled on the atomizing core.

In one embodiment, the manufacturing device of the atomizing base further comprises a base, the positioning, pressing and winding mechanism and the assembling driving mechanism are both arranged on the base, and the alignment and loosening mechanism is movably arranged on the base.

In one embodiment, the assembly driving mechanism is used for driving the mounting sleeve seat to abut against and push the alignment elastic mechanism when the mounting sleeve seat is sleeved on the atomizing core, so that the mounting sleeve seat moves to a first preset position along with the alignment elastic mechanism; the alignment elastic mechanism is also used for loosening the atomizing core when the mounting sleeve seat is positioned at the first preset position.

In one embodiment, after the installation sleeve seat is sleeved and assembled on the atomization core, the positioning and pressing winding mechanism releases the liquid guide piece, and the assembly driving mechanism separates the atomization seat from the positioning and pressing winding mechanism.

In one embodiment, the positioning, pressing and winding mechanism comprises a rotary driving component, a positioning component and a pressing component, the positioning component is arranged at a power output end of the rotary driving component, the positioning component is used for positioning the heating wire, the pressing component is arranged at the power output end of the rotary driving component, and the pressing component is used for pressing and abutting the liquid guiding piece to the heating wire and loosening the liquid guiding piece after the mounting sleeve seat is sleeved and assembled on the atomizing core.

A manufacturing method of an atomizing base, which is manufactured by using the manufacturing device of the atomizing base according to any one of the above embodiments, the manufacturing method comprising:

the heating wire is positioned through the positioning, pressing and winding mechanism;

the liquid guide piece is pressed and abutted against the heating wire through the positioning pressing winding mechanism, and the liquid guide piece rotates along with the heating wire and is wound on the heating wire to form the atomizing core;

the atomization core is clamped through the alignment elastic mechanism;

clamping the mounting sleeve seat through the assembling driving mechanism, and sleeving the mounting sleeve seat on the atomizing core;

loosening the atomizing core through the alignment tightening mechanism;

and assembling the mounting sleeve seat on the atomizing core through the assembling driving mechanism to obtain the atomizing seat.

In one embodiment, after the step of assembling the mounting socket to the atomizing core by the assembling driving mechanism, the manufacturing method further includes:

the liquid guide piece is loosened through the positioning, pressing and winding mechanism;

the atomization seat is separated from the positioning, pressing and winding mechanism through the assembly driving mechanism.

In one embodiment, the step of separating the atomizing base from the positioning, pressing and winding mechanism by the assembling and driving mechanism is specifically as follows:

and the atomization seat is pulled out of the positioning, pressing and winding mechanism through the assembly driving mechanism.

An atomizing base manufactured by the manufacturing device of the atomizing base in any embodiment.

An atomizer comprises the atomizing seat.

Compared with the prior art, the invention has at least the following advantages:

according to the manufacturing device of the atomizing base, when the atomizing base is manufactured, the heating wire is positioned through the positioning and pressing winding mechanism; then, the liquid guiding piece is pressed and abutted against the heating wire through the positioning pressing winding mechanism, and the liquid guiding piece rotates along with the heating wire and is wound on the heating wire to form an atomizing core; then the atomization core is clamped through an alignment elastic mechanism so as to clamp and position the atomization core; then clamping the mounting sleeve seat through an assembly driving mechanism, and sleeving the mounting sleeve seat on the atomizing core; then loosening the atomizing core through an alignment tightening mechanism; then assemble the mount sleeve seat in the atomizing core through equipment actuating mechanism, obtain the atomizing seat, so realize the automatic manufacturing of atomizing seat, the centre need not artifical intervention, has avoided traditional atomizing core to cup joint the not unanimous of elasticity in the mount sleeve seat at the atomizing core in manufacturing process, even unable equipment, also need not to loosen winding once more again, has avoided the equipment repeatedly, has solved the lower problem of packaging efficiency of atomizing seat.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

FIG. 1 is a schematic structural diagram of an apparatus for manufacturing an atomizing base according to an embodiment;

FIG. 2 is a schematic view of a part of the manufacturing apparatus of the atomizing base shown in FIG. 1;

FIG. 3 is a cross-sectional view of the manufacturing apparatus of the atomizing base shown in FIG. 2;

FIG. 4 is a schematic view from another perspective of a partial structure of the manufacturing apparatus of the atomizing base shown in FIG. 2;

FIG. 5 is a partial schematic view of a further perspective of the manufacturing apparatus of the atomizing base shown in FIG. 4;

FIG. 6 is a flowchart illustrating a method of manufacturing the atomizing base according to one embodiment.

Detailed Description

To facilitate an understanding of the invention, the invention will now be described more fully with reference to the accompanying drawings. Preferred embodiments of the present invention are shown in the drawings. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

The invention provides a manufacturing device of an atomizing base, which comprises a positioning, pressing and winding mechanism, an alignment and loosening mechanism and an assembly driving mechanism, wherein the positioning, pressing and winding mechanism is arranged on the positioning, loosening and tightening mechanism; the positioning, pressing and winding mechanism is used for positioning the heating wire, pressing and abutting the liquid guide piece on the heating wire, and enabling the liquid guide piece to rotate along with the heating wire and to be wound on the heating wire so as to form an atomizing core; the alignment elastic mechanism is used for clamping the atomization core; the assembly driving mechanism is used for clamping the mounting sleeve seat and assembling the mounting sleeve seat on the atomizing core in a sleeved mode to obtain the atomizing seat; the alignment elastic mechanism is also used for loosening the atomizing core before the mounting sleeve seat is sleeved and assembled on the atomizing core.

When the atomization seat is manufactured, the heating wire is positioned by the positioning, pressing and winding mechanism; then, the liquid guiding piece is pressed and abutted against the heating wire through the positioning pressing winding mechanism, and the liquid guiding piece rotates along with the heating wire and is wound on the heating wire to form an atomizing core; then the atomization core is clamped through an alignment elastic mechanism so as to clamp and position the atomization core; then clamping the mounting sleeve seat through an assembly driving mechanism, and sleeving the mounting sleeve seat on the atomizing core; then loosening the atomizing core through an alignment tightening mechanism; then assemble the mount sleeve seat in the atomizing core through equipment actuating mechanism, obtain the atomizing seat, so realize the automatic manufacturing of atomizing seat, the centre need not artifical intervention, has avoided traditional atomizing core to cup joint the not unanimous of elasticity in the mount sleeve seat at the atomizing core in manufacturing process, even unable equipment, also need not to loosen winding once more again, has avoided the equipment repeatedly, has solved the lower problem of packaging efficiency of atomizing seat.

In order to better understand the technical scheme and the beneficial effects of the present application, the following detailed description is further provided in conjunction with specific embodiments:

as shown in fig. 1, an apparatus 10 for manufacturing an atomizing base according to an embodiment is used to manufacture an atomizing base. Further, the manufacturing apparatus 10 of the atomizing base includes a positioning, pressing and winding mechanism 100, an alignment and loosening mechanism 200, and an assembly driving mechanism 300. The positioning and pressing winding mechanism 100 is used for positioning the heating wire 20, so that the positioning and pressing mechanism drives the heating wire to rotate. The positioning, pressing and winding mechanism 100 is further configured to press and abut the liquid guiding member 30 against the heater, and to enable the liquid guiding member to rotate along with the heater and to be wound around the heater, that is, the heater winds the liquid guiding member, so that the liquid guiding member is automatically wound around the surface of the heater to form an atomizing core. The assembly driving mechanism 300 is used for clamping the mounting sleeve seat and sleeving and assembling the mounting sleeve seat on the atomizing core to obtain the atomizing seat. Counterpoint straining device 200 be used for pressing from both sides tightly in the atomizing core, counterpoint straining device 200 is used for pressing from both sides tightly in the location and compresses tightly the atomizing core that winding mechanism 100 made the formation promptly to press from both sides tight location to the atomizing core, and then make the installation cover seat cup joint the atomizing core better, even the installation cover seat assembles with the atomizing core. The alignment tightening mechanism 200 is further configured to loosen the atomizing core before the mounting sleeve is sleeved and assembled on the atomizing core, so that the assembly driving mechanism 300 can further assemble the mounting sleeve in the atomizing core. It is understood that the wicking member may be a wicking cotton tape or other wicking member.

In the manufacturing device 10 for the atomization seat, when the atomization seat is manufactured, the heating wire is firstly positioned by the positioning and pressing winding mechanism 100; then, the liquid guiding piece is pressed and abutted against the heating wire through the positioning pressing winding mechanism 100, and the liquid guiding piece rotates along with the heating wire and is wound on the heating wire to form an atomizing core; then the atomization core is clamped through the alignment elastic mechanism 200 to clamp and position the atomization core; then clamping the mounting sleeve base through the assembly driving mechanism 300, and sleeving the mounting sleeve base on the atomizing core; then the atomization core is loosened through the alignment tightening mechanism 200; then assemble the mount sleeve seat in the atomizing core through equipment actuating mechanism 300, obtain the atomizing seat, so realize the automatic manufacturing of atomizing seat, the centre need not artifical intervention, has avoided traditional atomizing core to cup joint the elasticity nonconformity in the mount sleeve seat at the atomizing core in manufacturing process, even unable equipment, also need not to loosen winding once more again, has avoided the equipment repeatedly, has solved the lower problem of packaging efficiency of atomizing seat.

Referring to fig. 1 again, in one embodiment, the manufacturing apparatus 10 of the atomizing base further includes a base 400, the positioning, pressing and winding mechanism 100 and the assembling driving mechanism 300 are both disposed on the base 400, and the alignment take-up mechanism 200 is movably disposed on the base 400, so that the alignment take-up mechanism 200 can move relative to the base 400, and thus the alignment take-up mechanism 200 is more flexible in the process of clamping and positioning the atomizing core.

In one embodiment, the assembly driving mechanism 300 is configured to drive the mounting sleeve to abut against and push the alignment loosening and tightening mechanism 200 when the mounting sleeve is sleeved on the atomizing core, so that the mounting sleeve moves to a first predetermined position along with the alignment loosening and tightening mechanism 200, and since the heating wire is positioned in the positioning and tightening winding mechanism 100, the liquid guiding component rotates along with the heating wire and winds around the heating wire to form the atomizing core, and then the atomizing core is positioned in the positioning and tightening winding mechanism 100, so that when the mounting sleeve abuts against and pushes the alignment loosening and tightening mechanism 200 when the mounting sleeve is sleeved on the atomizing core, the mounting sleeve moves relative to the atomizing core, and then the atomizing core is assembled in the mounting sleeve. In this embodiment, counterpoint straining device 200 elastic clamping is in atomizing core, makes counterpoint straining device 200 press from both sides tight location to atomizing core, promotes to counterpoint straining device 200 in-process at the installation cover seat simultaneously and makes counterpoint straining device 200 move for atomizing core, makes the installation cover seat assemble gradually and cup joints in atomizing core. The alignment tightening mechanism 200 is further configured to loosen the atomizing core when the mounting sleeve is located at the first predetermined position.

Further, the assembly driving mechanism 300 is configured to push the mounting sleeve to move from the first predetermined position to the second predetermined position when the alignment tightening mechanism 200 releases the atomizing core, so that the mounting sleeve is further assembled and sleeved on the atomizing core, and mechanical interference between the mounting sleeve and the atomizing core during the assembly process is avoided.

In one embodiment, after the mounting sleeve is sleeved on the atomizing core, the positioning and pressing winding mechanism 100 releases the liquid guiding member, that is, the positioning and pressing winding mechanism 100 is used to release the liquid guiding member after the mounting sleeve is sleeved on the atomizing core. The assembly driving mechanism 300 separates the atomizing base from the positioning, pressing and winding mechanism 100, that is, the assembly driving mechanism 300 is used for separating the atomizing base from the positioning, pressing and winding mechanism 100 after the positioning, pressing and winding mechanism 100 releases the liquid guide member, so as to take out the atomizing base from the positioning, pressing and winding mechanism 100.

As shown in fig. 2 and 3, in one embodiment, the positioning, pressing and winding mechanism 100 includes a rotary driving component 110, a positioning component 120 and a pressing component 130, the positioning component 120 is disposed at a power output end of the rotary driving component 110, and the positioning component 120 is used for positioning the heating wire, so that the positioning, pressing and winding mechanism 100 can position the heating wire. The compressing assembly 130 is disposed at the power output end of the rotation driving assembly 110, so that the power output end of the rotation driving assembly 110 can simultaneously drive the compressing assembly 130 and the positioning assembly 120 to rotate. The compressing component 130 is used for compressing and abutting the liquid guiding component on the heating wire, so that the liquid guiding component reliably rotates along with the heating wire and the positioning component 120, and meanwhile, the heating wire is compressed on the positioning component 120, and further the liquid guiding component is wound on the surface of the heating wire. Further, the pressing assembly 130 also loosens the liquid guiding member after the mounting sleeve 40 is sleeved and assembled on the atomizing core, so that the assembled atomizing base can be removed from the positioning assembly 120.

As shown in fig. 2 and fig. 3, in one embodiment, the rotation driving assembly 110 includes a rotation driving element 110a and a rotation base 110b, the rotation driving element 110a is mounted on the base 400, the rotation base 110b is connected to a power output shaft of the rotation driving element 110a, the positioning assembly 120 is connected to the rotation base 110b, the pressing assembly 130 is movably disposed on the rotation base 110b, so that the driving element drives the rotation base 110b to rotate relative to the base 400, because the pressing assembly 130 is movably disposed on the rotation base 110b, the positioning assembly 120 positions the heating wire, so that the pressing assembly 130 presses and abuts against the heating wire, and thus the liquid guiding element can reliably rotate along with the heating wire and wind around the heating wire, so as to form the atomizing core. In this embodiment, when the liquid guiding member needs to be pressed, the pressing end of the pressing component 130 moves toward the direction close to the positioning component 120, so that the pressing component 130 presses and abuts against the liquid guiding member. When the liquid guiding member is not required to be compressed, i.e. the atomizing core is sleeved with the mounting sleeve seat, the compressing end of the compressing assembly 130 moves in the direction away from the positioning assembly 120, so that the compressing assembly 130 releases the liquid guiding member, and the atomizing seat is taken out.

As shown in fig. 2 and fig. 3, in one embodiment, the rotating base 110b is provided with a sliding groove 112, and the pressing component 130 is located in the sliding groove 112 and is slidably connected to the rotating base 110b, so that the pressing component 130 is movably connected to the rotating base 110b, the connection structure between the pressing component 130 and the rotating base 110b is simpler, and the pressing component 130 and the rotating base 110b relatively move along a predetermined direction.

As shown in fig. 2 and fig. 3, in one embodiment, the pressing assembly 130 includes a pressing block 132 and a self-returning element 134, the pressing block 132 is located in the sliding groove 112 and slidably connected to the rotating base 110b, so that the pressing assembly 130 is located in the sliding groove 112 and slidably connected to the rotating base 110 b. The automatic reset piece 134 is located in the sliding groove 112, and two ends of the automatic reset piece 134 are respectively abutted to the pressing clamp block 132 and the rotating seat body 110b, so that the pressing clamp block 132 is elastically and slidably connected to the rotating seat body 110 b. In this embodiment, the automatic restoring member 134 is a coil spring or an elastic rubber sleeve. When the liquid guiding member needs to be positioned, the pressing clamping block 132 slides on the rotating seat body 110b in the direction close to the positioning assembly 120, and simultaneously the automatic resetting member 134 is squeezed to deform the automatic resetting member 134, so that the liquid guiding member is clamped and positioned between the pressing clamping block 132 and the positioning assembly 120. When the liquid guiding member is not required to be positioned, the pressing clamp block 132 slides on the rotating seat body 110b in the direction away from the positioning assembly 120, and the automatic resetting member 134 automatically resets to release the liquid guiding member.

As shown in fig. 2 and fig. 3, in one embodiment, the pressing block 132 includes a sliding block 132a and a pressing piece 132b connected to each other, the sliding block 132a is located in the sliding groove 112 and slidably connected to the rotating base 110b, and the automatic returning element 134 abuts against the sliding block 132 a. The positioning assembly 120 is provided with a pressing groove 121 communicated with the sliding groove 112, and the pressing sheet 132b is located in the pressing groove 121 and is slidably connected with the positioning assembly 120. The pressing piece 132b is used for pressing and abutting the liquid guiding piece on the heating wire so as to position the liquid guiding piece on the heating wire, and the liquid guiding piece is loosened after the installation sleeve seat is sleeved and assembled on the atomizing core so as to take out the atomizing seat.

As shown in fig. 2 and fig. 3, in one embodiment, the rotating base 110b is further provided with a driving air channel 114, and the driving air channel 114 is used for driving the sliding clamp block 132a to slide relative to the rotating base 110b so as to drive the pressing clamp block 132 to slide relative to the rotating base 110 b. In the embodiment, the driving airflow channel 114 is opened on the rotating base 110b, so that the driving source of the sliding clamping block 132a is integrated on the rotating base 110b, and the structure of the rotating driving assembly 110 is more compact. When the pressing clamp block 132 is driven to press the liquid guiding member, the driving airflow channel 114 drives the sliding clamp block 132a to slide relative to the rotating base body 110b, so as to press and abut the liquid guiding member against the heating wire.

As shown in fig. 2 and fig. 3, in one embodiment, the rotary driving element 110a is a hollow motor, the rotary driving element 110a is formed with an intermediate air inlet 116, the intermediate air inlet 116 is communicated with the driving airflow channel 114, so that an external air source drives the sliding clamping block 132a to slide relative to the rotating seat body 110b through the intermediate air inlet 116 and the driving airflow channel 114, and the overall structure of the positioning, compressing and winding mechanism 100 is more compact. It is understood that in other embodiments, the rotary drive 110a is not limited to a hollow motor, and the drive airflow channel 114 directly connects to an external air source, for example, the rotary drive 110a is a rotary motor.

As shown in fig. 2 and 3, in one embodiment, the alignment release mechanism 200 includes a mounting base 210, an elastic member 220, and an alignment release assembly 230, wherein the mounting base 210 is slidably connected to the base 400, one end of the elastic member 220 abuts against the base 400, and the other end of the elastic member 220 abuts against the mounting base 210, so that the mounting base 210 is elastically and slidably connected to the base 400. The alignment elastic assembly 230 is disposed on the mounting base 210, and the alignment elastic assembly 230 is configured to be clamped to the atomizing core and loosen the atomizing core when the mounting sleeve is located at the first predetermined position. In this embodiment, the assembly driving mechanism 300 is configured to drive the mounting sleeve to abut against and push the alignment take-up assembly 230 when the mounting sleeve is sleeved on the atomizing core. When the mounting sleeve base pushes the alignment elastic assembly 230, the mounting sleeve base moves to a first predetermined position along with the alignment elastic assembly 230, and the elastic member 220 deforms under pressure. When the mounting sleeve base is located at the first preset position, the alignment elastic component 230 releases the atomizing core, and the alignment elastic component 230 automatically resets under the elastic action of the elastic component 220. Further, the elastic member 220 is a coil spring or an elastic rubber sleeve, so that the elastic member 220 has better elasticity.

As shown in fig. 2 and 3, in one embodiment, the alignment take-up assembly 230 includes a driving member 232, a first gripper 234 and a second gripper 236, the driving member 232 is connected to the mounting base 210, and the first gripper 234 and the second gripper 236 are both connected to a power output end of the driving member 232, such that the driving member 232 drives the first gripper 234 and the second gripper 236 to move relatively. The positioning and pressing winding mechanism 100 is located between the first gripper 234 and the second gripper 236, and the driving member 232 is used for driving the first gripper 234 and the second gripper 236 to approach each other to form a gripping positioning slot for clamping the atomizing core, so that the positioning and tightening assembly 230 can reliably clamp and position the atomizing core on the positioning and pressing winding mechanism 100. The driving member 232 is further configured to drive the first gripper 234 and the second gripper 236 to move away from each other before the mounting sleeve is sleeved on the atomizing core, so as to release the atomizing core, and enable the mounting sleeve to be better sleeved on the atomizing core.

As shown in fig. 4 and 5, the first gripper 234 defines a first clamping groove 234a, and the second gripper 236 defines a second clamping groove 236a corresponding to the first clamping groove 234 a. The driving member 232 is used for driving the first gripper 234 and the second gripper 236 to approach each other when clamping the atomizing core, and is used for driving the first gripper 234 and the second gripper 236 to move away from each other when releasing the atomizing core. In this embodiment, the first clamping groove 234a and the second clamping groove 236a are communicated with each other to form a grip positioning groove. Since the first gripper 234 is formed with the first clamping groove 234a, the second gripper 236 is formed with the second clamping groove 236a corresponding to the first clamping groove 234 a. When the atomizing core is clamped, the driving member 232 drives the first gripper 234 and the second gripper 236 to approach each other, so that the atomizing core is clamped in the first clamping groove 234a and the second clamping groove 236a, and the atomizing core is positioned in the fixture jig assembly, so that the mounting sleeve is sleeved on the atomizing core; when releasing the atomizing core, the driving member 232 drives the first gripper 234 and the second gripper 236 away from each other; so through the relative motion of first grabhook 234 of driving piece 232 drive and second grabhook 236, realize the clamp of atomizing core or loosen, avoided the manual work to grasp the problem that the atomizing core exists the pine or tension, avoided the great problem of the degree of difficulty of atomizing core equipment in the installation sleeve seat, or avoided the problem that the efficiency of atomizing core equipment in the installation sleeve seat is lower, realized the self-holding location of atomizing core simultaneously, need not artifical the intervention, further improved the manufacturing efficiency of atomizing seat.

In order to securely connect the first gripper 234 and the second gripper 236, as shown in fig. 4 and 5, in one embodiment, the first gripper 234 further defines a connecting groove 234b, the connecting groove 234b is communicated with the first clamping groove 234a, and the second gripper 236 is partially located in the connecting groove 234b and connected with the first gripper 234, so as to securely connect the first gripper 234 and the second gripper 236.

In this embodiment, the assembly driving mechanism 300 is configured to drive the mounting sleeve to abut against and push the alignment elastic assembly 230 when the mounting sleeve is sleeved on the atomizing core, so that the mounting sleeve moves to a first predetermined position along with the alignment elastic assembly 200, and is configured to push the mounting sleeve to move from the first predetermined position to a second predetermined position when the alignment elastic assembly 230 loosens the atomizing core, so that the mounting sleeve is further assembled and sleeved on the atomizing core. Specifically, the assembly driving mechanism 300 drives the mounting sleeve to abut against the first gripper 234 and the second gripper 236. In order to make the assembly driving mechanism 300 better drive the installation sleeve to abut against and push the first gripper 234 and the second gripper 236, further, the first gripper 234 is further provided with a first positioning step groove 234c communicated with the first clamping groove 234a, the second gripper 236 is further provided with a second positioning step groove 236b communicated with the second clamping groove 236a, the first positioning step groove 234c is communicated with the second positioning step groove 236b to form a positioning step groove, the assembly driving mechanism 300 is used for driving the installation sleeve to abut against the inner wall of the positioning step groove and push the alignment elastic component 230 when the installation sleeve is sleeved on the atomizing core, and is used for pushing the installation sleeve to move from the first predetermined position to the second predetermined position when the alignment elastic component 230 releases the atomizing core, so that the installation sleeve reliably abuts against and pushes the first gripper 234 and the second gripper 236, not easy to slip, and simultaneously, the mounting sleeve seat and the atomizing core are reliably aligned and assembled.

It should be noted that the alignment elastic assembly 230 is elastically clamped to the atomizing core, and the alignment elastic assembly 230 and the atomizing core can move relative to each other, that is, the alignment elastic assembly 230 can move relative to the atomizing core along the axial direction of the atomizing core, and at the same time, the liquid guide on the surface of the atomizing core is prevented from being scattered and falling off the heater, so that the mounting sleeve seat is reliably assembled with the atomizing core, and meanwhile, the mounting sleeve seat is driven to abut against the inner wall of the positioning step groove and push the alignment elastic assembly 230 along with the assembly driving mechanism 300 when the mounting sleeve seat is sleeved on the atomizing core, so that the atomizing core is gradually assembled in the mounting sleeve seat, and the alignment elastic assembly 230 is used for pushing the mounting sleeve seat to move from the first predetermined position to the second predetermined position when the atomizing core is loosened, so that the atomizing core is completely assembled in the mounting sleeve seat.

In one embodiment, the first gripper 234 and the second gripper 236 are elastic clamping blocks, so that the first gripper 234 and the second gripper 236 have better elasticity, and the first gripper 234 and the second gripper 236 crush the atomizing core when clamping the atomizing core, and the first gripper 234 and the second gripper 236 clamp the atomizing core better.

In one embodiment, the first gripper 234 and the second gripper 236 are detachably connected to the power output end of the driving member 232, so that the first gripper 234 and the second gripper 236 can be replaced or maintained.

As shown in fig. 4 and 5, in one embodiment, the driving member 232 includes a driving member main body 232a, a first connector 232b and a second connector 232c, the power output end of the driving member main body 232a is connected to the first connector 232b and the second connector 232c respectively, the first gripper 234 is detachably connected to the first connector 232b, and the second gripper 236 is detachably connected to the second connector 232c, so that the first gripper 234 and the second gripper 236 are detachably connected to the power output end of the driving member 232.

As shown in fig. 4 and 5, in one embodiment, the driving member 232 further includes a first fixing member 232d and a second fixing member 232 e. The first connector 232b is provided with a first through hole, the first gripper 234 is provided with a first fixing hole, and the first fixing member 232d is respectively inserted into the first through hole and the first fixing hole, so that the first connector 232b is detachably connected with the first gripper 234. The second connector 232c is provided with a second through hole, the second gripper 236 is provided with a second fixing hole, and the second fixing piece is respectively arranged in the second through hole and the second fixing hole in a penetrating manner, so that the second connector 232c is detachably connected with the second gripper 236. In this embodiment, the first catch 234 and the second catch 236 are both bolts or screws.

As shown in fig. 4 and 5, in one embodiment, one of the first gripper 234 and the second gripper 236 is provided with a feeding notch 235, the feeding notch 235 is communicated with the grasping positioning slot, and the liquid guide member is fed through the feeding notch 235, so that the first clamping member can be clamped with the second clamping member before the atomized core is manufactured and molded, and the positioning and pressing winding mechanism 100 is located between the first clamping member and the second clamping member, so that the atomized core is molded between the first clamping member and the second clamping member through the positioning and pressing winding mechanism 100, thereby improving the convenience of the automatic cotton winding clamping device. In this embodiment, the positioning and pressing winding mechanism 100 winds the liquid guiding member located in the grasping positioning groove, so that the liquid guiding member rotates along with the heating wire and winds around the heating wire to form the atomizing core. In this embodiment, the feed notch 235 opens into the first catch 234.

As shown in fig. 2 and 3, in one embodiment, the alignment take-up mechanism 200 further includes an auxiliary telescopic assembly 240, the auxiliary telescopic assembly 240 is disposed on the base 400, and a power output end of the auxiliary telescopic assembly 240 is connected to the mounting base 210. The elastic component 220 cover is located the power take off end of supplementary flexible subassembly 240, supplementary flexible subassembly 240 is used for the equipment actuating mechanism 300 promotes drive when counterpointing the motion of take-up unit 200 the mount pad 210 is to the first direction motion, and is in counterpoint take-up unit 230 loosens drive when atomizing the core mount pad 210 to with the second direction motion that the first direction is opposite makes supplementary flexible subassembly 240 be in equipment actuating mechanism 300 promotes play supplementary effect of promoting mount pad 210 when counterpointing the motion of take-up unit 200, and play the effect that supplementary elastic component 220 resets when counterpointing take-up unit 230 and loosen the atomizing core. In this embodiment, the auxiliary telescopic assembly 240 is a cylinder telescopic assembly.

The application also provides a manufacturing method of the atomizing base, and the atomizing base is manufactured by adopting the manufacturing device of the atomizing base in any embodiment. As shown in fig. 6, further, the manufacturing method includes a part or all of the following steps:

s101, positioning the heating wire through the positioning, pressing and winding mechanism;

s103, pressing and abutting the liquid guiding piece on the heating wire through the positioning pressing and winding mechanism, and enabling the liquid guiding piece to rotate along with the heating wire and to be wound on the heating wire so as to form the atomizing core;

s105, clamping the atomization core through the alignment elastic mechanism;

s107, clamping the mounting sleeve seat through the assembling driving mechanism, and sleeving the mounting sleeve seat on the atomizing core;

s109, loosening the atomizing core through the alignment tightening mechanism;

and S111, assembling the mounting sleeve seat on the atomizing core through the assembling driving mechanism to obtain the atomizing seat.

When the atomizing base is manufactured, firstly, the heating wire is positioned through the positioning and pressing winding mechanism; then, the liquid guiding piece is pressed and abutted against the heating wire through the positioning pressing winding mechanism, and the liquid guiding piece rotates along with the heating wire and is wound on the heating wire to form an atomizing core; then the atomization core is clamped through an alignment elastic mechanism so as to clamp and position the atomization core; then clamping the mounting sleeve seat through an assembly driving mechanism, and sleeving the mounting sleeve seat on the atomizing core; then loosening the atomizing core through an alignment tightening mechanism; then assemble the mount sleeve seat in the atomizing core through equipment actuating mechanism, obtain the atomizing seat, so realize the automatic manufacturing of atomizing seat, the centre need not artifical intervention, has avoided traditional atomizing core to cup joint the not unanimous of elasticity in the mount sleeve seat at the atomizing core in manufacturing process, even unable equipment, also need not to loosen winding once more again, has avoided the equipment repeatedly, has solved the lower problem of packaging efficiency of atomizing seat.

In one embodiment, after the step S111 of assembling the mounting socket to the atomizing core by the assembling driving mechanism, the manufacturing method further includes:

s113, loosening the liquid guide part through the positioning, pressing and winding mechanism;

and S115, separating the atomizing base from the positioning, pressing and winding mechanism through the assembling driving mechanism.

In one embodiment, the step S115 of separating the atomizing base from the positioning, pressing and winding mechanism by the assembling and driving mechanism is specifically: through the equipment actuating mechanism will the atomizing seat extract in location compresses tightly winding mechanism, realize the automatic unloading of the atomizing seat that the equipment obtained, further improved the degree of automation of atomizing seat in manufacturing process.

The application also provides an atomizing base which is manufactured by adopting the manufacturing device of the atomizing base in any embodiment.

The application also provides an atomizer, including foretell atomizing seat.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims

1. An apparatus for manufacturing an atomizing base, comprising:

2. The manufacturing device of the atomizing base according to claim 1, further comprising a base, wherein the positioning, pressing and winding mechanism and the assembling driving mechanism are both disposed on the base, and the alignment and tightening mechanism is movably disposed on the base.

3. The manufacturing device of the atomizing base according to claim 2, wherein the assembly driving mechanism is configured to drive the mounting sleeve base to abut against and push the alignment release mechanism when the mounting sleeve base is sleeved on the atomizing core, so that the mounting sleeve base moves to a first predetermined position along with the alignment release mechanism; the alignment elastic mechanism is also used for loosening the atomizing core when the mounting sleeve seat is positioned at the first preset position.

4. The manufacturing device of the atomizing base according to claim 1, wherein after the mounting sleeve is sleeved and assembled on the atomizing core, the positioning and pressing winding mechanism releases the liquid guiding member, and the assembly driving mechanism separates the atomizing base from the positioning and pressing winding mechanism.

5. The manufacturing device of the atomizing base according to claim 4, wherein the positioning, pressing and winding mechanism comprises a rotary driving component, a positioning component and a pressing component, the positioning component is arranged at a power output end of the rotary driving component, the positioning component is used for positioning the heating wire, the pressing component is arranged at a power output end of the rotary driving component, and the pressing component is used for pressing and abutting the liquid guiding component against the heating wire and loosening the liquid guiding component after the mounting sleeve base is sleeved and assembled on the atomizing core.

6. A manufacturing method of an atomizing base, characterized in that the atomizing base is manufactured by using the manufacturing device of the atomizing base according to any one of claims 1 to 5, and the manufacturing method comprises the following steps:

the atomization core is clamped through the alignment elastic mechanism;

loosening the atomizing core through the alignment tightening mechanism;

7. The method of manufacturing an atomizing base according to claim 6, wherein after the step of assembling the mounting boss to the atomizing core by the assembling drive mechanism, the method further comprises:

8. The manufacturing method of the atomizing base according to claim 7, characterized in that the step of separating the atomizing base from the positioning, pressing and winding mechanism by the assembly driving mechanism is specifically as follows:

9. An atomizing base manufactured by the manufacturing device of the atomizing base according to any one of claims 1 to 5.

10. An atomizer, characterized in that it comprises an atomizing mount according to claim 9.