CN115336798B - Atomizing child lock structure and electronic atomizer - Google Patents

Abstract

This application provides a child lock structure for atomization and an electronic atomizer. The aforementioned child lock structure includes a base and a child lock assembly; the base has a child lock track through hole; the child lock assembly includes a child lock air guide and a child lock switch, the child lock air guide is connected to the base, the child lock air guide has a first child lock channel communicating with the interior of the housing, the child lock switch is movably connected to the base, the child lock switch is located on the side of the base opposite to the child lock air guide and covers the child lock track through hole, the child lock switch passes through the child lock track through hole and slides against the child lock air guide, the child lock switch has a second child lock channel. When unlocking, the child lock switch is moved to a designated position, aligning the second child lock channel with the first child lock channel, so that the second child lock channel and the first child lock channel are interconnected, thereby forming an air intake channel together, realizing the unlocking of the airway of the electronic atomizer.

Description

Atomizing child lock structure and electronic atomizer

Technical Field

The invention relates to the technical field of electronic atomization, in particular to an atomization child lock structure and an electronic atomizer.

Background

With the rapid development of electronic atomizers, the sales of electronic atomizers in society are increasing year by year. The electronic atomizer with good quality and good brands is popular with consumers and occupies a large market share. In the actual use process, in order to prevent the false use of minors, a child lock electronic chip is generally adopted for locking.

However, the traditional child lock chip is too high in cost, and the production cost of the electronic atomizer is easily out of standard.

Disclosure of Invention

The invention aims to overcome the defects in the prior art and provide an atomization child lock structure and an electronic atomizer which effectively reduce the production and manufacturing cost.

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

The atomizing child lock structure comprises a base and a child lock assembly, wherein the base is used for being connected with a shell of an electronic atomizer, a child lock track through hole is formed in the base, the child lock assembly comprises a child lock air guide piece and a child lock switch piece, the child lock air guide piece is connected with the base, at least part of the child lock air guide piece is located in the shell, the child lock air guide piece is provided with a first child lock channel communicated with the interior of the shell, the child lock switch piece is movably connected with the base, the child lock switch piece is located on one side, away from the child lock air guide piece, of the base and covers the child lock track through hole, the child lock switch piece penetrates through the child lock track through hole and is in sliding butt with the child lock air guide piece, and the child lock switch piece is provided with a second child lock channel which is used for isolating the child lock channel from the first child lock channel when in locking.

In one embodiment, the projection area of the child lock switch piece on the base is larger than the through hole area of the child lock track through hole.

In one embodiment, the ratio of the projection area of the child lock switch piece on the base to the through hole area of the child lock track through hole is 5 to 10.

In one embodiment, the child lock switch member has a sliding abutment surface, the sliding abutment surface and the base are disposed parallel to each other, and the sliding abutment surface is disposed on the base in a fitting manner.

In one embodiment, the child lock switch piece comprises a switch slide plate and a switch slide rod which are connected with each other, the switch slide plate is in sliding butt joint with the base, and the switch slide rod is arranged in the child lock track through hole in a penetrating mode and is in butt joint with the child lock air guide piece.

In one embodiment, the switch slide plate is provided with a first through hole, the switch slide rod is provided with a second through hole communicated with the first through hole, and the first through hole and the second through hole form the second child lock channel.

In one embodiment, the second child lock channel is provided on the switch slide.

In one embodiment, the child lock air guide is provided with a sliding groove communicated with the first child lock channel, the sliding groove is also communicated with the child lock track through hole, and a part of the switch sliding rod is slidably arranged in the sliding groove.

In one embodiment, the caliber of the sliding groove is equal to the diameter of the switch sliding rod.

An electronic atomizer comprising an atomized child lock structure according to any of the embodiments described above.

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

When the electronic atomizer is unlocked, the child lock switch piece is required to be moved to a designated position to align the second child lock channel with the first child lock channel, so that the second child lock channel and the first child lock channel are mutually communicated, the second child lock channel and the first child lock channel form an air inlet channel together, the interior of the electronic atomizer is conveniently communicated with the external environment, gas is conveniently led into the interior of the electronic atomizer, and the air passage of the electronic atomizer is unlocked.

Drawings

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

FIG. 1 is a schematic view of a misted child lock structure in one embodiment;

FIG. 2 is a cross-sectional view of the atomized child lock structure of FIG. 1 taken along the direction A-A;

FIG. 3 is another cross-sectional view of the atomized child lock structure of FIG. 1;

fig. 4 is a further cross-sectional view of the atomized child lock structure of fig. 1.

Detailed Description

In order that the invention may be readily understood, a more complete description of the invention will be rendered by reference to the appended drawings. The drawings illustrate preferred embodiments of the invention. 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 "fixed 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 are used herein for illustrative purposes only and are not meant to be the only embodiment.

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. The term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

The invention relates to an atomization child lock structure. In one embodiment, the atomized child lock structure includes a base and a child lock assembly. The base is used for being connected with the shell of the electronic atomizer, and the base is provided with a child lock track through hole. The child lock assembly includes a child lock air guide and a child lock switch. The child lock air guide piece is connected with the base, at least part of the child lock air guide piece is positioned in the shell, and the child lock air guide piece is provided with a first child lock channel communicated with the interior of the shell. The child lock switch piece with base swing joint, child lock switch piece is located the base deviates from child lock air guide piece's one side and covers child lock track through-hole, child lock switch piece wears to locate in the child lock track through-hole and with child lock air guide piece sliding butt, child lock switch piece has the second child lock passageway. The second child lock passage is configured to be isolated from the first child lock passage during locking. When the electronic atomizer is unlocked, the child lock switch piece is required to be moved to a designated position to align the second child lock channel with the first child lock channel, so that the second child lock channel and the first child lock channel are mutually communicated, the second child lock channel and the first child lock channel form an air inlet channel together, the interior of the electronic atomizer is conveniently communicated with the external environment, gas is conveniently led into the interior of the electronic atomizer, and the air passage of the electronic atomizer is unlocked.

Please refer to fig. 1, which is a schematic diagram illustrating an atomized child lock structure according to an embodiment of the present invention.

The atomized child lock structure 10 of an embodiment includes a base 100 and a child lock assembly 200. Referring to fig. 2, the base 100 is used for connecting with a housing of an electronic atomizer, and the base 100 is provided with a child lock track through hole 102. The child lock assembly 200 includes a child lock air guide 210 and a child lock switch 220. The child-resistant gas guide 210 is connected to the base 100, at least a portion of the child-resistant gas guide 210 is located in the housing, and the child-resistant gas guide 210 has a first child-resistant channel 202 in communication with the interior of the housing. The child lock switch 220 is movably connected with the base 100, the child lock switch 220 is located at a side of the base 100 away from the child lock air guide 210 and covers the child lock rail through hole 102, the child lock switch 220 is inserted into the child lock rail through hole 102 and slidably abuts against the child lock air guide 210, and the child lock switch 220 has a second child lock channel 204. The second child-lock channel 204 is configured to be isolated from the first child-lock channel 202 during locking.

In this embodiment, in the locked state, the second child lock channel 204 is not communicated with the first child lock channel 202, and in the unlocked state, the child lock switch member 220 needs to be moved to a designated position to align the second child lock channel 204 with the first child lock channel 202, so that the second child lock channel 204 and the first child lock channel 202 are communicated with each other, and the second child lock channel 204 and the first child lock channel 202 together form an air inlet channel, so that the interior of the electronic atomizer is conveniently communicated with the external environment, and air is conveniently introduced into the interior of the electronic atomizer, thereby realizing the air passage unlocking of the electronic atomizer.

In another embodiment, the child lock rail through hole has a specific rail shape, for example, the child lock rail through hole has a Z-shaped structure, and for example, the child lock rail through hole has an X-shaped structure. Therefore, only when the child lock switch piece moves to the appointed position of the child lock track through hole, namely moves along the appointed track, the second child lock channel and the first child lock channel can be communicated, so that the unlocking difficulty of the atomized child lock structure is improved, and the false unlocking probability of the atomized child lock structure is effectively reduced.

In one embodiment, referring to fig. 2, the projection area of the child lock switch 220 on the base 100 is larger than the through hole area of the child lock rail through hole 102. In this embodiment, the child lock switch 220 is disposed on the base 100, the child lock switch 220 slides on the base 100, and the child lock switch 220 is configured to communicate with the first child lock channel 202 through the second child lock channel 204 thereon to form an air guide channel. Only one air guide channel is formed between the child lock switch member 220 and the child lock air guide member 210, that is, when the child lock switch member 220 moves to a designated position, the child lock rail through hole 102 is further provided on the base 100, so that the child lock rail through hole needs to be kept closed for a long time. The projection area of the child lock switch 220 on the base 100 is designed to be larger than the through hole area of the child lock rail through hole 102, specifically, the child lock switch 220 always covers the child lock rail through hole 102 completely, at this time, the child lock switch 220 can also avoid the child lock rail through hole 102 from being opened when sliding on the base 100, so that the first child lock channel 202 is ensured not to be communicated with the outside when locking.

In another embodiment, the projected area of the child lock switch 220 on the base 100 is much larger than the through hole area of the child lock rail through hole 102, specifically, the ratio of the projected area of the child lock switch 220 on the base 100 to the through hole area of the child lock rail through hole 102 is 5 to 10. In yet another embodiment, the ratio of the projected area of the child lock switch 220 on the base 100 to the through hole area of the child lock track through hole 102 is 8.3.

In one embodiment, referring to fig. 2, the child lock switch 220 has a sliding contact surface, the sliding contact surface and the base 100 are disposed parallel to each other, and the sliding contact surface is disposed on the base 100 in a fitting manner. In this embodiment, the sliding abutment surface is located on a surface of the child lock switch 220 near the base 100, and the sliding abutment surface is used for sliding abutment with the base 100, so as to facilitate the child lock switch 220 moving on the base 100. The sliding abutting surface is arranged in parallel with the base 100, so that the movement smoothness of the child lock switch piece 220 on the base 100 is ensured, the child lock switch piece 220 is further ensured to be always attached to the base 100, and the child lock switch piece 220 is further ensured to completely cover the child lock rail through hole 102 all the time.

In one embodiment, referring to fig. 2, the child lock switch 220 includes a switch slide 222 and a switch slide bar 224 connected to each other, the switch slide 222 is slidably abutted to the base 100, and the switch slide bar 224 is disposed through the child lock rail through hole 102 and is abutted to the child lock air guide 210. In this embodiment, the switch slide 222 is slidably abutted to the base 100, that is, the switch slide 222 is parallel to the base 100, so that the switch slide 222 drives the switch slide 224 to move in the child lock track through hole 102. The switch slide bar 224 is partially located in the child lock track through hole 102, that is, the switch slide bar 224 passes through the child lock track through hole 102, the end of the switch slide bar 224 is slidably abutted against the child lock air guide 210, and the switch slide bar 224 serves as a sliding limit bar of the switch slide bar 222 on the base 100, so that the switch slide bar 224 is conveniently limited in a movable area of the child lock track through hole 102, and therefore a movement track of the child lock switch piece 220 is conveniently limited.

Further, referring to fig. 2, the switch sliding plate 222 is provided with a first through hole 206, the switch sliding rod 224 is provided with a second through hole 208 communicated with the first through hole 206, and the first through hole 206 and the second through hole 208 form the second child lock channel 204. In this embodiment, the first through hole 206 is located on the switch sliding plate 222, the second through hole 208 is located on the switch sliding rod 224, and the second through hole 208 is communicated with the first through hole 206, so that the first through hole 206 and the second through hole 208 together form the second child-lock channel 204, which is convenient for forming an air passage communicating with the first child-lock channel 202 in the child-lock switch piece 220.

Still further referring to fig. 3, the second child-lock channel 204 is disposed on the switch slide 222. In this embodiment, the switch slide 222 is provided with the second child-lock channel 204, that is, the switch slide 222 is provided with an air channel that is in communication with the first child-lock channel 202, specifically, the second child-lock channel 204 is always isolated from the first child-lock channel 202 when locked, and the second child-lock channel 204 is in communication with the first child-lock channel 202 when unlocked. Thus, when the switch slide 222 is not moved to the designated position, the second child-lock channel 204 is offset from the first child-lock channel 202 to block the air intake channel of the atomized child-lock structure, and when the switch slide 222 is moved to the designated position, the second child-lock channel 204 is aligned with the first child-lock channel 202 to open the air intake channel of the atomized child-lock structure.

Still further, referring to fig. 2, the child lock air guide 210 is provided with a sliding groove 201 that is communicated with the first child lock channel 202, the sliding groove 201 is also communicated with the child lock rail through hole 102, and a portion of the switch slide bar 224 is slidably disposed in the sliding groove 201. In this embodiment, the sliding groove 201 is located on the child lock air guide 210, and the opening of the sliding groove 201 faces the child lock switch 220, so as to accommodate a portion of the switch slide 224 therein. The sliding groove 201 is communicated with the child lock track through hole 102, so that when the switch slide bar 224 moves in the child lock track through hole 102, the sliding groove 201 serves as a movable space at the end part of the switch slide bar 224, namely, the sliding groove 201 serves as a movable area of the switch slide bar 224, and the child lock track through hole 102 limits the movement of the switch slide bar 224. In another embodiment, the child lock switch member 220 further includes a pressing plate connected to the switch sliding rod 224, the pressing plate is disposed opposite to the switch sliding plate 222, the pressing plate and the switch sliding plate 222 jointly clamp the base 100, and the pressing plate is located in the sliding groove 201. Wherein, the opening of the sliding groove 201 is larger than the aperture of the child lock track through hole 102.

Further, the diameter of the sliding groove 201 is equal to the diameter of the switch slide 224. In this embodiment, the end portion of the switch slide bar 224 moves in the sliding groove 201, and the diameter of the switch slide bar 224 is equal to the caliber of the sliding groove 201, so that the switch slide bar 224 is in sliding contact with the side wall of the sliding groove 201, so that the side wall of the sliding groove 201 is convenient to clamp the switch slide bar 224, and the sliding stability of the switch slide bar 224 in the sliding groove 201 is improved.

It can be appreciated that during the movement of the child lock switch 220, there is a circulation of the movement track, that is, under the limitation of the child lock track through hole 102, there is a certain probability that the child lock is opened by mistake, which easily results in that the atomized child lock structure is opened unintentionally, so that the unlocking difficulty is low.

In order to increase the unlocking difficulty of the atomized child lock structure, referring to fig. 4, the switch sliding rod 224 includes a first sliding rod 2242 and a second sliding rod 2244 that are connected to each other, the first sliding rod 2242 is connected to the switch sliding plate 222, one end of the first sliding rod 2242 away from the switch sliding plate 222 is slidingly abutted to the child lock air guide 210, a first end of the second sliding rod 2244 is connected to the first sliding rod 2242, a second end of the second sliding rod 2244 is slidingly abutted to the child lock air guide 210, the first sliding rod 2242 has a first air hole 203 that is communicated with the first through hole 206, and the second sliding rod 2244 has a second air hole 205 that is communicated with the first air hole 203, where the first air hole 203 and the second air hole 205 jointly form the second through hole 208. In this embodiment, the first sliding rod 2242 is used as a main sliding rod of the switch sliding rod 224, that is, the first sliding rod 2242 is used to support the switch sliding plate 222 to slide on the base 100, so as to ensure that the switch sliding plate 222 always covers the child lock track through hole 102, and the first sliding rod 2242 is provided with the first air vent 203, and the first air vent 203 is communicated with the first through hole 206, so as to facilitate the introduction of external air into the first sliding rod 2242. The second sliding rod 2244 is used as an auxiliary sliding rod of the switch sliding rod 224, that is, the second sliding rod 2244 is used for assisting the switch sliding plate 222 to slide on the base 100, so as to further ensure that the switch sliding plate 222 always covers the child lock track through hole 102, and the second sliding rod 2244 is provided with the second air vent 205, and the second air vent 205 is communicated with the first air vent 203, so that external air is conveniently led into the first child lock channel 202 through the first air vent 203 and the second air vent 205. Since the air outlet end of the second slide bar 2244 is far away from the first slide bar 2242, that is, the end of the second slide bar 2244 far away from the first slide bar 2242 abuts against the child-lock air guide 210, specifically, the switch slide bar 224 has an "h" shape, and the second air guide hole 205 of the second slide bar 2244 guides the external air. Thus, after the switch slide bar 224 moves to the designated position, the first slide bar 2242 needs to be rotated, so that the second slide bar 2244 rotates with the first slide bar 2242 as a central axis, and the second slide bar 2244 can be aligned with the first child lock channel 202, so that the second child lock channel 204 is communicated with the first child lock channel 202, and unlocking in both moving and rotating modes is further realized, so that unlocking difficulty of the atomized child lock structure is improved, and probability of false opening is effectively reduced.

Further, when the atomized lock structure is locked and not in use, although the second lock channel 204 is isolated from the first lock channel 202, the second lock channel 204 is still in long-term communication with the external environment, which easily causes dust in the external environment to enter the inside through the first air guide holes 203 and the second air guide holes 205, so that dirt is deposited inside the atomized lock structure to block the second lock channel 204.

In order to reduce the blockage of the second child lock channel 204, referring to fig. 4, the first sliding rod 2242 has a dust collection accommodating groove 207 in communication with the first air vent 203, the opening of the dust collection accommodating groove 207 faces to a side facing away from the child lock air guide 210, the dust collection accommodating groove 207 is aligned with the first air vent 203, and the dust collection accommodating groove 207 is used for collecting dust in the external environment. In this embodiment, the dust collection accommodating groove 207 is disposed in the first sliding rod 2242, the dust collection accommodating groove 207 is communicated with the first air vent 203, the dust collection accommodating groove 207 and the first air vent 203 form a dust collection channel, that is, the dust collection accommodating groove 207 is communicated with the outside through the first air vent 203, and external dust can fall into the dust collection accommodating groove 207 through the first air vent 203, so that dust in the external environment is collected by the dust collection accommodating groove 207, so that dust entering the inside of the atomized child lock structure is mainly deposited in the dust collection accommodating groove 207, the probability of external dust entering the second air vent 205 is effectively reduced, and the blockage of the second child lock channel 204 is effectively reduced.

Still further, after the first slide bar 2242 is moved to the designated position, the switch slide 222 may be rotated so that the second air vent 205 of the second slide bar 2244 communicates with the first child-lock passage 202. In order to facilitate the identification of the rotation angle of the switch slide plate 222, so that the rotation of the switch slide plate 222 is more convenient, referring to fig. 1, the switch slide plate 222 includes a plate body 2222 and a first identification portion 2224, the plate body 2222 is slidably disposed on the base 100, the first identification portion 2224 is connected with the plate body 2222, the first identification portion 2224 is disposed away from the first slide bar 2242, and the first identification portion 2224 corresponds to the second slide bar 2244, the child lock mechanism 10 further includes a second identification portion 300 connected with the base 100, the second identification portion 300 is disposed between the base 100 and the plate body 2222, the second identification portion 300 is disposed corresponding to the first child lock channel 202, and the second identification portion 300 is used for being exposed when the first slide bar 2242 moves to a specified position.

In this embodiment, the first identifier 2224 is located on a surface of the plate 2222 facing away from the base 100, so that the first identifier 2224 is identified and found, and the first identifier 2224 corresponds to the second sliding rod 2244, so that when the plate 2222 rotates, the rotation angle of the first identifier 2224 and the rotation angle of the second sliding rod 2244 are equal, and it is ensured that the rotation of the first identifier 2224 as the second sliding rod 2244 is the same. The second identification portion 300 is disposed on a surface of the base 100 near the plate body 2222, the second identification portion 300 corresponds to the first child lock channel 202, and the second identification portion 300 is used as an equivalent position of the first child lock channel 202 on the base 100. When the first sliding rod 2242 moves to a designated position, the second identification part 300 is not blocked by the plate body 2222, so that the second identification part 300 is exposed and is convenient to align with the first identification part 2224, and the plate body 2222 is convenient to rotate rapidly according to the relative position between the first identification part 2224 and the second identification part 300, so that the second air guide hole 205 of the second sliding rod 2244 is communicated with the first child lock channel 202, and the rapid rotation unlocking of the atomization child lock structure is realized. The atomized child lock structure is unlocked through a moving mode and a rotating mode, so that the unlocking difficulty of the atomized child lock structure is further increased, and the misunlocking probability of the atomized child lock structure is further reduced.

In one embodiment, the application further provides an electronic atomizer, which comprises the atomizing child lock structure according to any one of the embodiments. In this embodiment, the atomized child lock structure includes a base and a child lock assembly. The base is used for being connected with the shell of the electronic atomizer, and the base is provided with a child lock track through hole. The child lock assembly includes a child lock air guide and a child lock switch. The child lock air guide piece is connected with the base, at least part of the child lock air guide piece is positioned in the shell, and the child lock air guide piece is provided with a first child lock channel communicated with the interior of the shell. The child lock switch piece with base swing joint, child lock switch piece is located the base deviates from child lock air guide piece's one side and covers child lock track through-hole, child lock switch piece wears to locate in the child lock track through-hole and with child lock air guide piece sliding butt, child lock switch piece has the second child lock passageway. The second child lock passage is configured to be isolated from the first child lock passage during locking. When the electronic atomizer is unlocked, the child lock switch piece is required to be moved to a designated position to align the second child lock channel with the first child lock channel, so that the second child lock channel and the first child lock channel are mutually communicated, the second child lock channel and the first child lock channel form an air inlet channel together, the interior of the electronic atomizer is conveniently communicated with the external environment, gas is conveniently led into the interior of the electronic atomizer, and the air passage of the electronic atomizer is unlocked.

The above examples illustrate only a few embodiments of the invention, which are described in detail and are not to be construed as limiting the scope of the invention. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.

Claims (6)

1. A fogging child lock structure, characterized in that it comprises: A base for connecting to the housing of an electronic atomizer, the base having a child lock track through hole; A child lock assembly includes a child lock vent and a child lock switch. The child lock vent is connected to the base, and at least a portion of the vent is located within the housing. The vent has a first child lock channel communicating with the interior of the housing. The child lock switch is movably connected to the base, located on the side of the base opposite to the vent and covering the child lock track through-hole. The switch passes through the track through-hole and slides against the vent. The switch has a second child lock channel, which is isolated from the first channel when locked. The switch also has a sliding contact surface, which is parallel to the base and fits against it. The child lock switch includes a switch slide plate and a switch slide rod connected to each other. The switch slide plate slides against the base, and the switch slide rod passes through the child lock track through hole and abuts against the child lock air guide. The second child lock channel is opened on the switch slide plate. The switch slide plate has a first through hole, and the switch slide rod has a second through hole communicating with the first through hole. The first through hole and the second through hole form the second child lock channel. 2. The atomizing child lock structure according to claim 1, wherein the projected area of the child lock switch on the base is greater than the through-hole area of the child lock track through hole. 3. The atomizing child lock structure according to claim 2, wherein the ratio of the projected area of the child lock switch on the base to the through-hole area of the child lock track through hole is 5 to 10. 4. The atomizing child lock structure according to claim 1, characterized in that the child lock air guide is provided with a sliding groove communicating with the first child lock channel, the sliding groove is also communicating with the child lock track through hole, and a portion of the switch slide rod is slidably disposed in the sliding groove. 5. The atomizing child lock structure according to claim 4, wherein the diameter of the sliding groove is equal to the diameter of the switch slide rod. 6. An electronic atomizer, characterized in that it includes an atomization child lock structure as described in any one of claims 1 to 5.