CN216255436U - Machine body and electronic atomization device - Google Patents

Abstract

The utility model relates to an electronic atomization device and a machine body, wherein the electronic atomization device comprises: the microphone comprises a shell assembly, a microphone head and a gas passing assembly, wherein the gas passing assembly comprises a sealing element and a gas passing net, the sealing element is connected in the shell assembly in a matching manner, an airflow channel communicated between the microphone head and an atomization channel is formed in the sealing element, and the gas passing net is connected in the sealing element in a matching manner and at least partially extends into the gas passing channel; the bottom wall of the airflow channel is provided with a condensate tank, and the condensate tank is used for collecting condensate which is formed after the air net blocks and condenses smoke. Among the above-mentioned electron atomizing device, cross the gas net and can block and condense the smog that flows to the miaow head, and set up the condensate cistern on the diapire of gas channel, after smog is blockked by the gas net towards the in-process that the miaow head flows, smog is earlier at the last condensate that condenses of gas net, and later the condensate flows to the condensate cistern under self action of gravity, collects the condensate in the condensate cistern, prevents that the condensate from flowing to other parts and influence electron atomizing device's life.

Description

Machine body and electronic atomization device

Technical Field

The utility model relates to the technical field of atomization, in particular to a machine body and an electronic atomization device.

Background

The suction is generally sensed through the microphone to the current electron cigarette, and when the user when breathing in the atmospheric pressure of microphone department produced the change, atomizing component began to work, produced smog this moment and supply the user to enjoy. However, the atomizing assembly and the microphone are located on the same airflow path, the microphone is located right below the atomizing channel in the atomizing assembly, and condensate formed in the atomizing channel easily drops onto the microphone under the action of self gravity. And, when atomizing subassembly work produced smog, if the user carries out the suction action smog and can follow outlet channel discharge entering user's mouth, nevertheless the smog that forms when the user pauses the suction in the atomizing passageway can flow to the miaow head, runs into the in-process smog and touch spare part inner wall and can cool down and produce the condensate, and the condensate flow direction miaow head that forms through long-time accumulation makes the miaow head inefficacy, influences the life of miaow head.

SUMMERY OF THE UTILITY MODEL

Therefore, it is necessary to provide a body and an electronic atomizing device for solving the problem that a conventional electronic atomizing device is prone to head failure.

An electronic atomization device, the electronic atomization device comprising:

a housing assembly;

the atomization assembly is matched and connected in the shell assembly and is provided with an atomization channel;

the microphone is arranged in the shell assembly and is positioned on an airflow path of the outside airflow flowing to the atomization channel; and

the air passing assembly comprises a sealing piece and an air passing net, the sealing piece is matched and connected in the shell assembly, an air flow channel communicated between the microphone and the atomization channel is formed on the sealing piece,

the bottom wall of the airflow channel is downwards provided with a condensate liquid groove, the air passing net is arranged on the condensate liquid groove and extends into the air passing channel, the air passing net allows airflow to flow from the microphone to the atomizing channel, and the air passing net blocks and condenses smoke flowing from the atomizing channel to the microphone; the condensate groove is used for collecting condensate which is formed after the smoke is blocked by the air passing net and condensed.

In the electronic atomization device, the sealing element is provided with the air passing channel communicated between the microphone and the atomization channel, and the air passing net is connected to the sealing element in a matching manner and extends into the air passing channel. External air current can follow the air passing channel flow direction atomizing passageway of sealing member behind the miaow head, will cross the air net and join in marriage on the sealing member to as the installation basis of crossing the air net through the sealing member, cross the air net simultaneously and stretch into the air passing channel on the sealing member, can realize blockking and the effect of condensation smog. Furthermore, set up the condensate tank on the diapire of air passage, after smog is blockked by the air net towards the in-process that the miaow head flows, smog is at first the condensation on the air net and forms the condensate, and later the condensate flows to the condensate tank under self action of gravity, collects the condensate in the condensate tank, prevents that the condensate from flowing to other parts and influencing electronic atomization device's life.

In one embodiment, the air passing net comprises a mounting section and an air passing section which are connected with each other, the mounting section is sleeved in the condensate tank and is provided with a first section, a connecting section and a second section which are sequentially arranged from left to right; the gas passing section is connected with the second section, the first section, the connecting section and the second section are sequentially connected into a U shape, and the first section and the second section are oppositely arranged and are respectively abutted against two groove walls opposite to the condensate tank;

the air passing section is connected with the second section and protrudes out of the condensate groove to extend into the air passing channel, and the air passing section is used for blocking and condensing smoke flowing from the atomizing channel to the microphone.

In one embodiment, a plurality of through holes are formed in the air passing section through an etching process, and the through holes allow airflow to flow from the microphone to the atomizing channel and block smoke flowing from the atomizing channel to the microphone.

In one embodiment, a limiting protrusion is arranged on the bottom wall of the condensate tank, a limiting groove is formed in the connecting section, and the limiting protrusion is inserted into the limiting groove.

In one embodiment, the air-passing net is a metal piece.

In one embodiment, the housing assembly comprises an upper housing assembly and a lower housing assembly which are detachably connected with each other, the atomization assembly is assembled in the upper housing assembly, and the microphone is assembled in the lower housing assembly;

the air passing assembly is arranged in the upper shell assembly and/or the lower shell assembly.

In one embodiment, the lower shell assembly is provided with an air passing port communicated with the atomization channel;

the sealing element comprises a main body part and a matching part, the main body part is provided with an accommodating cavity, the microphone is arranged in the accommodating cavity, the matching part is provided with a gas passing channel and a condensate tank which are communicated between the accommodating cavity and the gas passing port, and the gas passing net is matched and connected with the matching part;

the axis of the air passing port and the axis of the atomization channel are arranged in a staggered mode.

In one embodiment, the lower housing assembly includes a first housing and a second housing opposite to each other, the microphone and the first housing are disposed at an interval, the sealing member is sleeved on a side of the microphone facing the second housing, the sealing member is abutted to the first housing, an air inlet channel located in the accommodating cavity is defined among the microphone, the first housing and the sealing member, and the first housing and the second housing are abutted to each other to form an air inlet communicated with the air inlet channel.

In one embodiment, a holding portion is disposed on an inner wall of the second housing, the holding portion is formed with a holding groove, the matching portion is disposed in the holding groove, one end of the air passing net is coupled to the matching portion, and the other end of the air passing net is abutted to a top wall of the holding groove.

A fuselage, the fuselage comprising:

the lower shell assembly is provided with an air passing port;

the microphone is arranged in the lower shell assembly and is positioned on an airflow path of external airflow flowing to the air passing port; and

the air passing assembly comprises a sealing piece and an air passing net, the sealing piece is matched and connected in the lower shell assembly, an air flow channel communicated between the microphone and the atomization channel is formed in the sealing piece, and the air passing net is matched and connected on the sealing piece and at least partially extends into the air passing channel; the air passing net allows air to flow from the microphone to the air passing opening through the air flow channel, and blocks and condenses smoke flowing from the atomizing channel to the microphone;

and a condensate tank is arranged on the bottom wall of the airflow channel and is used for collecting condensate formed after the smoke is blocked and condensed by the air passing net.

Drawings

FIG. 1 is a schematic cross-sectional view of an electronic atomizer in accordance with an embodiment of the present invention;

FIG. 2 is a schematic structural diagram of an electronic atomizer according to an embodiment of the present invention;

FIG. 3 is an exploded view of the electronic atomizer shown in FIG. 2;

FIG. 4 is an exploded view of the seal and air-passing network of the electrospray device of FIG. 1;

FIG. 5 is a schematic view showing the structure of a sealing member in the electron atomizer shown in FIG. 1;

fig. 6 is a schematic structural view of a second housing in the electronic atomizer shown in fig. 1.

300. An electronic atomization device; 310. a housing assembly; 200. an atomizer; 210. an atomizing assembly; 211. an atomizing channel; 220. an upper housing assembly; 100. a body; 10. a lower housing assembly; 11. a gas passing port; 12. a first housing; 14. a second housing; 15. an air inlet; 16. a chucking section; 30. a microphone; 50. passing through an air net; 51. a through hole; 52. an installation section; 53. a first stage; 54. a second stage; 55. a gas passing section; 70. a seal member; 71. a gas passage; 72. a main body portion; 73. an accommodating cavity; 731. an air intake passage; 74. a fitting portion; 75. a condensate tank.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

In the description of the present invention, it is to be understood that the terms "central," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," "axial," "radial," "circumferential," and the like are used in the orientations and positional relationships indicated in the drawings for convenience in describing the utility model and to simplify the description, and are not intended to indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and are not to be considered limiting of the utility model.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In the present invention, unless otherwise expressly stated or limited, the first feature "on" or "under" the second feature may be directly contacting the first and second features or indirectly contacting the first and second features through an intermediate. Also, a first feature "on," "over," and "above" a second feature may be directly or diagonally above the second feature, or may simply indicate that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature.

It will be understood that when an element is referred to as being "secured to" or "disposed on" 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," "upper," "lower," "left," "right," and the like as used herein are for illustrative purposes only and do not denote a unique embodiment.

Referring to fig. 1, in an embodiment of the present invention, an electronic atomizing device 300 is provided, which includes a housing assembly 310, an atomizing assembly 210, and a microphone 30.

In some embodiments, the atomizing assembly 210 is coupled within the housing assembly 310 and has an atomizing channel 211, wherein an aerosol can be formed within the atomizing channel 211. Specifically, be formed with the stock solution chamber in the casing subassembly 310, atomizing component 210 locates the stock solution intracavity, and the atomizing core in the atomizer 210 passes atomizing passageway 211 and stretches into the stock solution intracavity to absorb the tobacco juice in the stock solution intracavity, and then make the adsorbed tobacco juice in the atomizing core flow to atomizing passageway 211 after the atomizing is heated, form the smog that supplies the user to inhale. The microphone 30 is disposed in the housing assembly 310 and located on an airflow path of the external airflow flowing to the atomizing channel 211, so as to sense the air pressure variation, i.e. the number of times of pumping, when the electronic atomizing device 300 is pumped.

Further, the electronic atomizing device 300 further includes an air passing assembly, the air passing assembly includes an air passing net 50, the air passing net 50 is disposed on the airflow path between the microphone 30 and the atomizing channel 211, the air passing net 50 allows the airflow to flow from the microphone 30 to the atomizing channel 211, and the air passing net 50 blocks and condenses the smoke flowing from the atomizing channel 211 to the microphone 30. Thus, the air net 50 is arranged on the air flow path between the microphone 30 and the atomization channel 211, when the electronic atomization device 300 works, external air flows enter the electronic atomization device 300 and flow to the atomization channel 211 from the air net 50 after passing through the microphone 30, the air flows are mixed with the smoke formed by atomization in the atomization channel 211, and a part of the air flows mixed with the smoke flows to the outside from the exhaust channel for the user to suck. When the user suspends smoking, smog in the atomizing channel 211 flows to the microphone 30 and is blocked by the air net 50 in the flowing process, the smog is condensed on the air net 50, and condensate formed by condensation is attached to the surface, back to the microphone 30, of the air net 50 so as to block the condensate from flowing to the microphone 30, the microphone 30 is prevented from being damaged, and the service life of the microphone 30 is prolonged.

Further, a plurality of through holes 51 are formed on the air net 50 through an etching process, and the through holes 51 allow airflow from the microphone 30 to the atomizing passage 211 and block smoke flowing from the atomizing passage 211 to the microphone 30. Thus, the through holes 51 on the air passing net 50 can allow the airflow to pass through, but the smoke particles formed by atomization are large and cannot pass through the through holes 51, and the smoke is blocked and then condensed on the air passing net 50 to form condensate, and the formed condensate cannot permeate through the through holes 51 and cannot flow to the microphone 30.

Specifically, the aperture of the through-hole 51 may be made small, so that the plurality of small-aperture through-holes 51 allow only air passage, while blocking passage of smoke and condensate. Optionally, the aperture of the through-hole 51 is 0.08-0.15 mm.

Furthermore, the air passing net 50 is a metal member, and the temperature of the air passing net 50 as the metal member is low, so that the smoke with high temperature can be condensed after contacting the air passing net 50 with low temperature, so as to condense the smoke on the air passing net 50.

In some embodiments, the air passing assembly further includes a sealing member 70, the sealing member 70 is coupled to the housing assembly 10, the sealing member 70 forms an air passing channel 71 communicating between the microphone 30 and the nebulizing channel 211, and the air passing net 50 is coupled to the sealing member 70 and extends into the air passing channel 71. After passing through the microphone 30, the external airflow can flow from the air passing channel 71 of the sealing member 70 to the atomizing channel 211, and the air passing net 50 is coupled to the sealing member 70, so that the sealing member 70 serves as an installation base of the air passing net 50, and meanwhile, the air passing net 50 extends into the air passing channel 71 of the sealing member 70, and the effects of blocking and condensing smoke can be achieved.

Further, a condensate tank 75 is formed at the bottom wall of the air passing channel 71 and is downward, and the condensate tank 75 is used for collecting condensate which is blocked by the air passing net 50 and formed after the smoke is condensed. In this way, the bottom wall of the air passage 71 is provided with the condensate tank, and after the smoke is blocked by the air passing net 50 in the process of flowing towards the microphone 30, the smoke is firstly condensed on the air passing net 50 to form condensate, and then the condensate flows to the condensate tank 75 under the action of self gravity, and is collected in the condensate tank 75, so that the condensate is prevented from flowing to other parts to influence the service life of the electronic atomization device 100.

Further, the air passing net 50 includes a mounting section 52 and an air passing section 55 connected to each other, the mounting section 52 is sleeved in the condensate tank 75, and the air passing section 55 protrudes out of the condensate tank 75 and extends into the air passing channel 71, and blocks and condenses smoke flowing from the atomizing channel 211 to the microphone 30. The mounting section 52 is partially sleeved and coupled in the condensate tank 75, so that the mounting section 52 is in fit with the condensate tank 75 to limit the air passing net 50. In addition, a plurality of through holes 51 are formed in the part of the air passing net 50 extending into the air passing channel 71, so that the air passing net 50 extending into the air passing channel 71 allows the air flow to the atomizing channel 211 through the through holes 51, and meanwhile, the smoke flowing to the smoke passing net 50 through the atomizing channel 211 is blocked and condensed by the air passing net 50 extending into the air passing channel 71.

Furthermore, a condensate groove 75 and an air passing section 55 are sequentially arranged on a smoke path from the atomizing channel 211 to the microphone in the air flow channel, namely the condensate groove 75 is positioned at the smoke path upstream of the air passing section 55, and the condensate groove 75 is positioned at one side of the air passing section 55 where condensate is formed, so that the condensate formed on the air passing section 55 can be collected through the condensate groove 75.

Specifically, on a smoke path from the atomizing channel 211 to the microphone in the airflow channel, the mounting section 52 has a first section 53, a connecting section, and a second section 54 that are sequentially arranged (i.e., the first section 53, the connecting section, and the second section 54 are sequentially arranged from left to right), the first section 52, the connecting section, and the second section 54 are sequentially connected to form a U-shape, and the first section 53 and the second section 54 are connected by the connecting section; first section 53 and second section 54 set up relatively and respectively with two cell wall butts that condensate groove 75 is relative, so through the butt of first section 53 and second section 54, locate the installation department 52 in condensate groove 75 steadily, prevent that installation department 52 from rocking. And, the gas passing section 55 is connected with the second section 54, so that the gas passing section 55 is located at the downstream of the condensate tank 75 in the smoke path, so that the condensate tank 75 is located at the side where the gas passing section 55 blocks and condenses the smoke, and the condensate formed on the gas passing section 55 can fall into the condensate tank 75 under the action of its own gravity.

Optionally, be provided with spacing arch on the diapire of condensate groove 75, seted up spacing recess on the linkage segment of installation department 52, when installation department 52 assembled in condensate groove 75, spacing arch was inserted in spacing recess to carry on spacingly to installation department 52, further prevent that installation department 52 from rocking in condensate groove 75.

Referring to fig. 1-3, in some embodiments, housing assembly 310 includes upper housing assembly 220 and lower housing assembly 10 removably coupled to each other, and atomization assembly 210 is mated to upper housing assembly 220 to form atomizer 200. The microphone 30 is fitted into the lower housing assembly 10 to form the body 100, and the body 100 and the nebulizer 200 are detachably connected. When the tobacco tar in the atomizer 200 is used up, the atomizer 200 can be replaced conveniently, so that the machine body 100 can be reused. Further, still be provided with the electric core in the fuselage 100, the electric core is used for supplying power for atomizing component 210, and atomizing component 210 heats atomizing tobacco tar after the circular telegram and forms smog, supplies the user suction.

Referring to fig. 1 and 4-5, in some embodiments, the air passing net 50 is disposed in the lower shell assembly 10, i.e., the air passing net 50 is disposed on the fuselage 100 to effectively block the condensate. Further, the lower housing assembly 10 is provided with an air vent 11 communicated with the atomization passage 211, the sealing element 70 includes a main body portion 72 and a matching portion 74 which are connected with each other, the main body portion 72 has a receiving cavity 73, the microphone 30 is installed in the receiving cavity 73, the matching portion 74 is provided with an air vent 71 communicated between the receiving cavity 73 and the air vent 11 and a condensate groove 75, and the air vent 50 is connected to the matching portion 74 in a matching manner. The sealing member 70 is provided with a main body part 72 and a matching part 74, the main body part 72 is sleeved on the sealing microphone 30, the matching part 74 is used for forming the air passing channel 71 and carrying the air passing net 50, and condensate formed by the air passing net 50 blocking and condensing smoke is collected in a condensate groove 75 of the matching part 74. The external air flow enters the electronic atomization device 300, and can flow to the air passing channel 71 through the microphone 30, and then flow to the atomization channel 211 after passing through the air passing net 50 in the air passing channel 71.

Optionally, the axis of air passing port 11 and the axis of atomizing passageway 211 are misplaced to make air passing port 11 and atomizing passageway 211 stagger, and the condensate that forms in atomizing passageway 211 can directly not fall into air passing port 11, reduces the condensate that gets into in the lower shell subassembly 10, the protection miaow head.

Referring to fig. 3, in some embodiments, the lower housing assembly 10 includes a first housing 12 and a second housing 14 opposite to each other, the microphone 30 is disposed at a distance from the first housing 12, the sealing element 70 is disposed on a side of the microphone 30 facing the second housing 14 and is abutted against the first housing 12, an air inlet passage 731 in the accommodating chamber 73 is defined between the microphone 30, the first housing 12 and the sealing element 70, and the first housing 12 and the second housing 14 are abutted against each other to form an air inlet 15 communicated with the air inlet. Thus, the microphone 30 is spaced apart from the first housing 12, and the sealing member 70 is sleeved on a side of the microphone 30 facing the second housing 14, so that the external air can enter the accommodating cavity 73 through the air inlet 15 between the first housing 12 and the second housing 14, pass through the microphone 30 from the air inlet passage 731 between the microphone 30 and the first housing 12, and finally enter the air passing passage 71 to achieve air suction.

Further, one end of the air passing net 50 far away from the sealing member 70 abuts against the first housing 12, so that one end of the air passing net 50 is connected to the sealing member 70, and the other end of the air passing net 50 abuts against the first housing 12, so that the air passing net 50 is completely blocked in the air passing channel 71 between the sealing member 70 and the first housing 12, and smoke is effectively blocked. Further, the contact between the air passing net 50 and the first housing 12 improves the mounting stability of the air passing net 50.

Referring to fig. 5-6, further, a retaining portion 16 is disposed on an inner wall of the second housing 14, and a sealing element 70 is mounted on the retaining portion 16 to limit and fix the sealing element 70 by the retaining portion 16, so that the sealing element 70 is fixed on the second housing 14. Specifically, the holding portion 16 surrounds the periphery of the sealing member 70, and holds the engaging portion 74, and applies a limiting force to the engaging portion 74, so as to only allow the engaging portion 74 to be clamped into or withdrawn from the holding portion 16 in a direction perpendicular to the second housing 14, and to limit the engaging portion 74 in other directions parallel to the second housing 14, so as to prevent the engaging portion 74 from shaking, and thus prevent the sealing member 70 from shaking. Specifically, the clamping portion 16 is provided with a clamping groove, the matching portion 74 is sleeved in the clamping groove, one end of the air passing net 50 is connected to the matching portion 74 in a matching manner, and the other end of the air passing net 50 is abutted to the top wall of the clamping groove, so that a certain limiting force is provided for the air passing net 50, the air passing net 50 is prevented from shaking under the driving of air flow, and the installation stability of the air passing net 50 is improved.

In other embodiments, the air net 50 is disposed within the upper housing assembly 220, i.e., the air net 50 is disposed on the atomizer 200.

A pass-through air net 50 is fitted within the upper housing assembly 220 and the pass-through air net 50 is provided in the air flow path between the microphone 30 and the nebulizing channel 211, the pass-through air net 50 allowing air flow from the microphone 30 to the nebulizing channel 211 and the pass-through air net 50 blocking and condensing smoke flowing from the nebulizing channel 211 to the microphone 30. Thus, the air net 50 is arranged on the air flow path between the microphone 30 and the atomization channel 211, when the electronic atomization device 300 works, external air flows enter the electronic atomization device 300 and flow to the atomization channel 211 from the air net 50 after passing through the microphone 30, the air flows are mixed with the smoke formed by atomization in the atomization channel 211, and a part of the air flows mixed with the smoke flows to the outside from the exhaust channel for the user to suck. When the user suspends smoking, the smoke in the atomizing channel 211 flows towards the microphone 30 and is blocked by the air net 50 in the flowing process, the smoke is condensed on the air net 50, the condensate formed by condensation is attached to the surface, back to the microphone 30, of the air net 50, so that the condensate is blocked from flowing towards the microphone 30, the microphone 30 is prevented from being damaged by the condensate, and the service life of the microphone 30 is prolonged.

In the electronic atomizer 300, the electronic atomizer 300 includes a housing assembly 310, an atomizer assembly 210, and a microphone 30. The atomizing assembly 210 is coupled in the housing assembly 310 and has an atomizing channel 211, and an aerosol can be formed in the atomizing channel 211. The microphone 30 is disposed in the housing assembly 310 and located on an airflow path of the external airflow flowing to the atomizing channel 211, so as to sense the air pressure variation, i.e. the number of times of pumping, when the electronic atomizing device 300 is pumped.

The electronic atomizing device 300 further includes an air passing assembly, the air passing assembly includes an air passing net 50, the air passing net 50 is disposed on an air flow path between the microphone 30 and the atomizing channel 211, the air passing net 50 allows the air flow to flow from the microphone 30 to the atomizing channel 211, and the air passing net 50 blocks and condenses the smoke flowing from the atomizing channel 211 to the microphone 30. Thus, the air net 50 is arranged on the air flow path between the microphone 30 and the atomization channel 211, when the electronic atomization device 300 works, external air flows enter the electronic atomization device 300 and flow to the atomization channel 211 from the air net 50 after passing through the microphone 30, the air flows are mixed with the smoke formed by atomization in the atomization channel 211, and a part of the air flows mixed with the smoke flows to the outside from the exhaust channel for the user to suck. When the user suspends smoking, smog in the atomizing channel 211 flows to the microphone 30 and is blocked by the air net 50 in the flowing process, the smog is condensed on the air net 50, and condensate formed by condensation is attached to the surface, back to the microphone 30, of the air net 50 so as to block the condensate from flowing to the microphone 30, the microphone 30 is prevented from being damaged, and the service life of the microphone 30 is prolonged.

Specifically, the air passing assembly further includes a sealing member 70, the sealing member 70 is coupled in the housing assembly 310, an air passing channel 71 communicating between the microphone 30 and the nebulizing channel 211 is formed on the sealing member 70, and the air passing net 50 is coupled on the sealing member 70 and blocked in the air passing channel 71. After passing through the microphone 30, the external airflow can flow from the air passing channel 71 of the sealing member 70 to the atomizing channel 211, and the air passing net 50 is coupled to the sealing member 70, so that the sealing member 70 serves as an installation base of the air passing net 50, and meanwhile, the air passing net 50 extends into the air passing channel 71 of the sealing member 70, and the effects of blocking and condensing smoke can be achieved.

Further, a condensate tank 75 is formed in the bottom wall of the air passing channel 71, and the condensate tank 75 is used for collecting condensate which is formed after the smoke is blocked and condensed by the air passing net 50. In this way, the condensation liquid groove 75 is formed in the bottom wall of the air passing channel 71, and after the smoke is blocked by the air passing net 50 in the process of flowing towards the microphone 30, the smoke is firstly condensed on the air passing net 50 to form condensation liquid, and then the condensation liquid flows to the condensation liquid groove 75 under the action of self gravity, so that the condensation liquid is collected in the condensation liquid groove 75, and the phenomenon that the service life of the electronic atomization device 300 is influenced due to the fact that the condensation liquid flows to other parts is prevented.

Referring to fig. 2-3, based on the same concept, in an embodiment of the present invention, there is also provided the above-mentioned body 100, wherein the body 100 includes a lower housing assembly 10 and a microphone 30, the lower housing assembly 10 is formed with an air vent 11, and the microphone 30 is disposed in the lower housing assembly 10 and located on an airflow path of an external airflow flowing to the air vent 11. When the atomizing assembly 210 is detachably assembled to the housing, the air vent 11 of the housing is communicated with the atomizing channel 211 of the atomizing assembly 210, so that when a user sucks the electronic atomizing device 300, external air can flow into the atomizing channel 211 through the microphone 30 after flowing to the air vent 11, and the microphone 30 senses air pressure change when the electronic atomizing device 300 is sucked, so as to sense the suction frequency.

The fuselage 100 further comprises an air passing assembly, which includes an air passing net 50 and a sealing member 70, wherein the sealing member 70 is coupled in the shell assembly 310, the sealing member 70 is formed with an air passing channel 71 communicated between the microphone 30 and the air passing opening 11, and the air passing net 50 is coupled on the sealing member 70 and blocked in the air passing channel 71. After passing through the microphone 30, the external airflow can flow from the air passing channel 71 of the sealing member 70 to the atomizing channel 211, and the air passing net 50 is coupled to the sealing member 70, so that the sealing member 70 serves as an installation base of the air passing net 50, and meanwhile, the air passing net 50 extends into the air passing channel 71 of the sealing member 70, and the effects of blocking and condensing smoke can be achieved.

Further, a condensate tank 75 is formed in the bottom wall of the air passing channel 71, and the condensate tank 75 is used for collecting condensate which is formed after the smoke is blocked and condensed by the air passing net 50. In this way, the condensation liquid groove 75 is formed in the bottom wall of the air passing channel 71, and after the smoke is blocked by the air passing net 50 in the process of flowing towards the microphone 30, the smoke is firstly condensed on the air passing net 50 to form condensation liquid, and then the condensation liquid flows to the condensation liquid groove 75 under the action of self gravity, so that the condensation liquid is collected in the condensation liquid groove 75, and the phenomenon that the service life of the electronic atomization device 300 is influenced due to the fact that the condensation liquid flows to other parts is prevented.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

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 utility model. 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 (10)

1. An electronic atomization device, comprising:

a housing assembly;

the atomization assembly is matched and connected in the shell assembly and is provided with an atomization channel;

the microphone is arranged in the shell assembly and is positioned on an airflow path of the outside airflow flowing to the atomization channel; and

the air passing assembly comprises a sealing piece and an air passing net, the sealing piece is matched and connected in the shell assembly, an air flow channel communicated between the microphone and the atomization channel is formed on the sealing piece,

the microphone comprises an airflow channel, a microphone head, an atomizing channel, a condensate tank, an air passing net, a condensate tank and a condenser, wherein the bottom wall of the airflow channel is downwards provided with the condensate tank, the air passing net is arranged in the condensate tank and extends into the airflow channel, the air passing net allows airflow to flow to the atomizing channel from the microphone head, blocks and condenses smoke flowing from the atomizing channel to the microphone head, and the condensate tank is used for collecting condensate formed after the smoke is blocked and condensed by the air passing net.

2. The electronic atomization device of claim 1, wherein the air passing net comprises a mounting section and an air passing section which are connected with each other, the mounting section is sleeved and connected in the condensate tank, the mounting section is provided with a first section, a connecting section and a second section which are sequentially arranged from left to right, the first section, the connecting section and the second section are sequentially connected into a U shape, and the first section and the second section are oppositely arranged and are respectively abutted against two opposite tank walls of the condensate tank;

the air passing section and the second section should not be connected, and the air passing section protrudes out of the condensed liquid groove and extends into the airflow channel and is used for blocking and condensing smoke flowing from the atomizing channel to the microphone.

3. The electronic atomizing device according to claim 2, wherein a plurality of through holes are formed on the air passing section through an etching process, and the through holes allow air to flow from the atomizing head to the atomizing channel and block smoke flowing from the atomizing channel to the atomizing head.

4. The electronic atomization device of claim 2, wherein a limiting protrusion is disposed on a bottom wall of the condensate tank, a limiting groove is disposed on the connection section, and the limiting protrusion is inserted into the limiting groove.

5. The electronic atomization device of any one of claims 1-4 wherein the air-over-mesh is a metallic piece.

6. The electronic atomizer device as set forth in any one of claims 1-4, wherein said housing assembly comprises an upper housing assembly and a lower housing assembly removably coupled to each other, said atomizer assembly being coupled to said upper housing assembly, said housing head being coupled to said lower housing assembly;

the air passing assembly is arranged in the upper shell assembly and/or the lower shell assembly.

7. The electronic atomizer according to claim 6, wherein said lower housing member defines a vent opening therein communicating with said atomizing passage;

the sealing element comprises a main body part and a matching part, the main body part is provided with an accommodating cavity, the microphone is arranged in the accommodating cavity, the matching part is provided with an airflow channel communicated between the accommodating cavity and the air passing port, and the air passing net is matched and connected with the matching part;

the axis of the air passing port and the axis of the atomization channel are arranged in a staggered mode.

8. The electronic atomizing device according to claim 7, wherein the lower housing assembly includes a first housing and a second housing opposite to each other, the microphone is spaced apart from the first housing, the sealing member is disposed on a side of the microphone facing the second housing, the sealing member is abutted with the first housing, the microphone, the first housing and the sealing member define therebetween an air inlet channel located in the accommodating chamber, and the first housing and the second housing are abutted with each other to form an air inlet communicated with the air inlet channel.

9. The electronic atomizing device of claim 8, wherein a retaining portion is disposed on an inner wall of the second housing, the retaining portion has a retaining groove, the engaging portion is disposed in the retaining groove, and one end of the air-passing net is coupled to the engaging portion, and the other end of the air-passing net abuts against a top wall of the retaining groove.

10. A fuselage, characterized in that the fuselage comprises:

the lower shell assembly is provided with an air passing port;

the microphone is arranged in the lower shell assembly and is positioned on an airflow path of external airflow flowing to the air passing port; and

the air passing assembly comprises a sealing element and an air passing net, the sealing element is matched and connected in the lower shell assembly, an air flow channel communicated between the microphone and the air passing opening is formed in the sealing element, and the air passing net is matched and connected on the sealing element and at least partially extends into the air flow channel; the air passing net allows airflow to flow from the microphone to the atomizing channel through the airflow channel, and blocks and condenses smoke flowing from the atomizing channel to the microphone;

and a condensate tank is arranged on the bottom wall of the airflow channel and is used for collecting condensate formed after the smoke is blocked and condensed by the air passing net.

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