CN214431822U - Atomizing core, atomizer and electronic atomization device - Google Patents

Abstract

The utility model relates to an atomizing core, atomizer and electron atomizing device. The atomizing core includes: the base body is provided with an atomizing surface and used for buffering and conducting liquid. And the heating body comprises a heating part attached to the base body, and the heating part can generate heat to atomize the liquid on the atomizing surface to form smoke. And the protective layer is arranged on the atomizing surface and covers the heating part, and smoke can overflow from the protective layer. Through setting up this inoxidizing coating, the overwhelming majority liquid particle and the solid particle in the smog of backward flow to atomizing core will directly adsorb in the protective layer for the inoxidizing coating has good filter function, avoids this part liquid particle and solid particle flow direction atomizing face and form and gather the surface of generating heat and the cigarette on every side and make down, thereby reduces the liquid particle that is used for turning into the cigarette and makes down in the smog by a wide margin and the proportion of solid particle, and then reduces the gathering and make up at the surface of generating heat and the cigarette on every side and make down the volume.

Description

Atomizing core, atomizer and electronic atomization device

Technical Field

The utility model relates to an atomizing technical field especially relates to an atomizing core, atomizer and contain the electron atomizing device of this atomizer.

Background

The electronic atomization device has the appearance and taste similar to those of a common cigarette, but generally does not contain tar, suspended particles and other harmful ingredients in the cigarette, so the electronic atomization device is widely used as a substitute of the cigarette. Electronic atomization device includes the atomizer usually, and the atomizer includes the atomizing core, and the atomizing core includes base member and heat-generating body, and stock solution chamber in the base member shutoff atomizer and can the buffer memory with the liquid of conduction stock solution intracavity, the heat-generating body setting is used for atomizing the liquid of conduction to the base member in order to form the smog that can supply the user's suction on the base member. However, with the conventional atomizer, smoke and soil are accumulated on the surface and the periphery of the heating body, and the smoke and soil continuously accumulate to form scorched smell or other peculiar smell in the smoke, so that the user experience is influenced.

SUMMERY OF THE UTILITY MODEL

The utility model provides a technical problem how hinder the cigarette and object and gather on the surface of heat-generating body and around.

An atomizing cartridge comprising:

the base body is provided with an atomizing surface and is used for buffering and conducting liquid;

a heat generating body including a heat generating portion attached to the base body, the heat generating portion being capable of generating heat to atomize the liquid on the atomizing surface to form mist; and

the protective layer is arranged on the atomizing surface and covers the heating part, and smoke can overflow from the protective layer.

In one embodiment, the protective layer has micropores formed therein and has a porosity of 30% to 70%, and a thickness of 100 μm to 500 μm.

In one embodiment, the heating element further comprises an electrode part for conducting electricity, the electrode part is electrically connected with the heating part, and the protective layer further covers all the electrode part.

In one embodiment, the protective layer has a covering surface arranged towards the atomizing surface, the covering surface is recessed to form a groove, and at least one part of the heat generating part is matched with the groove.

In one embodiment, the heat generating part is a line-shaped structure or a film-shaped structure; when the heat generating member is a film-like structure, the thickness of the heat generating portion is 30 to 130 μm.

In one embodiment, the matrix has micropores formed therein and has a porosity of 20 to 70%, and a thickness of 2 to 5 mm.

An atomizing cartridge comprising:

the base body is provided with an atomizing surface and is used for buffering and conducting liquid;

a heat generating body including a heat generating portion attached to the base body, the heat generating portion being capable of generating heat to atomize the liquid on the atomizing surface to form mist; and

the inoxidizing coating, the inoxidizing coating sets up on the atomizing face, the inoxidizing coating has dorsad the bottom surface that the atomizing face set up, set up on the bottom surface and run through the groove that runs through of inoxidizing coating, at least part the portion that generates heat is located run through the inslot, just the portion that generates heat be located run through the surface in the groove with the bottom surface is followed the thickness direction of inoxidizing coating keeps the settlement distance.

In one embodiment, the protective layer is provided with a covering surface which is arranged opposite to the bottom surface to cover the atomization surface, the protective layer is further provided with a vent hole, the vent hole penetrates through the covering surface and is communicated with the outside, and smoke can overflow from the vent hole.

In one embodiment, the vent hole forms a through hole on the covering surface, the through hole has an orthographic projection on the atomizing surface, and the orthographic projection keeps a set distance from the covering range of the heating part.

In one embodiment, the ventilation hole has an orthographic projection on the atomization surface, and the orthographic projection keeps a set distance from the coverage range of the heating part.

In one embodiment, the central axis of the vent hole and the atomization surface are arranged at an acute included angle; or, the air vent includes first bending segment and the second bending segment that communicates each other, first bending segment runs through the coverage, the second bending segment directly communicates the external world, the central axis of first bending segment with the contained angle setting is personally submitted in the atomizing, the central axis of second bending segment with the central axis of first bending segment is the contained angle setting.

An atomizer, offer the stock solution cavity and include any one the above-mentioned atomizing core, the base member still has with the atomizing surface is towards opposite imbibition face, the imbibition face is used for with the liquid in the stock solution cavity is inhaled in the base member.

An electronic atomization device comprises a power supply and the atomizer, wherein the power supply is electrically connected with a heating body.

The utility model discloses a technical effect of an embodiment is: through setting up this inoxidizing coating, the overwhelming majority liquid particle and the solid particle in the smog of backward flow to atomizing core will directly adsorb in the protective layer for the inoxidizing coating has good filter function, avoids this part liquid particle and solid particle flow direction atomizing face and form and gather the surface of generating heat and the cigarette on every side and make down, thereby reduces the liquid particle that is used for turning into the cigarette and makes down in the smog by a wide margin and the proportion of solid particle, and then reduces the gathering and make up at the surface of generating heat and the cigarette on every side and make down the volume.

Drawings

FIG. 1 is a schematic cross-sectional view of an atomizer according to an embodiment;

FIG. 2 is a schematic perspective view of an atomizing core provided in the first embodiment of the atomizer shown in FIG. 1;

FIG. 3 is an exploded view of the atomizing core of FIG. 2;

FIG. 4 is a schematic plan cross-sectional view of the atomizing core of FIG. 2;

FIG. 5 is a schematic perspective view of a heating element in the atomizing core shown in FIG. 2;

FIG. 6 is a schematic perspective view of an atomizing core provided in a second embodiment of the atomizer shown in FIG. 1;

FIG. 7 is an exploded view of the atomizing core of FIG. 6;

FIG. 8 is a first exemplary cross-sectional plan view of the atomizing core of FIG. 6;

FIG. 9 is a second exemplary cross-sectional plan view of the atomizing core of FIG. 6;

fig. 10 is a schematic perspective view of an atomizing core provided in a second embodiment;

FIG. 11 is an exploded view of the atomizing core of FIG. 10;

FIG. 12 is a schematic plan cross-sectional view of the atomizing core of FIG. 10;

fig. 13 is a schematic perspective sectional view of the atomizing core shown in fig. 10.

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described more fully hereinafter with reference to the accompanying drawings. The preferred embodiments of the present invention are shown in the drawings. The 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 "inner", "outer", "left", "right" and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

Referring to fig. 1, an atomizer 10 according to an embodiment of the present invention has a liquid storage cavity 11 and an airflow channel 12, and the liquid storage cavity 11 and the airflow channel 12 are isolated from each other and are not communicated with each other. The reservoir chamber 11 is for storing an aerosol-generating substrate, typically a liquid, which when atomised forms an aerosol (aerosol) which is discharged into the airflow channel 12 for absorption by a user. The atomizer 10 includes an atomizing core 20, and the atomizing core 20 includes a base 100, a heating element 200, and a protective layer 300. The matrix 100 has a plurality of micropores formed therein, and due to the existence of the micropores, the entire matrix 100 has a certain porosity, and the porosity may be defined as the total volume of the micropores as a percentage of the entire volume of the matrix 100. The porosity may be in the range of 20% to 70%, for example, it may be 20%, 30%, 60%, or 70%. The matrix 100 has a certain porosity, so that the matrix 100 can absorb and conduct liquid by capillary action, i.e. the matrix 100 can buffer and conduct liquid.

Referring to fig. 2, 3 and 4, the base body 100 has an atomizing surface 110 and a liquid-absorbing surface 120, the atomizing surface 110 and the liquid-absorbing surface 120 being oriented in opposite directions, and the liquid-absorbing surface 120 serving to suck the liquid in the liquid storage chamber 11 into the base body 100. For example, substrate 100 directly seals liquid storage chamber 11 such that liquid-absorbing surface 120 defines a portion of the boundary of liquid storage chamber 11, and liquid in liquid storage chamber 11 will be in direct contact with liquid-absorbing surface 120. By capillary action of the micropores in the substrate 100, the liquid in the liquid storage chamber 11 will enter the interior of the substrate 100 through the liquid absorption surface 120 and be conducted to the atomizing surface 110. The conduction velocity of the liquid inside the matrix 100 is proportional to the porosity, so the conduction velocity of the liquid can be changed by changing the porosity of the matrix 100. The thickness H1 of the substrate 100 ranges from 2mm to 5mm, the thickness of the substrate 100 can be defined as the distance between the liquid absorbing surface 120 and the atomizing surface 110, and the specific value of the thickness of the substrate 100 can be 2mm, 3mm, 4mm or 5 mm. The substrate 100 can be made of ceramic materials or glass materials, and the ceramic and glass materials have stable chemical properties, so that the substrate 100 can be prevented from generating chemical reaction at high temperature to form toxic gas, the toxic gas carried by smoke is prevented from being absorbed by a user, and the use safety of the atomizer 10 is ensured.

Referring to fig. 3 and 5, in some embodiments, the heating element 200 includes a heating portion 210 and two electrode portions 220, and the number of the electrode portions 220 may be two, wherein one electrode portion 220 may serve as a positive electrode and be electrically connected to one end of the heating portion 210, and the other electrode portion 220 may serve as a negative electrode and be electrically connected to the other end of the heating portion 210. The electrode part 220 has a resistance much smaller than that of the heat generating part 210, so that the electrode part 220 has an excellent conductive property, and since the electrode part 220 and the heat generating part 210 are used in series, when the entire heat generating body 200 is energized, the heat generating part 210 can generate a large amount of heat, and the amount of heat generated on the electrode part 220 can be relatively ignored.

The heat generating portion 210 may be disposed on the base 100 by silk-screen printing, for example, the heat generating portion 210 may be directly attached to the atomizing surface 110, so that the heat generating portion 210 protrudes a certain height from the atomizing surface 110. For another example, a portion of the atomizing surface 110 is recessed to form a sink, and the heat generating portion 210 is engaged with the sink, so that the surface of the heat generating portion 210 can be flush with the non-recessed portion of the atomizing surface 110. Of course, the electrode portion 220 may be provided on the base 100 in the same manner as the heat generating portion 210. In terms of material, the heat generating part 210 may be made of a metal material. Structurally, the heat generating portion 210 may have a line-shaped structure or a film-shaped structure. When the heat generating member 210 has a membrane-like structure, the heat generating member 210 may be a dense metal film, a porous metal film, or the like. The thickness H3 of the diaphragm-shaped heat generating member 210 ranges from 30 μm to 130 μm, and may be 30 μm, 50 μm, 100 μm, 130 μm, or the like. The electrode portion 220 may also have a line-like structure or a film-like structure.

Referring to fig. 2, 3 and 4, in some embodiments, the protective layer 300 may be a film-like structure. The protective layer 300 is a porous ceramic layer made of a porous ceramic material, so that a large number of micropores are formed in the protective layer 300, and thus the protective layer 300 also has a certain porosity, and the value of the porosity may range from 30% to 70%, for example, the specific value may be 30%, 40%, 60%, or 70%. The protective layer 300 is provided on the atomizing surface 110, so that the protective layer 300 covers the entire heat generating portion 210, and the protective layer 300 can protect the heat generating portion 210. When the heating portion 210 is powered on, the heating portion 210 converts the electric energy into heat energy, and the liquid on the atomization surface 110 absorbs the heat energy to atomize and form smoke. Given that the protective layer 300 has a certain porosity, the smoke generated on the atomizing surface 110 will overflow out of the protective layer 300 through the micropores inside the protective layer 300, and finally the smoke will be transmitted to the airflow channel 12 to be absorbed by the user. The amount of smoke overflowing from the protective layer 300 per unit time may be proportional to the porosity of the protective layer 300, and thus, the amount of smoke may be changed by changing the porosity of the protective layer 300, for example, when the porosity of the protective layer 300 is large, the requirement for a large amount of smoke may be satisfied.

When the user stops the suction, the pressure at the position where the entire atomizing core 20 is located is relatively small, so that the mist containing both solid particles and liquid particles flows back toward the atomizing core 20. If the protective layer 300 is not provided, most of the liquid particles and solid particles in the smoke flow directly to the atomizing surface 110 without obstruction, so as to form smoke and soil accumulated on the surface and around the heating portion 210, that is, the smoke and soil cover or surround the periphery of the heating portion 210, and obviously, the smoke and soil form a direct connection relationship with the heating portion 210. Therefore, when a large amount of smoke is accumulated on the surface and the periphery of the heating portion 210 in a short time, and when the smoke is accumulated to a certain amount, the temperature on the surface and the periphery of the heating portion 210 is relatively high when the heating portion 210 generates heat, the smoke generates a chemical reaction at a high temperature to generate gas with scorched smell, pungent smell or other peculiar smell, and the gas is mixed in the smoke and absorbed by a user, so that the taste of the smoke is deteriorated, and the user experience is influenced. Certainly, the smoke and soil can also generate a certain amount of toxic gas, thereby having influence on the health of human bodies.

By providing the protective layer 300, most of the liquid particles and solid particles in the smoke are directly adsorbed in the protective layer 300, so that the protective layer 300 has a good filtering function, and the situation that the part of the liquid particles and the solid particles flow to the atomizing surface 110 to form smoke scales accumulated on the surface and around the heating portion 210 is avoided, so that the proportion of the liquid particles and the solid particles in the smoke for being converted into the smoke scales is greatly reduced, and the smoke scales accumulated on the surface and around the heating portion 210 due to single suction is further reduced. Therefore, the amount and speed of the smoke accumulating on and around the heat generating part 210 in the same period of time are greatly reduced. Under the condition that the accumulated amount of smoke and soil is smaller than a certain value, the smoke and soil cannot generate gas with scorched smell, irritant smell or other peculiar smell which influences the taste of the smoke at high temperature, so that the taste of the smoke and the user experience are guaranteed. Meanwhile, the device can avoid the generation of toxic gas due to smoke and fouling, and improve the safety of the atomizer 10 in the use process.

In fact, the liquid in the storage chamber 11 usually contains essence, and even nicotine salt can be added. When the liquid absorbs heat and is atomized, the essence is decomposed to obtain a high molecular compound, the nicotine salt generates carbonate, the high molecular compound and the carbonate play a role in catalysis, more liquid particles and solid particles in smoke are quickly converted into smoke and scales, and the conversion rate of the smoke and scales is increased, so that the agglomeration speed of the smoke and scales is further increased. However, in the above embodiment, by providing the protective layer 300, the protective layer 300 can fully exert its own absorption and filtration functions, and not only can block fast flow of liquid particles and solid particles, but also, in view of the fact that the protective layer 300 is made of a ceramic material, the ceramic material can increase the absorption function of the high molecular compound and carbonate, and can reduce the catalytic action in the smoke and smoke generation process, thereby reducing the amount of smoke and smoke accumulation.

Meanwhile, by arranging the protective layer 300, the protective layer 300 and the base body 100 can form a certain clamping effect on the heating part, the protective layer 300 can absorb external impact energy, external impact force is prevented from being directly applied to the heating part, offset effect of thermal stress generated in the external impact force and the heating process on adhesive force of the heating part is reduced, the heating part is prevented from falling off from the base body 100, and stability and reliability of the heating part fixed on the base body 100 are improved. In addition, the protective layer 300 can absorb and buffer the leakage from the base body 100 to a certain extent, so as to prevent the leakage from the whole atomizing core 20 in a short time and improve the leakage-proof performance of the atomizing core 20.

In some embodiments, protective layer 300 may further cover electrode portions 220 of heat-generating body 200, for example, protective layer 300 may cover all electrode portions 220. By covering the electrode part 220, the protective layer 300 can protect the electrode part 220, reduce the offset effect of external impact force and thermal stress on the adhesive force of the electrode part 220, prevent the electrode part 220 from falling off from the substrate 100, and improve the stability and reliability of the electrode part 220 fixed on the substrate 100.

The protective layer 300 has a certain thickness H2, and the thickness H2 ranges from 100 μm to 500 μm, for example, the specific value may be 100 μm, 200 μm, 300 μm, or 500 μm. When the thickness of the protective layer 300 is increased, the flow resistance of the liquid particles and the solid particle flow in the micropores and the flow path of the liquid particles and the solid particle flow to the atomizing surface 110 can be increased, so that the absorption effect of the protective layer 300 on the liquid particles, the solid particle flow, the high molecular compounds and the carbonate is increased, and the focusing amount of smoke and soil is reduced. Of course, when the thickness of the shield 300 is large, the volume of the shield 300 increases, and the amount of leakage from the base 100 buffered by the shield 300 can be increased, thereby improving the leakage prevention performance of the atomizing core 20.

Referring to fig. 6, 7 and 8, in some embodiments, overcoat layer 300 has a capping surface 310 and a bottom surface 320, both bottom surface 320 and capping surface 310 facing opposite directions and spaced apart along the thickness direction of overcoat layer 300, capping surface 310 facing toward misting surface 110 of substrate 100, and bottom surface 320 facing away from misting surface 110. When the protective layer 300 is disposed on the atomizing surface 110, the covering surface 310 will cover the heat generating portion 210. The protective layer 300 is provided with a vent hole 330 inside, one end of the vent hole 330 penetrates the covering surface 310, and the other end of the vent hole 330 penetrates the bottom surface 320 to communicate with the outside, and it is obvious that, for the atomizing core 20 already installed in the atomizer 10, the vent hole 330 communicates with the airflow channel 12 (see fig. 1). By providing the ventilation holes 330, since the aperture of the ventilation holes 330 is several orders of magnitude higher than the aperture of the micropores, the flow resistance of the smoke entering the airflow channel 12 through the protective layer 300 can be reduced, and specifically, the flow resistance of the smoke in the ventilation holes 330 is significantly smaller than that in the micropores, when the heat generating portion 210 atomizes the liquid on the atomizing surface 110 to form the smoke, most of the smoke will be able to be rapidly discharged into the airflow channel 12 through the ventilation holes 330 except for a small part of the smoke discharged into the airflow channel 12 through the micropores in the protective layer 300, so as to ensure that a sufficient amount of smoke enters the airflow channel 12 per unit time to be absorbed by the user, and thus ensure that the amount of smoke discharged into the airflow channel 12 per unit time by the atomizing core 20 can meet the user's requirements.

In some embodiments, for example, the vent 330 forms a through hole 333 on the covering surface 310, and the through hole 333 has an orthographic projection on the atomizing surface 110, which keeps a set distance B from the covering range of the heat generating portion 210. When a user stops smoking, smoke flowing back to the atomizing core 20 can enter the inside of the protective layer 300 through the vent hole 330 and flow to the atomizing surface 110, the through hole 333 and the coverage range of the heating part 210 on the atomizing surface 110 keep a set distance B, the smoke flowing back to the vent hole 330 forms smoke on the atomizing surface 110 in a region close to the through hole 333, the smoke does not directly contact the heating part 210 and keeps a set distance with the heating part 210, the smoke is far away from the heating part 210, and the smoke is less accumulated, so that the smoke is difficult to form high temperature and substance amount required by smoke chemical reaction, and the smoke is difficult to generate gas with scorched smell or other peculiar smell. For another example, the whole air vent 330 has an orthographic projection on the atomizing surface 110, and the orthographic projection keeps a set distance from the coverage of the heating portion 210, so that the smoke entering the air vent 330 is difficult to reach the surface or the periphery of the heating portion 210 through the micropores in the protective layer 300, and further the smoke is prevented from forming smoke on the surface or the periphery of the heating portion 210.

Referring to fig. 8, the central axis of the vent hole 330 may be linear, and the central axis of the vent hole 330 and the atomization surface 110 form an acute included angle a, that is, the vent hole 330 is disposed to be inclined relative to the atomization surface 110, so that the total extension length of the vent hole 330 may be properly increased, thereby extending the flow path of the smoke in the vent hole 330 and increasing the contact area with the protective layer 300, resulting in increasing the flow resistance of the smoke and the adsorptive capacity of the protective layer 300 for the smoke, and preventing the smoke from forming smoke on the atomization surface 110. Referring to fig. 9, the central axis of the vent hole 330 may also be a zigzag, for example, the vent hole 330 includes a first bending section 331 and a second bending section 332 that are communicated with each other, the first bending section 331 penetrates through the covering surface 310, the second bending section 332 penetrates through the bottom surface 320 and is directly communicated with the outside (corresponding to the airflow channel 12), the central axis of the first bending section 331 and the atomization surface 110 form an included angle, and the central axis of the second bending section 332 and the central axis of the first bending section 331 form an included angle, so as to further increase the total extension length of the vent hole 330, and further prevent smoke from forming smoke on the atomization surface 110.

The covering surface 310 of the protective layer 300 is concavely formed with a groove 340, at least a part of the heating part 210 can be matched with the groove 340, so that the heating part 210 can fully utilize the installation space of the groove 340, the atomizing core 20 is compact in structure, and the groove 340 also has a limiting function on the heating part 210, thereby improving the stable reliability of the installation of the heating part 210.

Referring to fig. 10, 11 and 12, in other embodiments, the protective layer 300 may not cover the heat generating portion 210 at all. Specifically, the overcoat layer 300 has a through groove 350 penetrating the entire overcoat layer 300, one end of the through groove 350 penetrates the bottom surface 320, and the other end of the through groove 350 penetrates the cover surface 310. When the protective layer 300 is fixed on the atomizing surface 110, the cross-section of the heat generating part 210 is formed to be matched with the cross-sectional shape of the through groove 350, so that the heat generating part 210 is positioned in the through groove 350 to be matched with the through groove 350. A predetermined distance H4 is maintained between the surface of heat generating part 210 in through groove 350 and bottom surface 320 of shield 300 in the thickness direction of shield 300. In fact, the protective layer 300 is disposed around the edge of the heat generating portion 210, and due to the blocking effect of the protective layer 300, the smoke flowing back to the atomizing core 20 is difficult to reach the part of the atomizing surface 110 close to the heat generating portion 210 through the micropores of the protective layer 300, so that the amount of smoke accumulated around the heat generating portion 210 is significantly reduced. Meanwhile, the protective layer 300 has a side wall surface 360 defining the boundary of the through groove 350, and a set distance H4 is kept between the surface of the heating portion 210 in the through groove 350 and the bottom surface 320 of the protective layer 300, so that the side wall surface 360 has a sufficiently large area, and when backflow smoke flows to the heating portion 210 in the through groove 350, the smoke collides and contacts with the side wall surface 360, so that the side wall surface 360 has a reasonable contact area to form a strong adsorption capacity for the smoke, the smoke is difficult to reach the surface of the heating portion 210, the smoke is prevented from forming a large amount of smoke stains on the surface of the heating portion 210, and the taste of the smoke can also be ensured. Of course, the protective layer 300 may also partially cover the heat generating portion 210, such that a user may only see a portion of the heat generating portion 210 outside the atomizing core 20 through the through slot 350.

Referring to fig. 13, referring to the above arrangement of the vent holes 330, the through groove 350 may also be disposed obliquely with respect to the atomizing surface 110, that is, when the through groove 350 passes through the protective layer 330 along a straight line, the extending direction of the straight line forms an acute angle with the atomizing surface 110. Of course, the through groove 350 may also penetrate the overcoat layer 330 along a folding line. The arrangement can prolong the flow path of the smoke in the through groove 350 and increase the contact area with the protective layer 300, which results in increasing the flow resistance of the smoke and the adsorption capacity of the protective layer 300 to the smoke, and reducing the smoke and smoke generated on the heating part 220. The mist generated on the atomizing surface 110 can be rapidly discharged from the through groove 350 into the air flow channel 12 (see fig. 1), so as to ensure that the amount of the mist discharged to the air flow channel 12 per unit time of the atomizing core 20 can meet the user's requirement. In addition to the through-grooves 350, the ventilation holes 330 may be provided in the protective layer 300 according to the above-described embodiment, and by providing the ventilation holes 330, the amount of smoke discharged to the airflow path 12 per unit time of the atomizing core 20 can be further increased.

The utility model also provides an electronic atomization device, this electronic atomization device include power, controller, inductor and above-mentioned atomizer 10, and the power is followed controller and heat-generating body 200 electric connection, and when the inductor acquireed user's suction information and with suction information transmission to controller, controller control power supply supplied power to heat-generating body 200, and heat-generating body 200 turns into heat energy with the electric energy for liquid atomizing forms smog under the effect of heat energy. The suction information may be the negative pressure generated in the airflow passage 12 during suction by the user. The electronic atomization device comprises the atomizer 10, so that the taste and the safety of smoke generated by the electronic atomization device can be protected.

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 represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (13)

1. An atomizing core, comprising:

the base body is provided with an atomizing surface and is used for buffering and conducting liquid;

a heat generating body including a heat generating portion attached to the base body, the heat generating portion being capable of generating heat to atomize the liquid on the atomizing surface to form mist; and

the protective layer is arranged on the atomizing surface and covers the heating part, and smoke can overflow from the protective layer.

2. The atomizing core according to claim 1, wherein the protective layer has micropores formed therein and has a porosity of 30 to 70%, and a thickness of 100 to 500 μm.

3. The atomizing core according to claim 1, wherein the heat-generating body further includes an electrode portion for electrical conduction, the electrode portion being electrically connected to the heat-generating portion, and the protective layer further covers all of the electrode portion.

4. The atomizing core of claim 1, wherein the protective layer has a covering surface disposed toward the atomizing surface, the covering surface being recessed to form a groove, at least a portion of the heat-generating portion being engaged with the groove.

5. The atomizing core of claim 1, wherein the heat generating portion is a line-like structure or a film-like structure; when the heat generating member is a film-like structure, the thickness of the heat generating portion is 30 to 130 μm.

6. The atomizing core according to claim 1, wherein micropores are formed in the matrix and have a porosity of 20 to 70%, and the thickness of the matrix is 2 to 5 mm.

7. An atomizing core, comprising:

the base body is provided with an atomizing surface and is used for buffering and conducting liquid;

a heat generating body including a heat generating portion attached to the base body, the heat generating portion being capable of generating heat to atomize the liquid on the atomizing surface to form mist; and

the inoxidizing coating, the inoxidizing coating sets up on the atomizing face, the inoxidizing coating has dorsad the bottom surface that the atomizing face set up, set up on the bottom surface and run through the groove that runs through of inoxidizing coating, at least part the portion that generates heat is located run through the inslot, just the portion that generates heat be located run through the surface in the groove with the bottom surface is followed the thickness direction of inoxidizing coating keeps the settlement distance.

8. The atomizing core according to claim 7, wherein the protective layer has a covering surface facing away from the bottom surface to cover the atomizing surface, and a vent hole is further formed in the protective layer, the vent hole penetrates through the covering surface and is communicated with the outside, and smoke can overflow from the vent hole.

9. The atomizing core according to claim 8, characterized in that the vent hole forms a through opening on the cover surface, and the through opening has an orthographic projection on the atomizing surface, and the orthographic projection is kept at a set distance from a coverage of the heat generating portion.

10. The atomizing core of claim 8, wherein the vent hole has an orthographic projection on the atomizing surface, and the orthographic projection is kept at a set distance from a coverage of the heat generating portion.

11. The atomizing cartridge of claim 8, wherein the central axis of the vent is disposed at an acute included angle with respect to the atomizing surface; or, the air vent includes first bending segment and the second bending segment that communicates each other, first bending segment runs through the coverage, the second bending segment directly communicates the external world, the central axis of first bending segment with the contained angle setting is personally submitted in the atomizing, the central axis of second bending segment with the central axis of first bending segment is the contained angle setting.

12. An atomizer, characterized in that, offer the stock solution cavity and include any one of the stated atomizing core of claim 1 to 11, the stated basal body also has the liquid suction surface opposite to stated atomizing surface, the stated liquid suction surface is used for absorbing the liquid in the stated stock solution cavity into the stated basal body.

13. An electronic atomizer, comprising a power source and the atomizer of claim 12, said power source being electrically connected to said heating element.

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