CN215013609U - Atomizer and electronic atomization device - Google Patents

Abstract

The utility model relates to an atomizer and an electronic atomization device, wherein the atomizer comprises a shell; ultrasonic atomization subassembly has into the liquid level and encircles the first holding surface of feed liquor edge connection, first holding surface with the feed liquor is located ultrasonic atomization subassembly's homonymy, liquid is followed the feed liquor gets into atomizing formation liquid fog in the ultrasonic atomization subassembly. And the heating component is attached to the first supporting surface and used for preheating the liquid reaching the position near the liquid inlet surface. The heating assembly can preheat the liquid to a temperature close to that of the human body, and when the ultrasonic atomization assembly atomizes the liquid to form liquid mist, the temperature of the liquid mist is close to the body temperature of the human body. Can avoid the liquid fog to constitute amazing to human respiratory track, improve user experience.

Description

Atomizer and electronic atomization device

Technical Field

The utility model relates to an atomizing technical field especially relates to an atomizer and contain electronic atomization device of this atomizer.

Background

The atomizer generally includes an ultrasonic atomizing plate, in which an atomizing hole is disposed, and when the ultrasonic atomizing plate generates high-frequency vibration, the liquid in the atomizing hole can be atomized to form liquid mist, and the liquid mist is sprayed out from the atomizing hole to be absorbed by a user. However, with the conventional nebulizer, the generated liquid mist will cause irritation to the respiratory tract of the user, thereby affecting the user experience.

SUMMERY OF THE UTILITY MODEL

The utility model provides a technical problem how to improve the temperature of the produced liquid fog of atomizer.

An atomizer, comprising:

the ultrasonic atomization assembly is provided with a liquid inlet surface and a first supporting surface surrounding the edge of the liquid inlet surface, the first supporting surface and the liquid inlet surface are positioned on the same side of the ultrasonic atomization assembly, and liquid enters the ultrasonic atomization assembly from the liquid inlet surface and is atomized to form liquid mist; and

the heating assembly is attached to the first supporting surface and used for preheating liquid reaching the position near the liquid inlet surface.

In one embodiment, the ultrasonic atomization assembly comprises a piezoelectric ceramic piece and a metal piece, the liquid inlet surface and the first supporting surface are both located on a first side of the metal piece, a second side, opposite to the first side, of the metal piece is further provided with a second supporting surface corresponding to the first supporting surface and a fog outlet surface corresponding to the liquid inlet surface, the piezoelectric ceramic piece is attached to the second supporting surface and provided with a through hole corresponding to the fog outlet surface, and the metal piece is provided with an atomization hole penetrating through the liquid inlet surface and the fog outlet surface and communicated with the through hole.

In one embodiment, at least a part of both the liquid inlet surface and the mist outlet surface is a spherical cap surface, an opening of the spherical cap surface faces the first side, and the spherical cap surface is provided with the atomizing holes.

In one embodiment, the heating assembly includes a heating layer attached to a first side of the metal sheet, the heating layer configured to include a high temperature zone surrounding the liquid inlet surface and a low temperature zone surrounding the high temperature zone.

In one embodiment, the distance between the edge of the liquid inlet surface and the heating layer is smaller than the distance between the edge of the first supporting surface and the heating layer; and/or the presence of a gas in the gas,

the heating layer comprises a first resistance wire surrounding the liquid inlet surface and a second resistance wire surrounding the first resistance wire, and the resistance value of the first resistance wire is larger than that of the second resistance wire.

In one embodiment, the heating assembly further comprises a first insulating layer attached to the first support surface and a second insulating layer interposed between the first insulating layer and the second insulating layer.

In one embodiment, the thermal conductivity of the second insulating layer is greater than the thermal conductivity of the first insulating layer.

In one embodiment, the heating assembly further comprises an insulating layer and an adhesive layer, the heating layer is encapsulated in the insulating layer, and the adhesive layer is attached to the first supporting surface and connected with the insulating layer.

In one embodiment, the heating assembly is configured to be activated prior to the time of the ultrasonic atomization assembly.

An electronic atomising device comprising an atomiser as in any one of the above.

The utility model discloses a technical effect of an embodiment is: the heating assembly can preheat the liquid to a temperature close to that of the human body, and when the ultrasonic atomization assembly atomizes the liquid to form liquid mist, the temperature of the liquid mist is close to the body temperature of the human body. Can avoid the liquid fog to constitute amazing to human respiratory track, improve user experience. Meanwhile, the heating assembly is directly attached to the back of the ultrasonic atomization assembly, namely the heating assembly is integrally arranged on the ultrasonic atomization assembly. So can make heating element heat to the liquid that is located near the inlet surface, carry out local heating to liquid promptly for liquid can directly get into atomizing in the ultrasonic atomization subassembly after being heated, so liquid programming rate is fast, and can reduce heating element's energy consumption, reduces liquid fog spun latency in order to improve user experience. And directly set up heating element on the first holding surface of sheetmetal, heating element is located the one side that the inlet surface located promptly for heating element can with liquid direct contact, the heat that heating element produced need not intermediate medium and directly transmits to liquid, thereby reduces calorific loss and improves thermal utilization ratio, makes liquid programming rate fast, reduces liquid fog spun latency. Meanwhile, an additional heat insulation component is not required to be arranged on the heating assembly, so that the overall structure of the atomizer is simplified.

Drawings

Fig. 1 is a schematic perspective view of an atomizer according to an embodiment;

FIG. 2 is a schematic perspective view of the atomizer shown in FIG. 1 from another perspective;

FIG. 3 is a schematic view of the atomizer shown in FIG. 1 in an exploded configuration;

FIG. 4 is a schematic plan sectional view of the atomizer shown in FIG. 1;

FIG. 5 is a schematic view of a portion of the structure of FIG. 4;

FIG. 6 is an enlarged view of the structure at A in FIG. 5;

fig. 7 is a schematic plan sectional view of an atomizer according to another embodiment.

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, 2 and 3, an atomizer 10 according to an embodiment of the present invention includes an ultrasonic atomizing assembly 100 and a heating assembly 200, where the ultrasonic atomizing assembly 100 is used to atomize a liquid to form a liquid mist, and the liquid may be oil or liquid medicine. After the liquid is atomized to form the liquid mist, the user can suck the liquid mist.

Referring to fig. 3, 4, and 5, in some embodiments, the ultrasonic atomization assembly 100 includes a piezoceramic sheet 110, a metal sheet 120, a first electrode 131, and a second electrode 132. One ends of the first electrode 131 and the second electrode 132 are electrically connected to a circuit in the piezoelectric ceramic sheet 110, and the other ends of the first electrode 131 and the second electrode 132 are used for connecting to an ac power supply. Therefore, the circuit in the piezoceramic sheet 110 is used to energize an alternating current. When an alternating current is applied to the circuit in the piezoelectric ceramic sheet 110 through the first electrode 131 and the second electrode 132 by the alternating current power source, the piezoelectric ceramic sheet 110 generates high-frequency vibration, so that the vibration frequency of the piezoelectric ceramic sheet 110 is equivalent to the vibration frequency of the ultrasonic wave. The center of the piezoelectric ceramic plate 110 is provided with a through hole 111, the through hole 111 penetrates through two opposite surfaces of the piezoelectric ceramic plate 110, and the piezoelectric ceramic plate 110 is made to be in a circular ring-shaped structure by the through hole 111.

The metal sheet 120 has a substantially disc-shaped configuration, and the metal sheet 120 has a first supporting surface 121, a second supporting surface 122, an inlet surface 123 and a mist outlet surface 124. The liquid inlet surface 123 and the mist outlet surface 124 are both oppositely oriented and located in the central region of the metal sheet 120, and the second support surface 122 and the first support surface 121 are both oppositely oriented and located in the edge region of the metal sheet 120. The second supporting surface 122 and the mist outlet surface 124 are located on a second side (i.e., an upper side) of the metal sheet 120, and the second supporting surface 122 is connected to a periphery of the mist outlet surface 124, so that the second supporting surface 122 is annular and is disposed around the mist outlet surface 124. The first supporting surface 121 and the liquid inlet surface 123 are located on a first side (i.e., a lower side) of the metal sheet 120, and the first supporting surface 121 is connected to the periphery of the liquid inlet surface 123, so that the first supporting surface 121 is annular and is disposed around the liquid inlet surface 123. In short, the second supporting surface 122 and the first supporting surface 121 are both provided at intervals in the thickness direction of the metal sheet 120 to correspond to each other, and the liquid inlet surface 123 and the mist outlet surface 124 are both provided at intervals in the thickness direction of the metal sheet 120 to correspond to each other.

The metal sheet 120 is provided with a plurality of atomization holes 126, and the atomization holes 126 simultaneously penetrate through the liquid inlet surface 123 and the mist outlet surface 124. The heating assembly 200 is disposed on the first supporting surface 121 of the metal sheet 120. The piezoceramic sheet 110 is attached to the second supporting surface 122 of the metal sheet 120, so that the fogging surface 124 corresponds to the through hole 111 of the piezoceramic sheet 110, and the through hole 111 and the atomization hole 126 are ensured to be communicated with each other. The atomized liquid is located on the side of the liquid inlet surface 123, and the liquid is in direct contact with the liquid inlet surface 123, so that the liquid enters the atomizing holes 126 through the liquid inlet surface 123. When the piezoelectric ceramic plate 110 generates high-frequency vibration under the action of the alternating current, the vibration energy of the piezoelectric ceramic plate 110 is transmitted to the metal sheet 120, so that the metal sheet 120 generates high-frequency vibration along with the piezoelectric ceramic plate 110, and the liquid in the atomization holes 126 is atomized to form liquid mist, and the liquid mist is sprayed from the mist outlet surface 124 to the through holes 111 of the piezoelectric ceramic plate 110 to be absorbed by a user. Further, the atomization holes 126 are tapered holes, and the hole diameter of the atomization holes 126 gradually decreases from the inlet surface 123 to the outlet surface 124.

The metal sheet 120 may be a stainless steel sheet, that is, the metal sheet 120 is made of a stainless steel material, so that the metal sheet 120 has good structural strength, thermal conductivity and anti-rust capability. Therefore, the metal sheet 120 can have sufficient fatigue strength, the metal sheet 120 can be prevented from fatigue fracture under high-frequency vibration, and the service life of the whole ultrasonic atomization assembly 100 can be prolonged. Meanwhile, the corrosion particles are prevented from partially or completely blocking the atomizing holes 126, the particle sizes of the tiny liquid bead particles in the liquid mist are ensured to be equal, each atomizing hole 126 is also ensured to atomize the liquid, and the uniformity and reliability of the metal sheet 120 in atomizing the liquid are finally improved.

In some embodiments, at least a portion of both the inlet surface 123 and the outlet surface 124 are spherical crown surfaces 125, and the openings of the spherical crown surfaces 125 are arranged toward the heating assembly 200, so that the central region of the entire metal sheet 120 forms a spherical crown-shaped protrusion, which is, of course, the opening of the spherical crown surface 125. The protrusion may be formed by recessing a central region of the metal sheet 120 having a flat plate shape in a direction toward the first side. Another part of the atomization holes 126 may be located on the spherical crown surface 125, and another part of the atomization holes 126 may be located at other parts of the liquid inlet surface 123 and the mist outlet surface 124; of course, all of the atomization holes 126 may be located on the spherical cap surface 125. By providing the spherical cap surface 125, with a plane perpendicular to the thickness direction of the metal sheet 120 as a reference plane, although the orthogonal projections of the metal sheet 120 having the spherical cap surface 125 and the flat metal sheet 120 on the reference plane are equal, the metal sheet 120 having the spherical cap surface 125 can ensure that the liquid mist is ejected in different directions and has a relatively large ejection range, and at the same time, relatively more atomizing holes 126 can be provided, thereby increasing the atomizing amount of the liquid per unit time to increase the concentration of the liquid mist.

Referring to fig. 3, 5 and 6, in some embodiments, the heating assembly 200 includes a first insulating layer 210, a second insulating layer 220 and a heating layer 230, the first insulating layer 210, the second insulating layer 220 and the heating layer 230 are substantially annular, and all of them are provided with through holes 201 communicated with each other, the through holes 201 correspond to the liquid inlet surface 123 of the metal sheet 120, and the liquid can pass through the through holes 201 to contact the liquid inlet surface 123 and enter the atomizing holes 126 to be atomized. The first insulating layer 210 is attached to the first supporting surface 121 of the metal plate 120, and the first insulating layer 210 may be attached to the first supporting surface 121 through a Physical Vapor Deposition (PVD) process or a screen printing process, so that the first insulating layer 210 is directly connected to the metal plate 120, and the first insulating layer 210 is prevented from being connected to the metal plate 120 through other connecting layers, thereby reducing the thickness and weight of the whole atomizer 10, and facilitating the light design of the atomizer 10. The thickness of the first insulating layer 210 may range from 5 μm to 20 μm, for example, it may specifically be 5 μm, 10 μm, 15 μm, or 20 μm, and the thickness of the first insulating layer 210 may be appropriately reduced on the basis of ensuring that the first insulating layer 210 has sufficient insulating performance, so that the thickness of the whole atomizer 10 may be further compressed.

The heating layer 230 is attached to a surface of the first insulating layer 210 facing away from the metal sheet 120, and the heating layer 230 may also be attached to the first insulating layer 210 through a Physical Vapor Deposition (PVD) process or a screen printing process, so that the heating layer 230 is directly connected to the first insulating layer 210, thereby avoiding the connection between the heating layer 230 and the first insulating layer 210 through other connecting layers, and also reducing the thickness of the whole atomizer 10 and realizing a light and thin design of the atomizer 10. The thickness of the heating layer 230 may range from 5 μm to 40 μm, for example, it may specifically be 5 μm, 20 μm, 30 μm, or 40 μm. The heating layer 230 may further include a third electrode 231 and a fourth electrode 232, wherein one end of each of the third electrode 231 and the fourth electrode 232 is electrically connected to the heating layer 230, and the other end of each of the third electrode 231 and the fourth electrode 232 is used for connecting to a dc power supply. Thus, the heating layer 230 is used to energize an electric current. When a direct current is applied to the heating layer 230 by a direct current power source (e.g., a battery) through the third electrode 231 and the fourth electrode 232, the heating layer 230 may convert electrical energy into heat energy. The heating layer 230 may be a layered structure formed by bending a wire-shaped wire or directly a layered structure formed by a conductive film. The heating layer 230 may be a carbon nano-sheet, or may be made of a metal or alloy material such as a stainless steel material, a titanium metal material, or a titanium alloy material.

The second insulating layer 220 is attached to a surface of the heating layer 230 opposite to the metal sheet 120, and the second insulating layer 220 may also be attached to the heating layer 230 through a Physical Vapor Deposition (PVD) process or a screen printing process, so that the heating layer 230 is directly connected to the second insulating layer 220, thereby avoiding the connection between the heating layer 230 and the second insulating layer 220 through other connecting layers, and also reducing the thickness of the whole atomizer 10 and realizing the light and thin design of the atomizer 10. The thickness of the second insulating layer 220 may range from 5 μm to 20 μm, for example, it may specifically be 5 μm, 10 μm, 15 μm, or 20 μm, and the thickness of the second insulating layer 220 may be appropriately reduced on the basis of ensuring that the second insulating layer 220 has sufficient insulating performance, so that the thickness of the whole atomizer 10 may be further compressed. The second insulating layer 220 may be made of a ceramic glaze material, so that the second insulating layer 220 has high wear resistance and good thermal conductivity.

Accordingly, for the entire heating assembly 200, the first insulating layer 210 is disposed at the first supporting surface 121 of the metal sheet 120, and the heating layer 230 is directly interposed between the first insulating layer 210 and the second insulating layer 220. By providing the first insulating layer 210, a short circuit phenomenon caused by direct contact of the heating layer 230 with the metal sheet 120 can be prevented. By arranging the second insulating layer 220, the second insulating layer 220 is in direct contact with the liquid on the side of the liquid inlet surface 123, so that a short circuit phenomenon caused by the direct contact of the heating layer 230 and the liquid is prevented, and the pollution to the liquid caused by the contact of the heating layer 230 and the liquid can also be prevented.

During operation of the atomizer 10, the heating assembly 200 is activated prior to the ultrasonic atomization assembly 100. Specifically, the heating layer 230 is first powered by a dc power through the third electrode 231 and the fourth electrode 232, and then the circuit in the piezoelectric ceramic plate 110 is powered by an ac power through the first electrode 131 and the second electrode 132, so that the operation time of the heating layer 230 is earlier than that of the piezoelectric ceramic plate 110. For example, the heating layer 230 may be started before the piezoelectric ceramic sheet 110 for no more than one second, so that the piezoelectric ceramic sheet 110 drives the metal sheet 120 to oscillate to atomize the liquid into the liquid mist as soon as possible, and the waiting time of the liquid mist for the user is reduced, thereby improving the user experience of the whole atomizer 10.

By starting the heating assembly 200 first, the heating assembly 200 can preheat the liquid reaching the vicinity of the liquid inlet surface 123, and of course, the heating assembly 200 can preheat the liquid to a temperature close to the temperature of the human body, and when the metal sheet 120 atomizes the liquid to form the liquid mist sprayed from the mist outlet surface 124 into the through holes 111, the temperature of the liquid mist is close to the body temperature of the human body. Particularly, in the case of the atomization of the liquid medicine, when a user absorbs the liquid medicine which is close to the body temperature and exists in the form of liquid mist, the stimulation of the liquid medicine (liquid mist) to the respiratory tract of the human body can be avoided, thereby avoiding the generation of other symptoms such as cough or blood pressure rise and ensuring the treatment effect of the liquid medicine to the user. And the temperature difference of the liquid mist generated in the early stage and the middle and the later stage of the heating assembly 200 due to the simultaneous starting of the heating assembly 200 and the piezoelectric ceramic piece 110 can be eliminated, the temperature of the liquid mist in the atomizing process is kept consistent, and the comfort of liquid mist suction is improved. Meanwhile, for the liquid with relatively high viscosity, the viscosity of the liquid can be properly reduced through the preheating effect of the heating assembly 200, so that the liquidity of the liquid is increased, the liquid can more easily enter the atomization holes 126 and can be rapidly atomized to form liquid mist under high-frequency vibration, the phenomenon that the liquid is difficult to flow into the atomization holes 126 or is difficult to atomize to form the liquid mist is prevented, and the atomization efficiency and the atomization stability and reliability of the whole atomizer 10 are improved.

If a separate heating element 200 is used to heat the liquid, the heating element 200 will heat the liquid near the liquid inlet surface 123 and the liquid far from the liquid inlet surface 123 simultaneously, and when the liquid far from the liquid inlet surface 123 reaches the vicinity of the liquid inlet surface 123, the heating element 200 will heat the liquid repeatedly, which results in energy waste. And the liquid is heated more, so that the liquid is slowly heated, and the waiting time of a user is prolonged. In contrast, the above-described embodiment integrally provides the heating assembly 200 on the ultrasonic atomization assembly 100 by directly attaching the heating assembly 200 to the first support surface 121 of the ultrasonic atomization assembly 100. So can make heating element 200 only heat to being located near liquid level 123, carry out local heating to liquid promptly for heated back liquid can directly get into atomizing hole 126 and atomize, so liquid programming rate is fast, and can reduce heating element 200's energy consumption, reduces the spun latency of liquid fog in order to improve user experience.

If the heating assembly 200 is disposed on the side of the metal sheet 120 where the mist outlet surface 124 is located, the heating assembly 200 cannot directly contact with the liquid on the side of the liquid inlet surface 123, and the heat generated by the heating assembly 200 is transferred to the liquid through the metal sheet 120 to preheat the liquid, which prolongs the heat transfer path, thereby increasing the heat loss generated during the heat transfer process and reducing the heat utilization rate of the heating assembly 200. Further, the heating unit 200 needs to be protected by a heat insulating member to prevent heat of the heating unit 200 from being transferred to other components of the atomizer 10 to damage the components, and thus, the structure of the atomizer 10 becomes significantly more complicated by the heat insulating member. In the above embodiment, the whole heating assembly 200 is directly disposed on the first supporting surface 121 of the metal sheet 120, that is, the heating assembly 200 is located on one side of the liquid inlet surface 123, so that the heating assembly 200 can be directly contacted with the liquid, and the heat generated by the heating assembly 200 is directly transferred to the liquid without an intermediate medium, thereby reducing heat loss and improving the utilization rate of the heat, so that the temperature rising speed of the liquid is fast, and the waiting time for spraying the liquid mist is reduced. While eliminating the need for additional thermal insulation on the heating assembly 200 and thereby simplifying the overall construction of the atomizer 10.

In some embodiments, heating layer 230 is configured to include a high temperature region surrounding intake surface 123 and a low temperature region surrounding the high temperature region, such that the high temperature region of heating layer 230 is closer to intake surface 123 than the low temperature region. For example, the heating layer 123 includes a first resistance wire 231 surrounding the liquid inlet surface 123 and a second resistance wire 232 surrounding the first resistance wire, a resistance value of the first resistance wire 231 is greater than a resistance value of the second resistance wire 232, and the first resistance wire 231 and the second resistance wire 232 are connected in series, so that heat generated by the first resistance wire 231 is greater than heat generated by the second resistance wire 232 in the same time period, and thus the first resistance wire 231 corresponds to the high temperature region and the second resistance wire 232 corresponds to the low temperature region. The heat generated by the heating layer 230 is more focused on the liquid near the inlet plane 123, which can reduce the repeated heating and increase the temperature rising speed of the liquid. Meanwhile, the heat transferred from the heating layer 230 to other components of the atomizer 10 through the edge of the metal sheet 120 can be reduced, and the utilization rate of the energy of the heating layer 230 can be improved. Of course, in the case that the resistance value of the first resistance wire 231 is equal to the resistance value of the second resistance wire 232, the liquid inlet surface 123 can be closer to the heating layer 230 relative to the edge of the first supporting surface 121 of the metal sheet 120, in other words, the distance H from the heating layer 230 to the liquid inlet surface 123 is smaller than the distance H from the heating layer 230 to the edge of the first supporting surface 121, and the heat generated by the heating layer 230 can be focused on the liquid near the liquid inlet surface 123, so that the utilization rate of the energy of the heating layer 230 can be improved. The thermal conductivity of the second insulating layer 220 is greater than that of the first insulating layer 210, so that the heat generated by the heating layer 230 can be more easily transmitted to the liquid through the second insulating layer 220, the heat transmitted to other components of the atomizer 10 through the first insulating layer 210 and the metal sheet 120 is reduced, and the utilization rate of the energy of the heating layer 230 can also be improved.

Referring to fig. 7, in some embodiments, for manufacturing the heating element 200, for example, the prepared heating layer 230 may be first placed in an injection mold, and then a liquid insulating material may be injected into a cavity of the injection mold, and the liquid insulating material may be cooled and solidified to form an insulating layer, which may be referred to as a third insulating layer 241. Therefore, the entire heating layer 230 will be enclosed within the third insulating layer 241, and the heating layer 230 is also prevented from short-circuiting due to contact with the metal sheet 120 and the liquid by the action of the third insulating layer 241. Of course, the third insulating layer 241 may be formed with a slot structure, so that the third electrode 231 and the fourth electrode 232 electrically connected to the heating layer 230 are formed through the slot structure. During the installation of the heating assembly 200, the third insulating layer 241 may be attached to the adhesive layer 242 by disposing the adhesive layer 242 on the first supporting surface 121 of the metal sheet 120, and attaching the third insulating layer 241 to the adhesive layer 242, i.e., the third insulating layer 241 is disposed on the first supporting surface 121 of the metal sheet 120 through the adhesive layer 242. Of course, the third insulating layer 241 may also be fixed on the first supporting surface 121 of the metal sheet 120 by a snap connection. For another example, the insulating layer may be disposed on the front and back surfaces of the prepared heating layer 230 by physical vapor deposition, electrophoresis or spraying, and then the insulating layer is fixed on the metal sheet 120 by the adhesive layer 242 or the snap connection.

The utility model also provides an electronic atomization device, this electronic atomization device include foretell atomizer 10, through setting up this atomizer 10, can improve electronic atomization's user experience, reduce the energy consumption and make the structure frivolous more.

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 (10)

1. An atomizer, comprising:

the ultrasonic atomization assembly is provided with a liquid inlet surface and a first supporting surface surrounding the edge of the liquid inlet surface, the first supporting surface and the liquid inlet surface are positioned on the same side of the ultrasonic atomization assembly, and liquid enters the ultrasonic atomization assembly from the liquid inlet surface and is atomized to form liquid mist; and

the heating assembly is attached to the first supporting surface and used for preheating liquid reaching the position near the liquid inlet surface.

2. The atomizer according to claim 1, wherein the ultrasonic atomizing assembly comprises a piezoelectric ceramic plate and a metal plate, the liquid inlet surface and the first supporting surface are both located on a first side of the metal plate, a second side of the metal plate opposite to the first side further comprises a second supporting surface corresponding to the first supporting surface and a mist outlet surface corresponding to the liquid inlet surface, the piezoelectric ceramic plate is attached to the second supporting surface and provided with through holes corresponding to the mist outlet surface, and the metal plate is provided with atomizing holes penetrating through the liquid inlet surface and the mist outlet surface and communicating the through holes.

3. A nebulizer as claimed in claim 2, wherein at least a portion of both the liquid inlet surface and the mist outlet surface are spherical cap surfaces, the openings of the spherical cap surfaces facing the first side, the spherical cap surfaces being provided with the nebulizing holes.

4. The atomizer of claim 2, wherein said heating assembly comprises a heating layer attached to a first side of said metal sheet, said heating layer configured to include a high temperature zone surrounding said liquid intake surface and a low temperature zone surrounding said high temperature zone.

5. The atomizer of claim 4, wherein the distance between the edge of said liquid inlet surface and said heating layer is less than the distance between the edge of said first support surface and said heating layer; and/or the presence of a gas in the gas,

the heating layer comprises a first resistance wire surrounding the liquid inlet surface and a second resistance wire surrounding the first resistance wire, and the resistance value of the first resistance wire is larger than that of the second resistance wire.

6. The atomizer of claim 4, wherein said heating assembly further comprises a first insulating layer and a second insulating layer, said first insulating layer being adhered to said first support surface, said heating layer being sandwiched between said first insulating layer and said second insulating layer.

7. The nebulizer of claim 6, wherein the second insulating layer has a thermal conductivity greater than a thermal conductivity of the first insulating layer.

8. The atomizer of claim 4, wherein said heating assembly further comprises an insulating layer and an adhesive layer, said heating layer being encapsulated within said insulating layer, said adhesive layer being attached to said first support surface and being connected to said insulating layer.

9. The nebulizer of claim 1, wherein the heating assembly is configured to be activated prior to a time of the ultrasonic atomizing assembly.

10. An electronic atomisation device comprising a atomiser according to any of claims 1 to 9.

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