CN110876492A - Electronic atomization device - Google Patents

Abstract

The invention relates to an electronic atomization device. The method comprises the following steps: the atomizing assembly comprises a heating part, the heating part is provided with a transmission channel and a heating cavity for accommodating aerosol generating products, and the heating cavity is communicated with the transmission channel and the outside; and a microwave generator connected to the atomizing assembly, the microwaves generated by the microwave generator being able to enter the heating chamber through the transmission channel, the aerosol-generating article absorbing the microwaves and generating heat for atomization. After the microwave generated by the microwave generator enters the heating cavity through the transmission channel, the aerosol generating product in the heating cavity absorbs the microwave, and due to the special mechanism of microwave heating, the central part and the edge part of the object which has absorbed the microwave simultaneously generate heat to raise the temperature, so that the aerosol generating product can be rapidly raised from the normal temperature to the atomization temperature in a short time to atomize and form smoke, and the rapid heating function of the electronic atomization device is realized.

Description

Electronic atomization device

Technical Field

The invention relates to the technical field of electronic atomization, in particular to an electronic atomization device.

Background

The electronic atomization device can atomize aerosol generating products such as cigarettes to form smoke, and the smoke contains a large amount of nicotine and fragrance, so that habitual requirements of smokers can be well met. However, for the conventional electronic atomization device, when the cigarette is atomized by adopting a heating non-combustion mode, the cigarette needs to consume the unequal long preheating time of ten seconds to thirty seconds to reach the temperature required by the atomization of the cigarette, so that the cigarette is difficult to be rapidly atomized in a short time to form smoke which can be sucked by a user, and the electronic atomization device is difficult to meet the user experience.

Disclosure of Invention

One technical problem solved by the present invention is how to enable rapid heating of an electronic atomizer.

An electronic atomization device comprising:

the atomizing assembly comprises a heating part, the heating part is provided with a transmission channel and a heating cavity for accommodating aerosol generating products, and the heating cavity is communicated with the transmission channel and the outside; and

a microwave generator connected to the atomizing assembly, the microwave generated by the microwave generator being able to enter the heating chamber through the transmission channel, the aerosol-generating article absorbing the microwave and generating heat for atomization.

In one embodiment, the microwave generator comprises an anode and a cathode which are arranged around the heating cavity, and the microwaves generated by the excitation of the anode and the cathode enter the heating cavity through the transmission channel.

In one embodiment, the cathode is closer to the heating chamber than the anode.

In one embodiment, the side wall of the heating chamber is arranged around the bottom wall of the heating chamber, and the transmission passage is arranged on the bottom wall of the heating chamber.

In one embodiment, the heating portion is made of a metal material.

In one embodiment, the heating part is made of a ceramic material or a polytetrafluoroethylene material, and the atomizing assembly further comprises a metal reflecting layer which covers the bottom wall and the side wall of the heating cavity at the same time.

In one embodiment, the atomizing assembly further comprises a filter body interposed in the heating chamber to seal the heating chamber.

In one embodiment, the atomization assembly further comprises a filter membrane capable of reflecting microwaves, and the filter membrane is attached to the end of the filter body; when the filter body is inserted in the heating cavity, the filter membrane is positioned in the heating cavity.

In one embodiment, the atomizing assembly is provided with a mounting cavity, the transmission channel is communicated with the mounting cavity, the microwave generator comprises a magnetron and an output tube connected with the magnetron, the magnetron is accommodated in the mounting cavity, the output tube is arranged in the transmission channel in a penetrating manner, and microwaves generated by the magnetron enter the heating cavity through the output tube and the transmission channel.

In one embodiment, the side wall of the heating chamber is arranged around the bottom wall of the heating chamber, and the transmission passage is arranged on the side wall of the heating chamber.

In one embodiment, the microwave generator further comprises a battery and a circuit board, wherein the battery is electrically connected with the microwave generator through the circuit board.

In one embodiment, the heating chamber is circular in cross-section.

One technical effect of one embodiment of the invention is that: after the microwave generated by the microwave generator enters the heating cavity through the transmission channel, the aerosol generating product in the heating cavity absorbs the microwave, and due to the special mechanism of microwave heating, the central part and the edge part of the object which has absorbed the microwave simultaneously generate heat to raise the temperature, so that the aerosol generating product can be rapidly raised from the normal temperature to the atomization temperature in a short time to atomize and form smoke, and the rapid heating function of the electronic atomization device is realized.

Drawings

Figure 1 is a schematic cross-sectional structure view of an aerosol-generating article provided by a first embodiment;

figure 2 is a schematic cross-sectional structure view of an aerosol-generating article provided by a second embodiment;

FIG. 3 is a schematic diagram of a first example of a wave absorbing phase change body in the aerosol-generating article of FIG. 2;

figure 4 is a schematic diagram of a second example of a wave absorbing modification in the aerosol-generating article of figure 2;

FIG. 5 is a schematic diagram of a third example of a wave absorbing phase change body in the aerosol-generating article of FIG. 2;

figure 6 is a schematic cross-sectional structure view of an aerosol-generating article according to a third embodiment;

figure 7 is a schematic cross-sectional structure view of an aerosol-generating article according to a fourth embodiment;

figure 8 is a schematic cross-sectional structure view of an aerosol-generating article according to a fifth embodiment;

figure 9 is a schematic cross-sectional structure view of an aerosol-generating article according to a sixth embodiment;

fig. 10 is an exploded schematic view of an electronic atomizer according to a first embodiment;

FIG. 11 is a schematic view of an assembled structure of the electronic atomizer shown in FIG. 10;

fig. 12 is an exploded schematic view of an electronic atomizer according to a second embodiment;

fig. 13 is an exploded schematic view of an electronic atomizer according to a third embodiment;

fig. 14 is an exploded schematic view of an electronic atomizer according to a fourth embodiment;

fig. 15 is a flowchart of a method for preparing a wave-absorbing phase change material according to an embodiment.

Detailed Description

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

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "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 aerosol-generating article 10 according to an embodiment of the present invention includes an atomizing medium 11, where the atomizing medium 11 includes a matrix 100, a temperature control body 200, and a wave absorbing body 300, and the atomizing medium 11 is formed by uniformly mixing the three components. After being mixed uniformly, the atomized medium 11 can be compacted by a compacting device so that the atomized medium 11 is in a compacted state rather than a fluffy state, and the atomized medium 11 is ensured to be shaped, that is, the atomized medium 11 has a certain shape. The compacted aerosol 11 may be in the form of a cylinder, i.e. similar to a conventional cigarette.

In some embodiments, the matrix 100 may be tobacco, etc., and the matrix 100 may be formed into a spherical shape, a granular shape, or a filament shape having a certain length. The matrix 100 may be atomized to form a mist by heating without burning, and the atomization temperature may be less than 350 ℃.

The temperature-controlling body 200 may be in the form of a spherical particle, and the temperature-controlling body 200 may be a mixture of three materials, i.e., potassium nitrate, calcium nitrate, and sodium nitrate. When the preset temperature threshold is reached, the temperature control body 200 may generate phase change to absorb heat, and in the process of absorbing heat and generating phase change, the temperature of the temperature control body 200 itself may be kept unchanged, or the temperature rise is slow and the rise is small, for example, the temperature rise is not higher than 1 ℃. The value of the preset temperature threshold can be 300-350 ℃, and the specific value can be 300 ℃, 310 ℃, 340 ℃ or 350 ℃ and the like. For example, the phase change of the temperature control body 200 may be a solid-solid phase change, the temperature control body 200 has a first solid phase and a second solid phase, the first solid phase is a crystalline solid phase, the second solid phase is an amorphous solid phase, the temperature control body 200 can be transformed from the first solid phase to the second solid phase after absorbing heat, and conversely, the temperature control body 200 can be transformed from the second solid phase to the first solid phase after releasing heat. For another example, the phase change of the temperature control body 200 may be a solid-liquid phase change, the temperature control body 200 has a solid phase and a liquid phase, the solid phase may be transformed into the liquid phase from the solid phase after the temperature control body 200 absorbs heat, and conversely, the liquid phase may be transformed into the solid phase from the liquid phase after the temperature control body 200 releases heat.

The absorber 300 may be in the form of spherical particles. The wave absorber 300 can be made of zinc oxide, the wave absorber 300 can absorb microwaves, the wave absorber 300 after absorbing the microwaves can rapidly heat up and generate heat, and the wave absorber 300 can conduct the heat to the matrix 100 and the temperature control body 200.

After absorbing the microwaves, due to the particularity of the microwave heating mechanism, the central portion and the edge portion of the wave absorber 300 generate heat simultaneously to raise the temperature, so that the wave absorber 300 can rapidly raise the temperature in a very short time, and thus the wave absorber 300 can conduct a large amount of heat to the matrix 100 in a short time to rapidly raise the temperature of the matrix 100, thereby shortening the time required for raising the temperature of the matrix 100 from the normal temperature to the atomization temperature, and finally enabling the matrix 100 to be rapidly atomized in a short time (less than 0.5 seconds) to form smoke for pumping, thereby ensuring that the whole aerosol-generating article 10 has good user experience. Meanwhile, since the wave absorbers 300 are uniformly distributed in the atomizing medium 11, each wave absorber 300 can be regarded as a heat source, so that the chances of the matrix body 100 in the atomizing medium 11 absorbing heat from each heat source are uniform, and the matrix body 100 at each position in the atomizing medium 11 can be raised to the atomizing temperature for atomizing in the same short time, that is, the atomizing speed at each position in the whole aerosol-generating article 10 is the same. Whereas for conventional aerosol-generating articles 10, it is common to insert a heat generating sheet into the aerosol-generating article 10 to heat it, since the heat generating sheet is electrically heated, the heat generating sheet is heated slowly relative to the wave absorber 300, and in addition, the time required for heat to be conducted from the heat generating sheet to the aerosol-generating article 10 increases from the normal temperature to the atomizing temperature, which takes 10 seconds to 30 seconds, i.e. it is difficult to atomize and form smoke quickly. Also, the portion of the aerosol-generating article 10 that is relatively further from the heat-generating sheet has less chance of absorbing heat, making it more difficult for that portion of the aerosol-generating article 10 to be rapidly atomised to form an aerosol, further resulting in differences in the speed of atomisation throughout the aerosol-generating article 10.

Meanwhile, due to the arrangement of the temperature control body 200, the highest temperature of the matrix body 100 can be effectively controlled, and the highest temperature of the matrix body 100 is ensured not to exceed the preset temperature threshold of the temperature control body 200. Specifically, when the highest temperature of the matrix 100 reaches the preset temperature threshold of the temperature control body 200, the temperature control body 200 generates a phase change to continuously absorb heat, the temperature control body 200 does not heat up or has a small rising amplitude, and under the condition that a part of heat generated by the wave absorber 300 is absorbed by the temperature control body 200, the matrix 100 cannot absorb redundant heat to continuously heat up, so that the matrix 100 is prevented from being burnt due to exceeding the highest temperature, and soot and other harmful gases formed in the burning process are prevented from being generated.

Referring to fig. 2 to 4, in some embodiments, in the process of mixing the matrix 100, the temperature control body 200, and the wave absorbing body 300 to form the atomized medium 11, the temperature control body 200 and the wave absorbing body 300 are first mixed to form the wave absorbing phase change body 500 in an integrated form, where the wave absorbing phase change body 500 is denoted as a first wave absorbing phase change body 510, and then the first wave absorbing phase change body 510 is mixed with the matrix 100 to form the atomized medium 11. The first absorbing phase change material 510 may also be in the form of spherical particles.

Referring to fig. 3, for example, a temperature control body 200 is embedded inside a wave absorbing body 300. The wave absorbing body 300 is provided with only one accommodating hole 310 with a large volume inside, the accommodating hole 310 may be spherical, the temperature control body 200 is filled in the accommodating hole 310, and the wave absorbing body 300 wraps the temperature control body 200 in the accommodating hole 310 to form the first wave absorbing phase change body 510 of the first example. In other words, in the single first wave absorbing phase change body 510, one wave absorbing body 300 encloses one temperature control body 200 with a larger volume. In the first wave-absorbing phase change body 510, the volume of the wave-absorbing body 300 is slightly larger than the volume of the temperature-controlled body 200.

Referring to fig. 4, as another example, a plurality of discrete temperature control bodies 200 are embedded inside a wave absorber 300. The wave absorber 300 is provided therein with a plurality of accommodation holes 310 with small volume, the accommodation holes 310 may also be spherical and uniformly distributed in the wave absorber 300, and the accommodation holes 310 are independent and not communicated with each other. The second exemplary first wave-absorbing phase-change body 510 is formed by filling each of the housing holes 310 with the temperature-controlled body 200, and the wave-absorbing body 300 wraps the temperature-controlled bodies 200 in all the housing holes 310. In other words, in the single first wave absorbing phase change body 510, the plurality of temperature control bodies 200 are discretely distributed and embedded in the wave absorbing body 300, that is, one wave absorbing body 300 encapsulates the plurality of discrete temperature control bodies 200 with small volume. In the first wave absorbing phase change body 510, the volume of the wave absorbing body 300 is much larger than that of the temperature controlled body 200.

Referring to fig. 2 and 5, in some embodiments, the atomizing medium 11 further includes a heat conductor 400, the heat conductor 400 may be made of a material with good thermal conductivity, and in the process of mixing the matrix 100, the temperature control body 200, and the wave absorber 300 to form the atomizing medium 11, the heat conductor 400, the temperature control body 200, and the wave absorber 300 are first mixed to form the wave-absorbing phase-change body 500 in an integrated form, where the wave-absorbing phase-change body 500 is denoted as a second wave-absorbing phase-change body 520, and then the second wave-absorbing phase-change body 520 and the matrix 100 are mixed to form the atomizing medium 11. The second wave-absorbing phase-change body 520 may also be in the form of spherical particles.

Referring to fig. 5, in particular, a plurality of accommodating holes 310 are formed in the heat conductor 400, and each accommodating hole 310 may be equal in size and spherical. The plurality of receiving holes 310 are also independent and not connected to each other. Wherein a part of the accommodating holes 310 is filled with the temperature control body 200, the rest of the accommodating holes 310 is filled with the wave absorbing body 300, and the heat conductor 400 wraps the temperature control body 200 and the wave absorbing body 300 to form a second wave absorbing phase change body 520. In other words, in the single second wave absorbing phase change body 520, the plurality of temperature control bodies 200 and the wave absorbing bodies 300 are distributed discretely and embedded in the heat conducting body 400, that is, one heat conducting body 400 wraps the plurality of discrete temperature control bodies 200 and the wave absorbing bodies 300 with small volume. In the second wave absorbing modification 520, the volumes of the temperature control body 200 and the wave absorbing body 300 can be substantially equal, and the volume of the heat conducting body 400 is much larger than the volumes of the temperature control body 200 and the wave absorbing body 300.

In the first wave-absorbing phase-change body 510, the heat generated by the wave-absorbing body 300 is directly transferred to the temperature control body 200 and the matrix 100, the phase change of the temperature control body 200 may be a solid-liquid phase change, and the liquid temperature control body 200 is accommodated in the accommodating hole 310 and cannot overflow out of the wave-absorbing body 300 due to the wrapping effect of the wave-absorbing body 300, thereby constituting a leakage loss. Of course, the phase change of the temperature control body 200 may be a solid-solid phase change. In the second wave-absorbing phase-change body 520, the heat generated by the wave-absorbing body 300 is indirectly transferred to the temperature-controlled body 200 and the matrix body 100 through the heat conductor 400, and similarly, the liquid temperature-controlled body 200 is accommodated in the accommodating hole 310 by the accommodating function of the accommodating hole 310 and cannot overflow out of the heat conductor 400, and the phase change of the temperature-controlled body 200 may be a solid-solid phase change.

Referring to fig. 1, in other embodiments, in the mixing process, the temperature control body 200 and the wave absorber 300 may be separated from each other and processed in an independent state, that is, the temperature control body 200 and the wave absorber 300 are not combined into an intermediate wave-absorbing phase change body 500, but the temperature control body 200 and the wave absorber 300 are directly mixed with the matrix 100 to form the atomized medium 11, the wave absorber 300 does not generate an entrapment effect on the temperature control body 200, and the wave absorber 300 and the temperature control body 200 are not enveloped by other substances at the same time. At this time, in order to prevent free flow and leakage of the liquid temperature control body 200 after the phase transition, the phase transition of the temperature control body 200 in this embodiment adopts solid-solid phase transition.

Referring to both fig. 6 and 7, in some embodiments, the aerosol-generating article 10 further comprises a protective layer 12, and the protective layer 12 may be formed from a paper material. The holding layer is attached to the side peripheral surface of the atomized medium 11, that is, the atomized medium 11 is covered in the protective layer 12. Of course, the protective layer 12 may completely cover the entire surface of the atomized medium 11, and by providing the protective layer 12, the protective layer 12 may form a certain constraint force on the atomized medium 11, so as to prevent the atomized medium 11 from being detached from the material under the action of external force to form local collapse.

Referring to fig. 8 and 9 concurrently, in some embodiments, the aerosol-generating article 10 further comprises a filter segment 610, a cooling segment 630, and a filter membrane, referred to as a first filter membrane 620. The atomizing medium 11 and the filter segment 610 are divided at two ends, the cooling segment 630 is located in the middle, that is, the upper end of the cooling segment 630 is connected with the filter segment 610, and the lower end of the cooling segment 630 is connected with the atomizing medium 11. The first filter membrane 620 is attached to one end of the filter segment 610 near the atomizing assembly 700, i.e., the first filter membrane 620 is located at the lower end of the filter segment 610, and the first filter membrane 620 can prevent the microwave from penetrating therethrough, so as to reduce the microwave loss. The filter segment 610 may be made of a cotton material, and the filter segment 610 functions similarly to a filter in a conventional cigarette to filter harmful aerosols from the smoke to prevent the harmful aerosols from being absorbed by the user. Meanwhile, when the smoke passes through the cooling section 630, the smoke and the cooling section 630 generate heat exchange, so that the temperature of the smoke is reasonably reduced, and the smoke with higher temperature is prevented from forming hot discomfort for a user.

Referring to fig. 15, the present invention also provides a method of manufacturing the first absorbing phase variant, by which the first absorbing phase variant 510 of the first example described above can be formed. The preparation method mainly comprises the following steps:

step S901, potassium nitrate, calcium nitrate, and sodium nitrate are uniformly mixed to form a mixed raw material, and the mixed raw material is heated and melted to form a liquid melt.

Specifically, the mixed raw materials comprise, by weight, 10-30 parts of potassium nitrate, 10-40 parts of calcium nitrate and 30-80 parts of sodium nitrate. The mixed raw materials of potassium nitrate, calcium nitrate and sodium nitrate are placed in a crucible, the crucible is placed in a heating device such as an electric furnace, the temperature of the electric furnace is heated to 330-380 ℃, the mixed raw materials are melted to form liquid molten liquid, and the molten liquid is stirred to be uniformly mixed.

And a second step, S902, keeping the temperature of the highest temperature point of the melting liquid for a set time, and cooling to room temperature to obtain mixed phase-change powder.

Specifically, the molten liquid is kept at the highest temperature point for 3-8 h, and then the molten liquid is cooled to room temperature along with the furnace in an electric furnace, and at the moment, the molten liquid is converted into mixed phase-change powder.

Third, S903, dissolving zinc acetate dihydrate in absolute ethanol to form an ethanol solution of zinc acetate dihydrate; oxalic acid is dissolved in additional absolute ethanol to form an oxalic acid ethanol solution.

Specifically, a first container and a second container may be prepared, and anhydrous ethanol may be added to the first container and the second container, respectively. Adding zinc acetate dihydrate into the absolute ethyl alcohol in the first container, and heating the first container to completely dissolve the zinc acetate dihydrate into the absolute ethyl alcohol, wherein the heating temperature can be 40-60 ℃, and when the zinc acetate dihydrate is completely dissolved, an ethanol solution of the zinc acetate dihydrate is formed in the first container. Oxalic acid is added to the absolute ethyl alcohol in the first container, and an ethyl oxalate solution is formed in the second container.

The fourth step, S904, is to add the mixed phase change powder and the oxalic acid ethanol solution to an ethanol solution of zinc acetate dihydrate and heat-stir to form a gel.

Specifically, the mixed phase-change powder may be dispersed further by means of, for example, ultrasonic vibration for 10 to 20 min. And then adding the dispersed mixed phase change powder into an ethanol solution of zinc acetate dihydrate in the first container. Then, the oxalic acid ethanol solution in the second container is slowly added into the first container. And finally, stirring the mixed solution in the first container at a high speed under the heating condition, wherein the heating temperature can be 70-90 ℃, and at the moment, the mixed solution in the first container is converted into gel.

And step five, S905, ageing and drying the gel and then calcining the gel.

Referring to fig. 3, specifically, the gel is put into a high temperature furnace to be calcined, the calcining temperature is 400-800 ℃, and the calcining time is 2-8 h. After the calcination process, the gel is transformed into the first absorbing phase variant 510 of the first example, i.e. the absorbing body 300 only covers one temperature control body 200.

Referring to fig. 10, the present invention further provides an electronic atomizer 20, wherein the electronic atomizer 20 is configured to atomize the aerosol-generating article 10 into an aerosol by heating without burning. The electronic atomizer 20 includes an atomizing assembly 700 and a microwave generator 800. The atomizing assembly 700 includes a heating portion 710, the heating portion 710 defines a heating cavity 711 and a conveying passage 712, the heating cavity 711 communicates with the outside and the conveying passage 712, and the heating cavity 711 is used for receiving the aerosol-generating article 10. The microwave generator 800 is connected to the atomizing assembly 700, and the microwaves generated by the microwave generator 800 enter the heating chamber 711 through the transmission passage 712. With the aerosol-generating article 10 positioned in the heating chamber 711, referring to fig. 1, the wave absorber 300 in the aerosol-generating article 10 absorbs the microwaves and generates heat, and the heat of the wave absorber 300 is conducted to the matrix 100 to make the matrix 100 reach a temperature required for atomization, and at the same time, the temperature control body 200 can generate a phase change to absorb excess heat, thereby preventing the matrix 100 from being burnt due to an excessively high temperature.

In some embodiments, for example, referring to fig. 10, the heating part 710 is made of a metal material, so that the heating part 710 has a good reflection function for the microwaves, and the microwaves entering the heating cavity 711 are prevented from penetrating through the heating part 710 to cause microwave loss, and when the microwaves are reflected in the heating cavity 711 for multiple times, the wave absorber 300 fully absorbs the microwaves in the heating cavity 711, thereby improving the utilization rate of energy. For another example, the heating part 710 may also be made of a non-metal material such as a ceramic material or a teflon material, and in this case, the atomizing assembly 700 further includes a metal reflective layer (not shown), and the metal reflective layer covers both the bottom wall 711b and the side wall 711a of the heating cavity 711. By providing the metal reflective layer, the microwave can be prevented from being lost through the heating portion 710, and the absorber 300 can be ensured to absorb the microwave completely.

Referring also to fig. 10-13, in some embodiments, for example, the microwave generator 800 includes a cathode 810 and an anode 820 disposed around the heating cavity 711, with the cathode 810 being closer to the heating cavity 711 than the anode 820. Obviously, the side wall 711a of the heating cavity 711 is disposed around the bottom wall 711b of the heating cavity 711, the transmission passage 712 is disposed on the bottom wall 711b of the heating cavity 711, the microwaves generated by the excitation of the anode 820 and the cathode 810 enter the heating cavity 711 through the transmission passage 712 on the bottom wall 711b, and the number of the transmission passages 712 may be one or more. The entire electronic atomization device 20 can be made more compact by this arrangement. Referring to fig. 14, for example, the atomizing assembly 700 is provided with an installation cavity 713, the transmission channel 712 is simultaneously communicated with the heating cavity 711 and the installation cavity 713, the microwave generator 800 includes a magnetron 830 and an output tube 840, the magnetron 830 is accommodated in the installation cavity 713 and can generate microwaves, one end of the output tube 840 is connected with the magnetron 830, and the other end of the output tube 840 is inserted into the transmission channel 712. The magnetron 830 generates microwaves, and the microwaves generated by the magnetron 830 enter the heating chamber 711 through the output pipe 840 via the transmission passage 712. The transfer passages 712 are disposed on the side wall 711a of the heating cavity 711, and the number of the transfer passages 712 may be one or more, for example, the number of the transfer passages 712 is three.

Referring to fig. 12-14, in some embodiments, the atomizing assembly 700 further includes a filter body 720 and a filter membrane, which may be referred to as a second filter membrane 730. The filter body 720 may be made of a ceramic material, the filter body 720 is adapted to be inserted into the heating chamber 711 to seal the heating chamber 711, and the filter body 720 also functions similarly to a filter in a conventional cigarette to filter harmful aerosols in the smoke to prevent their absorption by the user. The second filter membrane 730 is attached to the end of the filter body 720, and when the filter body 720 is inserted into the heating cavity 711, the second filter membrane 730 is located in the heating cavity 711, the second filter membrane 730 can reflect microwaves, and the filter body 720 has the advantages of repeated use and convenience in plugging and unplugging.

Referring also to fig. 10-13, for the aerosol-generating article 10 described above that does not include the filter segment 610 and the cooling segment 630, the filter 720 is inserted into the heating chamber 711 when the aerosol-generating article 10 is positioned in the heating chamber 711. On one hand, the filter body 720 has a sealing effect on the heating cavity 711, so that the heating cavity 711 forms a sealed cavity, at this time, the microwaves entering the heating cavity 711 cannot leak from the sealed heating cavity 711 due to the reflection effect of the second filter film 730 and the heating part 710 on the microwaves or due to the reflection effect of the second filter film 730 and the metal reflection layer on the microwaves, so that the wave absorber 300 can completely absorb the microwaves in the heating cavity 711, and the energy utilization rate of the electronic atomization device 20 is improved. On the other hand, when the user draws smoke through the filter 720, the smoke generated by the aerosol-generating article 10 is filtered by the filter 720, so that harmful aerosols in the smoke cannot pass through the filter 720 and be drawn by the user, thereby improving the health and safety of the use of the electronic atomizer 20. Meanwhile, the filter 720 generates heat exchange with the smoke, so that the temperature of the smoke can be reasonably reduced.

Referring to figure 14, for the aerosol-generating article 10 described above with its own filter segment 610 and cooling segment 630, the cooling segment 630 has the cooling function of the filter body 720, as the filter segment 610 has the filtering function of the filter body 720. At this time, the entire aerosol-generating article 10 may be directly inserted into the heating chamber 711 without using the filter 720 of the electronic atomization device 20. Due to the reflection of the microwaves by the first filter film 620 and the heating unit 710, or due to the reflection of the microwaves by the first filter film 620 and the metal reflective layer, the microwaves cannot leak from the sealed heating chamber 711, and the microwaves in the heating chamber 711 can be absorbed by the wave absorber 300. Also, the filter section 610 of the aerosol-generating article 10 can filter out harmful aerosols from the smoke, and the cooling section 630 can reduce the temperature of the smoke.

Referring to both fig. 10 and 11, considering that the aerosol-generating article 10 and the filter 720 are cylindrical, the cross-section of the heating chamber 711 may be circular, i.e. the heating chamber 711 is also cylindrical, so that when engaged with the heating chamber 711, the aerosol-generating article 10 or the filter 720 seals the heating chamber 711. The electronic atomization device 20 further includes a battery 910 and a circuit board 920, and the battery 910 is electrically connected to the microwave generator 800 through the circuit board 920. When the battery 910 supplies power to the microwave generator 800, the microwave generator 800 can generate microwaves that are transmitted into the heating chamber 711.

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 invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (12)

1. An electronic atomization device, comprising:

the atomizing assembly comprises a heating part, the heating part is provided with a transmission channel and a heating cavity for accommodating aerosol generating products, and the heating cavity is communicated with the transmission channel and the outside; and

a microwave generator connected to the atomizing assembly, the microwave generated by the microwave generator being able to enter the heating chamber through the transmission channel, the aerosol-generating article absorbing the microwave and generating heat for atomization.

2. The electronic atomizing device of claim 1, wherein the microwave generator includes an anode and a cathode both disposed around the heating chamber, and the microwaves generated by the excitation of the anode and the cathode enter the heating chamber through the transmission channel.

3. The electronic atomizing device of claim 2, wherein the cathode is closer to the heating chamber than the anode.

4. The electronic atomizing device of claim 2, wherein the side wall of the heating chamber is disposed around the bottom wall of the heating chamber, and the transmission passage is disposed on the bottom wall of the heating chamber.

5. The electronic atomizer device of claim 1, wherein said heating portion is formed from a metallic material.

6. The electronic atomizer device according to claim 1, wherein said heating portion is made of a ceramic material or a polytetrafluoroethylene material, and said atomizer assembly further comprises a metal reflective layer covering both the bottom wall and the side wall of said heating chamber.

7. The electronic atomizing device of claim 1, wherein the atomizing assembly further comprises a filter inserted in the heating chamber to seal the heating chamber.

8. The electronic atomizer device of claim 7, wherein said atomizing assembly further comprises a filter membrane capable of reflecting microwaves, said filter membrane attached to an end of said filter body; when the filter body is inserted in the heating cavity, the filter membrane is positioned in the heating cavity.

9. The electronic atomizing device according to claim 1, wherein the atomizing assembly has a mounting cavity, the transmission channel communicates with the mounting cavity, the microwave generator includes a magnetron and an output tube connected to the magnetron, the magnetron is received in the mounting cavity, the output tube is inserted into the transmission channel, and the microwave generated by the magnetron passes through the output tube and enters the heating cavity through the transmission channel.

10. The electronic atomizing device of claim 9, wherein the side wall of the heating chamber is disposed around the bottom wall of the heating chamber, and the transmission passage is disposed on the side wall of the heating chamber.

11. The electronic atomization device of claim 1 further comprising a battery and a circuit board, wherein the battery is electrically connected to the microwave generator through the circuit board.

12. The electronic atomizing device of claim 1, wherein the heating chamber has a circular cross-section.

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