CN215381427U - Aerosol-generating system and aerosol-generating article thereof - Google Patents

Abstract

An aerosol generating system and aerosol generating article thereof, the aerosol generating article being cylindrical and capable of being inserted into a microwave heating chamber having a shielded enclosure to generate an aerosol under microwave heating; the aerosol-generating article comprises a microwave shielding structure in electrical connection with the shielding housing when the aerosol-generating article is inserted into the microwave heating chamber. The utility model has the beneficial effects that: the aerosol generating product forms the shielding of the whole machine when in use through the shielding structure which is arranged and electrically connected with the shielding shell of the microwave heating cavity, thereby improving the use safety.

Description

Aerosol-generating system and aerosol-generating article thereof

Technical Field

The present invention relates to aerosol generating technology, and in particular to an aerosol generating system and an aerosol generating article thereof.

Background

The aerosol generating 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 aerosol generating device, when the cigarette is atomized by adopting a heating non-combustion mode, the cigarette needs to consume a 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 aerosol generating device is difficult to meet the user experience.

SUMMERY OF THE UTILITY MODEL

In response to the deficiencies in the art, the present invention provides an improved aerosol-generating system and aerosol-generating article thereof.

To achieve the above objects, the present invention provides an aerosol-generating article in the form of a column that can be inserted into a microwave heating chamber with a shielded enclosure to generate an aerosol under microwave heating; the aerosol-generating article comprises a microwave shielding structure in electrical connection with the shielding housing when the aerosol-generating article is inserted into the microwave heating chamber.

In some embodiments, the shielding structure comprises a microwave shielding layer disposed on a cross-section of the aerosol-generating article, the microwave shielding layer comprising a resilient electrically conductive flange radially protruding from the aerosol-generating article; the microwave shielding structure is electrically connected with the shielding shell through the elastic conductive flange.

In some embodiments, the microwave shielding layer is made of a metal fiber layer.

In some embodiments, the microwave shielding layer further comprises a sleeve projecting towards the insertion end of the aerosol-generating article.

In some embodiments, the aerosol-generating article comprises a cylindrical shell and an aerosol-generating component and filter segment disposed within the shell.

In some embodiments, the filter segments are made of a material having microwave shielding.

In some embodiments, the filter segment is made of at least one of metal foam, conductive foam, carbon material, polymer composite material, mixed fabric of metal conductive fibers and acetate tow, mixed fiber tow with metal conductive fibers as core material and non-conductive fibers coated on the outer layer.

In some embodiments, the aerosol-generating article further comprises a cooling section disposed within the housing, the cooling section being located between the aerosol-generating component and the filter section.

In some embodiments, the aerosol-generating article comprises tobacco, an aerosol former, and functional particles, the functional particles being capable of absorbing microwaves; the functional particles can convert the absorbed microwaves into heat energy and then transfer the heat energy to the tobacco and the aerosol forming agent.

In some embodiments, the functional particles have an emissivity of greater than 0.9.

In some embodiments, the aerosol-generating article comprises a cylindrical housing and an aerosol-generating component and a filter segment disposed within the housing; the aerosol-generating article further comprises a microwave shielding layer disposed at the filter segment proximate to and/or distal to an end face of the aerosol-generating component.

In some embodiments, the microwave shielding layer is made of a highly conductive and gas permeable material.

In some embodiments, the microwave shielding layer is made of a transparent electromagnetic shielding film, a metal-plated thin film, a microwave shielding glass, a single/multi-layer metal grid, a composite shielding substrate made of a transparent conductive film and glass, a foamed metal, a carbon material, or a microwave shielding polymer composite.

There is provided an aerosol-generating system comprising an aerosol-generating article according to any preceding claim and an aerosol-generating device for microwave heating of the aerosol-generating article, the aerosol-generating device comprising a microwave heating chamber into which the aerosol-generating article is removably inserted, the microwave heating chamber comprising a shielded housing, the shielded housing being in electrical communication with the microwave shielding structure.

The utility model has the beneficial effects that: the aerosol generating product forms the shielding of the whole machine when in use through the shielding structure which is arranged and electrically connected with the shielding shell of the microwave heating cavity, thereby improving the use safety.

Drawings

Fig. 1 is a schematic diagram of an aerosol-generating system in some embodiments of the utility model.

Figure 2 is a schematic view of the aerosol-generating article of the aerosol-generating system of figure 1 separated from an aerosol-generating device.

Fig. 3 is a schematic block circuit diagram of an aerosol generating device of the aerosol generating system of fig. 1.

Figure 4 is a schematic block diagram of an electrical circuit of an aerosol generating device according to further embodiments of the present invention.

Figure 5 is a schematic block circuit diagram of an aerosol generating device in further embodiments of the utility model.

Figure 6 is a schematic block circuit diagram of an aerosol generating device in further embodiments of the utility model.

Figure 7 is a schematic block circuit diagram of an aerosol generating device in some other embodiments of the utility model.

Figure 8 is a flow chart of microwave control of an aerosol generating device according to some embodiments of the present invention.

Figure 9 is a schematic representation of microwave field strength distributions for aerosol generating devices according to some embodiments of the present invention.

Fig. 10 is a schematic view of the internal structure of the housing of the atomizing chamber of the aerosol-generating device according to some embodiments of the present invention.

Figure 11 is a schematic view of the internal structure of an aerosol-generating article according to some embodiments of the utility model.

Figure 12 is a schematic view of the internal structure of an aerosol-generating article according to further embodiments of the present invention.

Figure 13 is a schematic view of the internal structure of an aerosol-generating article according to further embodiments of the present invention.

Figure 14 is a reference view of the aerosol-generating article of figure 13 in use.

Figure 15 is a schematic view of the internal structure of an aerosol-generating article according to further embodiments of the present invention.

Figure 16 is a schematic view of the internal structure of an aerosol-generating article according to further embodiments of the present invention.

Figure 17 is a schematic diagram of an atomising chamber for an aerosol generating device according to some embodiments of the utility model.

Figure 18 is an enlarged partial schematic view of an aerosol-generating article according to some embodiments of the utility model.

Figure 19 is a schematic cross-sectional structure of functional particles of the aerosol-generating article of figure 18.

Figure 20 is a schematic diagram of an aerosol generating device according to still further embodiments of the present invention.

Detailed Description

The present invention will now be described more fully hereinafter for purposes of facilitating an understanding thereof, and may be embodied in many different forms and are not limited to the embodiments described 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 be present. When the terms "vertical," "horizontal," "left," "right," "upper," "lower," "inner," "outer," "bottom," and the like are used to indicate an orientation or positional relationship, it is for convenience of description only based on the orientation or positional relationship shown in the drawings, and it is not intended to indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present application. Furthermore, the terms "first," "second," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the utility model herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model.

Fig. 1 and 2 illustrate an aerosol-generating system 1 in some embodiments of the utility model, the aerosol-generating system 1 may comprise an aerosol-generating device 10 and an aerosol-generating article 20 detachably connected to the aerosol-generating device 10. The aerosol-generating device 10 is used to heat the aerosol-generating substrate of the aerosol-generating article 20 to generate an aerosol. The aerosol-generating device 10 may in some embodiments be a heated, non-burning aerosol-generating device, and may be hand-held, which may be used to heat an aerosol-generating article 20 comprising solid tobacco, such as a cigarette rod. It will be appreciated that the aerosol-generating article 20 is not limited to being a cigarette rod, but may also be a cigarette cake or a cigarette piece. It will be appreciated that the aerosol-generating article 20 may also be an aerosol-generating article comprising liquid tobacco smoke.

As further shown, the aerosol-generating device 10 may, in some embodiments, include a microwave generator 11, an atomization chamber 12 connected to the microwave generator 11, and a holder 13 disposed within the atomization chamber 12 for holding an aerosol-generating article 20. The cavity 12 is adapted to define a microwave heating chamber 122. The top wall of the atomization chamber 12 has an opening 120 that communicates with a microwave heating chamber 122 to allow for insertion of the aerosol-generating article 20 into the microwave heating chamber 122. The microwave generator 11 is used for feeding microwaves into the microwave heating chamber 122, and the operating frequency band thereof can be 915MHz to 30 GHz. A holder 13 is provided within the microwave heating chamber 122 for removably securing an aerosol-generating article 20 therein for microwave heating of the aerosol-generating article 20. It will be appreciated that when the aerosol-generating article 20 is a cake or a piece of tobacco that does not have a mouthpiece, the opening 120 for insertion of the aerosol-generating article 20 described above may be eliminated and replaced by a door that can be opened and closed, and a mouthpiece with microwave shielding may be provided on the atomizing chamber 12. It will be appreciated that the mounting 13 may be omitted in some embodiments.

The atomizing chamber 12 may be integrally or detachably connected to the microwave generator 11 through the bottom in some embodiments, and the housing of the atomizing chamber 12 may include a metal material having a microwave shielding function or other high-conductivity materials, a metal-plated film-coated hard plastic, a non-metal material such as a transparent shielding glass, or a multi-layer metal mesh, a film and non-metal composite shielding material in some embodiments. It is understood that the opening 120 of the atomizing chamber 12 is not limited to the top wall, and may be provided on the side wall as required.

The microwave generator 11 may include a housing 111, a microwave generating circuit 112 disposed within the housing 111, and a microwave transmitting antenna 113 connected to the microwave generating circuit 112 in some embodiments. The microwave generation circuitry 112 may include a solid state microwave source in some embodiments. The microwave transmitting antenna 113 may in some embodiments extend into the nebulizing chamber 12 for transmitting the microwave signal generated by the microwave generating circuit 112 into the nebulizing chamber 12. In addition, the microwave transmitting antenna 113 is located outside the holder 13, i.e. the microwave transmitting antenna 113 is not inserted into the aerosol-generating article 20 contained in the holder 13 during operation, enabling a non-contact heating of the aerosol-generating substrate of the aerosol-generating article 20 to facilitate the insertion and extraction of the aerosol-generating article 20. The number of the microwave transmitting antennas 113 may be one or more than one. Microwave generator 11 may, in some embodiments, include a battery 1101 disposed within housing 111, heat sink 1102, and connector 1103 for connecting to microwave transmitting antenna 113, battery 1101 being used to power the entire device.

Referring to fig. 3 together, the microwave generator 11 may include a microwave control circuit 114 and a feedback acquisition circuit 115 in some embodiments, and the microwave control circuit 114 is connected to the microwave generation circuit 112 and the feedback acquisition circuit 115, respectively. The operation of the aerosol generating device 10 may be: the microwave control circuit 114 determines a preset microwave frequency and controls the microwave generating circuit 112 to generate microwaves at the preset microwave frequency. The microwave transmitting antenna 113 emits microwaves in a frequency sweep within a predetermined microwave frequency range, at least a portion of which is focused in the nebulizing chamber 12 to heat the aerosol-generating article 20. It should be noted that, the microwave transmitting antenna 113 is required to perform frequency sweeping to transmit microwaves within the preset microwave frequency range through the microwave control circuit 114, and the microwave control circuit 114 performs frequency sweeping to determine the preset microwave frequency within the preset microwave frequency range, for example, gradually increasing the frequency from the minimum frequency of the preset microwave frequency range to the maximum frequency of the preset microwave frequency range, or gradually increasing the frequency from the minimum frequency of the preset microwave frequency range to the maximum frequency of the preset microwave frequency range according to the preset frequency interval, or gradually decreasing the frequency from the maximum frequency of the preset microwave frequency range to the minimum frequency of the preset microwave frequency range according to the preset frequency interval. For another example, the preset microwave frequency range includes at least two preset microwave frequency points, and each preset microwave frequency point is sequentially transmitted to the microwave generating circuit 112 according to a preset sequence.

Further, the feedback acquisition circuit 115 acquires a feedback signal corresponding to the microwave with the preset microwave frequency emitted by the microwave emitting antenna 113 after the microwave emitting antenna 113 emits the microwave, and transmits the feedback signal to the microwave control circuit 114, and the microwave control circuit 114 selects the microwave emitting frequency according to the feedback signal to maintain or correct the preset microwave frequency, that is, selects a proper microwave emitting frequency to enable the aerosol-generating product 20 in the atomizing cavity 121 to reach an optimal atomizing state. Alternatively, the microwave emission frequency at which the aerosol-generating article 20 absorbs the most is selected as the optimum microwave emission frequency at which the aerosol-generating device 10 emits microwaves until the next microwave sweep. In some embodiments, the aerosol-generating article 20 is directly heated using microwaves, and the microwave emission frequency is adjusted by frequency sweeping, the heating efficiency is high, and the equipment life is extended.

In some embodiments, the feedback signal is a feedback current value, and the feedback acquisition circuit 115 is a current acquisition circuit that takes an induced current value generated by the target object under the action of the microwave as the feedback current value. In some embodiments, the feedback signal is a feedback voltage value, and the feedback acquisition circuit 115 is a voltage acquisition circuit that takes an induced voltage value generated by the target object under the action of the microwave as the feedback voltage value. In some embodiments, the feedback signal is a feedback capacitance value, and the feedback acquisition circuit 115 is a capacitance acquisition circuit that uses an induced capacitance value generated by the target object under the action of the microwave as the feedback capacitance value. In some embodiments, the feedback signal is a feedback temperature value, and the feedback acquisition circuit 115 is a temperature acquisition circuit that acquires a temperature value of the target object under the action of microwaves. Alternatively, the target object may be an aerosol-generating article 20, the temperature acquisition circuit acquiring a temperature value of the aerosol-generating article 20 under the influence of microwaves.

As shown in fig. 4, the feedback signal is reverse microwave power, and the feedback acquisition circuit 115 is a microwave reverse power detector 116. After microwave emission, not all of the microwaves are absorbed by the aerosol-generating article 20 and some of the unabsorbed microwaves are detected by the reverse microwave power, resulting in reverse microwave power. Alternatively, the microwave transmitting antenna 113 acts as a receiving end for non-absorbed microwaves, the microwave reverse power detector 116 detects reverse microwave power received by the microwave transmitting antenna 113, the microwave transmitting antenna 113 absorbs a portion of the microwaves that are not absorbed by the aerosol-generating article 20, and the microwave reverse power detector 116 detects the power of the microwaves absorbed by the microwave transmitting antenna 113 to obtain the reverse microwave power. Further, after the reverse microwave power is obtained, the microwave control circuit 114 selects an optimal microwave transmitting frequency according to the reverse microwave power, for example, the microwave control circuit 114 selects a microwave transmitting frequency corresponding to the minimum value of the reverse microwave power, or the microwave control circuit 114 selects a microwave transmitting frequency in a range near the microwave transmitting frequency corresponding to the minimum value of the reverse microwave power.

As shown in fig. 5, microwave generator 11 may, in some embodiments, include a microwave forward power detector 117 coupled to microwave control circuit 114, microwave forward power detector 117 for collecting microwave transmit power. The microwave control circuit 114 may select an optimal microwave transmitting frequency according to the microwave transmitting power and the reverse microwave power, for example, select the optimal microwave transmitting frequency according to a ratio of the reverse microwave power to the microwave transmitting power, and select a corresponding microwave transmitting frequency when the ratio of the reverse microwave power to the microwave transmitting power is minimum.

As shown in fig. 6, microwave generator 11 may include a power amplifier 118 in some embodiments, an output of microwave generating circuit 112 is connected to a first input of power amplifier 118, and an output of power amplifier 118 is connected to microwave transmitting antenna 113; the microwave control circuit 114 is connected to the power amplifier 118, and the microwave control circuit 114 adjusts the power amplifier 118 according to the feedback signal. It will be appreciated that the microwave control circuit 114 may control the amplification of the power amplifier 118.

As shown in fig. 7, microwave generator 11 may, in some embodiments, include a power regulator 119, microwave control circuit 114 coupled to an input of power regulator 119, an output of power regulator 119 coupled to a second input of power amplifier 118, and microwave control circuit 114 adjusting power regulator 119 based on the feedback signal. It will be appreciated that the power amplifier 118 and the power regulator 119 may be two separate electronic components or may be an integrated electronic component that performs both the functions of the power amplifier 118 and the power regulator 119. Alternatively, the microwave control circuit 114 adjusts both the power amplifier 118 and the power regulator 119 according to the feedback signal, so as to achieve a wider range of microwave transmission power adjustment.

Referring collectively to fig. 8, a method of microwave control in an aerosol generating device 10 may, in some embodiments, include the steps of:

s1, the microwave control circuit 114 controls the microwave generating circuit 112 to generate microwaves, so that the microwave transmitting antenna 113 sweeps and transmits microwaves within a preset microwave frequency range, and the microwaves are used for heating the aerosol-generating article 20 in the atomizing chamber 12. Specifically, the microwave control circuit 114 determines a preset microwave frequency, and controls the microwave generation circuit 112 to generate microwaves at the preset microwave frequency. The microwave transmitting antenna 113 emits microwaves in a frequency sweep within a predetermined microwave frequency range, at least a portion of which is focused in the nebulizing chamber 12 to heat the aerosol-generating article 20. It should be noted that, the microwave transmitting antenna 113 is required to perform frequency sweeping to transmit microwaves within the preset microwave frequency range through the microwave control circuit 114, and the microwave control circuit 114 determines the preset microwave frequency by frequency sweeping within the preset microwave frequency range, for example, gradually increasing the frequency from the minimum frequency of the preset microwave frequency range to the maximum frequency of the preset microwave frequency range, or gradually increasing the frequency from the minimum frequency of the preset microwave frequency range to the maximum frequency of the preset microwave frequency range according to the preset frequency interval, or gradually decreasing the frequency from the maximum frequency of the preset microwave frequency range to the minimum frequency of the preset microwave frequency range according to the preset frequency interval. For another example, the preset microwave frequency range includes at least two preset microwave frequency points, and each preset microwave frequency point is sequentially transmitted to the microwave generating circuit according to a preset sequence.

S2, the feedback acquisition circuit 115 acquires a feedback signal corresponding to the microwave, and sends the feedback signal to the microwave control circuit 114. Specifically, the feedback acquisition circuit 115 acquires a feedback signal corresponding to the microwave with the preset microwave frequency transmitted by the microwave transmitting antenna 113 after the microwave transmitting antenna 113 transmits the microwave, and transmits the feedback signal to the microwave control circuit 114.

And S3, after the sweep frequency emission microwave is finished, the microwave control circuit 114 selects the microwave emission frequency according to the feedback signal. In particular, after the sweep frequency emission of microwaves is complete, the microwave control circuit 114 selects a microwave emission frequency to maintain or modify the preset microwave frequency based on the feedback signal, i.e., selects a suitable microwave emission frequency to achieve optimal atomization of the aerosol-generating article 20 in the atomization chamber. Alternatively, the microwave emission frequency at which the aerosol-generating article 20 absorbs the most is selected as the optimum microwave emission frequency at which the aerosol-generating device 10 emits microwaves until the next microwave sweep.

In some embodiments, the aerosol-generating article 20 is directly heated using microwaves, and the microwave emission frequency is adjusted by frequency sweeping, the heating efficiency is high, and the equipment life is extended.

In the microwave control method of some embodiments, the step S3 in which the microwave control circuit 114 selects the microwave transmitting frequency according to the feedback signal includes: the microwave control circuit 114 selects a microwave emission frequency and a microwave emission power according to the feedback signal, and simultaneously adjusts the microwave emission frequency and the microwave emission power to achieve an optimal atomization state of the aerosol-generating article 20 in the atomization chamber 12.

In the microwave control method of some embodiments, the feedback signal in step S2 is reverse microwave power. After microwave emission, not all of the microwaves are absorbed by the aerosol-generating article 20 and some of the unabsorbed microwaves are detected by the reverse microwave power, resulting in reverse microwave power. Correspondingly, the step S3, the selecting, by the microwave control circuit 114, the microwave transmitting frequency according to the feedback signal includes: the microwave control circuit 114 selects the microwave transmission frequency corresponding to the minimum value of the reverse microwave power.

In some embodiments, the microwave control method may cause an error in the manufacturing process of the aerosol generating device 10, which may cause the preset microwave transmitting frequency to be not the optimal microwave transmitting frequency, and thus the preset microwave transmitting frequency needs to be calibrated. Before step S1, the method further includes: s101, the microwave control circuit 114 receives a microwave frequency selection command, where the microwave frequency selection command may be generated by a physical key or a virtual key. Of course, this step may be done at the time of factory shipment or at the time of first use by the user.

In some embodiments, the microwave control method further comprises, before step S1, for the best heating effect, the step of: s102, the microwave control circuit 114 receives the aerosol-generating article complete installation instruction, i.e. generates an aerosol-generating article 20 complete installation instruction after the user newly installs or replaces the aerosol-generating article 20.

In some embodiments of the microwave control method, the location at which the aerosol-generating article 20 needs to be heated varies as the aerosol-generating article 20 is consumed, and prior to step S1, further comprising: and S103, the microwave control circuit 114 receives a pumping instruction, and the user generates a pumping instruction every time pumping.

In some embodiments of the microwave control method, the location at which the aerosol-generating article 20 needs to be heated varies as the aerosol-generating article 20 is consumed, and in order for the microwave energy to accurately heat the aerosol-generating article 20, prior to step S1, further comprising: s104, the microwave control circuit 114 presets pumping time at intervals.

The embodiments in the present description are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other. The device disclosed by the embodiment corresponds to the method disclosed by the embodiment, so that the description is simple, and the relevant points can be referred to the method part for description.

It is to be understood that the elements and algorithm steps of the various examples described in connection with the embodiments disclosed herein may be embodied in electronic hardware, computer software, or combinations of both, and that the components and steps of the various examples have been described in a functional generic manner in the foregoing description for clarity of hardware and software interchangeability. Whether such functionality is implemented as hardware or software depends upon the particular application and design constraints imposed on the implementation. Skilled artisans may implement the described functionality in varying ways for each particular application, but such implementation decisions should not be interpreted as causing a departure from the scope of the present invention.

Referring to fig. 9 together, the interior of the aerosolizing chamber 12 may, in some embodiments, comprise a region of high microwave field a and a region of low microwave field B, wherein the region of high microwave field a is distributed near the distal end of the holder 13, i.e. in the region of the aerosol-generating component 22 of the aerosol-generating article 20, and the region of low microwave field B is distributed at a position of the holder near the opening 120. This microwave field distribution causes more microwaves to microwave the aerosol-generating component 22 of the aerosol-generating article 20 near the end of the holder 13, to more fully utilize the microwaves, reduce energy consumption, and improve heating efficiency. The weak microwave field region B corresponds to the opening 120 of the fixing base 13, so that the microwave can be shielded conveniently, and the probability of microwave leakage through the opening of the fixing base 13 is reduced. In addition, the microwave shielding material of the aerosol-generating article 20 is preferably disposed adjacent to the opening 120 in a weak microwave field, which may prevent high temperature sparking of the shielding material in regions of strong microwave field, improving safety during smoking.

Referring to fig. 10, in some embodiments, the atomizing chamber 12 may include a microwave reflecting layer 121 on the inner side and a microwave shielding layer 122 on the outer side. The microwave reflecting layer 121 cooperates with the microwave transmitting antenna 113 to form the above-described strong microwave field region a and weak microwave field region B. Specifically, according to the size of the atomizing chamber 12 and the position layout of the microwave transmitting antenna 113, the predetermined area in the atomizing chamber 12 may be the strong microwave field area a, and the predetermined area may be the weak microwave field area B. The microwave shielding layer 122 is used to prevent microwave leakage and microwave pollution. The atomization chamber 12 may be cylindrical or other shapes in some embodiments.

The holder 13, which in some embodiments may be cylindrical, is suspended below the top wall of the atomization chamber 12 and communicates with an opening 120 in the top wall of the atomization chamber 12. The fixing base 13 may be made of a microwave-transparent material such as ceramic or high temperature-resistant plastic in some embodiments. The opening 120 is used for insertion of the aerosol-generating article 20 into the atomization chamber 12 and is secured by the holder 13.

In some embodiments, microwaves are generated by the microwave-generating circuit 112 and introduced into the nebulizing chamber 12 via the connector 1103 and the microwave-emitting antenna 113, forming a region a of intense microwave field above the microwave-emitting antenna 113, and the aerosol-generating article in the aerosol-generating article 20 located above the microwave-emitting antenna 113 is in the intense microwave field and vibrates intermolecularly under the action of the microwaves, generating a large amount of heat, thereby forming an aerosol. The heating regime of the aerosol-generating article 20 is changed from conventional heat-generating sheet heat conduction heating to microwave radiation heating, enabling a change in heating regime. The microwave heating has the advantages of heating from outside to inside, high heating speed, uniform heating and the like. The aerosol-generating article 20 is fixed by the side wall and the bottom of the fixing base 13 without inserting the aerosol-generating article 20 by other objects, so that after the aerosol-generating article 20 is sucked, the problem that the heat generating sheet is adhered to the aerosol-generating article 20 does not exist.

Figure 11 shows an aerosol-generating article 20 according to some embodiments of the present invention, which may comprise a cylindrical outer shell 21 and, arranged within the outer shell 21 in that order from bottom to top, a cylindrical aerosol-generating component 22, a cooling section 23 and a filter section 24. When the aerosol-generating article 20 is inserted into the holder 13, the aerosol-generating component 22 is in the region of strong microwave field a to produce an aerosol by microwave heating; the filter section 24 is at least partially exposed to the atomizing cavity 12 for the user to suck the aerosol through the mouth; the cooling section 23 is used for cooling the aerosol before flowing into the filter section 24, so as to prevent mouth burning.

The housing 21 may be made of a stiff paper tube, a polylactic acid material tube, a protein material tube, a plant gum material tube, a cellulose derivative material tube, or the like having a supporting function in some embodiments. The cooling section 23 may be made of a polylactic acid/aluminum foil composite film, a paper filter stick, a polylactic acid non-woven fabric, polylactic acid particles, a polylactic acid tow woven tube, a zigzag polylactic acid folded film, a cooling activated carbon composite material, or the like in some embodiments. The filter segment 24 may be made of polylactic acid tow or acetate tow, etc. in some embodiments.

In some embodiments, to prevent microwave leakage through the opening 120, the filter segment 24 may be made of a material having a shielding effect. Specifically, the composite material can be made of at least one of foam metal, conductive foam, carbon materials, polymer composite materials, mixed fabrics of metal conductive fibers and acetate fiber tows, and mixed fiber tows which take the metal conductive fibers as core materials and coat common fibers with outer layers. The filter segment 24 is capable of absorbing, reflecting small amounts of microwaves back into the aerosol-generating component 22, with an enhanced heating effect. The filter tip section with microwave shielding can prevent the high-temperature ignition phenomenon of the aerosol generating product 20 in a stronger microwave field area A, can also promote the enhancement effect of microwave reflection, can effectively shield microwaves and improve the safety during suction.

Figure 12 shows an aerosol-generating article 20a according to some embodiments of the present invention which may comprise a cylindrical outer shell 21 and, arranged within the outer shell 21 in that order from bottom to top, a cylindrical aerosol-generating component 22, a cooling section 23 and a filter section 24. The housing 21 may be made of at least one of a stiff paper tube, a polylactic acid material tube, a protein material tube, a vegetable gum material tube, or a cellulose derivative material tube having a supporting function in some embodiments. The cooling section 23 may be made of at least one material selected from a polylactic acid/aluminum foil composite film, a paper filter stick, a polylactic acid non-woven fabric, polylactic acid particles, a polylactic acid tow woven tube, a zigzag polylactic acid folded film, and a cooling activated carbon composite material in some embodiments. The filter segment 24 may be made of a material having a microwave shielding function in some embodiments, for example, at least one of foamed metal, conductive foam, carbon material, polymer composite material, mixed fabric of metal conductive fibers and acetate fiber tow, mixed fiber tow in which metal conductive fibers are used as a core material and common fibers are coated on an outer layer. The aerosol-generating article 20a may also comprise, in some embodiments, two microwave shielding layers 25, one disposed over the entire end face of each end of the filter segment 24. It will be appreciated that the shield 25 may also be provided at one of the ends of the filter segments 24. The shielding layer 25 may be made of a highly conductive and gas permeable material in some embodiments, such as at least one of a transparent electromagnetic shielding film, a metallized film, a microwave shielding glass, a single/multi-layered metal grid, a composite shielding substrate made of a transparent conductive film and glass, a foamed metal, a carbon material, a microwave shielding polymer composite, and the like. The shielding layer 25 together with the filter segment 24 having a microwave shielding function can prevent a high-temperature ignition phenomenon of the aerosol-generating article 20 in the stronger microwave field region a, and also can promote an enhancement effect of microwave reflection, so that microwaves can be effectively shielded, and safety during suction can be improved.

Figure 13 shows an aerosol-generating article 20b according to some embodiments of the utility model, which may comprise a cylindrical outer shell 21 and, arranged within the outer shell 21 in that order from bottom to top, a cylindrical aerosol-generating component 22, a cooling section 23 and a filter section 24. The housing 21 may be made of at least one of a stiff paper tube, a polylactic acid material tube, a protein material tube, a vegetable gum material tube, or a cellulose derivative material tube having a supporting function in some embodiments. The cooling section 23 may be made of at least one material selected from a polylactic acid/aluminum foil composite film, a paper filter stick, a polylactic acid non-woven fabric, polylactic acid particles, a polylactic acid tow woven tube, a zigzag polylactic acid folded film, and a cooling activated carbon composite material in some embodiments. The filter segment 24 may be made of a material having a microwave shielding function in some embodiments, for example, at least one of foamed metal, conductive foam, carbon material, polymer composite material, mixed fabric of metal conductive fibers and acetate fiber tow, mixed fiber tow in which metal conductive fibers are used as a core material and common fibers are coated on an outer layer. The aerosol-generating article 20b may also comprise a microwave shielding layer 25b in some embodiments, the microwave shielding layer 25b may be disposed between the cooling section 23 and the filter section 24 to prevent microwaves from being conducted to the filter section 24 via the cooling section 23, improving safety of use. The microwave shielding layer 25b may in some embodiments comprise a metal fiber layer comprising a resilient flange 251b protruding from the outer shell 21, the flange 251b being adapted to be snapped onto the edge of the opening 120 of the nebulizing chamber 12 to electrically connect with the shielding shell of the nebulizing chamber 12 to form a shielding of the whole device (see fig. 14).

Figure 15 shows an aerosol-generating article 20c according to some embodiments of the utility model, which may comprise a cylindrical outer shell 21 and, arranged within the outer shell 21 in that order from bottom to top, a cylindrical aerosol-generating component 22, a cooling section 23 and a filter section 24. The housing 21 may be made of at least one of a stiff paper tube, a polylactic acid material tube, a protein material tube, a vegetable gum material tube, or a cellulose derivative material tube having a supporting function in some embodiments. The cooling section 23 may be made of at least one material selected from a polylactic acid/aluminum foil composite film, a paper filter stick, a polylactic acid non-woven fabric, polylactic acid particles, a polylactic acid tow woven tube, a zigzag polylactic acid folded film, and a cooling activated carbon composite material in some embodiments. The filter segment 24 may be made of a material having a microwave shielding function in some embodiments, for example, at least one of foamed metal, conductive foam, carbon material, polymer composite material, mixed fabric of metal conductive fibers and acetate fiber tow, mixed fiber tow in which metal conductive fibers are used as a core material and common fibers are coated on an outer layer. The aerosol-generating article 20c may also comprise a microwave shielding layer 25b in some embodiments, which microwave shielding layer 25b may be disposed between the cooling section 23 and the filter section 24 to prevent microwaves from being conducted to the filter section 24 via the cooling section 23, improving safety of use. The microwave shielding layer 25b may in some embodiments comprise a resilient flange 251b protruding from the outer shell 21, the flange 251b being adapted to be snapped onto the edge of the opening 120 of the nebulizing chamber 12 to electrically connect with the shielding shell of the nebulizing chamber 12 to form a complete shielding (see fig. 14). The aerosol-generating article 20c may also include a microwave shielding layer 25c in some embodiments, the microwave shielding layer 25c being disposed on the upper end face of the filter segment 24 to further enhance the shielding effect.

Figure 16 shows an aerosol-generating article 20d according to some embodiments of the present invention, which may comprise a cylindrical outer shell 21 and, arranged within the outer shell 21 in that order from bottom to top, a cylindrical aerosol-generating component 22, a cooling section 23 and a filter section 24. The housing 21 may be made of at least one of a stiff paper tube, a polylactic acid material tube, a protein material tube, a vegetable gum material tube, or a cellulose derivative material tube having a supporting function in some embodiments. The cooling section 23 may be made of at least one material selected from a polylactic acid/aluminum foil composite film, a paper filter stick, a polylactic acid non-woven fabric, polylactic acid particles, a polylactic acid tow woven tube, a zigzag polylactic acid folded film, and a cooling activated carbon composite material in some embodiments. The filter segment 24 may be made of a material having a microwave shielding function in some embodiments, for example, at least one of foamed metal, conductive foam, carbon material, polymer composite material, mixed fabric of metal conductive fibers and acetate fiber tow, mixed fiber tow in which metal conductive fibers are used as a core material and common fibers are coated on an outer layer. The aerosol-generating article 20d may also comprise a microwave shielding layer 25b in some embodiments, which microwave shielding layer 25b may be disposed between the cooling section 23 and the filter section 24 to prevent microwaves from being conducted to the filter section 24 via the cooling section 23, improving safety of use. The microwave shield 25b may include a resilient flange 251b protruding from the housing 21 and a sleeve 252b in some embodiments. The flange 251b is adapted to overlap the edge of the opening 120 of the atomizing chamber 12 to electrically connect with the shielding shell of the atomizing chamber 12 to form a shielding of the whole device (as shown in fig. 14). The sleeve 252b is fitted over the sidewall of the cooling section 23.

Fig. 17 shows a schematic partial structure of an aerosol-generating device 10d according to some embodiments of the present invention, and as shown in the figure, the aerosol-generating device 10d includes a microwave generator 11d, an atomizing chamber 12d connected to the microwave generator 11d, and a holder 13d disposed in the atomizing chamber 12d for holding an aerosol-generating article 20. The microwave generator 11d includes a microwave transmitting antenna 113d for feeding microwaves into the atomizing chamber 12 d.

In some embodiments, the atomizing chamber 12d can be made of a highly conductive and transparent material, such as transparent microwave shielding glass (including wire mesh-sandwiched shielding glass, metal film-coated shielding glass, etched metal mesh shielding glass) and transparent non-glass material (such as acrylic material, PVC plastic, PCTG, crystal material, etc.) coated with microwave shielding film or single-layer/multi-layer metal grid. The preparation method can be vacuum coating such as interlayer process, laser/plasma etching process etching, magnetron sputtering or electron beam evaporation, or forming a metal film layer on the surface of the glass by adopting chemical vapor deposition, chemical thermal decomposition and sol-gel methods. The atomizing cavity 12d is made of transparent material, so that a user can directly observe the situation of aerosol during suction and the pollution degree in the atomizing cavity 12d, timely cleaning is facilitated, and the service life of the aerosol generating device 10d is prolonged. In addition, the transparent atomization cavity 12d has the characteristics of unique light transmission, color folding, elegant appearance and the like, can enable light rays to be changed and colorful, is rich in variety and strong in plasticity, and fully combines the practicability and the artistry perfectly. Moreover, the transparent microwave shielding glass has a light-transmitting observation window device with the function of attenuating the microwave radiation power, so that the microwave radiation is effectively shielded, the leakage is prevented, and the harm to a human body is reduced on the premise of ensuring higher visible light transmittance. And the shielding glass can isolate most ultraviolet light, and prevent devices in the cavity from aging due to the irradiation of sunlight and ultraviolet light.

In some embodiments, the microwave transmitting antenna 113d and the fixing base 13d can also be made of transparent materials. The fixing seat 13d can be made of glass, high temperature resistant transparent plastic, polyether ketone (PEK) or transparent non-glass material. The microwave transmitting antenna 113d may be a transparent conductive metal oxide film (including ITO, FTO, AZO, NTO, etc.), a AgHT series multilayer film system, a metal film system (mainly including aluminum, copper, silver, gold, etc. metal films) with a metal film thickness in a nanometer range, a metal mesh, or a transparent conductive ink sprayed by a printer, etc. When the microwave transmitting antenna 113d is manufactured, a transparent thin film layer may be formed on the surface of the transparent fixing base 13d near one end of the connector 1103d by vacuum coating such as spraying, radio frequency magnetron sputtering coating technology, laser/plasma etching process etching, electron beam evaporation, or by chemical vapor deposition, chemical thermal decomposition, or sol-gel method. The transparent microwave transmitting antenna 113d has the characteristics of optical transparency, high conductivity, high radiation efficiency and directional microwave transmission, has very small thickness, can realize better attractive and hidden characteristics, is convenient to realize the integral transparent structure of the atomizing cavity 12, and solves the defects that the microwave transmitting antenna 113d is heavy and shields the sight.

Some embodiments of the present invention also provide an aerosol-generating component 22, which aerosol-generating component 22 may be a smoking article, which is capable of rapidly generating an aerosol under microwave conditions. Specifically, the aerosol-generating member 22 is a tobacco product that does not burn when heated, and forms an aerosol by not burning when heated by a microwave of 915MHz to 30 GHz.

As shown in fig. 18, the aerosol-generating component 22 may, in some embodiments, include tobacco 221, an aerosol-forming agent 222, and functional particles 223, wherein the functional particles 223 are capable of absorbing microwaves and converting the absorbed microwaves into heat energy for transferring to the aerosol-forming agent 222 and the tobacco 223, while the functional particles may also reflect the microwaves so that other microwave-absorbing components of the aerosol-generating component 22 are heated by absorbing the microwaves to form an aerosol.

The functional particles 223 also have excellent surface infrared radiation properties in some embodiments, for example, the emissivity of the functional particles 223 is greater than 0.8, and preferably, the emissivity of the functional particles 223 is greater than 0.9. In order to realize the high surface infrared radiation performance of the functional particle 223, the high surface infrared radiation performance can be realized by adding an infrared radiation layer with higher radiance on the surface of the wave-absorbing inner core with lower radiance. For example, by forming a cordierite layer on the surface of silicon carbide, which is a wave-absorbing material having an emissivity of about 0.8, the emissivity of the functional particles 223 thus formed can be 0.95 or more. For the absorbing material zinc oxide with lower emissivity, a high emissivity layer is needed to be added for realization.

In some embodiments, this can also be achieved by selecting materials that have both good microwave absorption properties and high emissivity. For example, carbon powder, ferric oxide and other composite materials with high wave-absorbing performance and radiance are selected to realize the method.

The tobacco 221 includes base tobacco as an essential component in the aerosol-generating member 22. Optionally, the base tobacco is selected from at least one of cut tobacco and tobacco sheet. In an alternative specific example, the base tobacco is a blend of cut filler and tobacco sheet. Of course, the ratio of the cut tobacco and the tobacco sheet can be adjusted according to actual needs.

Optionally, the tobacco 221 in the aerosol-generating component 22 further comprises at least one of a flavorant and an inorganic filler. The flavor of the aerosol-generating member 22 can be enriched by adding a flavor to the tobacco 221. The inorganic filler added in the tobacco 221 has a certain supporting effect on the basic tobacco, so that the shaping is facilitated. Of course, the types and amounts of the perfume and the inorganic filler can be selected and adjusted according to actual requirements.

The aerosol former 222 is used to form an aerosol. Optionally, the aerosol former comprises propylene glycol. Of course, the aerosol-former 222 adheres to the tobacco to some extent. Further, the aerosol-forming agent 222 contains a substance having good microwave absorption performance. Substances with good microwave absorption can be quickly gasified by directly absorbing microwaves, so that smoke is generated, and heating without combustion is realized. Specifically, the substance having good microwave absorbing properties has a loss tangent of more than 0.1 to microwaves of a specific wavelength. Further, the mass percentage of the substance having good microwave absorbing performance in the aerosol-forming agent 222 is 1% to 50%.

In the aerosol-forming agent 222 containing a substance having a good microwave absorbability, smoke is generated mainly by boiling/evaporation of the substance having a good microwave absorbability, and the highest temperature is the boiling point of the substance having a good microwave absorbability, so that self-temperature control can be realized, and therefore, a temperature control member is not required. Of course, the ability of the aerosol-generating member 22 to absorb microwaves decreases as the amount of the substance having a good microwave absorbing ability decreases, and after the substance having a good microwave absorbing ability is completely released, the ability of the aerosol-generating member 22 to absorb microwaves decreases greatly, and the temperature rises due to the inability to continue to effectively absorb microwave energy, so that the adverse phenomenon such as scorching is less likely to occur. And a plurality of tests show that the smoking life of the aerosol generating component 22 has a threshold value, before the threshold value, the taste of the aerosol generating component 22 is good, the effective components are fully released, but after the threshold value is exceeded, the life of the whole aerosol generating component 22 is expired, the effective components are completely released, and the taste is poor. Therefore, the suction life of the aerosol-generating member 22 can be accurately controlled by the amount of the substance (for example, propylene glycol) having good microwave absorbing performance and the number of suction ports. Furthermore, the method is simple. The microwave heating has the characteristics of uniformity and temperature gradient from inside to outside, and the problem of insufficient tobacco heating like a central heating device does not exist.

Optionally, the aerosol-forming agent 222 comprises at least one of propylene glycol and glycerol. Further, the aerosol forming agent 222 contains propylene glycol, and the mass percentage of the propylene glycol is 1% to 50%. In an alternative specific example, the mass percentage of propylene glycol in the aerosol-former 222 is 2%, 5%, 10%, 15%, 20%, 35%, or 45%. Further, the mass percentage of the propylene glycol in the aerosol-forming agent 222 is 5% to 15%.

In some embodiments, the aerosol-former 222 also contains a nicotinic compound. The problem of poor taste of the aerosol-generating member 22 due to poor quality of the tobacco leaf can be solved by the addition of nicotine-based compounds. Of course, the problem of inconsistent taste of the aerosol-generating member 22 due to different batches of tobacco leaves can also be ameliorated by the addition of a nicotinic compound. Specifically, the nicotinic compound is at least one selected from nicotine and nicotine salt.

Further, the mass percentage of the nicotine compound in the aerosol-forming agent 222 is 0.1% to 33%. In an alternative specific example, the aerosol former has a nicotine compound content of 0.1%, 2%, 8%, 10%, 15%, 20%, 25% or 33% by mass. In some embodiments, the aerosol-former 222 may also contain non-tobacco flavoring agents. Optionally, the non-tobacco flavoring agent is selected from at least one of an alcohol flavoring agent (e.g., menthol) and an aldehyde flavoring agent (e.g., melonal). In other embodiments, the non-tobacco flavoring agent is not limited to the above, but may be other edible non-tobacco flavoring agents.

In some embodiments, the surface of the functional particles is rough. Roughening the surface of the functional particles 223 can prevent bumping, facilitating sufficient atomization of the tobacco 221 and the aerosol-forming agent 222. As shown in fig. 19, in an optional specific example, the functional particles 223 include a wave-absorbing material 2231 and an infrared radiation layer 2232 formed on an outer surface of the wave-absorbing material 2231. In some embodiments, the dielectric or hysteresis loss tangent of the absorbing material 2231 is greater than 0.1. The wave-absorbing material is selected from at least one of silicon carbide, zinc oxide, carbon powder, ferric oxide and ferroferric oxide. In some embodiments, the material of ir-emitting layer 2232 is selected from at least one of cordierite, perovskite-type (AB2O4, e.g., NiCr2O4, a is one or more of La, Sr, Ca, Mg, Bi, N, and B is one or more of Al, Ni, Fe, Co, Mn, Mo, Cr) materials.

In some embodiments, the functional particles are in the form of granules, the functional particles having a particle size of no more than 100 μm. Alternatively, the functional particles have a particle size of 2.5 μm, 10 μm, 15 μm, 20 μm, 30 μm, 40 μm, 50 μm, 60 μm, 70 μm, 80 μm, or 100 μm. Further, the functional particles have a particle diameter of 2.5 to 100. mu.m. Further, the functional particles have a particle diameter of 10 to 60 μm.

It is understood that in other embodiments, the shape of the functional particles 223 is not limited to the granular shape, and may be other shapes. E.g., filamentous, etc.

In some embodiments, the functional particles 223 have the ability to reflect, absorb microwaves, and release infrared radiation, and can function as follows: (1) so that more microwaves are received by the microwave absorbing substances (e.g., propylene glycol, glycerin, etc.) in the aerosol-generating component 22, thereby allowing more microwaves to be absorbed by the microwave absorbing substances; (2) the functional particles 223 absorb microwave energy to heat up, and the heat heats the nearby tobacco 221 and aerosol forming agent 222 through heat conduction; (3) after the temperature of the functional particles 223 rises, energy is transferred to the tobacco 221 and the aerosol-forming agent 222 by strong infrared radiation.

In some embodiments, the aerosol-generating component 22 is sheet-like, spherical, or ellipsoidal. Of course, in other embodiments, the shape of the aerosol-generating component 22 is not particularly limited, and other possible shapes are also possible.

In some embodiments, the aerosol-generating member 22 includes, by mass, 40 to 98 parts of tobacco, 1 to 55 parts of aerosol-forming agent, and 1 to 55 parts of functional particles.

In some embodiments, the aerosol-generating member 22 includes, by mass, 40 to 90 parts of tobacco, 5 to 55 parts of aerosol-forming agent, and 5 to 55 parts of functional particles.

In some embodiments, the aerosol-generating member 22 includes, by mass, 40 to 90 parts of tobacco, 5 to 55 parts of aerosol-forming agent, and 15 to 45 parts of functional particles.

In some embodiments, the aerosol-generating member 22 includes, by mass, 60 to 90 parts of tobacco, 10 to 55 parts of aerosol-forming agent, and 10 to 40 parts of functional particles.

In some embodiments, the aerosol-generating member 22 includes, by mass, 60 to 70 parts of tobacco, 10 to 25 parts of aerosol-forming agent, and 15 to 25 parts of functional particles.

The aerosol-generating component 22 described above has at least the following advantages:

(1) the aerosol-generating member 22 includes tobacco 221, an aerosol-forming agent 222, and functional particles 223, and the aerosol-generating member 22 can rapidly generate an aerosol by using microwaves of 915MHz to 30 GHz. Aerosol can be generated in a very short time (e.g., 1 second), the amount of aerosol mist generated in a certain time (e.g., 4 seconds) is much greater than the amount of aerosol mist generated in the same time as conventional heating of non-combustible aerosol-generating articles, and preheating may not be required, which is typically about 20 seconds; the use experience of the user can be greatly improved.

(2) The aerosol generation efficiency is high: the aerosol-forming agent 222 is a substance having a good microwave absorbing property (for example, propylene glycol) and can directly absorb microwaves to vaporize the microwaves to generate aerosol, and the aerosol generation efficiency is high.

(3) The utilization rate of the tobacco 221 is high: the problem of insufficient tobacco 221 is avoided and the utilization rate of the tobacco 221 is improved by the characteristics that the uniformity of microwave heating and the temperature gradient are from inside to outside.

(4) The later maintenance is simple: in use, as the aerosol generating member 22 generates aerosol using microwaves, a central heating device is not required, cleaning of the central heating device is naturally avoided, and post-maintenance is simple.

Some embodiments of the present invention also provide a method of making an aerosol-generating component 22 as described above, the method comprising the steps of:

after the tobacco 221, the aerosol-forming agent 222, and the functional particles 223 are mixed, the aerosol-generating member 22 is produced.

Specifically, the specific compositions and amounts of the tobacco 221, the aerosol-forming agent 222, and the functional particles 223 are as described above and will not be described herein. Further, in some embodiments, after mixing the tobacco 221, the aerosol-forming agent 222, and the functional particles 223, forming the mixture of the tobacco 221, the aerosol-forming agent 222, and the functional particles 223 is further included. Specifically, the molding process may employ a molding process commonly used in the art.

The aerosol generating member 22 is simple in production method and easy for industrial production.

Figure 20 shows an aerosol-generating device 10e according to some embodiments of the utility model, which may comprise a microwave generator 11, an atomising chamber 12 connected to the microwave generator 11 and a holder 13 for holding an aerosol-generating article 20 arranged within the atomising chamber 12. The top wall of the atomizing chamber 12 has an opening 120 communicating with the outside, and the microwave generator 11 is used for feeding microwaves into the atomizing chamber 12. The holder 13 is for the aerosol-generating article 20 to be removably secured therein, thereby allowing microwaves to microwave-heat the aerosol-generating article 20.

The microwave generator 11 may include a housing 111, a microwave generating circuit 112 disposed within the housing 111, and a microwave transmitting antenna 113e connected to the microwave generating circuit 112 in some embodiments. The microwave emitting antenna 113e may extend into the atomizing chamber 12 in some embodiments, and is spirally distributed on the outer wall surface of the fixing base 13, so as to form a strong microwave field region in the middle of the fixing base 13 during operation. The inner wall surface of the atomizing chamber 12 can also reflect the microwaves emitted from the microwave emitting antenna 113e toward the strong microwave field region to further strengthen the microwave field in the strong microwave field region.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the utility model. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (14)

1. An aerosol-generating article in the form of a column insertable into a microwave heating chamber with a shielded enclosure to generate an aerosol under microwave heating; characterised in that the aerosol-generating article comprises a microwave shielding structure which is in electrical connection with the shielding housing when the aerosol-generating article is inserted into the microwave heating chamber.

2. An aerosol-generating article according to claim 1, wherein the shielding structure comprises a microwave shielding layer disposed on a cross-section of the aerosol-generating article, the microwave shielding layer comprising a resilient electrically conductive flange projecting radially from the aerosol-generating article; the microwave shielding structure is electrically connected with the shielding shell through the elastic conductive flange.

3. An aerosol-generating article according to claim 2, wherein the microwave shielding layer is made of a metal fibre layer.

4. An aerosol-generating article according to claim 2, wherein the microwave shielding layer further comprises a sleeve projecting towards the insertion end of the aerosol-generating article.

5. An aerosol-generating article according to any of claims 1 to 4, comprising a cylindrical outer shell and, disposed within the outer shell, an aerosol-generating component and a filter segment.

6. An aerosol-generating article according to claim 5, wherein the filter segment is made of a material having microwave shielding effect.

7. An aerosol-generating article according to claim 6 in which the filter segment is made from at least one of a metal foam, a conductive foam, a carbon material, a polymer composite, a mixed fabric of metal conductive fibres and cellulose acetate tow, a mixed fibre tow with a core of metal conductive fibres and an outer layer of non-conductive fibres.

8. An aerosol-generating article according to claim 5, further comprising a cooling section disposed within the housing, the cooling section being located between the aerosol-generating component and the filter section.

9. An aerosol-generating article according to claim 1, comprising tobacco, aerosol former and functional particles, the functional particles being capable of absorbing microwaves; the functional particles can convert the absorbed microwaves into heat energy and then transfer the heat energy to the tobacco and the aerosol forming agent.

10. An aerosol-generating article according to claim 9, wherein the functional particles have an emissivity of greater than 0.9.

11. An aerosol-generating article according to claim 1, comprising a cylindrical housing and an aerosol-generating component and filter segment disposed within the housing; the aerosol-generating article further comprises a microwave shielding layer disposed at the filter segment proximate to and/or distal to an end face of the aerosol-generating component.

12. An aerosol-generating article according to claim 11, wherein the microwave shielding layer is made of a highly conductive and breathable material.

13. An aerosol-generating article according to claim 12, wherein the microwave shielding layer is made of a transparent electromagnetic shielding film, a metallized layer film, a microwave shielding glass, a single/multilayer metal grid, a composite shielding substrate made of a transparent conductive film and glass, a foamed metal, a carbon material, or a microwave shielding polymer composite.

14. An aerosol-generating system comprising an aerosol-generating article according to any of claims 1 to 13 and an aerosol-generating device for microwave heating of the aerosol-generating article, the aerosol-generating device comprising a microwave heating chamber into which the aerosol-generating article is removably inserted, the microwave heating chamber comprising a shielded enclosure, the shielded enclosure being in electrical communication with the microwave shielding structure.

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