KR102866402B1 - Atomizing assembly and aerosol generating device - Google Patents

Abstract

The present invention provides an atomizing assembly and an aerosol generating device. Here, the atomizing assembly comprises: a first housing having a first air passage installed therein; a second housing having a cavity-like structure with one end opened, and connected to the first housing by covering at least a portion of the exterior of the first housing through the opening, a second air passage formed between the first housing and the second housing, the second air passage communicating with the first air passage; and an aerosol generating assembly installed within the second housing and generating an aerosol. In the present invention, the first air passage and the second air passage are communicated with each other to ensure that air within the atomizing assembly flows during inhalation, and one end of the second housing is opened, and the aerosol generating assembly is installed within the second housing to ensure that the aerosol generating assembly receives heat evenly, and to prevent the phenomenon of contaminants generated after inhalation sticking to members within the aerosol generating device in which the atomizing assembly is installed, thereby facilitating cleaning of the aerosol generating device.

Description

Atomizing assembly and aerosol generating device

The present invention relates to the field of electronic atomization technology, and more particularly to atomization assembly and an aerosol generating device.

Heat-Not-Burning (HNB) devices are electronic devices that heat the aerosol-generating substrate (treated plant leaf product) but do not burn it. The heating device generates an aerosol by heating the aerosol-generating substrate to a high temperature, but not high enough to cause combustion. Assuming the substrate does not burn, the aerosol-generating substrate generates the desired aerosol.

Current commercially available heating and non-combustion devices primarily employ resistive heating. This means that the center of the aerosol-generating substrate is inserted into the aerosol-generating substrate and heated using a central heating sheet or heating probe. These devices have long preheating wait times, making them difficult to stop freely. Furthermore, the aerosol-generating substrate is not carbonized uniformly, preventing sufficient baking, resulting in low utilization. The heating sheet of the HNB device easily contaminates the aerosol-generating substrate extractor and heating sheet base, making cleaning difficult. Furthermore, some aerosol-generating substrates that come into contact with the heating element are excessively hot, decomposing and releasing substances harmful to the human body. Therefore, microwave heating technology is gradually replacing resistive heating as a new heating method. Microwave heating technology boasts high efficiency, instantaneity, selectivity, and no heating delay, allowing heating effects only on materials with specific dielectric properties. Microwave heating atomization offers the following advantages: a. microwave heating is radiant, non-conductive, and can be removed and stopped immediately; b. Since there is no heating sheet, there is no problem of leaving pieces behind or washing the heating sheet; c. The advantage is that the aerosol generating substrate is highly utilized and the taste is more consistent, while the taste is closer to that of a cigarette.

However, microwave heating atomization generally involves inserting a conductor column supplied with microwaves into an aerosol generating substrate, and after inhalation, the aerosol generating substrate is heated and burned at a high temperature, so the generated tobacco dust and the conductor column installed in the aerosol generating device easily stick together, making it difficult to clean.

The present invention aims to solve at least one of the technical problems existing in the prior art or related art.

In the first aspect of the present invention, a vapor assembly for this purpose is provided.

In a second aspect of the present invention, an aerosol generating device is provided.

In a first aspect of the present invention, an atomizing assembly is provided, comprising: a first housing having a first air passage installed therein; a second housing having a cavity-like structure with one end opened, and connected to the first housing while being installed to cover at least a portion of the outside of the first housing through the opening, a second air passage formed between the second housing and the first housing, the second air passage communicating with the first air passage; and an aerosol generating assembly installed within the second housing and generating an aerosol.

Accordingly, the atomizing assembly proposed in the present invention includes the first housing, the second housing, and the aerosol generating assembly. Here, the first air passage is installed through the inside of the first housing, the second housing has a cavity-type structure with one end opened, the second housing is installed to cover at least a portion of the outside of the first housing through the opening and is connected to the first housing, a second air passage is formed between the first housing and the second housing, and the second air passage and the first air passage are connected. As a result, a communicating intake air passage is formed inside the atomizing assembly, so that air inside the atomizing assembly can be guaranteed to flow when inhaled.

Furthermore, the second housing has a cavity-type structure with one end opened, and the aerosol generating assembly is installed within the second housing, and the second housing is installed over the first housing, so that the aerosol generating assembly is placed in a relatively strongly sealed environment, which further ensures that the aerosol generating assembly receives heat evenly, and can improve the utilization rate of the aerosol generating assembly. At the same time, the atomizing assembly proposed in the present invention does not need to install components such as a conductive pillar, a heating sheet, a heating probe, etc., and the above-mentioned components are inserted into the atomizing assembly, thereby avoiding the problem of cigarette shavings generated together with the aerosol generating assembly sticking to each other and making cleaning difficult. Furthermore, after the atomizing assembly is installed in the aerosol generating device, the bottom of the atomizing assembly is installed in a sealed manner, so that the aerosol generating device in which the atomizing assembly is installed cannot be contaminated.

Specifically, the first housing and the aerosol generating assembly are in close contact to ensure the stability of the internal structure of the atomizing assembly, while ensuring that air flows within the first air passage during inhalation and preventing air within the atomizing assembly from escaping.

Specifically, the first housing and the second housing are connected through a fitting groove to prevent the second housing from being detached.

Specifically, the first outer housing is one of a cardboard tube having a supporting function, a polylactic acid material tube, a Teflon (PTFE) tube, a synthetic resin tube, a protein material tube, a natural rubber material tube, or a cellulose derivative material tube.

Specifically, the first housing and the second housing are made of a low dielectric loss material having a constant strength and fixed shape. The first housing and the second housing can be manufactured from one of a cardboard tube, a polylactic acid material, Teflon, a synthetic resin, a chemical fiber product, a non-woven fabric, a ceramic sheet, a PEEK material, and glass.

Specifically, the length of the atomizing assembly is 30 mm to 70 mm, and preferably, 40 mm to 50 mm.

Therefore, in the atomizing assembly proposed in the present invention, the internally connected intake air passage is formed to ensure that the air inside the atomizing assembly flows when inhaled, and since the second housing has a cavity-type structure with one end open, the interior of the atomizing assembly becomes a relatively strongly sealed environment, ensuring that the aerosol generating assembly receives heat evenly, and improving the utilization rate of the aerosol generating assembly. In addition, the atomizing assembly proposed in the present invention does not require the installation of components such as the conductive pillar, the heating sheet, and the heating probe, and the above-described components are inserted into the atomizing assembly to adhere to the aerosol generating assembly, thereby avoiding the problem of difficulty in cleaning. Furthermore, after the atomizing assembly is installed in the aerosol generating device, the bottom of the atomizing assembly is installed in a sealed manner, so that the aerosol generating device in which the atomizing assembly is installed cannot be contaminated.

According to the above-described technical solution provided by the present invention, the following technical features can be further provided.

In the technical solution described above, the first housing includes a first body segment; a second body segment connected to an end of the first body segment and having an exterior covered by the second housing, a first gap provided at a distance from the second housing, and a second gap provided at a distance from the end of the second housing, wherein the first gap is used to form the second air passage, and the second gap is used to form an air inlet of the second air passage.

In this technical solution, the first housing includes the first body segment and the second body segment. Here, the second body segment and an end of the first body segment are connected, and the second housing is installed to cover the outside of the second body segment, such that the first gap is provided at a distance between the second housing and the second body segment, the second gap is provided at a distance between the second housing and an end of the second body segment, and the height of the second housing is lower than the end of the second body segment.

Furthermore, in this technical solution, the first gap between the second housing and the second body segment is used to form the second air passage, and the second gap between the second housing and the end of the second body segment is used to form an air inlet of the second air passage. During the inhalation process, air outside the atomizing assembly is introduced into the second air passage through the air inlet and enters the inside of the atomizing assembly, thereby ensuring that the air inside the atomizing assembly flows.

Specifically, the outer diameter of the first main body segment and the outer diameter of the second housing are the same or similar, and the outer diameter of the first main body segment is 6 mm to 20 mm, and preferably, 8 mm to 10 mm.

Specifically, the outer diameter of the second body segment is slightly smaller than the inner diameter of the second housing, the outer diameter of the second body segment is 4 mm to 18 mm, preferably 7 mm to 8.5 mm, and the inner diameter of the second housing is 7.5 mm to 19 mm, preferably 7.5 mm to 9 mm.

In any one of the above-described technical solutions, an accommodation space is formed between the second body segment and the second housing, the aerosol generating assembly is positioned within the accommodation space, and the atomizing assembly further includes a plurality of protrusions, which are spaced apart from the bottom wall of the second housing and positioned within the accommodation space, and the plurality of protrusions support the aerosol generating assembly, thereby allowing the second air passage and the first air passage to communicate.

In this technical solution, the receiving space is formed between the second body segment and the second housing, and the atomizing assembly further includes a plurality of protrusions. Here, the aerosol generating assembly and the plurality of protrusions are installed in the receiving space, and the plurality of protrusions are spaced apart from each other on the bottom wall of the second housing. In this way, the plurality of protrusions serve to support the aerosol generating assembly, and the plurality of protrusions are spaced apart from each other on the bottom wall of the second housing, so that a passage is formed between the second housing and the aerosol generating assembly to connect the second air passage and the first air passage, and a communicating suction passage is formed inside the atomizing assembly, thereby ensuring that air inside the atomizing assembly flows during inhalation and reducing resistance during inhalation.

In any one of the above-described technical solutions, the aerosol generating assembly comprises an aerosol generating substrate formed in a structure having a first through-hole; and a heating member installed within the first through-hole and capable of heating the aerosol generating substrate while absorbing microwaves.

In this technical solution, the aerosol generating assembly includes the aerosol generating substrate and the heating element. Here, the aerosol generating substrate has a structure including the first through-hole, and the heating element is installed within the first through-hole. When in use, the heating element absorbs microwaves and uses the microwaves to heat the aerosol generating substrate, thereby enabling the aerosol substrate to generate an aerosol.

Furthermore, in this technical solution, the heating element is installed in the first through-hole of the aerosol generating substrate, and in this way, when the aerosol generating substrate is heated using microwaves, the aerosol generating substrate located at the edge can be located within a relatively strong microwave field, so that the aerosol generating substrate at the edge can sufficiently receive heat, thereby ensuring that the entire aerosol generating substrate receives heat evenly, thereby enhancing the aerosol atomization effect of the aerosol generating substrate, and improving the utilization rate of the aerosol generating substrate.

Specifically, the aerosol generating substrate is manufactured using tobacco or herbs as raw materials, and the aerosol generating substrate includes forms such as particulate matter, flakes, powder pieces, filaments, pastes, thin pancakes, porous aerogels, or capsules.

Specifically, the diameter of the aerosol generating substrate is 4 mm to 17 mm, preferably 5 mm to 8 mm, and the height of the aerosol generating substrate is 6 mm to 25 mm, preferably 8 mm to 12 mm.

Specifically, the heating element is a relatively excellent heat-resistant microwave absorbing material, and has features such as good impedance matching, wide frequency range, thin matching thickness, light weight, and strong absorption capacity, which can enhance the aerosol atomization effect of the aerosol generating substrate.

Specifically, the heating element is made of one of ferrite, a ceramic matrix material, silicon carbide, barium titanate, and magnetic metal powder.

In any one of the above-described technical solutions, a predetermined distance is provided between one end near the opening of the aerosol generating substrate and the opening end of the second housing.

In this technical solution, a predetermined distance is provided between the end of the aerosol generating substrate and the opening end of the second housing to ensure the length of the second body segment, and when inhaled, air enters the second air passage from the air inlet at the opening end point of the second housing, passes through the aerosol generating substrate after passing the predetermined distance, and the aerosol flows into the first air passage, while preventing the aerosol from leaking out of the air inlet hole.

In any one of the above-described technical solutions, the first housing further includes a positioning member installed at one end of the second body segment far from the first body segment, the cross-sectional area of the positioning member being smaller than the cross-sectional area of the second body segment; the aerosol generating substrate is installed over the positioning member through the first through-hole, and the free end of the positioning member and the heating member are connected to each other.

In this technical solution, the first housing further includes a position fixing member. Here, the position fixing member is installed at one end of the second body segment far from the first body segment, a cross-sectional area of the position fixing member is smaller than a cross-sectional area of the second body segment, the aerosol generating substrate is installed over the position fixing member through the first through hole, and a free end of the position fixing member and the heating member are connected to each other. In this way, a step structure is formed between the first body segment, the second body segment, and the position fixing member, and the aerosol generating substrate is installed over the position fixing member, so that the second body segment, the position fixing member, and the aerosol generating substrate can be connected in an orderly and close manner.

In any one of the above-described technical solutions, the first air passage penetrates the first body segment, the second body segment, the position fixing member, and the heating member.

In this technical solution, the first air passage penetrates the first body segment, the second body segment, the position fixing member, and the heating member, and when inhaled, air enters the second air passage from the air inlet, passes through the passage between the plurality of protrusions, and then directly enters the first air passage, thereby ensuring that the air flows smoothly.

In any one of the above-described technical solutions, a plurality of second through holes are installed in the heating member, and the plurality of second through holes and the first air passage are connected to each other.

In this technical solution, the heating element is provided with a plurality of second through holes, and the plurality of second through holes are connected to the first air passage. In this manner, when inhaled, the aerosol generated from the aerosol generating substrate can directly enter the first air passage through the second through holes, thereby enhancing the aerosol atomization effect of the aerosol generating substrate.

In any one of the above-described technical solutions, the atomizing assembly further comprises an identification device installed within the heating element, wherein the identification device feeds back an identification signal detected by the frequency generating device.

In this technical solution, the atomizing assembly further includes the identification device. The identification device is installed within the heating element and feeds back an identification signal detected by the frequency generator. This enhances the consistency between the atomizing assembly and the microwave assembly when identifying each other, provides anti-counterfeiting capabilities, and is difficult to read and recycle, thereby protecting market order and the legitimate rights and interests of consumers.

Specifically, the identification device feeds back an identification signal toward the frequency generator of the microwave assembly, and after the frequency generator receives the identification signal, it verifies and matches it, and if the identification signal verification is successful, the microwave assembly activates the heating function of the atomizing assembly; and if the identification signal verification fails, the microwave assembly does not activate the heating function of the atomizing assembly. Through this, the consistency when the atomizing assembly and the microwave assembly identify each other can be strengthened, thereby achieving the purpose of automatically identifying a counterfeit of the atomizing assembly.

Specifically, the exterior of the identification device may be wrapped with a heat-resistant insulating material to protect the identification device. Here, the insulating material is one of insulating cotton, urethane foam, and polyamide.

An aerosol generating device provided in a second aspect of the present invention comprises an atomizing assembly in any one of the above-described technical solutions; and a microwave assembly for supplying microwaves into the atomizing assembly.

The aerosol generating device proposed in the present invention comprises the atomizing assembly of any of the aforementioned technical solutions. Therefore, the atomizing assembly described above possesses overall beneficial effects, which will not be described in detail herein.

In addition, the aerosol generating device further includes the microwave assembly. The microwave assembly supplies microwaves into the atomizing assembly to heat the aerosol generating substrate, thereby generating an aerosol.

Specifically, the atomizing assembly is disposable, detachably installed in the aerosol generating device, and is disposed of immediately after inhalation, so there is no need for cleaning, and it is easy to replace, ensuring convenience in use.

Specifically, the microwave heating frequency band is 300 MHz to 300 GHz, and preferably 915 MHz and 2450 MHz.

According to the aerosol generating device of the above-described technical solution provided in the present invention, the following additional technical features can be further provided.

The aerosol generating device further includes a frequency generating device capable of verifying the atomizing assembly by receiving an identification signal fed back by the identification device; and a storage device electrically connected to the microwave assembly and the frequency generating device, the storage device being used to supply power to the microwave assembly and the frequency generating device.

In this technical solution, the aerosol generating device further includes the frequency generating device and the power storage device. Here, the power storage device is electrically connected to the microwave assembly and the frequency generating device, and is used to supply power to the microwave assembly and the frequency generating device. The frequency generating device can receive an identification signal fed back by the identification device and verify the atomizing assembly.

Specifically, the frequency generator receives the identification signal fed back by the identification device, verifies and matches it, and if the identification signal verification is successful, the microwave assembly supplies microwaves to the atomizing assembly to heat the aerosol generating substrate, and if the identification signal verification fails, the microwave assembly cannot supply microwaves to the atomizing assembly. Through this, the consistency when the atomizing assembly and the microwave assembly identify each other can be strengthened, thereby achieving the purpose of automatically identifying counterfeit products of the atomizing assembly, which is advantageous for protecting market order and the legitimate rights and interests of consumers.

The additional aspects and advantages of the present invention are clearly revealed through the parts described below or can be understood by practicing the present invention.

The above-described and/or additional aspects and advantages of the present invention can be clearly and easily understood from the description of the embodiments combined with the drawings below, wherein:
Figure 1 is a structural schematic diagram showing a vapor assembly in one embodiment of the present invention.
FIG. 2 is a cross-sectional view showing the atomization assembly in the embodiment illustrated in FIG. 1.
FIG. 3 is a cross-sectional view showing a first housing of a vapor assembly in one embodiment of the present invention.
FIG. 4 is a structural schematic diagram showing a second housing of a vapor assembly in one embodiment of the present invention.
FIG. 5 is a structural schematic diagram showing an aerosol generating substrate of a vapor assembly in one embodiment of the present invention.
FIG. 6 is a structural schematic diagram showing a heating member of a vapor assembly in one embodiment of the present invention.

The following describes the present invention in detail, combining drawings and specific examples, to more clearly understand the aforementioned purposes, features, and advantages of the present invention. It should be noted that the embodiments and features described below may be combined, provided there is no conflict in content.

Although the following description sets forth various specific details to sufficiently understand the present invention, the present invention may be practiced in a manner different from that described herein, and therefore the scope of protection of the present invention is not limited to the specific embodiments disclosed below.

Below, with reference to the contents of FIGS. 1 to 6, a description is given of an atomizing assembly and an aerosol generating device provided in some embodiments of the present invention.

As illustrated in FIGS. 1 and 2, the atomizing assembly presented in the first embodiment of the present invention includes a first housing (102), a second housing (106), and an aerosol generating assembly (108).

In this embodiment, as illustrated in FIG. 2, a first air passage (104) is installed through the interior of the first housing (102), the second housing (106) has a cavity-type structure with one end opened, and the second housing (106) is connected to the first housing (102) by being installed to cover at least a portion of the exterior of the first housing (102) through the opening, and a second air passage (126) is formed between the first housing (102) and the second housing (106), and the second air passage (126) and the first air passage (104) are connected. As a result, a connected intake air passage is formed inside the atomizing assembly, so that air inside the atomizing assembly can be ensured to flow when inhaled.

In this embodiment, furthermore, as illustrated in FIGS. 2 and 4, the second housing (106) has a cavity-type structure with one end opened, the aerosol generating assembly (108) is installed within the second housing (106), and the second housing (106) is installed to cover the first housing (102), so that the aerosol generating assembly (108) is placed in a relatively strongly sealed environment. Through this, it is possible to ensure that the aerosol generating assembly (108) receives heat evenly, and to improve the utilization rate of the aerosol generating assembly (108). In addition, the atomizing assembly presented in the present invention does not require the installation of components such as a conductor pillar, a heating sheet, and a heating probe, and by inserting the above-described components into the atomizing assembly, the problem of sticking to the aerosol generating assembly (108) and making it difficult to clean can be avoided, and further, after the atomizing assembly is installed in the aerosol generating device, the bottom of the atomizing assembly is installed in a sealed manner, so that the aerosol generating device in which the atomizing assembly is installed cannot be contaminated, and the service life of the aerosol generating device can be extended.

In a specific embodiment, the first housing (102) and the aerosol generating assembly (108) are in close contact to ensure the stability of the internal structure of the atomizing assembly, while ensuring that air flows within the first air passage (104) during inhalation and preventing the air within the atomizing assembly from escaping.

In a specific embodiment, the first housing and the second housing may be connected through a fitting groove to prevent the second housing from being detached.

In a specific embodiment, the first outer housing is one of a cardboard tube having a supporting function, a polylactic acid material tube, a Teflon (PTFE) tube, a synthetic resin tube, a protein material tube, a natural rubber material tube, or a cellulose derivative material tube.

In a specific embodiment, the first housing (102) and the second housing (106) are made of a low dielectric loss material having a constant strength and a fixed shape. Specifically, the first housing (102) and the second housing (106) can be manufactured from one of a cardboard tube, a polylactic acid material, Teflon, a synthetic resin, a chemical fiber product, a non-woven fabric, a ceramic sheet, a PEEK material, and glass.

In a specific embodiment, the length of the atomizing assembly is 30 mm to 70 mm, and preferably 40 mm to 50 mm. Specifically, the length of the atomizing assembly may be 40 mm, 45 mm, 50 mm, etc., and is not specifically limited herein.

Therefore, in the atomizing assembly proposed in the present invention, a communicating intake air passage is formed inside thereof, thereby ensuring that the air inside the atomizing assembly flows during inhalation. In addition, since the second housing (106) has a cavity-type structure with one end open, the inside of the atomizing assembly becomes a relatively strongly sealed environment, thereby further ensuring that the aerosol generating assembly (108) receives heat evenly, and thereby improving the usability of the aerosol generating assembly (108). In addition, the atomizing assembly proposed in the present invention does not require the installation of components such as a conductive pillar, a heating sheet, or a heating probe, and by inserting the above-described components into the atomizing assembly, the problem of tobacco shavings generated together with the aerosol generating assembly (108) sticking to each other and making cleaning difficult can be avoided. Furthermore, after the atomizing assembly is installed in the aerosol generating device, the bottom of the atomizing assembly is installed in a sealed manner, so that the aerosol generating device in which the atomizing assembly is installed cannot be contaminated, and the service life of the aerosol generating device can be extended.

In the second embodiment of the present invention, a non-woven assembly is presented, and based on the first embodiment, further,

As shown in FIGS. 1 and 2, the first housing (102) includes a first body segment (110) and a second body segment (112).

In this embodiment, as shown in FIGS. 2 and 3, the ends of the second body segment (112) and the first body segment (110) are connected, and the second housing (106) is installed to cover the outside of the second body segment (112), so that a first gap is provided at a distance between the second housing (106) and the second body segment (112), a second gap is provided at a distance between the second housing (106) and the end of the second body segment (112), and the height of the second housing (106) is lower than the end of the second body segment (112).

In this embodiment, furthermore, as shown in FIGS. 1 and 2, a first gap between the second housing (106) and the second body segment (112) is used to form a second air passage (126), and a second gap between the end of the second housing (106) and the second body segment (112) is used to form an air inlet (124) of the second air passage (126). During the inhalation process, air outside the atomizing assembly is introduced into the second air passage (126) through the air inlet (124) and enters the inside of the atomizing assembly, thereby ensuring that the air inside the atomizing assembly flows.

In a specific embodiment, the outer diameter of the first body segment (110) and the outer diameter of the second housing (106) are the same or similar, and the outer diameter of the first body segment (110) is 6 mm to 20 mm, and preferably, 8 mm to 10 mm. Specifically, the outer diameter of the first body segment (110) may be 8 mm, 9 mm, 10 mm, etc., and is not specifically limited herein.

In a specific embodiment, the outer diameter of the second body segment (112) is slightly smaller than the inner diameter of the second housing (106), the outer diameter of the second body segment (112) is 4 mm to 18 mm, preferably 7 mm to 8.5 mm, and the inner diameter of the second housing (106) is 7.5 mm to 19 mm, preferably 7.5 mm to 9 mm. Specifically, the outer diameter of the second body segment (112) may be 7 mm, 7.5 mm, 8 mm, 8.5 mm, etc., and the inner diameter of the second housing (106) may be 7.5 mm, 8 mm, 8.5 mm, 9 mm, etc., and the like, without being specifically limited herein.

In addition, the atomizing assembly presented in this embodiment has the overall beneficial effects of the atomizing assembly of Embodiment 1, and a ventilation passage is installed inside the atomizing assembly to allow air to circulate smoothly, and the inside of the atomizing assembly is a relatively strongly sealed environment, which ensures that the aerosol generating assembly (108) receives heat evenly, and can improve the utilization rate of the aerosol generating assembly (108), and the atomizing assembly does not need to install components such as a conductive pillar, a heating sheet, and a heating probe, and by inserting the above-mentioned components into the atomizing assembly, the problem of tobacco dust generated together with the aerosol generating assembly (108) sticking to each other and being difficult to clean can be avoided, and further, the aerosol generating device in which the atomizing assembly is installed can be prevented from being contaminated, and the service life of the aerosol generating device can be extended, which is not described in detail herein any further.

In the third embodiment of the present invention, a non-woven assembly is presented, and based on Embodiment 2, further,

As illustrated in FIG. 2, a receiving space is formed between the second body segment (112) and the second housing (106), and the atomizing assembly further includes a plurality of protrusions (128).

In this embodiment, as illustrated in FIG. 2, an aerosol generating assembly (108) and a plurality of protrusions (128) are installed within a receiving space, and the plurality of protrusions (128) are spaced apart from each other on the bottom wall of the second housing (106). In this way, the plurality of protrusions (128) serve as a support for the aerosol generating assembly (108), and the plurality of protrusions (128) are spaced apart from each other on the bottom wall of the second housing (106), so that a passage is formed between the second housing (106) and the aerosol generating assembly (108), connecting the second air passage (126) and the first air passage (104), and a communicating suction passage is formed inside the atomizing assembly, thereby ensuring that air inside the atomizing assembly flows during inhalation and reducing resistance during inhalation.

In addition, the atomizing assembly presented in this embodiment has the overall beneficial effects of the atomizing assembly of Example 2, which are not described in detail herein.

In the fourth embodiment of the present invention, a non-woven assembly is proposed, and based on Embodiments 1 to 3, further,

As illustrated in FIG. 2, the aerosol generating assembly (108) includes an aerosol generating substrate (114) and a heating element (118).

In this embodiment, as illustrated in FIGS. 2 and 5, the aerosol generating substrate (114) has a structure including a first through-hole (116), and a heating member (118) is installed within the first through-hole (116). When in use, the heating member (118) absorbs microwaves and uses the microwaves to heat the aerosol generating substrate (114), thereby allowing the aerosol substrate to generate aerosol.

Furthermore, in this embodiment, as shown in FIG. 2, a heating member (118) is installed in the first through-hole (116) of the aerosol generating substrate (114), and in this way, when the aerosol generating substrate (114) is heated using microwaves, the aerosol generating substrate (114) positioned at the edge can be positioned within a relatively strong microwave field, so that the aerosol generating substrate (114) at the edge can sufficiently receive heat, thereby ensuring that the entire aerosol generating substrate (114) receives heat evenly, thereby enhancing the aerosol atomization effect of the aerosol generating substrate (114), and improving the utilization rate of the aerosol generating substrate (114).

In a specific embodiment, the aerosol generating substrate (114) is manufactured using tobacco or herbal as a raw material, and the aerosol generating substrate (114) includes a form such as a particulate material, flakes, powder pieces, filaments, paste, thin pancakes, porous aerogels, or capsules.

In a specific embodiment, the outer diameter of the aerosol generating substrate (114) is 4 mm to 17 mm, preferably 5 mm to 8 mm, and the height of the aerosol generating substrate (114) is 6 mm to 25 mm, preferably 8 mm to 12 mm. Specifically, the diameter of the aerosol generating substrate (114) may be 5 mm, 6 mm, 7 mm, 8 mm, etc., and the height of the aerosol generating substrate (114) may be 8 mm, 9 mm, 10 mm, 11 mm, 12 mm, etc., and are not specifically described herein.

In a specific embodiment, the heating element (118) is a relatively excellent heat-resistant microwave absorbing material, and has features such as good impedance matching, wide frequency range, thin matching thickness, light weight, and strong absorption capacity, which can enhance the aerosol atomization effect of the aerosol generating substrate (114).

In a specific embodiment, the heating element (118) is made of one of ferrite, a ceramic matrix material, silicon carbide, barium titanate, and a magnetic metal powder.

In addition, the atomizing assembly presented in this embodiment has the overall beneficial effects of the atomizing assembly, such as the atomizing assemblies of Examples 1 to 3, which are not described in detail herein.

In the fifth embodiment of the present invention, a non-woven assembly is proposed, and based on embodiment 4, further,

As shown in FIG. 2, a predetermined distance is provided between one end close to the opening of the aerosol generating substrate (114) and the opening end of the second housing (106).

In this embodiment, as shown in FIG. 2, a predetermined distance is provided between the end of the aerosol generating substrate (114) and the opening end of the second housing (106), so as to ensure the length of the second body segment (112), and when inhaled, air enters the second air passage (126) from the air inlet (124) at the opening end point of the second housing (106), passes through the aerosol generating substrate (114) after passing the predetermined distance, so that the aerosol flows into the first air passage (104), while preventing the aerosol from leaking out of the air inlet (124).

In addition, the atomizing assembly presented in this embodiment has the overall beneficial effects of the atomizing assembly of Example 4, which are not described in detail herein.

In the sixth embodiment of the present invention, a non-woven assembly is presented, and based on embodiment 4, further,

As illustrated in FIGS. 2 and 3, the first housing (102) further includes a position fixing member (120).

In this embodiment, as illustrated in FIGS. 2 and 3, a position fixing member (120) is installed at an end of a second body segment (112), a cross-sectional area of the position fixing member (120) is smaller than a cross-sectional area of the second body segment (112), an aerosol generating substrate (114) is installed to cover the position fixing member (120) through a first through hole (116), and a free end of the position fixing member (120) and a heating member (118) are connected to each other. In this way, a step structure is formed between the first body segment (110), the second body segment (112), and the position fixing member (120), and the aerosol generating substrate (114) is installed to cover the position fixing member (120), so that the second body segment (112), the position fixing member (120), and the aerosol generating substrate (114) can be connected in an orderly and close manner.

Furthermore, in this embodiment, as shown in FIGS. 2 and 3, the first air passage (104) penetrates the first body segment (110), the second body segment (112), the position fixing member (120), and the heating member (118), and when inhaled, air enters the second air passage (126) from the air inlet (124), passes through the passage between the plurality of protrusions (128), and then directly enters the first air passage (104), thereby ensuring that the air flows smoothly.

In addition, the atomizing assembly presented in this embodiment has the overall beneficial effects of the atomizing assembly of Example 4, which are not described in detail herein.

In the seventh embodiment of the present invention, a non-woven assembly is presented, and based on embodiment 4, further,

As shown in Fig. 6, a plurality of second through holes (122) are installed in the heating member (118), and the plurality of second through holes (122) and the first air passage (104) are connected.

In this embodiment, as illustrated in FIG. 6, a plurality of second through holes (122) are installed in the heating element (118), and the second through holes (122) and the first air passage (104) are connected to each other. In this manner, when inhaled, the aerosol generated in the aerosol generating substrate (114) can directly enter the first air passage (104) through the second through holes (122), thereby enhancing the aerosol atomization effect of the aerosol generating substrate (114).

In addition, the atomizing assembly presented in this embodiment has the overall beneficial effects of the atomizing assembly of Example 4, which are not described in detail herein.

In the eighth embodiment of the present invention, a non-woven assembly is presented, and based on embodiment 4, further,

The atomization assembly further includes an identification device (not shown).

In this embodiment, the identification device is installed inside the heating element (118), and the identification device feeds back the identification signal detected by the frequency generator. This enhances the consistency between the atomization assembly and the microwave assembly when identifying each other, provides anti-counterfeiting capabilities, and is difficult to read and recycle, thus protecting market order and the legitimate rights and interests of consumers.

In a specific embodiment, the identification device sends an identification signal to the frequency generator of the microwave assembly, and after the frequency generator receives the identification signal, it verifies and matches it, and if the identification signal verification is successful, the microwave assembly activates the heating function of the atomizing assembly; and if the identification signal verification fails, the microwave does not activate the heating function of the atomizing assembly. In this way, the consistency between the atomizing assembly and the microwave assembly when identifying each other can be strengthened, so as to achieve the purpose of automatically identifying counterfeit atomizing assemblies. In a specific embodiment, the exterior of the identification device can be wrapped with a heat-resistant insulating material to protect the identification device. Here, the insulating material is one of insulating cotton, urethane foam, and polyamide.

In addition, the atomizing assembly presented in this embodiment has the overall beneficial effects of the atomizing assembly of Example 4, which are not described in detail herein.

An aerosol generating device according to a ninth embodiment of the present invention comprises an atomizing assembly, a microwave assembly, a frequency generating device, and a storage device of any one of the above-described embodiments.

The aerosol generating device proposed in the present invention comprises an atomizing assembly according to one of the embodiments described above. Therefore, the atomizing assembly described above offers overall beneficial effects, which will not be described in detail herein.

Furthermore, in this embodiment, the aerosol generating device further includes a microwave assembly, a frequency generator, and a storage device. The microwave assembly supplies microwaves into the atomizing assembly to heat the aerosol generating substrate (114) to generate an aerosol. The storage device is electrically connected to the microwave assembly and the frequency generator, and is used to supply power to the microwave assembly and the frequency generator. The frequency generator receives an identification signal fed back by the identification device, and can verify and match the atomizing assembly to realize an anti-counterfeiting effect.

In a specific embodiment, the frequency generator receives the identification signal fed back by the identification device, verifies and matches it, and if the identification signal verification is successful, the microwave assembly supplies microwaves to the atomizing assembly to heat the aerosol generating substrate (114); and if the identification signal verification fails, the microwave assembly cannot supply microwaves to the atomizing assembly. This enhances the consistency between the atomizing assembly and the microwave assembly when they identify each other, thereby achieving the purpose of automatically identifying counterfeit atomizing assemblies, which is advantageous for protecting market order and the legitimate rights and interests of consumers.

In a specific embodiment, the microwave heating frequency band is 300 MHz to 300 GHz, preferably 915 MHz and 2450 MHz.

In a specific embodiment, the atomizing assembly is disposable, detachably installed in the aerosol generating device, and disposed of immediately after inhalation, eliminating the need for cleaning, and is easy to replace, ensuring convenience in use.

Therefore, the aerosol generating device proposed in the present invention can uniformly heat the aerosol generating substrate (114) and automatically identify counterfeit products of the atomized assembly, which is advantageous in protecting market order and the legitimate rights and interests of consumers.

In the description of the present invention, the technical term "plurality" means two or more, and unless otherwise clearly defined, the indicating direction or positional relationship such as "upper", "lower", etc. is based on the direction or positional relationship shown in the drawings, and is only for the purpose of conveniently and briefly explaining the contents of the present invention, and does not necessarily indicate or imply that all devices or elements indicated are configured and operated in a specific direction or a specific direction, and therefore should not be understood as limited to the present invention; the technical terms "connection," "mounting," "fixing," etc. should be understood in a broad sense. For example, "connection" can be a fixed connection, a detachable connection, or an integral connection; it can also be a direct connection, an indirect connection through an intermediate medium. A person skilled in the art should understand the specific meaning of the technical terms used in the contents of the present invention based on the specific situation.

References to "one embodiment," "some embodiments," "specific embodiments," and the like in this specification indicate that specific features, structures, materials, or characteristics of the embodiments or exemplary descriptions are included in at least one embodiment or example of the present invention. The schematic descriptions of the technical terms used herein may not refer to the same embodiment or example. Furthermore, the specific features, structures, materials, or characteristics described herein may be combined in a suitable manner in one or more embodiments or examples.

The above description merely outlines preferred embodiments of the present invention and does not limit the scope of the invention. Those skilled in the art will appreciate various modifications and variations to the present invention. Modifications, equivalent substitutions, improvements, etc., within the spirit and principles of the present invention, should be included within the scope of protection.

102: 1st Housing
104: Air passage 1
106: Second Housing
108: Aerosol generating assembly
110: First body segment
112: Second body segment
114: Aerosol generating substrate
116: First through hole
118: Heating element
120: Position fixation absence
122: Second through hole
124: Air inlet
126: Second air passage
128: Protrusion

Claims (11)

In the assembly of the machine,
A first housing having a first air passage installed therein;
A second housing having an open cavity-type structure formed, and connected to the first housing by being installed over the outside of at least a portion of the first housing through the opening, and a second air passage formed between the first housing and the second air passage, and the second air passage and the first air passage communicating with each other; and
An aerosol generating assembly installed within the second housing and generating an aerosol,
The above aerosol generating assembly,
An aerosol generating substrate formed with a structure having a first through hole; and
An atomizing assembly characterized by comprising a heating member installed in the first through-hole and capable of heating the aerosol generating substrate while absorbing microwaves. In the first paragraph,
The first housing comprises a first body segment;
A second body segment is connected to an end of the first body segment, the outside of which is covered by the second housing, and a first gap is provided at a distance from the second housing, and a second gap is provided at a distance from the end of the second housing;
An atomizing assembly characterized in that the first gap is used to form the second air passage, and the second gap is used to form an air inlet of the second air passage. In the second paragraph,
An accommodation space is formed between the second body segment and the second housing, and the aerosol generating assembly is positioned within the accommodation space;
The above-mentioned atomized assembly,
An atomizing assembly characterized in that it further includes a plurality of protrusions, is spaced apart from each other on the bottom wall of the second housing, is positioned within the receiving space, and the plurality of protrusions support the aerosol generating assembly, thereby allowing the second air passage and the first air passage to communicate. delete In the first paragraph,
An atomizing assembly characterized in that a predetermined distance is provided between one end near the opening of the aerosol generating substrate and the opening end of the second housing. In the second paragraph,
The first housing further includes a position fixing member, the position fixing member being installed at one end of the second body segment far from the first body segment, and the cross-sectional area of the position fixing member being smaller than the cross-sectional area of the second body segment;
An atomizing assembly characterized in that the aerosol generating substrate is installed over the position fixing member through the first through hole, and the free end of the position fixing member and the heating member are connected to each other. In paragraph 6,
An atomizing assembly characterized in that the first air passage penetrates the first body segment, the second body segment, the position fixing member, and the heating member. In the first paragraph,
An atomizing assembly characterized in that a plurality of second through holes are installed in the heating member, and the plurality of second through holes and the first air passage are connected to each other. In the first paragraph,
The atomizing assembly further comprises an identification device, wherein the identification device is installed inside the heating member, and the identification device feeds back an identification signal detected by the frequency generating device. In an aerosol generating device,
A vapor assembly according to any one of claims 1 to 3 and claims 5 to 9;
An aerosol generating device comprising a microwave assembly for supplying microwaves into the atomizing assembly. In Article 10,
The above-mentioned atomizing assembly further comprises an identification device, wherein the identification device is installed inside the heating element, and the identification device feeds back an identification signal detected by the frequency generating device.
The above aerosol generating device,
A frequency generator capable of verifying the atomized assembly by receiving an identification signal fed back by the identification device; and
An aerosol generating device, characterized in that it further comprises a storage device electrically connected to the microwave assembly and the frequency generating device and used to supply power to the microwave assembly and the frequency generating device.