CN217446672U - Atomization structure, atomizer and aerosol generating device - Google Patents

Abstract

The application relates to atomizing structure, atomizer and aerosol generate device, atomizing core subassembly is including the atomizing part, linkage segment and the guide portion that the order contact set up, and the heat-generating body is at least partly inlayed and is located the inside of atomizing part, and guide portion and the contact of atomizing medium, and the order is through guide portion and linkage segment, will atomize the inside that the medium transmitted the atomizing part. The heating body indirectly contacts the atomized medium in the liquid storage cavity through the guide part, so that a longer distance exists between the heating body and the atomized medium in the liquid storage cavity, the heat transfer is effectively isolated, the atomized medium in the liquid storage cavity can be prevented from deteriorating due to high temperature, and the heating efficiency of the whole atomization structural part is high due to heat concentration; lead the oil area big and all-round oil of leading, can effectively ensure the fuel feeding abundant, the atomizing part contains intraductal and a plurality of atomizing regions outside the pipe simultaneously, and the atomizing volume is big, has solved traditional atomizing atomization effect not good, and the smog volume is not enough problem.

Description

Atomization structure, atomizer and aerosol generating device

Technical Field

The present application relates to the field of atomization technology, and in particular, to an atomization structure, an atomizer, and an aerosol-generating device.

Background

The electronic atomization device in the prior art mainly comprises an atomizer and a power supply. The atomizer generally comprises a liquid storage cavity and an atomizing structural part, wherein the liquid storage cavity is used for storing an atomizable medium, and the atomizing structural part is used for heating and atomizing the atomizable medium to form aerosol which can be eaten by a smoker; the power supply is used to provide energy to the atomizing structure.

In the prior art, a heating element on an atomizing core is usually installed on an oil guide surface of an oil guide member by printing, embedding and the like or directly and fixedly installed on the oil guide surface of the oil guide member. Adopt such heat-generating body fixed mode, its heat-generating body all with lead oil level direct contact, at the heat-generating body during operation, the heat of its production can lead to the oil level through atomizing face direct conduction to the atomizing medium that contacts bottom position heats, so, not only can lead to the too much loss of heat-generating body heat, can heat the atomizing medium of bottom many times repeatedly moreover, is unfavorable for atomizing medium's storage.

SUMMERY OF THE UTILITY MODEL

In view of this, there is a need for an atomizing structure, an atomizer and an aerosol-generating device.

An atomization structural member comprises an atomization core component and a heating body; the atomizing core assembly comprises an atomizing part, a connecting section and a guiding part which are sequentially arranged in a contact manner, the heating body is at least partially embedded in the atomizing part, and the atomizing part is fixed in the guiding part through the connecting section; the guide part is in contact with an atomized medium and sequentially passes through the guide part and the connecting section to transfer the atomized medium to the atomization part; the atomizing part has inner wall and outer wall, the inner wall forms first atomizing face and transmission the first air flue of the produced aerosol of first atomizing face, the outer wall forms second atomizing face and cooperation guide portion forms the transmission jointly the second air flue of the produced aerosol of second atomizing face.

According to the atomization structural part, on one hand, a physical interval is formed between the atomization surface and the liquid absorption surface, and the heating body indirectly contacts the atomization medium in the liquid storage cavity through the guide part, so that a longer distance exists between the heating body and the atomization medium in the liquid storage cavity, the heat transfer is effectively isolated, the atomization medium in the liquid storage cavity is prevented from deteriorating due to high temperature, and the heating efficiency of the whole atomization structural part is high; on the other hand will atomize the part and lead the oily part and connect, and the guide acquires the atomizing medium through the imbibition face, leads the big and all-round oil of leading of oily area, can effectively ensure the fuel feeding abundant, and the part of atomizing contains intraductal and a plurality of atomizing areas of outside of tubes simultaneously, and the atomizing volume is big, and it is not good to have solved traditional atomizing atomization effect, and the smog volume is not enough problem.

In one embodiment, the number of the connecting sections is at least two, and each connecting section is uniformly arranged relative to the atomizing part and the guide part.

In one embodiment, the atomizing part and the guiding part are both regular round tubular structures or regular prism tubular structures, or one of the structures is a regular round tubular structure and the other is a regular prism round tubular structure.

In one embodiment, the atomizing part and the guiding part are coaxially arranged; and/or the outer surface of the guide part is completely set as a liquid suction surface in contact with the atomized medium or the surface of the guide part, which is away from the outer wall, is completely set as a liquid suction surface in contact with the atomized medium.

In one embodiment, the height of the atomizing part is smaller than the height of the guide part in the gravity direction.

In one embodiment, the connecting section is arranged at the same height with the atomizing part in the gravity direction; or the connecting sections are arranged to form at least two layers, each layer is provided with at least two connecting sections, the connecting sections of each layer are uniformly arranged relative to the axis of the atomizing part, and the projections of the connecting sections of each layer do not coincide with each other at the bottom position of the atomizing part.

In one embodiment, an air inlet end is formed in one side of the atomizing core assembly, and the first air passage and the second air passage are respectively communicated with the air inlet end; an air outlet end is formed in the other side of the atomizing core component, and the first air passage and the second air passage are respectively communicated with the air outlet end; and/or the heating body comprises a spiral heating wire, a net heating wire and a sheet heating wire; and/or the heating body and the atomizing part are integrally formed and are positioned between the outer wall and the inner wall; and/or the atomization part is provided with a top support position which is arranged to be matched with and keep the fluid communication of the first air passage and the second air passage when being installed; and/or the atomization part, the guide part and the connecting section are integrally formed; and/or the atomizing part, the guide part and the connecting section are all made of microporous materials with certain porosity; and/or, in the gravity direction, the surfaces of the bottom of the atomization part, the guide part and/or the connecting section are provided with leakproof sealing layers.

In one embodiment, the atomizer comprises a liquid storage structure, a suction nozzle structure and any one of the atomizing structures; the liquid storage structural part is provided with a liquid storage cavity, the liquid storage cavity is used for containing the atomized medium, and the guide part is used for contacting the atomized medium; the aerosol generated by the heating element is communicated with the fluid of the suction nozzle structural part through the first air passage and the second air passage.

In one embodiment, the liquid storage structure is provided with a liquid storage structure, the atomization structure is provided with a sealing sleeve and a vent pipe, the vent pipe is at least partially fixedly arranged in the liquid storage structure, and one end of the vent pipe is hermetically fixed on the guide part through the sealing sleeve; the liquid storage cavity is formed between the liquid storage structure and the vent pipe, and the vent pipe is respectively in fluid communication with the first air passage, the second air passage and the suction nozzle structural part so as to transmit the aerosol; the atomizing structure still includes the installed part, the installed part cooperation the stock solution structure reaches the guide seals the stock solution chamber, so that in the stock solution chamber the atomizing medium only contact the liquid absorption surface of guide.

In one embodiment, an aerosol-generating device comprises a power source and any one of the nebulizers, the power source being connected to the nebulizer for supplying power.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments or the conventional technologies of the present application, the drawings used in the descriptions of the embodiments or the conventional technologies will be briefly introduced below, it is obvious that the drawings in the following descriptions are only some embodiments of the present application, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic structural view of an embodiment of an atomizing core assembly as described herein.

FIG. 2 is a schematic sectional view taken along line A-A of the embodiment shown in FIG. 1.

FIG. 3 is another schematic cross-sectional view of the embodiment of FIG. 1.

Fig. 4 is another schematic view of the embodiment shown in fig. 1.

Fig. 5 is a schematic structural diagram of an embodiment of the atomization structure according to the present application.

FIG. 6 is a schematic cross-sectional view of the embodiment of FIG. 5 in one direction.

Fig. 7 is another schematic cross-sectional view of the embodiment of fig. 5.

Fig. 8 is another schematic view of the embodiment of fig. 5.

Fig. 9 is another schematic view of the embodiment of fig. 5.

Fig. 10 is another schematic view of the embodiment of fig. 5.

Fig. 11 is another schematic view of the embodiment of fig. 5.

Fig. 12 is another schematic view of the embodiment of fig. 5.

Fig. 13 is another schematic view of the embodiment shown in fig. 5.

Fig. 14 is a schematic structural diagram of an embodiment of an atomization device according to the present application.

FIG. 15 is a cross-sectional view of the embodiment of FIG. 14 in one direction.

Fig. 16 is an enlarged view of a portion of the structure of the embodiment shown in fig. 15.

FIG. 17 is another schematic cross-sectional view of the embodiment of FIG. 14.

Fig. 18 is an exploded view of the embodiment of fig. 14.

Fig. 19 is another schematic view of the embodiment of fig. 14.

Fig. 20 is a partial structural view of the embodiment shown in fig. 14.

FIG. 21 is a schematic cross-sectional view in one direction of the embodiment of FIG. 20.

Fig. 22 is an exploded view of the embodiment of fig. 20.

Fig. 23 is another schematic view of the embodiment of fig. 21.

Reference numerals: an atomization structural component 100, a liquid storage structural component 200, a suction nozzle structural component 300, a gravity direction G and an air flow direction P; the atomizing core assembly 110, the heating body 120, the sealing kit 130, the electrode assembly 140, the vent pipe 150, the mounting member 160, the base 170, the air duct 190; the atomizing part 111, the guiding part 112, the air outlet end 113, the connecting section 114, the inner wall 115, the outer wall 116, the top supporting position 117, the air inlet end 118 and the liquid absorbing surface 119; an electrode core 141, an electrode sealing sleeve 142, an exhaust hole 151, an air inlet 171, a fixed end 172, a connecting end 173, an air inlet chamber 174, a first air passage 191, a second air passage 192 and a main air passage 193; a first outer tube 210, a second outer tube 220, a liquid storage structure 230, a liquid storage cavity 240, and a contact area 241; the suction nozzle 310, the air outlet 311, the clamp spring 320, the suction nozzle sealing sleeve 330 and the suction nozzle inner tube 340.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present application more comprehensible, embodiments accompanying the present application are described in detail below with reference to the accompanying drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present application. This application is capable of embodiments in many different forms than those described herein and that modifications may be made by one skilled in the art without departing from the spirit and scope of the application and it is therefore not intended to be limited to the specific embodiments disclosed below. It will be understood that when an element is referred to as being "secured to" or "disposed" on another element, it can be directly on the other element or intervening elements may also be present. When a component is referred to as being "connected" to another component, it can be directly connected to the other component or intervening components may also be present. The terms "vertical," "horizontal," "upper," "lower," "left," "right," and the like as used in the description of the present application are for illustrative purposes only and do not represent the only embodiments.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present application, "plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

In this application, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may mean that the first feature is in direct contact with the second feature, or that the first feature and the second feature are in indirect contact via an intermediate. Also, a first feature "on," "over," and "above" a second feature may be directly or diagonally above the second feature, or may simply indicate that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature. Unless defined otherwise, all technical and scientific terms used in the specification of the present application have the same meaning as commonly understood by one of ordinary skill in the art to which the present application belongs. The terminology used in the description of the present application is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. As used in the description of the present application, the term "and/or" includes any and all combinations of one or more of the associated listed items.

The application discloses an atomization structural component, which comprises a part of or the whole structure of the following embodiments; that is, the atomizing structure includes some or all of the following technical features. In an embodiment of the application, the atomizing structure includes an atomizing core component and a heating element. In one embodiment, as shown in fig. 1 and 2, the atomizing core assembly 110 includes an atomizing part 111 and a guiding part 112 disposed in contact with each other, and with reference to fig. 3 and 4, the atomizing part 111 is fixed in the guiding part 112. The guide part 112 is in contact with the atomizing medium and transfers the atomizing medium to the atomizing part 111; the atomization portion 111 has an inner wall 115 and an outer wall 116, the inner wall 115 forms a first atomization surface and a first air passage 191 for transmitting aerosol generated by the first atomization surface, and the outer wall 116 forms a second atomization surface and cooperates with the guide portion 112 to jointly form a second air passage 192 for transmitting aerosol generated by the second atomization surface.

In one embodiment, the guiding portion 112 is provided with a liquid absorbing surface 119 in contact with the atomizing medium, and the liquid absorbing surface 119 is configured to absorb the atomizing medium into the inside of the guiding portion 112 and transmit the atomizing medium to the inside of the atomizing portion 111 through the inside of the guiding portion 112. In one embodiment, the first air channel 191 and the second air channel 192 are respectively disposed to communicate with two sides of the atomizing core assembly 110. In this embodiment, an air inlet 118 is disposed on one side of the atomizing core assembly 110, and the first air channel 191 and the second air channel 192 are respectively communicated with the air inlet 118; an air outlet end 113 is formed in the other side of the atomizing core assembly 110, and the first air passage 191 and the second air passage 192 are respectively communicated with the air outlet end 113. The air inlet 118 and the air outlet 113 are designed such that outside air can enter the atomization region formed by the inner wall 115 and the outer wall 116 due to the action of the heating element 120, thereby forming a passage for air circulation from outside to inside to outside, and aerosol generated by the heating element 120 heating the atomization medium can be mixed with the outside air and then output.

In one embodiment, as shown in fig. 2 or 3, the atomizing area 111 has a top support 117, and the top support 117 is configured to cooperate with the first air channel 191 and the second air channel 192 to maintain fluid communication when installed, for example, when other components are installed. Such a design is advantageous to avoid blockage of the first air passage 191 and the second air passage 192 due to a tight fitting installation manner, thereby ensuring that the aerosol generated by the first atomizing surface is transmitted through the first air passage 191 and the aerosol generated by the second atomizing surface is transmitted through the second air passage 192. Further, in one embodiment, as shown in fig. 2 and 3, in the gravity direction, the height of the atomizing part 111 is smaller than that of the guiding part 112. Further, in one embodiment, the connecting section 114 is disposed at the same height as the atomizing area 111 in the gravity direction; in one embodiment, the connecting section 114 is disposed at the same height as the atomizing area 111 in the gravity direction, and the height of the atomizing area 111 is smaller than the height of the guiding area 112. The design is beneficial to comprehensively utilizing the gravity action and the capillary action to convey the atomized medium from the inside of the atomized core assembly 110.

In one embodiment, the guiding portion 112 contacts with the atomizing medium, and the atomizing medium is sequentially transferred to the atomizing portion 111 through the guiding portion 112 and the connecting section 114; further, in one embodiment, as shown in fig. 3, the guiding portion 112 is connected with the atomizing portion 111 through at least one connecting segment 114. In this embodiment, the outer surface of the guide portion 112 is provided with the liquid suction surface 119, and the liquid suction surface 119 is configured to sequentially pass through the inside of the guide portion 112 and the inside of the connecting section 114 to deliver the atomized medium to the inside of the atomization portion 111. In this embodiment, the connecting section 114 is convexly disposed relative to the atomizing area 111 to form the top supporting position 117 which is concavely disposed.

In one embodiment, as shown in fig. 3 and 4, the atomizing core assembly 110 includes an atomizing part 111, a connecting section 114 and a guiding part 112, which are sequentially arranged in contact with each other, the heating element 120 is at least partially embedded in the atomizing part 111, and the atomizing part 111 is fixed in the guiding part 112 through the connecting section 114; the guide part 112 is provided with a liquid absorbing surface 119 which is in contact with the atomized medium, the liquid absorbing surface 119 is arranged to absorb the atomized medium into the guide part 112, and the atomized medium is transmitted to the inside of the atomization part 111 through the inside of the guide part 112 and the inside of the connecting section 114 in sequence; in one embodiment, the heat generating body 120 is integrally formed with the atomizing area 111 and is located between the outer wall 116 and the inner wall 115. According to the design, on one hand, a physical interval is formed between the atomizing surface and the liquid absorbing surface, and the heating body indirectly contacts the atomizing medium in the liquid storage cavity through the guide part, so that a longer distance exists between the heating body and the atomizing medium in the liquid storage cavity, the heat transfer is effectively isolated, the atomizing medium in the liquid storage cavity is prevented from deteriorating due to high temperature, and the heating efficiency of the whole atomizing structural part is high due to heat concentration; on the other hand will atomize the part and lead the oily part and connect, and the guide acquires the atomizing medium through the imbibition face, leads the big and all-round oil of leading of oily area, can effectively ensure the fuel feeding abundant, and the part of atomizing contains intraductal and a plurality of atomizing areas of outside of tubes simultaneously, and the atomizing volume is big, and it is not good to have solved traditional atomizing atomization effect, and the smog volume is not enough problem.

In one embodiment, an atomizing structure 100 is shown in fig. 5, which includes an atomizing core assembly 110 and a heating element 120; with reference to fig. 6 and 7, the atomizing core assembly 110 includes an atomizing part 111 and a guiding part 112, which are disposed in contact with each other, the heating element 120 is at least partially embedded in the atomizing part 111, and the atomizing part 111 is fixed in the guiding part 112; the guide part 112 is provided with a liquid absorbing surface 119 which is in contact with the atomized medium, and the liquid absorbing surface 119 is arranged to absorb the atomized medium into the inside of the guide part 112 and transmit the atomized medium to the inside of the atomization part 111 through the inside of the guide part 112; the atomization part 111 is provided with an inner wall 115 and an outer wall 116, the inner wall 115 forms a first atomization surface and a first air passage 191 for transmitting aerosol generated by the first atomization surface, and the outer wall 116 forms a second atomization surface and cooperates with the guide part 112 to form a second air passage 192 for transmitting aerosol generated by the second atomization surface; the first air passage 191 and the second air passage 192 are respectively communicated with two sides of the atomizing core assembly 110. In such a design, an important point of the present embodiment is to heat the heating element 120 uniformly, so as to ensure the uniformity of heating the atomized medium, and further ensure the consistency of the atomized aerosol, and another important point of the present invention is to make the heating element 120 indirectly contact the atomized medium in the liquid storage chamber to effectively isolate the heat transfer, which is beneficial to avoiding the deterioration of the atomized medium in the liquid storage chamber caused by high temperature. In this embodiment, the heating element 120 includes a spiral heating wire, a mesh heating wire, and a sheet heating wire; and/or, the heating element 120 is provided with a wire extending outside the atomizing unit 111.

In one embodiment, as shown in fig. 8 and 9, an air inlet 118 is formed at one side of the atomizing core assembly 110, and the first air channel 191 and the second air channel 192 are respectively communicated with the air inlet 118; an air outlet end 113 is formed in the other side of the atomizing core assembly 110, and the first air passage 191 and the second air passage 192 are respectively communicated with the air outlet end 113.

In one embodiment, the atomizing core assembly 110 includes an atomizing part 111 and a guide part 112; the part of the atomization structure 100 for realizing the atomization function comprises an atomization part 111 and a heating element 120, wherein the heating element 120 is embedded in the atomization part 111; the guiding portion 112 is a tubular structure including an inner wall and an outer wall, the inner wall is connected to the atomizing portion 111 through at least one connecting section 114, and at least a portion of the outer wall is used for contacting the atomizing medium, so that the atomizing medium is transmitted to the atomizing portion 111 through the outer wall and the connecting section 114, and is finally atomized by the heating element 120 to generate aerosol.

In this embodiment, the atomizing part 111, the guiding part 112 and the connecting section 114 are all made of microporous materials with a certain porosity, so that the atomizing medium can be conducted by means of the capillary action of the internal pores of the structure, and the atomizing medium and the guiding part are all integrally formed, thereby reducing the number of components to be assembled and effectively improving the assembly efficiency and the yield. Of these, the number of the connecting sections 114 is preferably at least two, and the space between the atomizing area 111 and the guide 112 is equally distributed, that is, the space between the outer wall 116 of the atomizing area 111 and the inner wall of the guide 112 is equally distributed. Further, in one embodiment, at least two of the connecting sections 114 are symmetrical with respect to a central axis of the atomizing area 111. Such a design facilitates the liquid surface 119 to uniformly deliver the atomized medium to the atomizing area 111.

The atomizing core assembly 110 includes a first smoke channel, i.e., a first air channel 191, which penetrates through the atomizing area 111, and the inner wall 115 of the atomizing area 111 forms a first atomizing surface adjacent to the first smoke channel, and the aerosol generated by the first atomizing surface can be transmitted through the first air channel 191.

The surface of the atomizing area 111 not covered by the connecting section 114 is a second atomizing surface, that is, the surface not contacting the connecting section 114 is a second atomizing surface, that is, the surface of the outer wall 116 of the atomizing area 111 not covered by the connecting section 114 is a second atomizing surface, the inner walls of the second atomizing surface, the connecting section 114 and the guiding portion 112 form a second smoke channel, that is, a second air passage 192, and the aerosol generated by the second atomizing surface can be transmitted through the second smoke channel.

The heating element 120 is located between the first atomization surface and the second atomization surface, and may be, but need not necessarily be, located at an intermediate position. The heating element 120 used in this embodiment is a spiral heating wire, and is connected to a power supply through a wire. In other embodiments, the heating element 120 may have other structures, such as a mesh heating element, and a metal sheet heating wire, and in addition, the possibility of electromagnetic heating is considered, and the wire is not necessarily required, and only the heating element 120 may generate heat in some way to atomize the atomizing medium.

With reference to fig. 8, the atomizing core assembly 110 further includes an air inlet 118 and an air outlet 113, and the external air can enter from the air inlet 118, pass through the first air channel 191 and the second air channel 192, carry away the generated aerosol, and flow out from the air outlet 113.

Further, in one embodiment, at least 80% of the outer surface of the guide portion 112 is set as the suction surface 119. Further, in one embodiment, as shown in fig. 9 and 10, the outer surface of the guide portion 112 is entirely set as the liquid suction surface 119 or the surface of the guide portion 112 facing away from the outer wall 116 is entirely set as the liquid suction surface 119.

In one embodiment, as shown in fig. 10, the guiding portion 112 is a regular round tubular structure, and the outer surface of the guiding portion 112 away from the atomizing portion 111 is the liquid suction surface 119. In one embodiment, the atomizing part 111 and the guiding part 112 are made of microporous materials with certain porosity, that is, the atomizing core assembly 110 has a porous structure inside, that is, the atomizing part 111 and the guiding part 112 have a porous structure. In various embodiments, the porous structure may also be referred to as a hollow porous body, and exhibits a "porous" form on a microscopic level, so as to transmit the atomizing medium inside the atomizing core assembly 110 and the atomizing part 111 thereof, and due to the characteristics of the porous structure, the atomizing medium is transmitted by gravity and capillary action, so that the heating element 120 can heat the atomizing medium in the atomizing part 111 to generate aerosol, and the aerosol is transmitted out of the first air passage 191 and the second air passage 192 outside the atomizing part 111. Further, the pore size of the porous structure is 100 nanometers to 120 micrometers; in one embodiment, the pore size of the porous structure is from 1 micron to 100 microns. In one embodiment, the pore size of the porous structure is 10 to 50 microns. The porous structure is made of ceramic or glass and the like. In one embodiment, the internal porosity of the porous structure is from 30% to 90%, and in one embodiment, the internal porosity of the porous structure is from 50% to 65%. Such a design facilitates the transport of the atomized medium only through the interior of the atomizing part 111.

Further, in one embodiment, the porosity of the guiding portion 112 is greater than the porosity of the atomizing portion 111, so that the total amount of the atomizing medium supplied by the guiding portion 112 is sufficient, and the relatively low porosity of the atomizing portion 111 can prevent the atomizing portion 111 from leaking due to the high porosity, thereby facilitating the flow of the atomizing medium to the atomizing portion 111. Further, in one embodiment, the guiding portion 112 is provided with different apertures inside to form a guiding channel, and the liquid absorbing surface 119 delivers the atomizing medium to the atomizing portion 111 or the connecting section 114 through the guiding channel, so as to facilitate accurate and uniform delivery of the atomizing medium to the atomizing portion 111 and the heating element 120 therein, thereby obtaining a uniform aerosol. In addition, the design connects the atomizing part and the oil guiding part, and the atomizing medium is transported, such as oil guiding, through the oil guiding part, i.e., the entire tubular outer wall of the guiding part 112, so that the oil guiding area is large and the oil is guided in all directions, thereby effectively ensuring sufficient supply of the atomizing medium to the heating element 120, and the atomizing part, i.e., the atomizing part 111, includes a plurality of atomizing areas inside and outside the tube, thereby increasing the atomizing amount.

In one embodiment, the number of the connecting segments 114 is at least two, and each connecting segment 114 is uniformly arranged relative to the atomizing part 111 and the guiding part 112. In one embodiment, as shown in fig. 9 and 11, the number of the connecting segments 114 is two, and each connecting segment 114 is uniformly arranged with respect to the atomizing area 111 and the guiding area 112. In one embodiment, the atomizing part 111, the guiding part 112 and the connecting section 114 are integrally formed; and/or the atomizing part 111, the guiding part 112 and the connecting section 114 are all made of microporous materials with certain porosity.

In one embodiment, as shown in fig. 11 and 12, the guiding portion 112 has a tubular structure, and the inner tube surface of the tubular structure is connected with the atomizing portion 111 through at least one connecting segment 114; the outer tube surface of the tubular structure is provided with the liquid suction surface 119, and the liquid suction surface 119 is arranged to sequentially pass through the inside of the guide part 112 and the inside of the connecting section 114 to transmit the atomized medium to the inside of the atomization part 111. In one embodiment, the atomizing part 111 and the guiding part 112 are both regular round tubular structures. In one embodiment, the atomizing part 111 and the guiding part 112 are both regular prism-shaped structures, or one of the atomizing part 111 and the guiding part 112 is a regular circular prism-shaped structure and the other is a regular prism-shaped structure. In one embodiment, the atomizing part 111 and the guiding part 112 are coaxially disposed. Referring to fig. 13, the heating element 120 is provided with a wire extending to the outside of the atomizing part 111 of the atomizing core assembly 110.

In order to avoid the leakage of the atomized medium, in one embodiment, the surfaces of the bottom of the atomizing part 111, the guiding part 112 and/or the connecting section 114 are provided with a leakage-proof sealing layer, i.e. a sealing medium, in the gravity direction. Further, in one embodiment, the leak-proof sealing layer is a coating layer or a sheet layer. In one embodiment, the bottom of the atomizing part 111, the guiding part 112 and/or the connecting section 114 is coated with a non-oil-guiding medium, which may include a coating, a sealing member, and the like, to prevent the atomizing medium stored inside the atomizing part 111, the guiding part 112 and/or the connecting section 114 from leaking out of the atomizing core assembly 110. Further, in one embodiment, the leakage-proof sealing layer is disposed on the guiding portion 112 except for the liquid suction surface 119 and the position where the liquid suction surface contacts the atomizing portion 111 or the connecting section 114, so as to prevent the atomizing medium from leaking.

Further, in one embodiment, the connecting sections 114 are arranged to form at least two layers, each layer has at least two connecting sections 114, the connecting sections 114 of each layer are uniformly arranged relative to the axis of the atomizing area 111, and at the bottom position of the atomizing area 111, the projections of the connecting sections 114 of each layer do not overlap each other. In one embodiment, the connecting segments 114 of each layer form a uniform line segment passing through the center or axis, i.e., a portion of a diametrical line; and each of the connection segments 114 of each layer spatially forms a plurality of transmission layers that do not overlap with each other. Such design is favorable to forming multistage formula even input system, guarantees that the atomizing medium passes through the linkage segment from guide and inputs the inside of atomizing portion, and the porosity of cooperation guide is more than or equal to the porosity of atomizing portion, has effectively utilized capillary action, can effectively ensure to the atomizing medium supply of heat-generating body 120 is abundant, especially is fit for the supply demand that the atomizing volume is big.

In one embodiment, an atomizer comprises a liquid storage structure, a nozzle structure, and the atomizing structure 100 of any one of the embodiments. In one embodiment, an atomizer is shown in fig. 14, which comprises a liquid storage structure 200, a nozzle structure 300 and any one of the atomizing structures 100; the atomizing structure 100 is shown in its configuration or partial exterior configuration. In one embodiment, the nozzle structure 300 is disposed on the reservoir structure 200, the reservoir structure 200 is disposed on the atomizing structure 100, and the atomizing structure 100 is partially disposed in the reservoir structure 200. Referring to fig. 15, the reservoir 200 defines a reservoir 240, the reservoir 240 is configured to contain the atomized medium, and the guiding portion 112, such as the liquid absorbing surface 119, is configured to contact the atomized medium; the aerosol generated by the heating element 120 is in fluid communication with the suction nozzle structure 300 through the first air passage 191 and the second air passage 192; i.e. the mouthpiece structure 300 is in fluid communication with the aerosol generated by the atomizing structure 100. Wherein, the liquid storage cavity 240 is used for storing atomization media, such as tobacco tar, essence, spice, etc.; the snorkel 150 is used to convey aerosol generated by the aerosol for inhalation.

In one embodiment, as shown in fig. 14, the liquid storage structure 200 includes a first outer tube 210, a second outer tube 220 and a liquid storage structure 230, wherein one end of the liquid storage structure 230 is tightly coupled to the atomizing structure 100 through the first outer tube 210, and the other end of the liquid storage structure 230 is tightly coupled to the nozzle structure 300 through the second outer tube 220. In one embodiment, referring to fig. 15, the suction nozzle structure 300 or the suction nozzle 310 thereof is in fluid communication with the first air passage 191 and the second air passage 192, or the suction nozzle structure 300 or the suction nozzle 310 thereof is in fluid communication with the main air passage 193 of the air duct 150 of the atomizing structure 100.

In one embodiment, as shown in fig. 15 and 16, the liquid storage structure 200 is provided with a liquid storage structure 230, the atomizing structure 100 is provided with a sealing assembly 130 and a vent pipe 150, the vent pipe 150 is at least partially fixedly disposed in the liquid storage structure 230, and one end of the vent pipe 150 is hermetically fixed on the guide portion 112 through the sealing assembly 130; the reservoir 240 is formed between the reservoir structure 230 and the vent tube 150, and the vent tube 150 is in fluid communication with the first air passage 191, the second air passage 192 and the mouthpiece structure 300 respectively for delivering the aerosol; the atomizing structure 100 further includes a mounting member 160, the mounting member 160 cooperates with the reservoir structure 230 and the guide portion 112 to seal the reservoir cavity 240, so that the atomizing medium in the reservoir cavity 240 contacts only the liquid surface 119 of the guide portion 112. In this embodiment, the mounting member 160 is disposed outside the atomizing core assembly 110.

In one embodiment, as shown in fig. 15 and 16, the air passage 190 includes a first air passage 191, a second air passage 192, and a main air passage 193; the first air passage 191 and the second air passage 192 are both in fluid communication with the main air passage 193 for output. Further, referring to fig. 16, a gap exists between the ventilation tube 150 and the atomization portion 111 through the top support 117, so that the second air passage 192 is in fluid communication with the main air passage 193 through the gap; that is, the diameters of the vent pipe 150 and the atomizing area 111 may be the same or different, and the vent pipe 150 and the atomizing area 111 are disposed in a non-contact manner to form a space communicating with the second air passage 192 between the vent pipe 150 and the atomizing area 111, and the space may be a part of the main air passage 193, that is, the main air passage 193 and the second air passage 192 communicate with each other. This is an important point of the present invention, and since two atomizing surfaces, the first air passage 191 and the second air passage 192, are formed on the inner wall and the outer wall of the atomizing area 111, there is an advantage that the amount of atomized aerosol is large.

Further, as shown in fig. 16, one end of the vent pipe 150 abuts against the top support position 117 of the atomizing core assembly 110 through the sealing sleeve 130, and abuts against the inner wall of the guiding portion 112 of the atomizing core assembly 110, and the top support position 117 is configured to cooperate to maintain the fluid communication between the first air passage 191 and the second air passage 192 when the vent pipe 150 is installed.

Further, as shown in FIG. 16, the snorkel 150 passes through the mounting member 160 such that the main air passage 193 of the snorkel 150 is in fluid communication with the first air passage 191 and the second air passage 192 of the atomizing core assembly 110, and on the one hand, the bottom of the atomizing core assembly 110 abuts against the mounting member 160 and, via the mounting member 160, against the base 170; on the other hand, the outer wall of the guide portion 112 of the atomizing core assembly 110 abuts against the mounting member 160, and the mounting member 160 abuts against the base 170, so that the base 170 abuts against the reservoir structure 230 and the first outer tube 210 tightly, and the first outer tube 210 is sleeved outside one end of the reservoir structure 230 tightly, thereby achieving effective sealing of the end portion to the reservoir cavity 240. Further, the outer side of the mounting member 160 abuts against the base 170, and the inner side of the mounting member 160 abuts against the atomizing part 111 tightly, or the inner side of the mounting member 160 abuts against the atomizing core assembly 110 or the guiding part 112 thereof tightly, so as to cooperate with the base 170, the liquid storage structure 230 and the first outer tube 210 to position and fix the atomizing core assembly 110 together, which is also an implementation manner that one end of the liquid storage structure 230 is tightly combined with the atomizing structure 100 through the first outer tube 210. In this embodiment, the main air passage 193 of the vent tube 150 is in fluid communication with the first air passage 191, and the main air passage 193 is in fluid communication with the second air passage 192.

For the sealing of the reservoir 240, the focus in the art has been, and this application is not exceptional, and because the vent pipe 150 penetrates through the reservoir 240, it needs to be considered to solve the problem of sealing the two ends of the reservoir 230 and the reservoir 240, on one hand, the seal assembly 130 of the atomizing structure 100, the vent pipe 150 and the atomizing core assembly 110 are matched and tightly combined to prevent the atomizing medium in the reservoir 240 from leaking into the first air channel 191 and the second air channel 192 in the atomizing core assembly 110 through the gap between the vent pipe 150 and the seal assembly 130; on the other hand, the first outer tube 210 passes through one end of the liquid storage structure 230, and is matched with the base 170 to apply pressure to the mounting member 160 so as to be tightly sleeved outside the atomizing core assembly 110, so as to integrally form a sealing system, so that the atomizing medium in the liquid storage cavity 240 is prevented from leaking out of the atomizer through gaps among the mounting member 160, the base 170 and the liquid storage structure 230. This design provides an effective seal for the reservoir structure 230 and one end of the reservoir chamber 240.

In this embodiment, the atomizing structure 100 further includes an electrode assembly 140, the electrode assembly 140 is connected to the heating element 120, and the electrode assembly 140 is further used for connecting a power supply; in one embodiment, the electrode assembly 140 includes an electrode core 141 and an electrode sealing sleeve 142, the electrode sealing sleeve 142 is sleeved outside the electrode core 141, and the electrode core 141 is used for connecting an electrode of a power supply or a joint thereof, and is electrically connected to the heating element 120; in this embodiment, the electrode sealing sleeve 142 cooperates with the base 170 to jointly fix the electrode core 141 in an insulating manner. In one embodiment, the electrode core 141 is used for connecting an electrode or a connector thereof to a power source by means of snap-fit, screw-fit, plug-in, or the like. Due to the design, except for the part of the electrode core 141 exposed to the outside through the base 170 for connecting to an electrode of a power supply or a joint thereof, the rest part is jointly sealed and protected by the electrode sealing sleeve 142 in cooperation with the base 170, and the atomizing structure 100, especially the atomizing core assembly 110, inside the liquid storage structure 200 is also protected.

In one embodiment, as shown in fig. 15, the atomizing structure 100 further includes a base 170, the base 170 is tightly coupled to one end of the reservoir structure 230 through the first outer tube 210, please refer to fig. 18, and a connection end 173 of the base 170 is located outside the reservoir structure 230, and is configured to be mounted on a power source for supplying power to the atomizing structure 100, and directly or indirectly achieve an electrically conductive connection. In other embodiments, the atomizing structure 100 may further include a base sleeve detachably mounted on the connecting end 173 of the base 170 to protect the structures, such as the electrode assembly 140, disposed inside the base 170 in a non-use state, such as a transportation state. Further, for convenience of use, the base housing is made of rubber or silicone so as to be quickly mounted to the connecting end 173 of the base 170 or removed from the connecting end 173 of the base 170 so that the connecting end 173 of the base 170 is connected to a power source such as a battery or an electrode terminal thereof.

Further, in one embodiment, referring to fig. 16 and 18, the fixed end 172 of the base 170 abuts against the liquid storage structure 200 and the atomizing structure 100 or the sealing assembly 130 or the mounting member 160 thereof to fit the atomizing structure 100 or the atomizing core assembly 110 thereof, and the connecting end 173 of the base 170 is used for mounting a power supply; in this embodiment, the base 170 is provided with an air inlet 171 and an air inlet chamber 174 communicated with the air inlet 171, the air inlet chamber 174 is located inside the base 170, and the air inlet 171 is in fluid communication with the first air channel 191 and the second air channel 192 through the air inlet chamber 174, and is used for providing air to transfer the generated aerosol during suction and outputting the aerosol through the air channel 190 of the air pipe 150, so that the aerosol flows to the air outlet 311 of the suction nozzle structure 300 according to the air flow direction P. With such a design, a path for air circulation of atomization delivery is formed.

Further, in one embodiment, the vent tube 150 is provided with a positioning groove for positioning and installing the nozzle structure 300 or the nozzle sealing sleeve 330 thereof. Further, the nozzle sealing sleeve 330 corresponds to the positioning groove is provided with a positioning convex part, the positioning convex part is in the positioning groove tightly abutted against the vent pipe 150, on one hand, installation and positioning are guaranteed, too shallow or too deep installation is avoided, on the other hand, the sealing effect of the joint of the vent pipe 150 is guaranteed, and the liquid storage cavity 240 of the liquid storage structure member 200 is sealed together by matching with other structures.

Further, in one embodiment, please refer to fig. 17 and 18 together, the nozzle structure 300 has a nozzle 310, a clamp spring 320, a nozzle sealing sleeve 330 and a nozzle inner tube 340, wherein the clamp spring 320 is fastened on the vent tube 150 or a positioning groove thereof for limiting the installation positions of the nozzle 310, the nozzle sealing sleeve 330 and the nozzle inner tube 340; the nozzle sealing sleeve 330 and the nozzle 310 are sleeved outside the vent pipe 150, the nozzle sealing sleeve 330 and the nozzle 310 are respectively contacted with the vent pipe 150, the nozzle 310 is positioned above the nozzle sealing sleeve 330, and the nozzle inner pipe 340 is sleeved outside the nozzle sealing sleeve 330; the suction nozzle 310 has a sandwich layer, the suction nozzle sealing sleeve 330 and the suction nozzle inner tube 340 are at least partially located in the sandwich layer, and the suction nozzle sealing sleeve 330 and the suction nozzle inner tube 340 are located between the suction nozzle 310 and the air duct 150; an extending end of the suction nozzle 310 is located between the suction nozzle inner tube 340 and one end of the liquid storage structure 230, the second outer tube 220 is located outside one end of the liquid storage structure 230, so that one end of the liquid storage structure 230 is closely combined with the suction nozzle 310 through the second outer tube 220 in cooperation with the air tube 150, the suction nozzle sealing sleeve 330 and the suction nozzle inner tube 340, that is, the second outer tube 220, the liquid storage structure 230, one extending end of the suction nozzle 310, the suction nozzle inner tube 340, the suction nozzle sealing sleeve 330 and the other extending end of the suction nozzle 310 are sequentially and closely sleeved outside the air tube 150, wherein a part of the suction nozzle sealing sleeve 330 is directly sleeved outside the air tube 150, such a design is beneficial to realize that the air passage 190 at the suction nozzle structure 300 and the suction nozzle 310 thereof penetrates through the air tube 150 on one hand, and is beneficial to seal the liquid storage cavity 240 of the liquid storage structure 230 on the other hand, the atomized medium in the nozzle structure 300 is prevented from being heated and evaporated or volatilized at normal temperature and then being dissipated from one end connected with the nozzle structure. With the embodiment having the sealing assembly 130, the mounting member 160, and the base 170, the two ends of the reservoir 240 of the reservoir structure 230 are sealed.

In one embodiment, as shown in fig. 16 and 17, a contact area 241 is disposed in the reservoir 240, and the atomized medium contacts the liquid absorbing surface 119 in the contact area 241, then enters the atomizing part 111, and contacts the heating element 120. In one embodiment, as shown in fig. 18 and 19, the heating element 120 has a spiral shape, and the base 170 has a connection end 173 for screw connection.

In one embodiment, as shown in fig. 20 and 21, the heating element 120 is connected to the electrode assembly 140, the mounting member 160 is sleeved outside the atomizing core assembly 110, and the sealing member 130 is sleeved outside the vent pipe 150 and inside the air outlet 113 of the atomizing core assembly 110; referring to fig. 22 and 23, the vent pipe 150 further defines an air vent hole 151, and the air vent hole 151 is used for preventing air from being exhausted due to an excessive air pressure in the reservoir chamber 240 of the reservoir structure 230 during assembly, and the air vent hole 151 is separated from the reservoir chamber 240 of the reservoir structure 230 and exposed outside the reservoir chamber 240 as assembly advances.

In one embodiment, an atomizer includes the atomization structural component 100 and an atomizer main body according to any embodiment, the atomization structural component 100 is housed in the atomizer main body, the atomizer main body includes a liquid storage cavity 240, and the guide portion 112 transfers an atomization medium in the liquid storage cavity 240 to the atomization portion 111 through a liquid suction surface 119 of the guide portion to be atomized. The atomizer still includes breather pipe 150 and gas outlet 311, atomizing core subassembly 110's the end 113 of giving vent to anger still is equipped with and accomodates the chamber, breather pipe 150 can insert give vent to anger end 113 or its accomodate the intracavity, atomizing core subassembly 110's the end 113's of giving vent to anger flue gas accessible breather pipe 150 and through the outflow of gas outlet 311. The nebulizer further comprises a sealing kit 130, wherein the sealing kit 130 is disposed between the vent tube 150 and the wall of the receiving chamber, i.e. the inner wall of the guiding portion 112, so as to seal the gap between the vent tube 150 and the oil storage chamber 240. The atomizing core assembly 110 further has a groove extending toward the air outlet end 113 at the bottom of the accommodating cavity, and the groove fluidly connects the air pipe 150, the first air passage 191 and the second air passage 192. The groove may be formed separately on the upper end surface of the atomizing area 111, or may be formed on the upper end surfaces of the atomizing area 111 and the connecting section 114. The top support locations 117 may be employed as the grooves. Or, the connecting section 114 is provided with a limiting part for limiting the air duct 150 and the sealing sleeve 130 to downwardly seal two air ducts, namely two smoke air ducts, including the first air duct 191 and the second air duct 192, and the formed limiting space ensures that the air duct 150 and the two smoke air ducts are in fluid communication.

In each embodiment, the atomization device further has an air inlet and an air outlet 311, and the air inlet is in fluid communication with the first air passage 191 and the second air passage 192. The number of air inlets is not limited, for example, the atomization device may include two air inlets, and the two air inlets are respectively communicated with the first air passage 191 and the second air passage 192. The air outlet 311 is in fluid communication with the air passage 190 or its main air passage 193, e.g. the air outlet 311 is in fluid communication with the main air passage 193 in the snorkel 150, such that the formed aerosol is expelled from the air outlet 311 via the snorkel 150.

In one embodiment, an aerosol-generating device comprises a power source and the nebulizer of any embodiment, the power source being connected to the nebulizer for supplying power. In one embodiment, the power source has electrodes that are removably coupled to the electrode assembly 140 or its electrode core 141.

In addition, other embodiments of the present application further include an atomization structure, an atomizer, and an aerosol-generating device, which are formed by combining technical features of the above embodiments with each other and can be implemented. The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features. The above-mentioned embodiments only express several implementation modes of the present application, and the description thereof is specific and detailed, but not construed as limiting the scope of the claims. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present application shall be subject to the appended claims.

Claims (10)

1. An atomization structural member (100) is characterized by comprising an atomization core assembly (110) and a heating body (120);

the atomizing core assembly (110) comprises an atomizing part (111), a connecting section (114) and a guiding part (112) which are sequentially arranged in a contact manner, the heating body (120) is at least partially embedded in the atomizing part (111), and the atomizing part (111) is fixed in the guiding part (112) through the connecting section (114);

the guide part (112) is contacted with an atomizing medium and sequentially passes through the guide part (112) and the connecting section (114) to transfer the atomizing medium to the atomizing part (111);

the atomization part (111) is provided with an inner wall (115) and an outer wall (116), the inner wall (115) forms a first atomization surface and a first air passage (191) for transmitting aerosol generated by the first atomization surface, and the outer wall (116) forms a second atomization surface and cooperates with the guide part (112) to form a second air passage (192) for transmitting aerosol generated by the second atomization surface;

the number of the connecting sections (114) is at least two, and the connecting sections (114) are uniformly arranged relative to the atomizing part (111) and the guide part (112).

2. The atomizing structure (100) according to claim 1, characterized in that the atomizing part (111) and the guiding part (112) are both regular round tubular structures or regular prismatic tubular structures, or one is a regular round tubular structure and the other is a regular prismatic round tubular structure.

3. The nebulizing structure (100) according to claim 2 characterized in that the nebulizing segment (111) and the guiding segment (112) are coaxially arranged; and/or the outer surface of the guide part (112) is completely set as an absorption surface (119) contacted with the atomized medium or the surface of the guide part (112) departing from the outer wall (116) is completely set as an absorption surface (119) contacted with the atomized medium.

4. The nebulizing structure (100) according to claim 3 characterized in that the height of the nebulizing segment (111) is smaller than the height of the guide segment (112) in the direction of gravity.

5. The atomising structure (100) according to claim 4 characterized in that the connecting section (114) is arranged level with the atomising portion (111) in the direction of gravity.

6. The atomising structure (100) according to claim 4 characterized in that the connecting sections (114) are arranged to form at least two layers, and each layer has at least two connecting sections (114), and the connecting sections (114) of each layer are uniformly arranged relative to the axis of the atomising portion (111), and the projections of the connecting sections (114) of each layer do not coincide with each other at the bottom position of the atomising portion (111).

7. The atomizing structure (100) according to any one of claims 1 to 6, wherein an air inlet (118) is opened at one side of the atomizing core assembly (110), and the first air channel (191) and the second air channel (192) are respectively communicated with the air inlet (118); an air outlet end (113) is formed in the other side of the atomizing core assembly (110), and the first air passage (191) and the second air passage (192) are respectively communicated with the air outlet end (113); and/or the presence of a catalyst in the reaction mixture,

the heating body (120) comprises a spiral heating wire, a net heating wire and a sheet heating wire; and/or the presence of a catalyst in the reaction mixture,

the heating element (120) is integrally formed with the atomizing part (111) and is positioned between the outer wall (116) and the inner wall (115); and/or the presence of a catalyst in the reaction mixture,

the atomizer portion (111) having a top support location (117), the top support location (117) configured to cooperate to retain fluid communication between the first and second passageways (191, 192) when installed; and/or the presence of a catalyst in the reaction mixture,

the atomizing part (111), the guide part (112) and the connecting section (114) are integrally formed; and/or the presence of a catalyst in the reaction mixture,

the atomizing part (111), the guiding part (112) and the connecting section (114) are all made of microporous materials with certain porosity; and/or the like, and/or,

in the gravity direction, the surfaces of the bottom of the atomizing part (111), the guiding part (112) and/or the connecting section (114) are provided with anti-leakage sealing layers.

8. An atomizer, characterized by comprising a liquid storage structure (200), a suction nozzle structure (300) and an atomizing structure (100) according to any one of claims 1 to 7;

the liquid storage structure (200) is provided with a liquid storage cavity (240), the liquid storage cavity (240) is used for containing the atomized medium, and the guide part (112) is used for contacting the atomized medium;

the aerosol generated by the heating element (120) is communicated with the fluid of the suction nozzle structural part (300) through the first air passage (191) and the second air passage (192).

9. A nebulizer according to claim 8, wherein the reservoir structure (200) is provided with a reservoir structure (230), the nebulizer structure (100) is provided with a sealing assembly (130) and a vent tube (150), the vent tube (150) is at least partially fixedly arranged in the reservoir structure (230), and one end of the vent tube (150) is sealingly fixed on the guide portion (112) through the sealing assembly (130);

the reservoir chamber (240) is formed between the reservoir structure (230) and the vent tube (150), the vent tube (150) is in fluid communication with the first air passage (191), the second air passage (192) and the mouthpiece structure (300) respectively for delivering the aerosol;

the atomizing structure (100) further comprises a mounting member (160), wherein the mounting member (160) is matched with the liquid storage structure (230) and the guide part (112) to seal the liquid storage cavity (240), so that the atomizing medium in the liquid storage cavity (240) only contacts the liquid absorption surface (119) of the guide part (112).

10. An aerosol-generating device comprising a power source and an atomiser as claimed in claim 8 or 9, the power source being connected to the atomiser for supplying power.

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