RU2844591C2 - Tubular spray assembly of an aerosol-generating device and a method for assembling same, an aerosol-generating device - Google Patents

Abstract

FIELD: aerosol generating devices.

SUBSTANCE: proposed group of inventions relates to the field of the aerosol generating device, in particular to the aerosol generating device tubular spraying assembly and method of its assembly, to the aerosol generating device. Tubular spray assembly of an aerosol-generating device comprises a heating element which consists of a heated part and a conductive part electrically connected to the heated part, a bushing having a hollow cavity for accommodation, and an insulating base connected to one end of the bushing. Conductive part comprises first conductive part and second conductive part. Heated part is connected between the first conductive part and the second conductive part. Heated part is placed inside the accommodation cavity, and at least one current-conducting part extends to the outer side of the accommodation cavity. Insulating base includes one perforated hole, and the first current-conducting part and the second current-conducting part are fixed on the insulating base through the perforated hole. Method of assembling a tubular atomisation assembly of an aerosol-generating device includes forming a first assembly by winding a heating element and a liquid conducting element on a rod, inserting a first assembly from one end of the bushing into the accommodation cavity, connecting an insulating base to the same end of the bushing, wherein two conductive parts of heating element are arranged in perforated hole of insulating base. Tubular spray assembly is used in an aerosol generating device comprising a housing, inside of which there is a liquid cavity for storing a liquid matrix. Tubular spray assembly is capable of spraying the liquid matrix to generate an aerosol.

EFFECT: easier fixation of the heating element.

19 cl, 8 dwg

Description

Cross references to relevant applications

[1] This application claims priority to Provisional Application No. 202210052294.7, “Spraying Unit and Assembly Method, Aerosol Generating Device,” filed January 18, 2022, the contents of which are incorporated herein by reference in their entirety.

Field of technology

[2] Embodiments of the present application relate to the field of an aerosol generating device, in particular to a tubular spray unit of an aerosol generating device and a method for assembling the same, an aerosol generating device.

State of the art

[3] The main component of the aerosol generating device is the atomization unit. The atomization unit can atomize the liquid matrix stored inside the aerosol generating device to generate an aerosol. In the existing art, the atomization unit includes a heating element, a liquid conductive element and a support unit. The tubular atomization unit is widely used in the aerosol generating device due to its small volume. In particular, the heated part of the heating element is mainly a sheet heating mesh, and the liquid conductive element is fibrous cotton. However, the heating element and the liquid conductive element have a soft texture, and when these two elements are mounted on a rigid support unit, the heated part of the heating element is easily moved by the conductive pins at both ends thereof, thereby affecting the quality of the aerosol generated from the aerosol generating device, and the atomization unit cannot be applied to an automated assembly line.

[4] Document CH 204317504 U discloses an electronic smoking device with a heating element, but it does not describe how to facilitate fixation of the heating element.

The essence of the invention

[5] In order to solve the problem existing in the prior art, embodiments of the present application provide a tubular spray unit and an aerosol generating device comprising the same, which can facilitate fixing of a heating element.

[6] According to a first aspect, the present application provides a tubular spray unit of an aerosol generating device, comprising a heating element, which consists of a heated portion and a conductive portion electrically connected to the heated portion; the conductive portion comprises a first conductive portion and a second conductive portion, and the heated portion is connected between the first conductive portion and the second conductive portion; a sleeve having a hollow accommodation cavity; the heated portion of the heating element is placed inside the accommodation cavity, and the conductive portion extends to the outside of the accommodation cavity; an insulating base connected to one end of the sleeve; the insulating base includes one perforated hole, and the first conductive portion and the second conductive portion are fixed to the insulating base through the perforated hole.

[7] In some embodiments, said tubular spray assembly further comprises a retaining ring surrounding the outer portion of the insulating base.

[8] In some embodiments, the heating element comprises a heating plate having a mesh structure, and the heated portion is formed as an open tubular structure.

[9] In some embodiments, the first conductive portion comprises a first conductive terminal, and the second conductive portion comprises a second conductive terminal; the first conductive terminal and the second first conductive terminal are fixed to an insulating base, and the distance between them does not exceed the distance between the two free sides of the heating element.

[10] In some embodiments, an intermediate region exists between the two free sides of the heated portion, and the perforated hole is aligned with the intermediate region in the longitudinal direction.

[11] In some embodiments, at least one U-shaped hole is provided on the side of the sleeve.

[12] In some embodiments, the opening includes a first opening and a second opening separated from each other; at least one fluid-conducting opening is also provided between the first opening and the second opening.

[13] In some embodiments, the insulating base is provided with a protruding rib, wherein the protruding rib is sized to fit into the opening.

[14] In some embodiments, the protruding rib is located in a position corresponding to a perforated hole on the outer surface of the insulating base.

[15] In some embodiments, the insulating base further has a through hole; the through hole is located coaxially with the accommodation cavity.

[16] In some embodiments, a perforated hole is provided on one side of the through hole, and a separating wall is provided between the through hole and the perforated hole.

[17] In some embodiments, said tubular spray assembly also comprises a fluid-conducting element at least partially located around the heating element, wherein the fluid-conducting element includes a convex structure located in the opening.

[18] In some embodiments, said tubular spray assembly also comprises a liquid-conducting element at least partially located around the heating element, wherein the liquid-conducting element is fixed to the insulating base in a longitudinal direction.

[19] In some embodiments, the fluid-conducting element has a convex structure, wherein the protruding rib has a size that allows for accommodating at least a portion of the convex structure of the fluid-conducting element and the protruding rib of the insulating base.

[20] In some embodiments, the insulating base comprises a flange, wherein one end of the flange is secured to the sleeve.

[21] In some embodiments, the retaining ring is secured to the other end of the flange.

[22] According to a second aspect, embodiments of the present invention also provide a method for assembling said tubular atomization unit of an aerosol generating device, wherein the method for assembling includes a first unit formed by winding a heating element and a liquid-conducting element onto a rod wrapped in cotton; inserting the first unit from one end of a sleeve into a housing cavity; connecting an insulating base to the same end of the sleeve, wherein two conductive parts of the heating element are accommodated in a perforated hole of the insulating base.

[23] In some embodiments, the assembly method further includes riveting the retaining ring to the insulating base.

[24] According to a third aspect, embodiments of the present invention provide an aerosol generating device comprising a housing, inside which a liquid cavity is provided for storing a liquid matrix and a tubular spray unit, wherein the tubular spray unit includes said tubular spray unit, and the tubular spray unit is capable of spraying a liquid matrix to generate an aerosol.

[25] The advantageous effect of the present invention is that since the first conductive portion and the second conductive portion of the heating element are fixed in the same perforated hole of the insulating base, i.e. the first conductive portion and the second conductive portion can be inserted into the perforated hole in a state of mutual concentration or convergence, the first conductive portion and the second conductive portion do not exert a pulling force on the heated portion of the heating element during the fixing process, so that the heated portion of the heating element can be fixed in a predetermined fixing position in the sleeve housing cavity.

Description of drawings

[26] One or more embodiments of the invention are schematically illustrated by means of corresponding images in the drawings, which do not limit the embodiments of the invention; in particular, elements having the same reference numerals in the drawings are designated as similar elements. And the figures in the drawings are not limited in scale, unless this is specifically stated.

[27] Fig. 1 shows a sectional view of an aerosol generating device according to an embodiment of the present application;

[28] Fig. 2 is a spatial diagram of a tubular spray assembly according to an embodiment of the present application;

[29] Fig. 3 is a detailed drawing of a tubular spray assembly according to an embodiment of the present application;

[30] Fig. 4 shows a sectional view of a tubular spray assembly according to an embodiment of the present application;

[31] Fig. 5 shows a spatial diagram of a sleeve according to an embodiment of the present application;

[32] Fig. 6 shows a spatial diagram of an insulating base according to an embodiment of the present application;

[33] Fig. 7 is a spatial diagram of a heating element according to an embodiment of the present application;

[34] Fig. 8a is a diagram of assembly step I of a spray tube assembly according to an embodiment of the present application;

[35] Fig. 8b is a diagram of step II of the assembly of the spray tube assembly according to an embodiment of the present application;

[36] Fig. 8c is a diagram of assembly step III of the spray tube assembly according to an embodiment of the present application;

[37] Fig. 8d is a diagram of an assembly step IV of a spray tube assembly according to an embodiment of the present application.

Examples of the invention

[38] To facilitate understanding of the present application, a more detailed description thereof is provided below in combination with drawings and specific examples of the invention.

[39] It should also be noted that all directional indications (such as up, down, left, right, forward, backward, horizontal, vertical, etc.) in the embodiments of this application are used only to explain the relative positional relationship between the parts and the state of their movement in a certain position (as shown in the drawings); and when a specific position is changed, the directional indications are changed accordingly, and the said "connection" may be direct or indirect, and the said "set" and "set to" may be direct or indirect.

[40] Furthermore, the terms "first" and "second" as used in this application are used for descriptive purposes only and are not to be understood as indicating or implying relative importance or implicitly indicating the number of technical characteristics specified. Thus, features limited to "first" and "second" may explicitly or implicitly include at least one such feature.

[41] The present application provides an aerosol generating device that includes a liquid storage component, a tubular atomization unit, a power supply unit and other supporting units. In particular, the power supply unit mainly includes a battery and an inductive air flow switch unit, wherein the battery is electrically connected to the tubular atomization unit, thereby providing an electric drive for the tubular atomization unit. The liquid storage component can be formed as a part of the internal cavity of the body of the aerosol generating device, and can also be a separate liquid storage tank. The liquid matrix stored in the liquid storage component can enter the tubular atomization unit, and the tubular atomization unit can atomize the liquid matrix to generate an aerosol. Depending on the type of liquid matrix stored in the liquid storage component, the aerosol generating device can be divided into an electronic cigarette and a medical device. The liquid matrix stored in the electronic cigarette typically contains nicotine products. A liquid matrix stored in an aerosol generating device related to a medical device is atomized to produce an aerosol having a therapeutic effect on respiratory diseases.

[42] The aerosol generating device can be configured as two removable connection units, one of which is a nebulizer and the other is a power supply unit. Such an aerosol generating device is called an aerosol generating device with a replaceable nebulizer. In particular, the power supply unit includes a rechargeable element, inside which a control module can also be installed. The nebulizer mainly includes a nebulizer tubular unit and a liquid storage component; and when the liquid matrix has been used up, the service life of the nebulizer expires, and a new nebulizer can be connected to the power supply unit. In another embodiment, the aerosol generating device is configured as a whole, and the battery and the nebulizer tubular unit are housed inside the housing. Such an aerosol generating device is called a disposable aerosol generating device. The disposable aerosol generating device has a small volume and is easy to carry.

[43] As an example, the internal structure of a cylindrical disposable aerosol generating device is briefly described. Referring to Fig. 1, the aerosol generating device includes a housing 10, from an external point of view, one end of the housing 10 is provided with a substantially flattened mouthpiece 11, and the user's mouth contacts the mouthpiece 11 during use of the aerosol generating device, thus, in a preferred embodiment of the invention, the mouthpiece 11 will be made of a material with a high level of safety. According to an alternative embodiment of the invention, the mouthpiece 11 and the housing 10 can also be formed as a single piece. A lower cover 12 is connected to the other end of the housing 10. The components inside the housing 10 are generally installed through the other open end of the housing 10, and after completion of the installation, the lower cover 12 is connected to the open end of the housing 10.

[44] A spray tube unit 20, a battery 51, an inductive air flow switch 52 and other components are installed inside the housing 10. A part of the internal cavity of the housing 10 serves as a liquid cavity 13 for storing a liquid matrix. The liquid cavity 13 is formed by a separate liquid storage tube 131 located inside the housing 10. The internal part of the liquid storage tube 131 is filled with a capillary element having excellent liquid storage properties, and the liquid matrix is stored inside the capillary element. In particular, the capillary element includes fibrous cotton. Further, the spray tubular unit 20 is disposed in the inner cavity of the liquid storage tube 131, and the capillary member is disposed around the spray tubular unit 20. The upper end cover 141 and the lower end cover 142 are respectively connected to both ends of the liquid storage tube 131. The upper end cover 141 and the lower end cover 142 are connected to the liquid storage tube 131 by means of a thread.

[45] Part of the mouthpiece 11 is located in the internal cavity of the housing 10; at one end of the mouthpiece 11, a neck 110 is provided; one end of the mouthpiece 11, located in the internal cavity of the housing 10, is fixed to the upper end cover 141, and in the internal part of the mouthpiece 11 there is an outlet cavity 111 connected to the neck 110. At one end of the tubular spray unit 20, an outlet tube 15 is provided; a portion of the outlet tube 15 extends longitudinally inside the liquid storage tube 131 and passes through the upper end cap 141, and the outlet end of the outlet tube 15 is connected to the outlet cavity 111 inside the mouthpiece 11. The aerosol generated in the tubular spray unit 20 can enter the outlet tube 15 and is directed to the mouthpiece 11 through the outlet tube 15, and then into the neck 110 for inhalation by the consumer. The other end of the tubular spray unit 20 is fixed to the lower end cap 142. At least an inlet channel is formed by a portion of the lower end cap 142, and outside air enters the inner cavity of the tubular spray unit 20 through the inlet channel.

[46] In the disposable aerosol generating device, the inner cavity of the upper part of the housing 10 contains the spray tubular unit 20 and the liquid storage tube 13, and the inner cavity of the lower part of the housing 10 mainly contains the battery 51 and the inductive air flow switch 52. The spray tubular unit 20 is electrically connected to the battery 51 and the inductive air flow switch 52. The open end of the housing 10, located at a distance from the mouthpiece 11, is designed to facilitate the installation of such components as the liquid storage tube 13, the battery 51, etc. A lower cover is installed on the open end of the housing 10 after completing the components inside the housing 10. The inductive air flow switch 52 is installed on the lower cover 12; an air inlet is provided on the lower cover 12, and outside air enters the inner cavity of the housing 10 through the air inlet.

[47] Referring to Fig. 2-7, the spray tubular unit 20 includes a sleeve 21, an insulating base 22, a heating element 23 and a liquid-conducting element 24. In particular, the heating element 23 includes a heated portion 231 and a conductive portion 232, wherein the conductive portion 232 is used for electrical connection with a power supply unit to facilitate the supply of electric power to the heated portion 231. In one example, referring to Fig. 7, the heated portion 231 preferably uses a heating plate having a mesh structure, and two conductive portions 232 are provided at both ends of the heating plate, i.e. a first conductive portion 233 and a second conductive portion 234. The conductive portion 232 includes a conductive pin 2321 and a conductive terminal 2322, wherein the outer portion of the conductive pin 2321 is covered with an insulating shell to form the conductive terminal 2322. The heating plate includes two free sides, respectively, a first free side and a second free side. The heating plate is surrounded in the form of an open tubular structure; the two free sides of the heating plate are connected to two conductive pins 2321, wherein the first conductive pin is connected to the first free side of the heating plate, and the second conductive pin is connected to the second free side of the heating plate. A certain distance is provided between the two free sides of the heating plate to prevent a short circuit caused by the collision of the first conductive pin with the second conductive pin.

[48] The sleeve 21 has a hollow accommodation cavity 211; the heated portion 231 of the heating element 23 is arranged inside the accommodation cavity 211; one portion of the conductive portion 232 is arranged inside the accommodation cavity 211; the other portion of the conductive portion 232 extends toward the outer side of the accommodation cavity 211. In particular, one portion of the conductive portion 232 extending toward the outer side of the accommodation cavity 211 is mainly formed as a conductive terminal 2322 for preventing a short circuit caused by a collision of the conductive portion 232 with other metal parts or a collision of two conductive portions 232 with each other. The first conductive portion 233 includes a first conductive terminal 2331, and the second conductive portion 234 includes a second conductive terminal 2341.

[49] An insulating base 22 is connected to the other end of the sleeve 21, wherein the insulating base 22 is preferably made of a plastic material. On the insulating base 22, a perforated hole 221 is provided for fixing the first conductive terminal 2331 and the second conductive terminal 2341 of the heating element 23. In one example of the present application, only one perforated hole 221 is provided on the insulating base 22. In particular, the first conductive terminal 2331 and the second conductive terminal 2341 can be inserted into the perforated hole 221 in a relatively vertical and free state without bending or pulling outward from the two free sides of the heated part 231. In particular, the distance between the first conductive terminal 2331 and the second conductive terminal 2341 does not exceed the distance between the two free sides of the heating plate, so that the main part of the heating plate is in a free state in the process of fixing the first conductive terminal 2331 and the second conductive terminal 2341. In a preferred embodiment of the invention, the distance between the first the conductive terminal 2331 and the second conductive terminal 2341 is equal to the distance between the two free sides of the heating plate, so that secondary positioning relative to the main part of the heating plate is not required in the process of fixing the first conductive terminal 2331 and the second conductive terminal 2341, and that the relative position between the main part of the heating plate and the liquid conductive element 24 can be set in accordance with a predetermined operation. It should be understood that if the distance between the first conductive terminal 2331 and the second conductive terminal 2341 exceeds the distance between the two free sides of the heating plate, then secondary positioning relative to the heated portion 231 of the heating plate is required during the assembly process of the first conductive terminal 2331 and the second conductive terminal 2341, for example, the first conductive terminal 2331 and the second conductive terminal 2341 are bent and then fixed on the inner side of the perforated hole 221 of the insulating base 22. The secondary positioning of the first conductive terminal 2331 and the second conductive terminal 2341 of the heating plate generates an outwardly expanding voltage on the heated portion 231 of the heating plate, which leads to a distortion of the fixed shape of the heating plate, which affects the effect of transferring the liquid matrix between the liquid conductive element 24 and the heating element 23, and also affects the local resistance of the heated portion 231 heating element 23, thereby affecting the uniformity of the heating efficiency of the heating plate as a whole.

[50] The insulating base 22 is provided with a flange 222 extending around the circumference, wherein the flange 222 divides the insulating base 22 into two sections; the first section, located above the flange 222, can be placed in the cavity for placing 211 of the sleeve 21, and the outer part of the second part, located under the flange 222, is provided with a fixing ring 25. In some embodiments, the fixing ring 25 is riveted to the outer wall of the second section of the insulating base 22, so that the conductive terminal 2322, when compressed, can be securely located inside the perforated hole 221 of the insulating base 22 without shaking. In other examples, after the first conductive terminal 2331 and the second conductive terminal 2341 are located inside the perforated hole 221 of the insulating base 22, the first conductive terminal 2331 and the second conductive terminal 2341 may also be firmly located inside the perforated hole 221 using adhesive.

[51] A through hole 223 is provided on the insulating base 22, and the through hole 223 is connected to the housing cavity 211 of the sleeve 21, so that the external air flow can penetrate into the inside of the spray tubular unit 20 through the through hole 223 of the insulating base 22. In a preferred embodiment of the invention, a perforated hole 221 is provided on one side of the through hole 223, and the size of the perforated hole 221 is determined so as to accommodate two conductive terminals 2322. Specifically, a raised protruding rib 224 is provided on one side of the insulating base 22, and the perforated hole 221 is formed by the inner space of the protruding rib 224. The raised height of the protruding rib 224 is mainly determined depending on the inner diameter of the perforated hole 221. The protruding rib 224 is mainly composed of two sections: the first section of the protruding rib 224 is provided above the flange 222, and the second section of the protruding rib 224 is provided below the flange 222.

[52] The perforated hole 221 and the through hole 223 are provided inside the insulating base 22, and extend along the longitudinal direction of the insulating base 22 by substantially the same distance, so that the perforated hole 221 is located near the through hole 223. In a preferred embodiment of the invention, the projection region along the axial direction of the through hole 223 can substantially coincide with the projection region along the axial direction of the open tubular space formed by the heated portion 231 of the heating element 23, and the perforated hole 221 in the longitudinal direction is substantially aligned with an intermediate region between two free sides of the heated portion 231 of the heating element 23, so that the conductive portion 232 of the heating element 23 can be maintained in a relatively vertical state and inserted directly into the perforated hole 221. To facilitate the penetration of the conductive terminal 2322 into the perforated hole 221 and its fixation inside the perforated hole 221, between the perforated hole 221 and the through hole 223 only a dividing wall 225 is provided, and a part of the conductive terminal 2322 located above the dividing wall 225 can enter the inside of the perforated hole 221 in a relatively free state, and the dividing wall 225 provides support for the conductive terminal 2322, so that the conductive terminal 2322 can remain relatively vertical and is fixed inside the perforated hole 221. In order to facilitate the penetration of the terminal, two notches are provided at the lower end of the perforated hole 221 of the insulating base 22, which are located on both sides of the protruding rib 224 and under the flange 222. In order to avoid this, so the lower end of the conductive wire 2322 is not fixed securely and thus interferes with the positioning of the heated part 231 of the heating element 23, after After the conductive terminal 2322 is brought out from the perforated hole 221, the fixing ring 25 is riveted to the lower end of the flange 222 of the insulating base 22, so that the conductive terminal 2322 can be securely located inside the perforated hole 221. Due to the presence of the fixing ring 25, the conductive terminal 2322 no longer needs to be fixed inside the perforated hole 221 with glue, which makes the work simpler and more convenient.

[53] In a preferred embodiment of the invention, the heated portion 231 of the heating element 23 forms a nearly open tubular spray cavity, the central axis of the spray cavity, the central axis of the cavity for accommodating 211 of the sleeve 21 and the central axis of the through hole 223 of the insulating base 22 coincide. When installing the tubular spray unit 20, the central axial direction can be accurately positioned using a rod wrapped with cotton. The outer diameter of the rod wrapped with cotton is equal to the inner diameter of the through hole 223 of the insulating base 22.

[54] The liquid-conducting element 24 is preferably made of fibrous cotton, and during installation, the liquid-conducting element 24 is located along the periphery of the heating element 23. In some embodiments of the invention, the liquid-conducting element 24 includes a plurality of liquid-conducting cottons, and after folding the plurality of liquid-conducting cottons, the liquid-conducting cottons surround the outer periphery of the heating element 23, and two free sides of the liquid-conducting cottons have been collected to form a convex structure 241 through which the liquid-conducting element 24 is fixed. In another embodiment of the invention, the liquid-conducting element 24 is a liquid-conducting block of a certain thickness, wherein the liquid-conducting element 24 has a hollow internal cavity, and the heating element 23 is fixed in the internal cavity of the liquid-conducting element 24. The side portion of the liquid-conducting block has a convex structure 241, which also facilitates the fixing of the liquid-conducting element 24.

[55] In order to facilitate fixing the liquid-conducting element 24 of a certain thickness inside the sleeve 21, a U-shaped hole 212 is provided in the sleeve 21, so that the liquid-conducting element 24 can be inserted into the sleeve 21 through the side portion of the U-shaped hole 212, and then the convex structure 241 on the liquid-conducting element 24 is fixed on the U-shaped hole 212, and the liquid-conducting element 24 is connected to the liquid cavity 13. The sleeve 21 has an oppositely located first end portion and a second end portion, wherein the insulating base 22 is fixed to the second end portion of the housing 21, and the U-shaped hole 212 extends in the longitudinal direction to the second end portion of the sleeve 21. In some embodiments, referring to FIG. 5, the sleeve 21 has an oppositely located first opening 2121 and a second opening 2122, wherein the first opening 2121 and the second opening 2122 are configured in such a way that the second end of the sleeve 21 can be opened at a certain angle so that the sleeve 21 can be placed directly on the outer side of the liquid-conducting element 24.

[56] The upper end of the liquid-conducting element 24 is longitudinally fixed to the end portion of the U-shaped opening 212 of the sleeve 21, and the lower end of the liquid-conducting element 24 is longitudinally fixed to the upper end portion of the protruding rib 224 of the insulating base 22. The width of the protruding rib 224 of the insulating base 22 is equal to the width of the opening 212 of the sleeve 21. The length of the U-shaped opening 212 of the sleeve 21, extending along the longitudinal direction, is determined in such a way as to fix the convex structure 241 of the liquid-conducting element 24 and the first section of the protruding rib 224 of the insulating base 22.

[57] One embodiment of the present application also provides a method for assembling a spray tube assembly 20 with reference to Figs. 8a-8d:

[58] The first step: the plate heating element 23 is placed on the liquid-conducting element 24, then the rod wrapped with cotton 30 is placed on the heating element 23, and the liquid-conducting cotton is wrapped by hands around the rod wrapped with cotton to form a first knot, as shown with reference to Fig. 8a; in particular, the heating element 23 is located in the middle of the liquid-conducting element 24; the rod wrapped with cotton has a sufficiently large size that the heating element 23 can only partially wrap around the rod wrapped with cotton 30, and the conductive portions 232 on both sides of the heating element 23 can be attached to the rod wrapped with cotton 30.

[59] Second step: the first assembly is inserted from the U-shaped opening of the sleeve 21 until the convex structure 241 of the liquid-conducting element 24 snaps into the U-shaped opening 212 of the sleeve 21, forming the second assembly, as shown with reference to Fig. 8b;

[60] Third step: the convex structure 241 on the liquid-conducting element 24 of the second assembly is aligned with the protruding rib 224 of the insulating base 22 until the end portion of the second assembly is fixed on the flange 222 of the insulating base 22, forming a third assembly, as shown with reference to Fig. 8c;

[61] The fourth step: the fixing ring 25 is riveted to the insulating base 22 of the assembly 3, as shown with reference to Fig. 8d; in particular, the fixing ring 25 compresses the insulating base 22 during the riveting process, compressing the conductive terminal 2322, so that the conductive terminal 2322 is firmly located inside the perforated hole 221.

[62] And since each operation is mainly determined by the structure of the component itself, a fully automated assembly can be realized, and a fixing hole 215 can be provided on the sleeve 21 to facilitate fixation with a clamping device for automated assembly.

[63] After the assembly, the spray tube unit 20 is installed in the liquid storage tube 131 inside the body 10. After the inside of the liquid storage tube 131 is replenished with a sufficient amount of the liquid matrix, the rod wrapped with cotton 30 is removed. During the assembly of the spray tube unit 20, the heated portion 231 of the heating element 23 is always wrapped around the rod wrapped with cotton 30, and the rod wrapped with cotton 30 can provide a radial holding force of the heating element 23, allowing the position of the heating element 23 to remain relatively stable.

[64] The liquid-conducting element 24 is connected to the liquid matrix in the liquid storage tube through the first opening 2121 and the second opening 2122 on the sleeve 21. In some examples, a separate liquid inlet opening 213 is further provided on the sleeve 21, located between the first opening 2121 and the second opening 2122, to further increase the contact path of the liquid matrix with the liquid-conducting element 24. For a liquid matrix with poor flowability, a plurality of liquid inlet openings 213 can be provided on the sleeve 21.

[65] The conductive terminal 2322 of the tubular spray unit 20 can be electrically connected directly to the battery 51 and the inductive air flow switch 52, located inside the housing 10 of the aerosol generating device. It should be understood that the tubular spray unit 20 can also be used in an aerosol generating device with a replaceable atomizer. The tubular spray unit 20 is mounted on the atomizer, and an electrode column is provided on the lower cover 12 of the atomizer, and two conductive terminals 2322 of the tubular spray unit 20 are electrically connected to the electrode column.

[66] When the sleeve 21 of the tubular spray unit 20 has a sufficient length, the heating element 23 and the liquid-conducting element 24 are located in one part of the space of the sleeve 21, and an outlet channel is formed in the other part of the space of the sleeve 21, and the other end of the sleeve 21 extends into the outlet cavity 111 of the mouthpiece 1, which makes it possible to direct the aerosol to the neck 110. When the length of the sleeve 21 of the tubular spray unit 20 is short, an outlet tube 15 can be connected to one end of the sleeve 21. In particular, the outlet tube 15 can be fixed on the outer side of the sleeve 21, and the outlet tube 15 can also be inserted into the inner cavity of the sleeve 21.

[67] In the above example, the heating element 23 is formed as a heating plate; the liquid-conducting element 24 is arranged around the heating element 23; the heating element 23 and the liquid-conducting element 24 are fixed in the inner cavity of the sleeve 21 along the longitudinal direction of the housing 10; the conductive terminal 2322 of the heating element 23 is fixed to the insulating base 22 at the lower end of the sleeve 21. A perforated hole 221 is provided on the insulating base 22, in which two conductive terminals 2322 can be simultaneously placed, and the two conductive terminals 2322 can be inserted into the perforated hole 221 in a relatively free state without bending; the fastening of the conductive terminal 2322 does not create a pulling force on the housing of the heating element 23 itself, which makes it possible to fix the heating element 23 inside the liquid-conducting element 24 in a predetermined manner. In other examples, the heating element 23 can be made in the form of a heating wire that is wound around a substantially rod-shaped liquid-conducting element 24, wherein the conductive pin 2321 is connected to both ends of the heating wire, and the conductive pin 2321 is fixed to the insulating base 22 at the lower end of the sleeve 21 by means of the conductive terminal 2322. Alternatively, the liquid-conducting element 24 can be made in the form of a ceramic tube, and the heating element 23 is fixed in the internal cavity having a ceramic tube, in the form of a heating wire or a heating plate.

[68] It should be noted that the description and drawings of this application provide the best embodiments of the invention, but are not limited to the embodiments described in the description; further, specialists in this field can make various modifications and changes to this application, but all such modifications and changes must be within the scope of protection of this application.

Claims (22)

1. A tubular spray unit of an aerosol generating device, characterized in that it comprises: a heating element that consists of a heated part and a conductive part electrically connected to the heated part; the conductive part comprises a first conductive part and a second conductive part, and the heated part is connected between the first conductive part and the second conductive part; a sleeve having a hollow accommodation cavity; a heated portion located inside the accommodation cavity and at least one conductive portion extending toward the outside of the accommodation cavity; and an insulating base connected to one end of the sleeve; the insulating base includes one perforated hole, and the first conductive portion and the second conductive portion are fixed to the insulating base through the perforated hole. 2. The unit according to item 1, characterized in that it additionally contains a retaining ring surrounding the outer part of the insulating base. 3. The unit according to item 1 or 2, characterized in that the heated part contains a heating plate having a mesh structure, and the heated part is made in the form of an open tubular structure. 4. The unit according to item 3, characterized in that the first conductive part contains a first conductive terminal, and the second conductive part contains a second conductive terminal; the first conductive terminal and the second conductive terminal are fixed on an insulating base, and the distance between them does not exceed the distance between the two free sides of the heating element. 5. The unit according to item 4, characterized in that between the two free sides of the heated part there is an intermediate region, and the perforated hole is aligned with the intermediate region in the longitudinal direction. 6. The unit according to item 1, characterized in that at least one U-shaped hole is provided on the side of the sleeve. 7. The unit according to claim 6, characterized in that it includes a first U-shaped opening and a second U-shaped opening separated from each other; between the first U-shaped opening and the second U-shaped opening, at least one opening for inlet of liquid is also provided. 8. The unit according to item 6, characterized in that the insulating base is provided with a protruding rib, and the protruding rib has a size that allows it to be inserted into a U-shaped opening. 9. The unit according to item 8, characterized in that the protruding rib is located in a position corresponding to a perforated hole on the outer surface of the insulating base. 10. The unit according to item 1, characterized in that the insulating base additionally has a through hole; the through hole is located coaxially together with the accommodation cavity. 11. The unit according to item 10, characterized in that the perforated hole is provided on one side of the through hole, and a dividing wall is provided between the through hole and the perforated hole. 12. The assembly according to claim 6, characterized in that it also comprises a liquid-conducting element at least partially located around the heating element, wherein the liquid-conducting element includes a convex structure located in the U-shaped opening. 13. The unit according to claim 1 or 8, characterized in that it also comprises a liquid-conducting element at least partially located around the heating element, wherein the liquid-conducting element is fixed to the insulating base in the longitudinal direction. 14. The unit according to claim 13, characterized in that the liquid-conducting element has a convex structure, and the protruding rib has a size that allows for the placement of at least a portion of the convex structure of the liquid-conducting element and the protruding rib of the insulating base. 15. The unit according to item 1 or 2, characterized in that the insulating base comprises a flange, wherein one end of the flange is secured to the bushing. 16. The unit according to item 15, characterized in that the retaining ring is secured to the other end of the flange. 17. A method for assembling a tubular spray unit of an aerosol generating device according to any one of claims 1 to 16, characterized in that it includes forming a first unit by winding a heating element and a liquid-conducting element onto a rod; inserting the first unit from one end of a sleeve into a placement cavity; connecting an insulating base to the same end of the sleeve, wherein two conductive parts of the heating element are placed in a perforated hole of the insulating base. 18. The method according to item 17, characterized in that it additionally includes riveting the fixing ring to the insulating base. 19. An aerosol generating device, characterized in that it comprises a housing, inside which a liquid cavity is provided for storing a liquid matrix and a tubular spray unit, wherein the tubular spray unit includes a tubular spray unit according to any one of claims 1 to 16, and the tubular spray unit is capable of spraying a liquid matrix to generate an aerosol.