WO2023207677A1 - Atomizer - Google Patents

Abstract

An atomizer, comprising an e-liquid cup (10), and a bottom assembly (20) which is assembled at one end of the e-liquid cup (10) and forms an e-liquid storage cavity (100) with the e-liquid cup (10), wherein the bottom assembly (20) comprises a base (1) and at least two vertical or inclined heating assemblies (2), an atomization gas channel (200) is formed in the bottom assembly (20), an e-liquid intake channel is formed between an outer side wall of the base (1) and an inner wall of the e-liquid cup (10), the outer side wall of the base (1) is provided with an e-liquid intake hole (122) in communication with the e-liquid intake channel, the width of the e-liquid intake hole (122) gradually decreases towards the bottom end of the base (1), and the e-liquid intake hole (122) provides atomized e-liquid in the e-liquid storage cavity (100) to the heating assemblies (2) through the e-liquid intake channel. The speed at which the atomized e-liquid permeates into the heating assemblies (2) is uniform, and the smooth guiding of e-liquid can be ensured, so that the atomization effect is improved, and the taste is better.

Description

an atomizer

Cross-references to related applications

This application claims priority to Chinese patent applications with application number 202210441820.9 filed with the Chinese Patent Office on April 25, 2022 and application number 202220975652.7 filed with the Chinese Patent Office on April 25, 2022, the entire contents of which are incorporated into this application by reference.

Technical field

The present application belongs to the field of electronic atomization technology, and particularly relates to an atomizer.

Background technique

Electronic atomization equipment is a device that atomizes atomized liquid to form aerosol. In related technologies, the atomizer in electronic atomization equipment usually includes an oil cup, a heating component and a bracket. The oil cup and bracket are enclosed together. A liquid storage chamber is formed, and the heating component is assembled in the bracket. The bracket is provided with a lower oil hole to guide the atomized liquid in the liquid storage chamber to the heating component.

However, in the related art, the lower oil hole is usually opened vertically inside the bracket, and the atomized liquid is introduced into the heating component from the top. The applicant's research found that if the lower oil hole in this arrangement is used for atomization when the heating component is placed vertically, In the device, the atomized liquid cannot be supplied to the heating components smoothly and evenly, which may easily lead to dry burning, burnt smell, blackening and other undesirable conditions in some parts of the heating components, while other parts are prone to leakage due to excessive oil conduction, resulting in The fried oil or atomized liquid is not sufficiently atomized and is sucked into the mouth.

technical problem

The oiling method in the related art cannot supply atomized liquid to the heating components smoothly and evenly, which can easily cause some parts of the heating components to suffer from dry burning, burnt smell, blackening and other undesirable conditions, while other parts are prone to leakage due to too fast oil transfer. liquid, the oil will explode, or the atomized liquid will be sucked into the mouth due to insufficient atomization.

Technical solutions

The technical problem to be solved by this application is to provide an atomizer to solve the deficiencies in the related technology to at least a certain extent.

The present application provides an atomizer, including an oil cup and a bottom assembly assembled on one end of the oil cup and forming a liquid storage chamber with the oil cup. The bottom assembly includes a base installed on the oil cup and a vertical assembly. At least two heating components are assembled straightly or obliquely on the base. The bottom component is formed with an atomization air channel located on one side of the heating component. A gap is formed between the outer wall of the base and the inner wall of the oil cup. Liquid inlet channel, the outer wall of the base is provided with a liquid inlet hole connected to the liquid inlet channel, the width of the liquid inlet hole gradually decreases toward the bottom end of the base, the liquid inlet hole passes through the liquid inlet channel The channel provides the atomized liquid in the liquid storage chamber to the heating component.

beneficial effects

This solution guides the atomized liquid in the liquid storage chamber to the liquid inlet hole through the liquid inlet channel formed between the outer wall of the base and the inner wall of the oil cup, and then supplies the atomized liquid to the heating component through the liquid inlet hole. Since the heating component is vertical Or set it at an angle, and the width of the liquid inlet hole gradually decreases toward the bottom of the base, so that the oil supply volume at the upper end of the liquid inlet hole is large, and the oil supply volume at the lower end gradually decreases, and the speed of the atomized liquid penetrating into the heating component is more uniform. And it can ensure smooth liquid conduction, improve atomization effect, and taste better.

Description of drawings

Figure 1 is a schematic three-dimensional exploded structural diagram of an atomizer in an embodiment of the present application;

Figure 2 is a schematic diagram of the effect of the atomizer in the embodiment of the present application when viewed by the user in the front direction;

Figure 3 is a cross-sectional view of the atomizer in the first direction according to the embodiment of the present application;

Figure 4 is a cross-sectional view of the atomizer in the second direction according to the embodiment of the present application;

Figure 5 is a schematic structural diagram of the oil cup of the atomizer in the embodiment of the present application in the upward direction;

Figure 6 is a schematic diagram of the return air path of the atomizer in the embodiment of the present application.

In the drawings, each reference number indicates: 100. Liquid storage chamber; 200. Atomization airway; 10. Oil cup; 20. Bottom assembly; 101. Air guide tube; 102. Bone position; 103. Seal; 1 , Base; 2. Heating component; 3. Air channel parts; 4. Electrode; 5. Sealing ring; 11. Base body; 12. Bracket; 111. Air inlet; 115. Giving way cavity; 116. Air return groove ; 121. Liquid inlet groove; 122. Liquid inlet hole; 1221. First hole wall; 1222. Second hole wall; 1223. Bottom wall; 21. Oil conductor; 22. Heating element.

Embodiments of the invention

The embodiments of the present application are described in detail below. Examples of the embodiments are shown in the accompanying drawings, wherein the same or similar reference numerals throughout represent the same or similar elements or elements with the same or similar functions. The embodiments described below with reference to the accompanying drawings are illustrative and are intended to be used to explain the present application and cannot be understood as limitations of the present application. Based on the embodiments in the present application, those of ordinary skill in the art will not make creative efforts without premise All other embodiments obtained below belong to the protection scope of this application.

In the description of this application, it needs to be understood that the terms "center", "longitudinal", "transverse", "length", "width", "thickness", "upper", "lower", "front", " "Back", "Left", "Right", "Vertical", "Horizontal", "Top", "Bottom", "Inside", "Outside", "Clockwise", "Counterclockwise", "Axis", " The orientation or positional relationship indicated by "circumferential", "radial", etc. is based on the orientation or positional relationship shown in the drawings. It is only for the convenience of describing the present application and simplifying the description, and does not indicate or imply that the device or element referred to must be Having a specific orientation, being constructed and operating in a specific orientation, and therefore should not be construed as limiting the application.

In addition, the terms “first” and “second” are used for descriptive purposes only and cannot be understood as indicating or implying relative importance or implicitly indicating the quantity of indicated technical features. Therefore, features defined as "first" and "second" may explicitly or implicitly include one or more of these features. In the description of this application, "plurality" means two or more than two, unless otherwise explicitly and specifically limited.

Referring to Figures 1-4, the embodiment of the present application discloses an atomizer, including an oil cup 10 and a bottom assembly 20 assembled at one end of the oil cup 10 and forming a liquid storage chamber 100 with the oil cup 10. The bottom assembly 20 includes The base 1 installed on the oil cup 10 and at least two heating components 2 installed vertically or obliquely on the base 1, the bottom component 20 is formed with an atomization air passage 200 located on one side of the heating component 2, the outer wall of the base 1 and the oil A liquid inlet channel is formed between the inner walls of the cup 10, and the outer wall of the base 1 is provided with a liquid inlet hole 122 connected to the liquid inlet channel. The width of the liquid inlet hole 122 gradually decreases toward the bottom end of the base 1, and the liquid inlet hole 122 passes through the liquid inlet channel. The channel provides the atomized liquid in the liquid storage chamber 100 to the heating component 2 .

This solution guides the atomized liquid in the liquid storage chamber 100 to the liquid inlet hole 122 through the liquid inlet channel formed between the outer wall of the base 1 and the inner wall of the oil cup 10, and then provides the atomized liquid to the heating component 2 through the liquid inlet hole 122. , since the heating component 2 is arranged vertically or obliquely, and the width of the liquid inlet hole 122 gradually decreases toward the bottom end of the base 1, the oil supply volume at the upper end of the liquid inlet hole 122 is large, and the oil supply volume at the lower end gradually decreases, and the atomized liquid penetrates The speed into the heating component 2 is more uniform, and can ensure smooth liquid conduction, improve the atomization effect, and have a better taste.

Further, the liquid inlet hole 122 has a first hole wall 1221 and a second hole wall 1222 that are oppositely arranged and both extend toward the bottom end of the base 1; the first hole wall 1221 and the second hole wall 1222 may be curved surfaces or curved surfaces. Plane; in this embodiment, the first hole wall 1221 and the second hole wall 1222 are both planes, and the extension surface of the first hole wall 1221 toward one end of the base 1 and the extension surface of the second hole wall 1222 toward one end of the base 1 are one of The angle between them is 0-90°. That is to say, the first hole wall 1221 and the second hole wall 1222 jointly form an inverted trumpet shape, which can ensure the smoothness of oil discharge and prevent oil leakage.

Further, the height of the liquid inlet hole 122 along the axial direction of the atomizer is at least 1 mm, the first spacing dimension C between the bottom ends of the first hole wall 1221 and the second hole wall 1222 is minimum, and the first spacing dimension C ranges is 1-4 mm; the second spacing dimension B between the tops of the first hole wall 1221 and the second hole wall 1222 is the largest, and the ratio of the second spacing dimension B to the first spacing dimension C ranges from 1.2 to 5. Adopting such a size parameter setting can ensure the smooth flow of oil on the one hand, and on the other hand can gradually reduce the oil inlet rate at the lower end to match the rate at which the heating component 2 consumes atomized oil, thereby preventing oil leakage.

In this embodiment, each heating component 2 receives the atomized liquid in the liquid storage chamber 100 through two liquid inlet channels. Each liquid inlet channel is provided with a liquid inlet hole 122, that is, each heating component 2 receives the atomized liquid in the liquid storage chamber 100 through two liquid inlet holes. 122 receives the atomized liquid in the liquid storage chamber 100. At this time, the range of the first spacing dimension C is 1-3 mm, and the ratio range of the second spacing dimension B and the first spacing dimension C is 1.2-4. Specifically, the two-input The liquid channel is arranged symmetrically, and the liquid inlet hole 122 is located at the bottom end of the liquid inlet channel. Oil is supplied to a heating component 2 through the two liquid inlet channels, and the liquid inlet hole 122 is arranged at the bottom end, and the first hole wall 1221 faces one end of the base 1 The angle between the extension direction and the extension direction of the second hole wall 1222 toward one end of the base 1 is 0-45°, and, from the perspective of FIG. 2, the liquid inlet hole 122 in the liquid inlet groove 121 on the left side For example, the extension direction of the first hole wall 1221 is parallel to the axial direction of the base 1, and the included angle is 90°. That is, the first hole wall 1221 is arranged vertically, the second hole wall 1222 is arranged obliquely, and the liquid inlet hole 122 on the right is It is arranged symmetrically with the liquid inlet hole 122 on the left. Therefore, the bottom ends of the two liquid inlet holes 122 have a tendency to converge toward the middle. The atomized oil can be directed to the middle of the atomized oil, which can ensure the smoothness of the oil. Moreover, the mist Carburized oil will not remain in the liquid inlet channel, and the utilization rate is higher, which can improve the atomization effect. In some embodiments, each heating component 2 can receive the atomized liquid in the liquid storage chamber 100 through a liquid inlet channel. The liquid inlet channel can be provided with a liquid inlet hole 122, that is, each heating component 2 can receive the atomized liquid in the liquid storage chamber 100 through a liquid inlet hole. 122 receives the atomized liquid in the liquid storage chamber 100. At this time, the first spacing size range is 2-4mm, the ratio range of the second spacing size and the first spacing size is 1.25-2.5, and the first hole wall 1221 faces the base 1 The angle between the extension direction of one end and the extension direction of one end of the second hole wall 1222 toward the base 1 can be 0-60°. With this arrangement, when the atomized liquid in the liquid inlet channel is directed to the heating component 2 It is smoother and can ensure more fuel supply.

Further, the ratio of the length dimension of the liquid inlet hole 122 in the axial direction of the base 1 to the first spacing dimension C is greater than 1. In this embodiment, each heating component 2 receives the atomized liquid in the liquid storage chamber 100 through two liquid inlet channels. When each liquid inlet channel is provided with a liquid inlet hole 122, the liquid inlet hole 122 is located on the axis of the base 1. The ratio of the length dimension in the direction to the first spacing dimension may range from 1.5 to 2.0, thereby providing sufficient oil supply to the heating component 2 .

Furthermore, the liquid inlet hole 122 also has a bottom wall 1223 connected between the bottom ends of the first hole wall 1221 and the second hole wall 1222 , and the bottom wall 1223 is recessed toward the bottom end of the base 1 . Specifically, the two ends of the bottom wall 1223 are curvedly connected to the first hole wall 1221 and the second hole wall 1222 respectively. The bottom wall 1223 is inclined, and the connecting end of the bottom wall 1223 and the second hole wall 1222 is closer to the base 1 The bottom end, that is, the curved connection section equivalent to the bottom wall 1223 and the second hole wall 1222 is recessed toward the bottom end of the base 1, which can make the width of the bottom end of the liquid inlet hole 122 decrease faster, and the recess of the bottom wall 1223 The small width and low height can further reduce the oil supply rate at the bottom of the oil inlet hole, thereby reducing the risk of leakage. In some embodiments, it may also be configured such that the middle part of the bottom wall 1223 is recessed toward the bottom end of the base 1 .

It should be understood that the specific shapes of the first hole wall 1221, the second hole wall 1222 and the bottom wall 1223 are not limited. For example, the first hole wall 1221, the second hole wall 1222 and the bottom wall 1223 can all be plane; or, The first hole wall 1221, the second hole wall 1222 and the bottom wall 1223 may all be curved surfaces; or, part of the first hole wall 1221, the second hole wall 1222 and the bottom wall 1223 may be flat and the other part may be curved. When the first hole wall 1221 and/or the second hole wall 1222 are curved surfaces, the included angle between the extending surfaces toward the base 1223 at any position on the first hole wall 1221 and the second hole wall 1222 is between 0-90°.

Further, the first hole wall 1221 , the second hole wall 1222 and the bottom wall 1223 are flush with at least part of the side walls of the liquid inlet channel in the radial direction of the base 1 . That is, the shapes of the bottom of the liquid inlet hole 122 and the bottom end of the liquid inlet channel match, which is more conducive for the atomized liquid to flow from the liquid inlet channel into the liquid inlet hole 122 .

Further, the width of the liquid inlet channel gradually decreases toward the bottom end of the base 1 . Specifically, in this embodiment, the two side walls of the liquid inlet channel are coplanar with the first hole wall 1221 and the second hole wall 1222 respectively. The transition between the liquid inlet hole 122 and the liquid inlet channel is smoother and the oil conduction is smoother. More unobstructed. In some embodiments, the bottom end of the side wall of the liquid inlet channel can also be coplanar with the first hole wall 1221 and the second hole wall 1222 respectively. At the top of the liquid inlet hole 122, the side wall of the liquid inlet channel can face By bending outward, the end of the liquid inlet channel facing the liquid storage chamber 100 has a larger opening, further improving the smoothness of oil conduction.

In this application, the liquid inlet channel can have different structural forms. Preferably, the outer wall of the base 1 can be provided with a liquid inlet groove 121, and the projection of the liquid inlet hole 122 in its normal direction is located in the liquid inlet groove 121. , the liquid inlet groove 121 and the inner wall of the oil cup 10 together form a liquid inlet channel. In some embodiments, the inner wall of the oil cup 10 may be provided with a liquid inlet groove 121 . The liquid inlet hole 122 corresponds to the position of the liquid inlet groove 121 . The liquid inlet groove 121 and the outer wall of the base 1 together form a liquid inlet groove 121 . The channel, the position of the oil cup 10 and the liquid inlet groove 121 can form a convex structure. On the one hand, it can increase the space of the liquid storage chamber 100 and increase the oil storage capacity. On the other hand, it can be held and used by the user. More convenient.

Further, the oil cup 10 is made of transparent material, and the central axis of the liquid inlet hole 122 is perpendicular to the inner wall of the oil cup 10 toward which it faces. Therefore, the user can directly observe the liquid inlet hole 122 from the outside of the oil cup 10 and pass the liquid inlet. The working status of the heating component 2 is observed through the hole 122. When the amount of atomized liquid is low, or the oil supply is not smooth, or the heating component 2 is found to be faulty, the atomizer can be stopped in time to ensure the suction experience and health.

Further, the base 1 includes a base 11 assembled on the oil cup 10 and a bracket 12 assembled on the base 11. The heating component 2 is clamped and fixed by the base 11 and the bracket 12. The liquid inlet 122 is provided on the bracket 12, and the liquid inlet hole 122 is provided on the bracket 12. The channel is formed by the outer side of the bracket 12 and the inner side of the oil cup 10 .

Specifically, the base 1 includes two brackets 12 symmetrically arranged on opposite sides of the base 11. The bottom assembly 20 includes two heating components 2 corresponding to the two brackets 12. The two heating components 2 are respectively located opposite the base 11. On both sides, each heating component 2 is clamped and fixed to the base 11 by a corresponding bracket 12. Two liquid inlet grooves 121 are symmetrically provided on the side of each bracket 12 away from the base body 11. Each liquid inlet groove is Each slot 121 is provided with a liquid inlet 122. The heating component 2 includes an oil conductor 21 that is clamped and fixed to one side of the liquid inlet 122 by the base 11 and the bracket 12, and an oil conductor 21 attached to the oil conductor 21 away from the liquid inlet. The heating element 22 on one side of 122 and the oil conductor 21 cover the liquid inlet hole 122. Therefore, the two liquid inlet channels can smoothly and evenly provide atomized oil to the oil conductor 21 to improve the atomization effect. In some embodiments, one, three, four, etc. liquid inlet grooves 121 may also be provided on the same bracket 12 , and two, three, etc. liquid inlet grooves 121 may also be provided in the same liquid inlet groove 121 . Liquid hole 122 is used to increase the amount of oil supply. The specific setting can be adjusted according to the actual situation.

In this solution, the base 11 and the bracket 12 are arranged in a horizontal arrangement. Therefore, the airway member 3 is arranged in the base 11. It should be understood that in some implementations, the base 11 and the bracket 12 can also be arranged vertically. At this time, the bracket 12 can be assembled on the top of the base 11, and a receiving space is formed between the base 11 and the bracket 12. The airway member 3 and the heating component 2 can both be sandwiched by the base 11 and the bracket 12. Alternatively, the heating component 2 can be clamped and fixed by the base 11 and the bracket 12, and the airway member 3 is separately assembled on the base 11 or the bracket 12 and is located in the accommodation space, that is, the present application The specific arrangement form of the base 1 is not limited, as long as the airway member 3 is assembled on the base 1 .

The oil conductor 21 has a flat structure, and the heating element 22 has a sheet structure. The heating element 22 includes two conductive parts and a heating part connected in series between the two conductive parts. The two electrodes 4 are inserted through the base 11 and are respectively electrically connected to the two conductive parts.

The oil-conducting body 21 is a flat-shaped oil-absorbing cotton. The oil-absorbing cotton has a large amount of atomization, which makes the suction experience better and the aroma reduction degree of the atomized liquid is high. In this embodiment, the oil guide 21 and the bottom surface of the atomizer are 90°, that is, they are arranged vertically; in actual application, the angle range between the oil guide 21 and the bottom surface of the atomizer can be 60 to 120°, that is, the oil guide body 21 is tilted. It should be understood that the bottom surface of the above-mentioned atomizer is a plane perpendicular to the central axis of the atomizer.

A heating element 22 is connected to the opposite sides of the electrode 4 respectively. The heating element 22 can be a metal sheet formed by etching conductive metal. For example, it can be made of nickel-chromium parts, iron-chromium aluminum parts, stainless steel parts, etched or laser cut. It includes two conductive parts and a heating part connected in series between the two conductive parts. The resistance of the conductive part is much smaller than the heating part. Therefore, when the heating element 22 is energized and heated, the conductive part only generates a small amount of heat to concentrate the heat. in the heating area to ensure the atomization effect. The shape of the heating part is not particularly limited in this embodiment. For example, it can be grid-shaped, striped, S-shaped, polygonal, wavy, zigzag, spiral, circular or rectangular, as long as it can achieve flat heating. Can.

Further, with reference to Figures 4-5, the oil cup 10 includes an air guide tube 101 and a bone position 102 connected between the air guide tube 101 and the inner wall of the oil cup 10. The air guide tube 101 and the bone position 102 are both connected to the base 1. The oil cup The inner wall of 10, the base 1, the outer wall of the air guide 101 and the bone 102 together form at least two liquid storage chambers 100. Each liquid storage chamber 100 is independent of each other and corresponds to each heating component 2 one-to-one, and the liquid storage chamber 100 A liquid inlet channel is provided between the heat-generating component 2 and the corresponding heating component 2 .

Specifically, the base 1 has an air inlet 111, the oil cup 10 has an air outlet, the seat 11 has a relief cavity 115, the relief cavity 115 has at least two relief openings, and the relief cavity 115 is equipped with an airway. Part 3. The heating component 2 is assembled on the opposite side of the base 11 to the airway part 3. The heating component 2 and the airway part 3 form an atomizing airway 200 that communicates with the air inlet 111 and the air outlet. The atomized gas The cross-sectional area of the channel 200 gradually increases from the end close to the air inlet 111 toward the air outlet, that is, each heating component 2 corresponds to an independent atomization air channel 200.

Therefore, different types of atomized liquids can be injected into different liquid storage chambers 100, and the atomized liquid in the corresponding liquid storage chamber 100 is guided to the corresponding heating component 2 through the lower liquid channel and the liquid inlet hole 122 for atomization, forming a The aerosols enter the corresponding atomization airway 200, that is, each atomization airway 200 can form aerosols of different flavors. After that, the aerosols in the different atomization airways 200 are merged together for the user to inhale. , you can get a mixed flavor smoking experience, making the user experience richer.

In addition, since each atomizing air channel 200 is provided with a corresponding heating component 2, the atomized liquid in the oil cup 10 can be separately atomized by the heating components 2 on both sides and formed in the corresponding atomizing air channel 200. For aerosols, the atomization processes in the two atomization airways 200 do not interfere with each other. After that, the aerosols in the two atomization airways 200 merge together, which can double the TPM (Total Particulate Matter: total particulate matter), thus Improve the user's smoking experience.

Furthermore, in order to balance the negative pressure formed in the liquid storage chamber 100 during the consumption of atomized liquid, the base body 11 is provided with an air return groove 116 spaced apart from the lower liquid channel and connected to the liquid storage chamber 100 and the air inlet 111. Referring to Figure 6, in this embodiment, the air return groove 116 is disposed on the relief opening side of the seat 11, and is enclosed with the oil guide body 21 to form an air return channel. The air return channel can connect the corresponding liquid storage chamber 100 and the relief cavity. 115 is connected, specifically connected to the atomization air channel 200 corresponding to the position of the liquid storage chamber 100; moreover, the lower liquid channel and the return air channel are separated from each other through the physical part of the bracket 12, so that the gas does not need to pass through the lower liquid channel during ventilation. Liquid channel and oil inlet hole, the bubbles generated by ventilation will not be stuck by the atomized liquid, so that the atomized liquid can be discharged more smoothly, overcoming the shortcomings of setting the oil channel and the air return channel together.

Further, the distance A between the other end of the return air channel and the liquid inlet hole 122 is at least 0.8 mm. In this way, the liquid discharging and air exchange are separated, the air exchange will not affect the liquid dispensing at a moment, and there is no risk of bubbles getting stuck at the liquid inlet hole 122 . Moreover, in this solution, the air return groove 116 is located on the base 11 and the liquid inlet hole 122 is located on the bracket 12. The two are not on the same component, which can reduce the mutual influence between the two.

Further, the air guide tube 101 and the seat 11 are connected through a seal 103 to ensure sealing. The seal 103 can be made of silicone. The aerosol of each atomizing airway 200 collects at the connection between the air guide tube 101 and the seat 11. into one line, and is guided to the air outlet of the oil cup 10 through the air guide tube 101 for the user to draw; two bone positions 102 are provided between the outer wall of the air guide tube 101 and the inner wall of the oil cup 10 to separate the inner cavity of the oil cup 10 into symmetrical The two halves of the base body 11 are connected to the ends of the air guide tube 101 and the bone position 102, thereby forming two non-connected liquid storage chambers 100 together with the air guide tube 101, the bone position 102 and the side wall of the oil cup 10.

In some embodiments, a greater number of bone positions 102 can be provided in the oil cup 10 to divide the inner cavity of the oil cup 10 into three, four, five, etc. cavities. The oil cup 10 and the base 11 After assembly, three, four, or five liquid storage chambers 100 can be enclosed and formed, and the settings of the bone positions 102 can be adjusted adaptively according to actual needs. It should be understood that the shape and capacity of each liquid storage chamber 100 can be set to be the same or different, and are not limited here. In some embodiments, the inner cavity of the oil cup 10 can also be separated by providing a separator on the base 11 . For example, a sheet-shaped separator is provided on one end of the base 11 facing the inside of the oil cup 10 . 11 is assembled with the oil cup 10, the edge of the separator is sealingly connected to the inner wall of the oil cup 10 and the outer wall of the air guide tube 101, so as to divide the inner cavity of the oil cup 10 into multiple liquid storage chambers 100 that are not connected to each other, so that Provides a more flavorful smoking experience. In some embodiments, only one liquid storage chamber 100 can be provided. At this time, the atomized liquid in the liquid storage chamber 100 can flow to the heating component 2 through different lower liquid channels for atomization, and be atomized under different atomizing gases. Aerosols are formed in lane 200.

In the above embodiments, each embodiment is described with its own emphasis. For parts that are not described in detail in a certain embodiment, please refer to the relevant descriptions of other embodiments.

The above is a description of the technical solutions provided by this application. For those skilled in the art, there will be changes in the specific implementation methods and application scope based on the ideas of the embodiments of this application. In summary, the contents of this specification should not understood as a limitation on this application.

Claims (20)

1. An atomizer, characterized in that it includes an oil cup and a bottom assembly assembled on one end of the oil cup and forming a liquid storage chamber with the oil cup. The bottom assembly includes a base installed on the oil cup; At least two heating components are assembled vertically or obliquely on the base. The bottom component is formed with an atomization air channel located on one side of the heating component. Between the outer wall of the base and the inner wall of the oil cup A liquid inlet channel is formed. The outer wall of the base is provided with a liquid inlet hole connected to the liquid inlet channel. The width of the liquid inlet hole gradually decreases toward the bottom end of the base. The liquid inlet hole passes through the liquid inlet channel. The liquid channel provides the atomized liquid in the liquid storage chamber to the heating component.
2. The atomizer according to claim 1, wherein the liquid inlet hole has a first hole wall and a second hole wall that are oppositely arranged and both extend toward the bottom end of the base, and the first hole wall faces toward the bottom end of the base. The included angle between the extension surface of one end of the base and the extension surface of the second hole wall toward one end of the base is 0-90°.
3. The atomizer according to claim 2, characterized in that the first hole wall is a flat surface or a curved surface, and the second hole wall is a flat surface or a curved surface; when the first hole wall and/or the third hole wall is a flat surface or a curved surface, When the two hole walls are curved surfaces, the included angle between the extending surfaces of the first hole wall and the second hole wall toward the base at any position is 0-90°.
4. The atomizer according to claim 2, wherein the first distance between the bottom end of the first hole wall and the second hole wall is the smallest, and the first distance range is 1- 4mm, and the height of the liquid inlet hole along the axial direction of the atomizer is at least 1mm.
5. The atomizer according to claim 4, characterized in that the second spacing dimension between the top of the first hole wall and the second hole wall is the largest, and the second spacing dimension and the first The ratio of spacing dimensions ranges from 1.2-5.
6. The atomizer according to claim 5, characterized in that each of the heating components receives the atomized liquid in the liquid storage chamber through a liquid inlet hole, and the first spacing size range is 2-4mm, The ratio of the second spacing dimension to the first spacing dimension ranges from 1.25 to 2.5.
7. The atomizer according to claim 6, wherein the included angle between the extending direction of the first hole wall toward one end of the base and the extending direction of the second hole wall toward one end of the base is 0- 60°.
8. The atomizer according to claim 5, characterized in that each of the heating components receives the atomized liquid in the liquid storage chamber through two liquid inlet holes, and the first spacing size range is 1- 3mm, and the ratio range of the second spacing dimension and the first spacing dimension is 1.2-4.
9. The atomizer according to claim 4, wherein the liquid inlet hole further has a bottom wall connected between the bottom ends of the first hole wall and the second hole wall, and the bottom wall Recessed towards the bottom end of the base.
10. The atomizer according to claim 9, wherein the ratio of the length dimension of the liquid inlet hole in the axial direction of the base to the first spacing dimension is greater than 1.
11. The atomizer according to claim 10, characterized in that each of the heating components receives the atomized liquid in the liquid storage chamber through two liquid inlet channels, and each liquid inlet channel is provided with a As for the liquid inlet hole, the ratio of the length dimension of the liquid inlet hole in the axial direction of the base to the first spacing dimension ranges from 1.5 to 2.0.
12. The atomizer according to claim 2, wherein the width of the liquid inlet channel gradually decreases toward the bottom end of the base.
13. The atomizer according to claim 12, wherein the two side walls of the liquid inlet channel are coplanar with the first hole wall and the second hole wall respectively;

    Alternatively, the bottom end of the side wall of the liquid inlet channel is coplanar with the first hole wall and the second hole wall respectively, and the side wall of the liquid inlet channel faces the top of the liquid inlet hole. Bend outward.
14. The atomizer according to claim 12, wherein the outer wall of the base is provided with a liquid inlet groove, and the projection of the liquid inlet hole in its normal direction is located in the liquid inlet groove, so The liquid inlet groove and the inner wall of the oil cup together form the liquid inlet channel.
15. The atomizer according to claim 12, wherein the inner wall of the oil cup is provided with a liquid inlet groove, the liquid inlet hole corresponds to the position of the liquid inlet groove, and the liquid inlet groove and The outer walls of the base together form the liquid inlet channel.
16. The atomizer according to claim 12, wherein the base includes a base body assembled to the oil cup and a bracket assembled to the base body, and the heating component is composed of the base body and the base body. The bracket is clamped and fixed, the liquid inlet hole is provided on the bracket, and the liquid inlet channel is formed by the outer side of the bracket and the inner side of the oil cup.
17. The atomizer according to claim 16, wherein the base includes two brackets symmetrically arranged on opposite sides of the base body, and the bottom assembly includes two and two brackets corresponding to each other one by one. The two heating components are located on opposite sides of the base body. Each heating component is clamped and fixed to the base body by a corresponding bracket. The side of each bracket facing away from the base body Two liquid inlet grooves are symmetrically provided, and each liquid inlet groove 121 is provided with one liquid inlet hole.
18. The atomizer according to claim 17, characterized in that the heating component includes an oil guide body clamped and fixed to one side of the liquid inlet by the base body and the bracket, and an oil guide body attached to the liquid inlet hole. The heating element is on the side of the oil conductor away from the liquid inlet, and the oil conductor covers the liquid inlet.
19. The atomizer according to claim 18, characterized in that the oil conductor is a flat structure, the heating element is a sheet structure, and the gap between the oil conductor and the bottom surface of the atomizer is The included angle range is 60~120°.
20. The atomizer according to claim 1, characterized in that the oil cup is provided with a liquid storage chamber corresponding to each of the heating components and independent of each other, and the liquid storage chamber and the corresponding The liquid inlet channel is provided between the heating components.