WO2021134419A1 - 一种雾化装置 - Google Patents

一种雾化装置 Download PDF

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Publication number
WO2021134419A1
WO2021134419A1 PCT/CN2019/130370 CN2019130370W WO2021134419A1 WO 2021134419 A1 WO2021134419 A1 WO 2021134419A1 CN 2019130370 W CN2019130370 W CN 2019130370W WO 2021134419 A1 WO2021134419 A1 WO 2021134419A1
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WO
WIPO (PCT)
Prior art keywords
groove
component
protruding structure
main body
opening
Prior art date
Application number
PCT/CN2019/130370
Other languages
English (en)
French (fr)
Inventor
徐升阳
袁宜平
付家祺
Original Assignee
深圳雾芯科技有限公司
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by 深圳雾芯科技有限公司 filed Critical 深圳雾芯科技有限公司
Priority to PCT/CN2019/130370 priority Critical patent/WO2021134419A1/zh
Publication of WO2021134419A1 publication Critical patent/WO2021134419A1/zh

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    • AHUMAN NECESSITIES
    • A24TOBACCO; CIGARS; CIGARETTES; SIMULATED SMOKING DEVICES; SMOKERS' REQUISITES
    • A24FSMOKERS' REQUISITES; MATCH BOXES; SIMULATED SMOKING DEVICES
    • A24F40/00Electrically operated smoking devices; Component parts thereof; Manufacture thereof; Maintenance or testing thereof; Charging means specially adapted therefor
    • A24F40/10Devices using liquid inhalable precursors
    • AHUMAN NECESSITIES
    • A24TOBACCO; CIGARS; CIGARETTES; SIMULATED SMOKING DEVICES; SMOKERS' REQUISITES
    • A24FSMOKERS' REQUISITES; MATCH BOXES; SIMULATED SMOKING DEVICES
    • A24F47/00Smokers' requisites not otherwise provided for

Definitions

  • the present disclosure generally relates to an electronic device, and in particular, to a vaporization device that provides an aerosol.
  • an electronic cigarette is an electronic product that heats and atomizes an atomizable solution and generates an aerosol for users to inhale.
  • an electronic cigarette product includes a casing, an oil storage chamber, an atomization chamber, a heating component, an air inlet, an air flow channel, an air outlet, a power supply device, a sensing device, and a control device.
  • the oil storage chamber is used to store the atomizable solution
  • the heating component is used to heat and atomize the atomizable solution and generate aerosol.
  • the air inlet and the atomizing chamber communicate with each other, and provide air to the heating assembly when the user inhales.
  • the aerosol generated by the heating element is first generated in the atomization chamber, and then inhaled by the user through the air flow channel and the air outlet.
  • the power supply device provides the power required by the heating element, and the control device controls the heating time of the heating element according to the user's inhalation action detected by the sensing device.
  • the shell covers the above-mentioned components.
  • the existing electronic cigarette products have different defects.
  • the electronic cigarette product in the prior art may cause poor assembly yield in order to reduce the number of components.
  • the electronic cigarette products in the prior art may increase the manufacturing cost of the components in order to reduce the number of components.
  • the electronic cigarette products in the prior art may not consider the high temperature of the aerosol, which may cause a potential risk of burns to the user.
  • e-cigarette devices often have some restrictions on repetitive use, including: the need to replace or fill their e-liquid, complicated operations, e-liquid spills, burns, shortage of battery life, and high prices, etc., which are inevitable. Caused a bad user experience.
  • the present disclosure proposes an atomization device that can solve the above-mentioned problems.
  • the proposed atomization device includes an oil storage component and a main body.
  • the oil storage component includes a heating component, a supporting component, a sealing component and a heating component base.
  • the heating component is arranged between the first groove and the second groove of the supporting component. One end of the heating component is in direct contact with the sealing component.
  • the sealing component is arranged on the first part of the heating component base.
  • the heating element base includes a first protruding structure and a second protruding structure. The first protruding structure and the second protruding structure extend in a direction away from the heating element.
  • the proposed atomization device includes an oil storage assembly and a main body.
  • the oil storage component includes a shell, a heating component and a heating component base.
  • the main body includes battery components and sensor mounts.
  • the heating element base includes a first protruding structure and a second protruding structure. The first protruding structure and the second protruding structure extend in a direction away from the heating element.
  • the battery assembly is arranged between the heating assembly base and the sensor fixing base.
  • FIG. 1A and 1B illustrate exploded views of an atomization device according to some embodiments of the present disclosure.
  • FIGS. 2A and 2B illustrate exploded views of an atomization device according to some embodiments of the present disclosure.
  • FIG. 3A illustrates a perspective view of a sealed connection member according to some embodiments of the present disclosure.
  • Figure 3B illustrates a front view of a sealed connection according to some embodiments of the present disclosure.
  • Figure 3C illustrates a cross-sectional view of a sealed connection according to some embodiments of the present disclosure.
  • FIG. 4A illustrates a perspective view of a heating element base according to some embodiments of the present disclosure.
  • FIG. 4B illustrates a perspective view of a heating element base according to some embodiments of the present disclosure.
  • FIG. 5A illustrates a perspective view of a sensor fixing seat according to some embodiments of the present disclosure.
  • FIG. 5B illustrates a top view of the sensor mount according to some embodiments of the present disclosure.
  • FIG. 5C illustrates a bottom view of the sensor mount according to some embodiments of the present disclosure.
  • FIG. 5D illustrates a cross-sectional view of the sensor mount according to some embodiments of the disclosure.
  • FIG. 5E illustrates a cross-sectional view of the sensor mount according to some embodiments of the disclosure.
  • FIGS. 6A and 6B illustrate perspective views of the bottom cover according to some embodiments of the present disclosure.
  • FIG. 6C illustrates a top view of the bottom cover according to some embodiments of the present disclosure.
  • Figure 6D illustrates a bottom view of the bottom cover according to some embodiments of the present disclosure.
  • FIG. 6E illustrates a cross-sectional view of the bottom cover according to some embodiments of the present disclosure.
  • FIG. 6F illustrates a cross-sectional view of the bottom cover according to some embodiments of the present disclosure.
  • FIG. 7A illustrates a cross-sectional view of an atomization device according to some embodiments of the present disclosure.
  • FIG. 7B illustrates a cross-sectional view of an atomization device according to some embodiments of the present disclosure.
  • FIG. 8 illustrates a cross-sectional view of an atomization device according to some embodiments of the present disclosure.
  • FIG. 9A illustrates a schematic diagram of the air flow of the atomization device according to some embodiments of the present disclosure.
  • FIG. 9B illustrates a schematic diagram of the air flow of the atomization device according to some embodiments of the present disclosure.
  • first feature on or on the second feature may include embodiments in which the first feature and the second feature are formed in direct contact, and may also include additional features that may be formed on An embodiment between the first feature and the second feature so that the first feature and the second feature may not be in direct contact.
  • present disclosure may repeat reference numerals and/or letters in various examples. This repetition is for the purpose of simplification and clarity, and does not in itself indicate the relationship between the various embodiments and/or configurations discussed.
  • FIG. 1A and 1B illustrate exploded views of an atomization device according to some embodiments of the present disclosure.
  • the atomization device 100 may include an oil storage assembly 100A and a main body 100B.
  • the oil storage assembly 100A and the main body 100B can be designed as a whole.
  • the oil storage assembly 100A and the main body 100B can be designed to be inseparable from each other.
  • the oil storage assembly 100A and the main body 100B can be designed as two separate components.
  • the oil storage assembly 100A may be designed to be removably combined with the main body 100B.
  • the oil storage assembly 100A may be designed to be partially received in the main body 100B.
  • the oil storage assembly 100A may include a housing 1, a sealing connection member 2, a heating assembly 3, a supporting assembly 4, a sealing assembly 5, and a heating assembly base 6.
  • the housing 1 includes a mouthpiece 1m and an oil cup 1b.
  • the mouthpiece portion 1m and the oil cup portion 1b may be two separate components.
  • the mouthpiece portion 1m and the oil cup portion 1b may be integrally formed.
  • the inside of the cigarette holder portion 1m and the oil cup portion 1b may jointly define a cavity to store the atomizable liquid.
  • the liquid stored in the inner cavity of the cigarette holder portion 1m and the oil cup portion 1b may be referred to as e-liquid.
  • the mouthpiece portion 1m has an opening 1h1.
  • the opening 1h1 constitutes a part of the gas passage.
  • the aerosol generated by the atomizing device 100 can be ingested by the user through the hole 1h.
  • the mouthpiece portion 1m includes a cannula 1t, and the cannula 1t is connected to the opening 1h1.
  • the cannula 1t constitutes a part of the gas passage.
  • the sealing connector 2 may have a cylindrical shape.
  • the sealing connection member 2 may have a rectangular parallelepiped shape or other suitable shapes.
  • the sealed connector 2 includes an opening 2h penetrating the sealed connector 2.
  • the sealed connection member 2 includes grooves 2r1 and 2r2.
  • the inner side of the opening 2h may include one or more ring structures.
  • the annular structure inside the opening 2h may protrude from the inner surface of the opening 2h.
  • the annular structure inside the opening 2h can increase the sealing effect between the sealing connector 2 and the cannula 1t.
  • the grooves 2r1 and 2r2 can be arranged on both sides of the bottom of the sealing connector 2.
  • the grooves 2r1 and 2r2 can be used to install the heating element 3.
  • the grooves 2r1 and 2r2 can be used to fix the heating element 3.
  • the grooves 2r1 and 2r2 can directly contact the heating element 3.
  • the sealing connection member 2 may have a hardness between 65 and 75. In some embodiments, the sealing connection member 2 may have a hardness between 75 and 85. In some embodiments, the sealing connection member 2 may have a hardness between 85 and 90.
  • the hardness unit used here is Shore Hardness A (HA). The hardness of the sealing connection member 2 may be greater than the hardness of the sealing assembly 5.
  • the heating assembly 3 may be arranged between the sealing connection member 2 and the supporting assembly 4.
  • the heating element 3 can be arranged between the grooves 4r1 and 4r2 of the supporting element 4.
  • the grooves 4r1 and 4r2 of the supporting component 4 can fix the heating component 3.
  • the heating element 3 may include a cotton core material. In some embodiments, the heating element 3 may comprise a non-woven fabric material. In some embodiments, the heating element 3 may comprise ceramic material. In some embodiments, the heating element 3 may comprise a combination of cotton core, non-woven fabric or ceramics.
  • the heating assembly 3 includes a heating circuit 31.
  • the heating circuit 31 may be wound around a part of the heating assembly 3.
  • the heating circuit 31 may be wound around the central part of the heating assembly 3.
  • the heating circuit 31 may include a metal material. In some embodiments, the heating circuit 31 may include silver. In certain embodiments, the heating circuit 31 may include platinum. In some embodiments, the heating circuit 31 may include palladium. In some embodiments, the heating circuit 31 may include nickel. In some embodiments, the heating circuit 31 may include a nickel alloy material.
  • the support assembly 4 may have a cylindrical shape.
  • the support assembly 4 may have a rectangular parallelepiped shape or other suitable shapes.
  • the support assembly 4 includes an opening 4h penetrating the support assembly 4.
  • the supporting component 4 may be made of plastic material.
  • the supporting component 4 may be made of plastic material.
  • the supporting component 4 may be made of a metal material. In some embodiments, the support assembly 4 may be made of metal material. In some embodiments, the support assembly 4 may be made of stainless steel.
  • the support assembly 4 made of metal has many advantages. Compared with the use of plastic materials, the support assembly 4 made of metal materials may have a thinner thickness. The support assembly 4 made of metal material can have a smaller volume. The support assembly 4 made of metal material can have a thinner thickness or a smaller volume without sacrificing structural strength. For example, if the support assembly 4 is made of metal material and has a thickness of 0.2 mm, if it is made of plastic material, the thickness needs to be increased to 0.7 mm to achieve the same support strength.
  • Plastic materials need to be opened and injected. In the research and development process, it is often time-consuming and labor-intensive to modify the structure of components made of plastic materials. Since the modification of the metal structure is relatively easy, the use of metal materials to make the support assembly 4 also has many advantages in the manufacturing process. The metal material also has the characteristics of heat resistance and not easy to produce toxic substances.
  • the support assembly 4 that is in direct contact with the heating assembly 3 is made of metal material, which can benefit the health of the user of the atomization device.
  • the outer surface of the sealing assembly 5 may have ring structures 5r1 and 5r2.
  • the ring structures 5r1 and 5r2 can protrude from the outer surface of the sealing assembly 5.
  • the ring structures 5r1 and 5r2 can enhance the sealing effect of the sealing assembly 5.
  • the annular structures 5r1 and 5r2 can be in close contact with the inner surface of the oil cup portion 1b.
  • the inner surface of the oil cup portion 1b compresses the annular structures 5r1 and 5r2 to produce deformation.
  • the annular structures 5r1 and 5r2 are in interference fit with the inner surface of the oil cup portion 1b.
  • the sealing component 5 can be sleeved on the part 6a of the heating component base 6.
  • the sealing component 5 can abut the portion 6b of the heating component base 6.
  • the part 6a has a smaller outer diameter than the part 6b.
  • the sealing element 5 and the portion 6a of the heating element base 6 have a similar appearance.
  • the sealing component 5 may include a hole 5h.
  • the hole 5h can form part of the gas passage.
  • the supporting component 4 can pass through the hole 5h of the sealing component 5.
  • the hole 5h of the sealing component 5 can fix the supporting component 4.
  • the sealing component 5 may have flexibility.
  • the sealing assembly 5 may be malleable.
  • the sealing component 5 may comprise silicone material.
  • the sealing component 5 may have a hardness between 20-40.
  • the sealing component 5 may have a hardness between 40-60.
  • the sealing component 5 may have a hardness between 60 and 75.
  • the material of the sealing component 5 can withstand high temperatures.
  • the material of the sealing component 5 is not easily deteriorated due to the high temperature generated by the heating component 3.
  • the material of the sealing component 5 may have a melting point greater than 250°C.
  • the material of the sealing component 5 may have a melting point greater than 300°C.
  • the material of the sealing component 5 may have a melting point greater than 400°C.
  • the melting point of the sealing component 5 is in the range of 250°C to 300°C.
  • the melting point of the sealing component 5 is in the range of 300°C to 350°C.
  • the melting point of the sealing component 5 is in the range of 350°C to 400°C.
  • the melting point of the sealing component 5 is in the range of 400°C to 500°C.
  • the heating element base 6 may include a plastic material.
  • the heating element base 6 may include polypropylene (PP), high-pressure polyethylene (LDPE), high-density polyethylene (HDPE), and other materials.
  • the heating element base 6 and the housing 1 may comprise the same material.
  • the heating element base 6 and the housing 1 may be made of different materials.
  • the hardness of the heating element base 6 may be greater than the hardness of the sealing connection member 2.
  • the hardness of the heating component base 6 may be greater than the hardness of the sealing component 5.
  • the main body 100B may include a battery assembly 7, a sensor 8, a sensor fixing seat 9, a bottom cover 10 and a main body shell 11.
  • the battery assembly 7 may be a disposable battery.
  • the battery assembly 7 may be a rechargeable battery.
  • the battery assembly 7 may be a lithium battery.
  • the battery assembly 7 includes a part 7a and a part 7b.
  • the width 7L1 of the portion 7a is greater than the width 7L2 of the portion 7b.
  • the exterior design of the battery assembly 7 has many advantages.
  • the smaller width portion 7b can prevent the battery assembly 7 from blocking the groove on the sensor fixing seat 9.
  • the smaller width portion 7b can prevent the battery assembly 7 from blocking the air flow passage in the main body 100B.
  • the sensor 8 can sense changes in the air pressure inside the main body 100B.
  • the sensor 8 can sense the air flow inside the main body 100B.
  • the sensor 8 can sense sound waves inside the main body 100B.
  • the bottom of the sensor 8 may include a light-emitting component 81.
  • the light-emitting component 81 can be illuminated when the sensor 8 detects a change in air pressure. When the sensor 8 detects the air flow, the light-emitting component 81 can light up. The light-emitting component 81 can be illuminated when the sensor 8 detects sound waves.
  • the sensor mount 9 includes a trench 9t1 and a trench 9t2.
  • the trench 9t1 and the trench 9t2 form a part of the intake passage of the main body 100B.
  • the sensor 8 can be arranged in the cavity of the sensor fixing seat 9.
  • the sensor fixing base 9 may be made of a light-transmitting material.
  • the sensor fixing base 9 may be made of a transparent material.
  • the sensor holder 9 may be made of a translucent material.
  • the sensor fixing seat 9 may be made of silicone material.
  • the sensor fixing seat 9 may have flexibility.
  • the light emitted by the light-emitting assembly 81 can enter the sensor fixing seat 9.
  • the light emitted by the light-emitting component 81 can be refracted in the sensor fixing seat 9.
  • the light emitted by the light-emitting component 81 can be reflected in the sensor fixing seat 9.
  • the light emitted by the light-emitting component 81 can make the sensor fixing seat 9 light up as a whole.
  • the sensor fixing seat 9 can make the light emitted by the light-emitting assembly 81 scatter more uniformly.
  • the bottom cover 10 includes an opening 10h1.
  • the opening 10h1 may be used as one of the air inlets of the atomization device 100.
  • the bottom cover 10 may be fixed in the opening 11h of the main body housing 11.
  • the bottom cover 10 may be made of a light-transmitting material.
  • the bottom cover 10 may be made of a translucent material. The light emitted by the light emitting component 81 can cause the bottom cover 10 to emit light. The light emitted by the light emitting assembly 81 is visible from the outside of the bottom cover 10.
  • the main body shell 11 may be made of metal material.
  • the main body shell 11 may include a metal material.
  • the main body shell 11 may be made of plastic material.
  • the main body shell 11 may include the same material as the mouthpiece portion 1m and the oil cup portion 1b.
  • the main body shell 19 may be made of different materials from the cigarette holder portion 1m and the oil cup portion 1b.
  • FIGS. 2A and 2B illustrate exploded views of an atomization device according to some embodiments of the present disclosure.
  • the atomization device 200 may include an oil storage assembly 200A and a main body 200B.
  • the oil storage assembly 200A may include a housing 1, a sealing connection member 20, a heating assembly 3, a supporting assembly 4, a sealing assembly 5, and a heating assembly base 6.
  • the main body 200B may include a battery assembly 7, a sensor 8, a sensor fixing seat 9, a bottom cover 10 and a main body shell 11.
  • the components in the oil storage assembly 200A are similar to the components in the oil storage assembly 100A, except that the seal connection member 20 is used in the oil storage assembly 200A to replace the seal connection member 2 of the oil storage assembly 100A.
  • the components in the main body 200B are similar to the components in the main body 100B.
  • the main body of the sealing connector 20 may have a cylindrical shape.
  • the main body of the sealing connector 20 may have a rectangular parallelepiped shape or other suitable shapes.
  • the sealing connection member 20 includes an opening 20 h penetrating the sealing connection member 20.
  • the sealing connecting member 20 includes grooves 20r1 and 20r2.
  • the inner side of the opening 20h may include one or more ring structures.
  • the annular structure inside the opening 20h may protrude from the inner surface of the opening 20h.
  • the annular structure inside the opening 20h can increase the sealing effect between the sealing connector 20 and the cannula 1t.
  • the grooves 20r1 and 20r2 can be arranged on both sides of the bottom of the sealing connector 20.
  • the grooves 20r1 and 20r2 can be used to install the heating element 3.
  • the grooves 20r1 and 20r2 can be used to fix the heating element 3.
  • the sealing connection member 20 may have a hardness between 65 and 75. In some embodiments, the sealing connection member 20 may have a hardness between 75 and 85. In some embodiments, the sealing connection member 20 may have a hardness between 85 and 90. The hardness of the sealing connection member 20 may be greater than the hardness of the sealing assembly 5.
  • One side of the sealing connection member 20 includes a fin structure 20f1.
  • the other side of the sealing connector 20 includes a fin structure 20f2.
  • the fin structure 20f1 can contact the inner surface of the oil cup portion 1b.
  • the fin structure 20f2 can contact the inner surface of the oil cup portion 1b.
  • the sealing connection member 20 may include the same material as the sealing connection member 2.
  • the sealing connection member 20 and the sealing connection member 2 may be made of the same material.
  • FIG. 3A illustrates a perspective view of a sealed connection member according to some embodiments of the present disclosure.
  • Figure 3B illustrates a front view of a sealed connection according to some embodiments of the present disclosure.
  • Figure 3C illustrates a cross-sectional view of a sealed connection according to some embodiments of the present disclosure.
  • the inner side of the opening 20h may include one or more ring structures.
  • the inner side of the opening 20h may include ring structures 20s1, 20s2, and 20s3.
  • the inner side of the opening 20h may include more ring structures.
  • the inner side of the opening 20h may include fewer ring structures.
  • the ring structures 20s1, 20s2, and 20s3 can protrude from the inner surface of the opening 20h.
  • the annular structures 20s1, 20s2, and 20s3 can increase the sealing effect between the sealing connector 20 and the cannula 1t.
  • FIG. 4A illustrates a perspective view of a heating element base according to some embodiments of the present disclosure.
  • FIG. 4B illustrates a perspective view of a heating element base according to some embodiments of the present disclosure.
  • the heating element base 6 includes an opening 6h1, an opening 6h2, a groove 6r1, and a groove 6r2 on the portion 6a.
  • the opening 6h1 does not penetrate the heating element base 6.
  • the opening 6h2 does not penetrate the heating element base 6.
  • the openings 6h1 and 6h2 are provided on the part 6a to improve the structural strength of the heating element base 6.
  • the openings 6h1 and 6h2 are provided on the part 6a so that the heating element base 6 can withstand stronger pressure from above the heating element base 6.
  • providing openings 6h1 and 6h2 on the portion 6a can reduce the raw material cost of the heating element base 6.
  • the groove 6r1 and the groove 6r2 are provided on opposite sides of the portion 6a. When the sealing component 5 and the heating component base 6 are combined with each other, the sealing component 5 can cover the groove 6r1 and the groove 6r2.
  • the groove 6r1 and the groove 6r2 can be used as positioning marks of the sealing assembly 5.
  • the inner side of the sealing component 5 may include positioning structures corresponding to the groove 6r1 and the groove 6r2.
  • the groove 6r1 and the groove 6r2 and the positioning structure inside the sealing component 5 can improve the bonding between the sealing component 5 and the heating component base 6.
  • the groove 6r1 and the groove 6r2 and the positioning structure inside the sealing component 5 can avoid the misalignment between the sealing component 5 and the heating component base 6 during the assembly process.
  • the groove 6r1 and the groove 6r2 and the positioning structure inside the sealing component 5 can reduce the gap between the sealing component 5 and the heating component base 6.
  • the heating element base 6 includes a protruding structure 6p1, a protruding structure 6p2, a protruding structure 6p3, and a protruding structure 6p4 on a portion 6b.
  • the heating element base 6 further includes a supporting structure 6s1 and a supporting structure 6s2 on the part 6b.
  • the protruding structure 6p1, the protruding structure 6p2, the protruding structure 6p3, and the protruding structure 6p4 extend in the vertical direction (y-axis direction).
  • the protruding structure 6p1, the protruding structure 6p2, the protruding structure 6p3, and the protruding structure 6p4 extend from the heating element base 6 toward a direction away from the heating element 3.
  • the supporting structure 6s1 and the supporting structure 6s2 extend in the horizontal direction (x-axis direction).
  • the extending direction of the protruding structure 6p1, the protruding structure 6p2, the protruding structure 6p3, and the protruding structure 6p4 is perpendicular to the extending direction of the supporting structure 6s1 and the supporting structure 6s2.
  • a main body bracket is usually arranged around the battery assembly to fix the distance between the battery assembly and its surrounding components. Because the main body bracket itself has a certain volume, it limits the space in the main body shell, so that the traditional atomization device can only use a small-volume main body. The smaller body reduces the use time of the atomization device or increases the charging frequency of the atomization device.
  • the atomization device proposed in the present disclosure does not provide a main body bracket in the main body shell, thereby increasing the usable space in the main body shell. Therefore, the atomization device proposed in the present disclosure can use a larger body to achieve a longer use time and a lower charging frequency.
  • the effect of eliminating the main body bracket can be achieved.
  • the support structure 6s1 and the support structure 6s2 provided on the heating element base 6 can achieve the effect of eliminating the main body bracket.
  • the protruding structure 6p1, the protruding structure 6p2, the protruding structure 6p3, and the protruding structure 6p4 can maintain a space between the heating assembly base 6 and the battery assembly 7.
  • the protruding structure 6p1, the protruding structure 6p2, the protruding structure 6p3, and the protruding structure 6p4 can prevent the battery assembly 7 from blocking the opening 6h5 of the heating assembly base 6 (see FIG. 7A).
  • the protruding structure 6p1, the protruding structure 6p2, the protruding structure 6p3, and the protruding structure 6p4 can prevent the battery assembly 7 from blocking the air intake passage in the oil storage assembly 100A.
  • the supporting structure 6s1 and the supporting structure 6s2 can abut against the bottom of the oil cup portion 1b (see FIG. 8).
  • the protruding structure 6p1, the protruding structure 6p2, the protruding structure 6p3, and the protruding structure 6p4 can abut against the top of the battery assembly 7 (see FIG. 8).
  • the protruding structure 6p1, the protruding structure 6p2, the protruding structure 6p3, and the protruding structure 6p4 may directly contact the upper surface of the battery assembly 7 (see FIG. 8).
  • the housing 1 can be placed against the supporting structure 6s1 and the supporting structure 6s2 to place the heating element base 6 at a predetermined position in the main housing 11.
  • the heating element base 6 can use the protruding structure 6p1, the protruding structure 6p2, the protruding structure 6p3, and the protruding structure 6p4 to place the battery assembly 7 in a predetermined position in the main body shell 11.
  • the heating element base 6 further includes a pair of openings 6h3 penetrating through the portion 6b.
  • the heating circuit 31 of the heating assembly 3 can pass through the opening 6h3 and be electrically connected to the battery assembly 7.
  • FIG. 5A illustrates a perspective view of a sensor fixing seat according to some embodiments of the present disclosure.
  • the sensor mount 9 includes a part 9a and a part 9b.
  • the part 9a has a larger outer diameter than the part 9b.
  • the sensor mount 9 includes a cavity 9c.
  • the cavity 9c can be used to house the sensor 8.
  • the sensor fixing seat 9 can be used to fix the sensor 8.
  • the sensor fixing seat 9 can be used to protect the sensor 8.
  • the air flow channel design on the sensor fixing seat 9 enables the sensor 8 to accurately detect the air flow in the main body 100B.
  • the sensor mount 9 includes a trench 9t1.
  • the trench 9t1 communicates with the cavity 9c.
  • FIG. 5B illustrates a top view of the sensor mount according to some embodiments of the present disclosure.
  • the portion 9a of the sensor mount 9 includes an arc-shaped surface 9g1.
  • the curved surface 9g1 forms a part of the surface of the sensor fixing seat 9.
  • the portion 9a of the sensor mount 9 includes a flat surface 9s1.
  • the flat surface 9s1 and the arc-shaped surface 9g1 jointly surround the portion 9a of the sensor fixing seat 9.
  • the flat surface 9s1 and the arc-shaped surface 9g1 jointly define the boundary of the portion 9a of the sensor fixing seat 9.
  • the connection between the flat surface 9s1 and the arc-shaped surface 9g1 includes a first angle ⁇ 1 and a second angle ⁇ 2 .
  • the first angle ⁇ 1 and the second angle ⁇ 2 are the same.
  • the first angle ⁇ 1 and the second angle ⁇ 2 may be different.
  • first angle ⁇ 1 and the second angle ⁇ 2 may be in the range of 30° to 40°. In some embodiments, the first angle ⁇ 1 and the second angle ⁇ 2 may be in the range of 40° to 50°.
  • the connection between the flat surface 9s1 and the curved surface 9g1 constitutes a "missing corner" of the sensor fixing seat 9.
  • the "missing angle" formed by the flat surface 9s1 and the arc-shaped surface 9g1 can prevent the sensor fixing seat 9 from blocking the air flow passage in the main body 100B.
  • the outer shape of the sensor fixing seat 9 on the left and right sides of the central axis 9x1 of the portion 9a is asymmetrical.
  • FIG. 5C illustrates a bottom view of the sensor mount according to some embodiments of the present disclosure.
  • Figure 5D illustrates a cross-sectional view of the sensor mount according to some embodiments of the present disclosure.
  • Fig. 5D shows a cross-sectional view of the sensor holder 9 in Fig. 5A along the dashed line A-A' direction.
  • FIG. 5E illustrates a cross-sectional view of the sensor mount according to some embodiments of the disclosure.
  • Fig. 5E shows a cross-sectional view of the sensor holder 9 in Fig. 5A along the direction of the broken line B-B'.
  • the sensor fixing seat 9 has a trench 9t2 and an opening 9h1 at the bottom.
  • the trench 9t2 communicates with the opening 9h1.
  • the trench 9t2 and the cavity 9c communicate with each other via an opening 9h1.
  • the trench 9t2 extends from one side of the sensor holder 9 (the left side of FIG. 5C) to the opening 9h1. After the trench 9t2 extends to the opening 9h1, it does not continue to extend to the other side (the right side of FIG. 5C).
  • the trench 9t2 is shown in FIG. 5C, and the sensor holder 9 has asymmetrical appearance on the left and right sides of the central axis 9x2 of the portion 9b.
  • the extending direction of the trench 9t2 is substantially perpendicular to the extending direction of the trench 9t1.
  • the sensor holder 9 includes a groove 9r1 at the top.
  • the groove 9r1 is adjacent to the surfaces 9s2 and 9s3 of the portion 9a.
  • the groove 9r1 is sunk by a distance 9L from the surfaces 9s2 and 9s3 of the portion 9a.
  • the surfaces 9s2 and 9s3 of the sensor holder 9 are in direct contact with the battery assembly 7.
  • the groove 9r1 can ensure that the air flow channel in the sensor holder 9 will not be blocked by the battery assembly 7.
  • FIG. 6A and 6B illustrate perspective views of the bottom cover according to some embodiments of the present disclosure.
  • FIG. 6C illustrates a top view of the bottom cover according to some embodiments of the present disclosure.
  • Figure 6D illustrates a bottom view of the bottom cover according to some embodiments of the present disclosure.
  • FIG. 6E illustrates a cross-sectional view of the bottom cover according to some embodiments of the present disclosure.
  • Fig. 6E shows a cross-sectional view of the bottom cover 10 in Fig. 6A along the dashed line C-C' direction.
  • FIG. 6F illustrates a cross-sectional view of the bottom cover according to some embodiments of the present disclosure.
  • Fig. 6F shows a cross-sectional view of the bottom cover 10 in Fig. 6A along the dashed line D-D' direction.
  • the bottom of the bottom cover 10 has an opening 10h1.
  • the opening 10h1 penetrates the bottom cover 10 and forms a part of the air flow channel.
  • the bottom of the bottom cover 10 includes grooves 10r1, 10r2, 10r3, and 10r4.
  • the grooves 10r1 and 10r2 or the grooves 10r3 and 10r4 can form a part of the air flow channel.
  • the grooves 10r3 and 10r4 are not part of the air flow channel.
  • the grooves 10r1 and 10r2 are not part of the air flow channel.
  • the grooves 10r1 and 10r2 correspond to the "missing corners" of the sensor holder 9, the grooves 10r1 and 10r2 form an airflow channel. Part.
  • the grooves 10r3 and 10r4 correspond to the "missing corners" of the sensor holder 9, the grooves 10r3 and 10r4 form part of the air flow channel Copies.
  • the bottom cover 10 has a symmetrical appearance on the left and right sides of the central axis 10x1. Although only the grooves on one side of the bottom cover 10 can form air flow channels, symmetrical grooves on both sides of the bottom cover 10 have advantages.
  • the bottom cover 10 with a symmetrical appearance can reduce the difficulty of assembly.
  • the bottom cover 10 with a symmetrical appearance can prevent errors in the assembly process from blocking the air flow passage of the main body 100B.
  • FIG. 7A illustrates a cross-sectional view of an atomization device according to some embodiments of the present disclosure.
  • FIG. 7A shows a cross-sectional view of the atomization device 100 as shown in FIG. 1A.
  • a storage tank 1c is defined between the cannula 1t and the oil cup 1b.
  • the liquid storage tank 1c can contain e-liquid.
  • the heating assembly 3 is arranged between the sealing connection piece 2 and the sealing assembly 5.
  • the heating assembly 3 is in direct contact with the sealing connector 2 and the sealing assembly 5.
  • the two ends of the heating assembly 3 can absorb the e-liquid in the liquid storage tank 1c.
  • the sealing connector 2, the sealing assembly 5 and the heating assembly base 6 jointly define the atomization chamber 6c.
  • the aerosol generated by the heating circuit 31 is first generated in the atomizing chamber 6c, and then inhaled by the user through the cannula 1t.
  • the heating element base 6 includes one or more openings 6h5.
  • the heating element base 6 may include six openings 6h5.
  • the pore size of the opening 6h5 is designed to allow gas to pass through but difficult for liquid to pass through.
  • the aperture size of the opening 6h5 is designed so that the condensed liquid cannot easily enter the main body 100B through the opening 6h5.
  • the aperture size design of the opening 6h5 can prevent the electronic components in the main body 100B from malfunctioning due to condensate.
  • the aperture size of the opening 6h5 is in the range of 0.1 mm to 0.3 mm.
  • the aperture size of the opening 6h5 is in the range of 0.01 mm to 0.2 mm. In some embodiments, the aperture size of the opening 6h5 is in the range of 0.4 mm to 1.2 mm. In some embodiments, the aperture size of the opening 6h5 is about 0.55 mm.
  • the protruding structures 6p3 and 6p4 of the heating element base 6 can keep the distance between the battery assembly 7 and the heating element base 6.
  • the protruding structures 6p3 and 6p4 of the heating element base 6 can ensure that the opening 6h5 is unblocked.
  • the battery assembly 7 can be in contact with the protruding structures 6p3 and 6p4.
  • the battery assembly 7 can be in contact with the surfaces 9s2 and 9s3.
  • the battery assembly 7 can be fixed between the heating assembly base 6 and the sensor fixing base 9.
  • FIG. 7B illustrates a cross-sectional view of an atomization device according to some embodiments of the present disclosure.
  • FIG. 7B shows a cross-sectional view of the atomizing device 200 as shown in FIG. 2A.
  • the difference between the atomization device 200 and the atomization device 100 is that the two sides of the sealing connection member 20 have fin structures 20f1 and 20f2.
  • the fin-shaped structures 20f1 and 20f2 can be in contact with the inner surface of the oil cup portion 1b.
  • the extension direction of the fin structures 20f1 and 20f2 is substantially parallel to the extension direction of the heating element 3.
  • the fin-shaped structures 20f1 and 20f2 can produce a flow diversion function in the liquid storage tank 1c.
  • the fin structures 20f1 and 20f2 can promote the contact between the e-liquid in the liquid storage tank 1c and the heating assembly 3.
  • the fin-shaped structures 20f1 and 20f2 can also prevent the heating element 3 from adsorbing too much e-liquid. As shown in FIG. 7B, the fin-like structures 20f1 and 20f2 are arranged above the heating assembly 3, so that the e-liquid can contact the heating assembly 3 from the side of the heating assembly 3, and prevent the e-liquid from directly impacting the two ends of the heating assembly 3.
  • FIG. 8 illustrates a cross-sectional view of an atomization device according to some embodiments of the present disclosure.
  • the supporting structure 6s1 and the supporting structure 6s2 can abut against the bottom of the oil cup portion 1b.
  • the protruding structure 6p1 and the protruding structure 6p4 can abut the top of the battery assembly 7.
  • the battery assembly 7 can be fixed between the heating assembly base 6 and the sensor fixing base 9.
  • FIG. 9A illustrates a schematic diagram of the air flow of the atomization device according to some embodiments of the present disclosure.
  • FIG. 9B illustrates a schematic diagram of the air flow of the atomization device according to some embodiments of the present disclosure.
  • the groove 10r1 and the groove 10r2 correspond to the flat surface 9s1 of the sensor holder 9 in the vertical direction.
  • the groove 10r3 and the groove 10r4 correspond to the flat surface 9s1 of the sensor holder 9 in the vertical direction.
  • the air flow entering the main body 100B through the opening 10h1 of the bottom cover 10 is denoted by f1.
  • the air flow f1 passes through the bottom surface and the side surface of the sensor 8 and enters the gap between the battery assembly 7 and the main body casing 11. After entering the opening 10h1, the airflow directly contacts the bottom surface of the sensor 8 at f1, but does not directly contact the top surface of the sensor 8.
  • the airflow f1 can ensure a pressure difference between the top surface and the bottom surface of the sensor 8 when the user inhales.
  • the airflow f1 can ensure that the user's inhalation action can be detected by the sensor 8.
  • the airflow channel design of the sensor fixing seat 9 allows the top surface and the bottom surface of the sensor 8 to generate a pressure difference when the user inhales.
  • the airflow channel design of the sensor holder 9 enables the sensor 8 to accurately detect the user's inhalation action.
  • the air flow channel design of the sensor holder 9 can improve the sensitivity of the sensor 8.
  • the air flow channel design of the sensor holder 9 can improve the accuracy of the sensor 8.
  • the air flow entering the main body 100B through the groove 10r1 is denoted by f2.
  • the airflow f2 can ensure that enough fresh air enters the atomization chamber 6c during the user's inhalation process.
  • Part of the airflow entering the main body 100B from the groove 10r1 merges with the airflow f1 along the trench 9t2.
  • the air flow entering the opening 9h1 along the trench 9t2 is denoted by f3.
  • the temperature rise Tr may be in the range of 200°C to 220°C. In some embodiments, the temperature rise Tr may be in the range of 240°C to 260°C. In some embodiments, the temperature rise Tr may be in the range of 260°C to 280°C. In some embodiments, the temperature rise Tr may be in the range of 280°C to 300°C. In some embodiments, the temperature rise Tr may be in the range of 300°C to 320°C. In some embodiments, the temperature rise Tr may be in the range of 200°C to 320°C.
  • the air flow out of the atomization chamber 6c enters the cannula 1t.
  • the airflow can produce a temperature drop Tf before reaching the opening 1h1.
  • the temperature drop Tf may be in the range of 145°C to 165°C. In some embodiments, the temperature drop Tf may be in the range of 165°C to 185°C. In some embodiments, the temperature drop Tf may be in the range of 205°C to 225°C. In some embodiments, the temperature drop Tf may be in the range of 225°C to 245°C. In some embodiments, the temperature drop Tf may be in the range of 245°C to 265°C. In some embodiments, the temperature drop Tf may be in the range of 145°C to 265°C.
  • the cannula 1t may have an uneven inner diameter.
  • the opening 1h1 may have an uneven inner diameter.
  • the inner diameter of the opening 1h1 gradually increases from a position close to the heating element 3 to a direction away from the heating element 3.
  • the gradually larger inner diameter of the opening 1h1 can increase the volume of the aerosol.
  • the temperature of the aerosol sucked by the user from the opening 1h1 can be controlled.
  • the width of the inner diameter of the cannula 1t1 the volume of aerosol sucked by the user from the opening 1h1 can be controlled. Controlling the temperature of the aerosol can prevent users from being burned by the aerosol. Controlling the aerosol volume can improve the user's inhalation experience.
  • the aerosol inhaled by the user through the opening 1h1 may have a temperature lower than 65°C. In some embodiments, the aerosol inhaled by the user through the opening 1h1 may have a temperature lower than 55°C. In some embodiments, the aerosol inhaled by the user through the opening 1h1 may have a temperature lower than 50°C. In some embodiments, the aerosol inhaled by the user through the opening 1h1 may have a temperature lower than 45°C. In some embodiments, the aerosol inhaled by the user through the opening 1h1 may have a temperature lower than 40°C. In some embodiments, the aerosol inhaled by the user through the opening 1h1 may have a temperature lower than 30°C.
  • the terms “approximately”, “substantially”, “substantially” and “about” are used to describe and consider small variations. When used in conjunction with an event or situation, the term may refer to an example in which the event or situation occurs precisely and an example in which the event or situation occurs in close proximity. As used herein with respect to a given value or range, the term “about” generally means within ⁇ 10%, ⁇ 5%, ⁇ 1%, or ⁇ 0.5% of the given value or range. Ranges can be expressed herein as from one endpoint to another or between two endpoints. Unless otherwise specified, all ranges disclosed herein include endpoints.
  • substantially coplanar may refer to two surfaces located within a few micrometers ( ⁇ m) along the same plane, for example, within 10 ⁇ m, within 5 ⁇ m, within 1 ⁇ m, or within 0.5 ⁇ m located along the same plane.
  • ⁇ m micrometers
  • the term may refer to a value within ⁇ 10%, ⁇ 5%, ⁇ 1%, or ⁇ 0.5% of the average value of the stated value.
  • the terms “approximately”, “substantially”, “substantially” and “about” are used to describe and explain small changes.
  • the term may refer to an example in which the event or situation occurs precisely and an example in which the event or situation occurs in close proximity.
  • the term when used in combination with a value, can refer to a range of variation less than or equal to ⁇ 10% of the stated value, for example, less than or equal to ⁇ 5%, less than or equal to ⁇ 4%, less than or equal to ⁇ 3% , Less than or equal to ⁇ 2%, less than or equal to ⁇ 1%, less than or equal to ⁇ 0.5%, less than or equal to ⁇ 0.1%, or less than or equal to ⁇ 0.05%.
  • the difference between two values is less than or equal to ⁇ 10% of the average value of the value (for example, less than or equal to ⁇ 5%, less than or equal to ⁇ 4%, less than or equal to ⁇ 3%, less than Or equal to ⁇ 2%, less than or equal to ⁇ 1%, less than or equal to ⁇ 0.5%, less than or equal to ⁇ 0.1%, or less than or equal to ⁇ 0.05%), then the two values can be considered “substantially” or " About” is the same.
  • substantially parallel can refer to a range of angular variation less than or equal to ⁇ 10° relative to 0°, for example, less than or equal to ⁇ 5°, less than or equal to ⁇ 4°, less than or equal to ⁇ 3°, Less than or equal to ⁇ 2°, less than or equal to ⁇ 1°, less than or equal to ⁇ 0.5°, less than or equal to ⁇ 0.1°, or less than or equal to ⁇ 0.05°.
  • substantially perpendicular may refer to an angular variation range of less than or equal to ⁇ 10° relative to 90°, for example, less than or equal to ⁇ 5°, less than or equal to ⁇ 4°, less than or equal to ⁇ 3°, Less than or equal to ⁇ 2°, less than or equal to ⁇ 1°, less than or equal to ⁇ 0.5°, less than or equal to ⁇ 0.1°, or less than or equal to ⁇ 0.05°.
  • the two surfaces can be considered coplanar or substantially coplanar if the displacement between two surfaces is equal to or less than 5 ⁇ m, equal to or less than 2 ⁇ m, equal to or less than 1 ⁇ m, or equal to or less than 0.5 ⁇ m, then the two surfaces can be considered coplanar or substantially coplanar if the displacement between any two points on the surface relative to the plane is equal to or less than 5 ⁇ m, equal to or less than 2 ⁇ m, equal to or less than 1 ⁇ m, or equal to or less than 0.5 ⁇ m, then the surface can be considered to be flat or substantially flat .
  • the terms "conductive,””electricallyconductive,” and “conductivity” refer to the ability to transfer current. Conductive materials generally indicate those materials that exhibit little or zero resistance to current flow. One measure of conductivity is Siemens/meter (S/m). Generally, the conductive material is a material with a conductivity greater than approximately 10 4 S/m (for example, at least 10 5 S/m or at least 10 6 S/m). The electrical conductivity of a material can sometimes change with temperature. Unless otherwise specified, the electrical conductivity of the material is measured at room temperature.
  • a/an and “said” may include plural indicators.
  • a component provided “on” or “above” another component may cover the case where the former component is directly on the latter component (for example, in physical contact with the latter component), and one or more A situation in which an intermediate component is located between the previous component and the next component.
  • spatially relative terms such as “below”, “below”, “lower”, “above”, “upper”, “lower”, “left”, “right” may be used herein. Describes the relationship between one component or feature and another component or feature as illustrated in the figure. In addition to the orientation depicted in the figures, the spatial relative terms are intended to cover different orientations of the device in use or operation. The device can be oriented in other ways (rotated by 90 degrees or in other orientations), and the spatial relative descriptors used herein can also be interpreted accordingly. It should be understood that when a component is referred to as being “connected to” or “coupled to” another component, it can be directly connected or coupled to the other component, or intervening components may be present.
  • the terms “about”, “substantially”, “substantially” and “about” are used to describe and consider small variations. When used in conjunction with an event or situation, the term can refer to a situation in which the event or situation clearly occurs and a situation in which the event or situation is very close to occurrence. As used herein in relation to a given value or range, the term “about” generally means within ⁇ 10%, ⁇ 5%, ⁇ 1%, or ⁇ 0.5% of the given value or range. Ranges can be expressed herein as from one endpoint to the other or between two endpoints. Unless otherwise specified, all ranges disclosed herein include endpoints.
  • substantially coplanar may refer to two surfaces located along the same plane within a few microns ( ⁇ m), for example, within 10 ⁇ m, within 5 ⁇ m, within 1 ⁇ m, or within 0.5 ⁇ m along the same plane.
  • ⁇ m microns
  • the term may refer to a value within ⁇ 10%, ⁇ 5%, ⁇ 1%, or ⁇ 0.5% of the average value of the stated value.

Abstract

一种雾化装置(100)包含储油组件(100A)及主体(100B)。储油组件(100A)包含加热组件(3)、支撑组件(4)、密封组件(5)及加热组件底座(6)。加热组件(3)设置于支撑组件(4)的第一凹槽(4r1)与第二凹槽(4r2)之间。加热组件(3)的一端与密封组件(5)直接接触。密封组件(5)设置于加热组件底座(6)的第一部分上。其中加热组件底座(6)包含第一突出结构(6p1)及第二突出结构(6p2)。第一突出结构(6p1)及第二突出结构(6p2)朝向远离加热组件(3)的方向延伸。

Description

一种雾化装置 技术领域
本揭露大体上涉及一种电子装置,具体而言涉及一种提供可吸入气雾(aerosol)之雾化装置(vaporization device)。
背景技术
电子烟系一种电子产品,其将可雾化溶液加热雾化并产生气雾以供用户吸食。近年来,各大厂商开始生产各式各样的电子烟产品。一般而言,一电子烟产品包括外壳、储油室、雾化室、加热组件、进气口、气流通道、出气口、电源装置、感测装置及控制装置。储油室用于储存可雾化溶液,加热组件用于将可雾化溶液加热雾化并产生气雾。进气口与雾化室彼此连通,当使用者吸气时提供空气给加热组件。由加热组件产生之气雾首先产生于雾化室内,随后经由气流通道及出气口被使用者吸入。电源装置提供加热组件所需之电力,控制装置根据感测装置侦测到的用户吸气动作,控制加热组件的加热时间。外壳则包覆上述各个组件。
现有的电子烟产品存在不同的缺陷。举例言之,现有技术中的电子烟产品可能为了减少组件数目而造成组装良率不佳。现有技术中的电子烟产品可能为了减少组件数目反而使组件制造成本上升。此外,现有技术中的电子烟产品可能未考虑气雾的高温问题,造成使用者灼伤的潜在危机。
此外,电子烟装置在重复性的使用上往往具有一些限制包括:需要对其烟油进行更换或填充、操作复杂、烟油溢漏、烧焦、电池寿命短缺以及价格昂贵等,其不可避免的造成了不良的使用者体验。
因此,本揭露提出一种可解决上述问题之雾化装置。
发明内容
提出一种雾化装置。所提出的雾化装置包含储油组件及主体。储油组件包含加热组件、支撑组件、密封组件及加热组件底座。加热组件设置于支撑组件的第一凹槽与第二凹槽之间。加热组件的一端與密封组件直接接觸。密封组件设置于加热组件底座的第一部分上。其中加热组件底座包含第一突出结构及第二突出结构。第一突出结构及第二突出结构朝向远离加热组件的方向延伸。
提出一种雾化装置。所提出的雾化装置包括储油组件及主体。储油组件包含外壳、加热组件及加热组件底座。主体包含电池组件及传感器固定座。加热组件底座包含第一突出结构及第二突出结构。第一突出结构及第二突出结构朝向远离加热组件的方向延伸。其中电池组件设置于加热组件底座与传感器固定座之间。
附图说明
当结合附图阅读时,从以下详细描述容易理解本揭露的各方面。应注意,各种特征可能未按比例绘制,且各种特征的尺寸可出于论述的清楚起见而任意增大或减小。
图1A及1B说明根据本揭露的一些实施例的雾化装置的分解图。
图2A及2B说明根据本揭露的一些实施例的雾化装置的分解图。
图3A说明根据本揭露的一些实施例的密封连接件的立体图。
图3B说明根据本揭露的一些实施例的密封连接件的前视图。
图3C说明根据本揭露的一些实施例的密封连接件的剖面图。
图4A说明根据本揭露的一些实施例的加热组件底座的立体图。
图4B说明根据本揭露的一些实施例的加热组件底座的立体图。
图5A说明根据本揭露的一些实施例的传感器固定座的立体图。
图5B说明根据本揭露的一些实施例的传感器固定座的俯视图。
图5C说明根据本揭露的一些实施例的传感器固定座的仰视图。
图5D说明根据本揭露的一些实施例的传感器固定座的剖面图。
图5E说明根据本揭露的一些实施例的传感器固定座的剖面图。
图6A及6B说明根据本揭露的一些实施例的底盖的立体图。
图6C说明根据本揭露的一些实施例的底盖的俯视图。
图6D说明根据本揭露的一些实施例的底盖的仰视图。
图6E说明根据本揭露的一些实施例的底盖的剖面图。
图6F说明根据本揭露的一些实施例的底盖的剖面图。
图7A说明根据本揭露的一些实施例的雾化装置的剖面图。
图7B说明根据本揭露的一些实施例的雾化装置的剖面图。
图8说明根据本揭露的一些实施例的雾化装置的剖面图。
图9A说明根据本揭露的一些实施例的雾化装置的气流示意图。
图9B说明根据本揭露的一些实施例的雾化装置的气流示意图。
贯穿图式和详细描述使用共同参考标号来指示相同或类似组件。根据以下结合附图作出的详细描述,本揭露的特点将更为清楚。
具体实施方式
以下公开内容提供用于实施所提供的标的物的不同特征的许多不同实施例或实例。下文描述组件和布置的特定实例。当然,这些仅是实例且并不意图为限制性的。在本揭露中,在以下描述中对第一特征在第二特征之上或上的形成的参考可包含第一特征与第二特征直接接触形成的实施例,并且还可包含额外特征可形成于第一特征与第二特征之间从而使得第一特征与第二特征可不直接接触的实施例。另外,本揭露可能在各个实例中重复参考标号和/或字母。此重复是出于简化和清楚的目的,且本身并不指示所论述的各种实施例和/或配置之间的关系。
下文详细论述本揭露的实施例。然而,应了解,本揭露提供了可在多种多样的特定情境中实施的许多适用的概念。所论述的特定实施例仅仅是说明性的且并不限制本揭露的范围。
图1A及1B说明根据本揭露的一些实施例的雾化装置的分解图。
雾化装置100可包含储油组件100A及主体100B。在某些实施例中,储油组件100A及主体100B可设计为一个整体。在某些实施例中,储油组件100A及主体100B可设计为无法彼此分离。在某些实施例中,储油组件100A及主体100B可设计成分开的两组件。在某些实施例中,储油组件100A可设计成可移除式地与主体100B结合。在某些实施例中,储油组件100A可设计成一部分收纳于主体100B中。
储油组件100A可包含外壳1、密封连接件2、加热组件3、支撑组件4、密封组件5、及加热组件底座6。
外壳1包含烟嘴部(mouthpiece)1m及油杯部1b。在某些实施例中,烟嘴部1m与油杯部1b可以是分开的两个组件。在某些实施例中,烟嘴部1m与油杯部1b可以一体成形。烟嘴部1m与油杯部1b内部可以共同界定空腔以储存可雾化液体。烟嘴部1m与油杯部1b内部空腔中储存的液体可以称为烟油(e-liquid)。烟嘴部1m具有开口1h1。开口1h1构成气体通道的一部份。雾化装置100产生的气雾可经由孔1h被使用者吸食。烟嘴部1m包含插管1t,插管1t与开口1h1连接。插管1t构成气体通道的一部份。
密封连接件2可呈现圆柱状外型。密封连接件2可呈现长方体外型或其他合适外型。密封连接件2包含贯穿密封连接件2的开口2h。密封连接件2包含凹槽2r1及2r2。虽然图1A中未显示,开口2h内侧可包含一或多个环状结构。开口2h内侧的环状结构可凸起于开口2h的内侧表面。开口2h内侧的环状结构可增加密封连接件2与插管1t之间的密封效果。凹槽2r1及2r2可设置于密封连接件2的底部两侧。凹槽2r1及2r2可用以安置加热组件3。凹槽2r1及2r2可用以固定加热组件3。凹槽2r1及2r2可与加热组件 3直接接触。
在某些实施例中,密封连接件2可具有65至75之间的硬度。在某些实施例中,密封连接件2可具有75至85之间的硬度。在某些实施例中,密封连接件2可具有85至90之间的硬度。此处采用的硬度单位为邵氏硬度A型(Shore Hardness A;HA)。密封连接件2的硬度可以大于密封组件5的硬度。
加热组件3可设置于密封连接件2与支撑组件4之间。加热组件3可设置于支撑组件4的凹槽4r1与4r2之间。支撑组件4的凹槽4r1与4r2可以固定加热组件3。
在某些实施例中,加热组件3可以包含棉芯材质。在某些实施例中,加热组件3可以包含无纺布材质。在某些实施例中,加热组件3可以包含陶瓷材质。在某些实施例中,加热组件3可以包含棉芯、无纺布或陶瓷之组合物。
加热组件3包括加热线路31。加热线路31可以缠绕加热组件3的一部份。加热线路31可以缠绕加热组件3的中心部份。经由向加热线路31提供电源,雾化装置100可使加热组件3温度上升。
加热线路31可包含金属材料。在某些实施例中,加热线路31可包含银。在某些实施例中,加热线路31可包含铂。在某些实施例中,加热线路31可包含钯。在某些实施例中,加热线路31可包含镍。在某些实施例中,加热线路31可包含镍合金材料。
支撑组件4可呈现圆柱状外型。支撑组件4可呈现长方体外型或其他合适外型。支撑组件4包含贯穿支撑组件4的开口4h。在某些实施例中,支撑组件4可以由包含塑料材质。在某些实施例中,支撑组件4可以由塑料材质制成。
在某些实施例中,支撑组件4可以由包含金属材质。在某些实施例中,支撑组件4可以由金属材质制成。在某些实施例中,支撑组件4可以由不锈钢制成。
支撑组件4由金属材质制成有许多优势。与使用塑料材料相比,金属材质制成的支撑组件4可具有较薄的厚度。使用金属材质制成的支撑组件4可具有较小的体积。使用金属材质制成的支撑组件4可以在不牺牲结构强度的前提下具有较薄的厚度或较小的体积。举例言之,以金属材质制成的、厚度为0.2mm的支撑组件4,若改以塑料材料制作,则厚度需增加为0.7mm才能达成相同的支撑强度。
塑料材料需要开模并注塑,在研发过程中,修改塑料材料制成的组件的结构往往费时费工。因金属结构的修改相对容易,使用金属材质制成支撑组件4在制造流程上亦有许多优势。金属材质亦有耐热并不易产生有毒物质的特性。与加热组件3直接接触的支撑组件4采用金属材质制成,可对雾化装置的用户健康产生益处。
密封组件5外表面上可具有环状结构5r1及5r2。环状结构5r1及5r2可凸起于密封 组件5的外表面。环状结构5r1及5r2可增强密封组件5的密封效果。当密封组件5设置于油杯部1b内时,环状结构5r1及5r2可与油杯部1b的内部表面紧密接触。当密封组件5设置于油杯部1b内时,油杯部1b的内部表面使环状结构5r1及5r2压缩产生形变。当密封组件5设置于油杯部1b内时,环状结构5r1及5r2与油杯部1b的内部表面过盈配合。
密封组件5可以套于加热组件底座6的部份6a上。密封组件5可以抵着加热组件底座6的部份6b。部份6a与部份6b相比具有较小的外径。密封组件5与加热组件底座6的部份6a具有相似外型。密封组件5可包含孔5h。孔5h可构成气体通道的一部份。支撑组件4可以穿过密封组件5的孔5h。密封组件5的孔5h可以固定支撑组件4。
密封组件5可以具有可挠性。密封组件5可以具有延展性。在某些实施例中,密封组件5可以包含硅胶材质。在某些实施例中,密封组件5可具有20至40之间的硬度。在某些实施例中,密封组件5可具有40至60之间的硬度。在某些实施例中,密封组件5可具有60至75之间的硬度。
密封组件5的材质可耐受高温。密封组件5的材质不易因加热组件3产生的高温而变质。在某些实施例中,密封组件5的材质可具有大于250℃的融点。在某些实施例中,密封组件5的材质可具有大于300℃的融点。在某些实施例中,密封组件5的材质可具有大于400℃的融点。在某些实施例中,密封组件5的融点在250℃至300℃的范围内。在某些实施例中,密封组件5的融点在300℃至350℃的范围内。在某些实施例中,密封组件5的融点在350℃至400℃的范围内。在某些实施例中,密封组件5的融点在400℃至500℃的范围内。
加热组件底座6可以包含塑料材料。在某些实施例中,加热组件底座6可以包含聚丙烯(PP)、高压聚乙烯(LDPE)、高密度聚乙烯(HDPE)等材料。在某些实施例中,加热组件底座6可以与外壳1包含相同材质。在某些实施例中,加热组件底座6可以与外壳1包含不同材质。在某些实施例中,加热组件底座6的硬度可以大于密封连接件2的硬度。在某些实施例中,加热组件底座6的硬度可以大于密封组件5的硬度。
主体100B可包含电池组件7、传感器8、传感器固定座9、底盖10及主体外壳11。
电池组件7可以为一次性电池。电池组件7可以为充电电池。电池组件7可以为锂电池。电池组件7包含部分7a及部分7b。部分7a的宽度7L1大于部分7b的宽度7L2。电池组件7的外型设计具有许多优势。宽度较小的部分7b可以避免电池组件7堵塞传感器固定座9上的凹槽。宽度较小的部分7b可以避免电池组件7堵塞主体100B内的气流通道。
传感器8可感测主体100B內部的气压变化。传感器8可感测主体100B內部的气流。传感器8可感测主体100B內部的声波。传感器8底部可包含发光组件81。当传感器8侦测到气压变化时发光组件81可以发亮。当传感器8侦测到气流时发光组件81可以发亮。当传感器8侦测到声波时发光组件81可以发亮。
传感器固定座9包含沟渠(trench)9t1及沟渠9t2。沟渠9t1及沟渠9t2形成主体100B的进气通道的一部分。传感器8可设置于传感器固定座9的空腔内。
传感器固定座9可以由透光材料制成。传感器固定座9可以由透明材料制成。传感器固定座9可以由半透明材料制成。传感器固定座9可以由硅胶材料制成。传感器固定座9可以具有可挠性。发光组件81发出的光可以进入传感器固定座9内。发光组件81发出的光可以在传感器固定座9内产生折射。发光组件81发出的光可以在传感器固定座9内产生反射。发光组件81发出的光可以使传感器固定座9整体发亮。传感器固定座9可以使发光组件81发出的光更均匀地散射。
底盖10上包含开口10h1。开口10h1可以作为雾化装置100的进气口之一。底盖10可以固定于主体外壳11的开口11h中。底盖10可以由透光材料制成。底盖10可以由半透明材料制成。发光组件81发出的光可使底盖10发光。发光组件81发出的光从底盖10外部为可见(visible)的。
主体外壳11可以由金属材质制成。主体外壳11可以包含金属材质。主体外壳11可以由塑料材质制成。在某些实施例中,主体外壳11可以与烟嘴部1m与油杯部1b包含相同材质。在某些实施例中,主体外壳19可以与烟嘴部1m与油杯部1b包含不同材质。
图2A及2B说明根据本揭露的一些实施例的雾化装置的分解图。
雾化装置200可包含储油组件200A及主体200B。储油组件200A可包含外壳1、密封连接件20、加热组件3、支撑组件4、密封组件5、及加热组件底座6。
主体200B可包含电池组件7、传感器8、传感器固定座9、底盖10及主体外壳11。
储油组件200A内的组件与储油组件100A内的组件类似,除了在储油组件200A中以密封连接件20替换储油组件100A的密封连接件2。主体200B内的组件与主体100B内的组件类似。
密封连接件20的主体可呈现圆柱状外型。密封连接件20的主体可呈现长方体外型或其他合适外型。密封连接件20包含贯穿密封连接件20的开口20h。密封连接件20包含凹槽20r1及20r2。虽然图2A中未显示,开口20h内侧可包含一或多个环状结构。开口20h内侧的环状结构可凸起于开口20h的内侧表面。开口20h内侧的环状结构可增加 密封连接件20与插管1t之间的密封效果。凹槽20r1及20r2可设置于密封连接件20的底部两侧。凹槽20r1及20r2可用以安置加热组件3。凹槽20r1及20r2可用以固定加热组件3。
在某些实施例中,密封连接件20可具有65至75之间的硬度。在某些实施例中,密封连接件20可具有75至85之间的硬度。在某些实施例中,密封连接件20可具有85至90之间的硬度。密封连接件20的硬度可以大于密封组件5的硬度。
密封连接件20的一侧包含鳍状结构20f1。密封连接件20的另一侧包含鳍状结构20f2。当密封连接件20设置于油杯部1b内时,鳍状结构20f1可与油杯部1b的内侧表面接触。当密封连接件20设置于油杯部1b内时,鳍状结构20f2可与油杯部1b的内侧表面接触。
密封连接件20可以与密封连接件2包含相同材料。密封连接件20可以与密封连接件2由相同材料制成。
图3A说明根据本揭露的一些实施例的密封连接件的立体图。图3B说明根据本揭露的一些实施例的密封连接件的前视图。图3C说明根据本揭露的一些实施例的密封连接件的剖面图。
图3A、图3B及图3C分别显示了密封连接件20的立体图、前视图及剖面图。如图3C所示,开口20h内侧可包含一或多个环状结构。在某些实施例中,开口20h内侧可包含环状结构20s1、20s2及20s3。在某些实施例中,开口20h内侧可包含更多个环状结构。在某些实施例中,开口20h内侧可包含较少个环状结构。环状结构20s1、20s2及20s3可凸起于开口20h的内侧表面。环状结构20s1、20s2及20s3可增加密封连接件20与插管1t之间的密封效果。
图4A说明根据本揭露的一些实施例的加热组件底座的立体图。图4B说明根据本揭露的一些实施例的加热组件底座的立体图。
如图4A所示,加热组件底座6在部分6a上包含开口6h1、开口6h2、凹槽6r1及凹槽6r2。开口6h1并未贯穿加热组件底座6。开口6h2并未贯穿加热组件底座6。在部分6a上设置开口6h1及6h2可以提升加热组件底座6的结构强度。举例言之,在部分6a上设置开口6h1及6h2使加热组件底座6可以承受来自加热组件底座6上方更强的压力。此外,在部分6a上设置开口6h1及6h2可以减少加热组件底座6的原料成本。
凹槽6r1及凹槽6r2设置于部分6a的相对两侧。当密封组件5与加热组件底座6彼此结合时,密封组件5可覆盖凹槽6r1及凹槽6r2。
凹槽6r1及凹槽6r2可以作为密封组件5的定位标记。在某些实施例中,密封组件 5内侧可包含与凹槽6r1及凹槽6r2相对应的定位结构。凹槽6r1及凹槽6r2及密封组件5内侧的定位结构可以增进密封组件5与加热组件底座6之间的结合。凹槽6r1及凹槽6r2及密封组件5内侧的定位结构可以避免组装过程中密封组件5与加热组件底座6之间产生错位。凹槽6r1及凹槽6r2及密封组件5内侧的定位结构可以减少密封组件5与加热组件底座6之间的间隙。
如图4B所示,加热组件底座6在部分6b上包含突出结构6p1、突出结构6p2、突出结构6p3及突出结构6p4。加热组件底座6在部分6b上另包含支撑结构6s1及支撑结构6s2。
突出结构6p1、突出结构6p2、突出结构6p3及突出结构6p4沿着垂直方向延伸(y轴方向)。突出结构6p1、突出结构6p2、突出结构6p3及突出结构6p4从加热组件底座6朝向远离加热组件3的方向延伸。支撑结构6s1及支撑结构6s2沿着水平方向延伸(x轴方向)。
在某些实施例中,突出结构6p1、突出结构6p2、突出结构6p3及突出结构6p4的延伸方向与支撑结构6s1及支撑结构6s2的延伸方向互相垂直。
在传统雾化装置的主体外壳中,通常在电池组件周围设置一主体支架以固定电池组件与其周边组件的距离。因主体支架本身具有一定的体积大小,反而限制了主体外壳内的空间,使得传统的雾化装置只能使用体积较小的主体。体积较小的主体降低了雾化装置的使用时间,或增加了雾化装置的充电频率。
本揭露提出的雾化装置在主体外壳中并不设置一主体支架,因此提高了主体外壳内可使用的空间。本揭露提出的雾化装置因此可以使用体积较大的主体,达成较长的使用时间与较低的充电频率。
在主体外壳中取消主体支架可带来上述优势。然而,取消主体支架亦需考虑如何将各个组件适当地设置于主体外壳中。
藉由在加热组件底座6上设置突出结构6p1、突出结构6p2、突出结构6p3及突出结构6p4可达成取消主体支架的效果。藉由加热组件底座6设置支撑结构6s1及支撑结构6s2可达成取消主体支架的效果。
突出结构6p1、突出结构6p2、突出结构6p3及突出结构6p4可以使加热组件底座6与电池组件7之间保持一空间。突出结构6p1、突出结构6p2、突出结构6p3及突出结构6p4可以避免电池组件7阻塞了加热组件底座6的开口6h5(见图7A)。突出结构6p1、突出结构6p2、突出结构6p3及突出结构6p4可以避免电池组件7阻塞了储油组件100A内的进气通道。
支撑结构6s1及支撑结构6s2可以抵靠油杯部1b的底部(见图8)。突出结构6p1、突出结构6p2、突出结构6p3及突出结构6p4可以抵靠电池组件7的顶部(见图8)。突出结构6p1、突出结构6p2、突出结构6p3及突出结构6p4可以与电池组件7的上表面直接接触(见图8)。
在雾化装置100的组装过程中,外壳1可藉由抵靠支撑结构6s1及支撑结构6s2,将加热组件底座6安置于主体外壳11内的预定位置。在雾化装置100的组装过程中,加热组件底座6可藉由突出结构6p1、突出结构6p2、突出结构6p3及突出结构6p4,将电池组件7安置于主体外壳11内的预定位置。
加热组件底座6另包含贯穿部分6b的一对开口6h3。加热组件3的加热线路31可以穿过开口6h3并与电池组件7电连接。
图5A说明根据本揭露的一些实施例的传感器固定座的立体图。传感器固定座9包含部分9a及部分9b。部分9a与部分9b相比具有较大的外径。传感器固定座9包含一空腔9c。空腔9c可用以收纳传感器8。传感器固定座9可用以固定传感器8。传感器固定座9可用以保护传感器8。传感器固定座9上的气流通道设计可使传感器8精确侦测主体100B内的气流。传感器固定座9包含沟渠9t1。沟渠9t1与空腔9c连通。
图5B说明根据本揭露的一些实施例的传感器固定座的俯视图。传感器固定座9的部分9a包含弧形表面9g1。弧形表面9g1形成传感器固定座9的一部份表面。传感器固定座9的部分9a包含平坦表面9s1。平坦表面9s1与弧形表面9g1共同环绕传感器固定座9的部分9a。平坦表面9s1与弧形表面9g1共同界定传感器固定座9的部分9a的边界。平坦表面9s1与弧形表面9g1的连接处包含第一角度θ 1及第二角度θ 2。在某些实施例中,第一角度θ 1与第二角度θ 2相同。在某些实施例中,第一角度θ 1与第二角度θ 2可以不同。
在某些实施例中,第一角度θ 1与第二角度θ 2可以在30°至40°的范围内。在某些实施例中,第一角度θ 1与第二角度θ 2可以在40°至50°的范围内。
与传感器固定座9的另一侧(如图5B的右侧)相比,平坦表面9s1与弧形表面9g1的连接处构成传感器固定座9的一个「缺角」。平坦表面9s1与弧形表面9g1构成的「缺角」与主体外壳11之间具有一空隙。该空隙可成为主体100B内气流通道的一部份。平坦表面9s1与弧形表面9g1构成的「缺角」可避免传感器固定座9阻塞了主体100B内的气流通道。
如图5B中所示,传感器固定座9在部分9a的中心轴9x1的左右两侧的外型不对称。
图5C说明根据本揭露的一些实施例的传感器固定座的仰视图。图5D说明根据本揭 露的一些实施例的传感器固定座的剖面图。图5D显示图5A中传感器固定座9沿着虚线A-A’方向的剖面图。图5E说明根据本揭露的一些实施例的传感器固定座的剖面图。图5E显示图5A中传感器固定座9沿着虚线B-B’方向的剖面图。
传感器固定座9在底部具有沟渠9t2与开口9h1。沟渠9t2与开口9h1连通。沟渠9t2与空腔9c经由开口9h1连通。沟渠9t2从传感器固定座9的一侧(如图5C的左侧)延伸至开口9h1。沟渠9t2延伸至开口9h1后并未继续朝另一侧(如图5C的右侧)延伸。
沟渠9t2如图5C中所示,传感器固定座9在部分9b的中心轴9x2的左右两侧的外型不对称。沟渠9t2的延伸方向与沟渠9t1的延伸方向大体上垂直。
如图5D中所示,传感器固定座9在顶部包含凹槽9r1。凹槽9r1与部分9a的表面9s2及9s3相邻。凹槽9r1从部分9a的表面9s2及9s3下陷一距离9L。当传感器固定座9与电池组件7设置于主体外壳11内时,传感器固定座9的表面9s2及9s3与电池组件7直接接触。凹槽9r1可以确保传感器固定座9内的气流通道不会被电池组件7阻塞。
图6A及6B说明根据本揭露的一些实施例的底盖的立体图。图6C说明根据本揭露的一些实施例的底盖的俯视图。图6D说明根据本揭露的一些实施例的底盖的仰视图。图6E说明根据本揭露的一些实施例的底盖的剖面图。图6E显示图6A中底盖10沿着虚线C-C’方向的剖面图。图6F说明根据本揭露的一些实施例的底盖的剖面图。图6F显示图6A中底盖10沿着虚线D-D’方向的剖面图。
底盖10的底部具有开口10h1。开口10h1贯穿底盖10并形成气流通道的一部份。底盖10的底部包含凹槽10r1、10r2、10r3及10r4。当传感器固定座9及底盖10安置于主体外壳11内时,凹槽10r1与10r2或凹槽10r3与10r4可形成气流通道的一部份。当传感器固定座9及底盖10安置于主体外壳11内时,若凹槽10r1与10r2形成气流通道的一部份时,凹槽10r3与10r4并非气流通道的一部份。当传感器固定座9及底盖10安置于主体外壳11内时,若凹槽10r3与10r4形成气流通道的一部份时,凹槽10r1与10r2并非气流通道的一部份。
举例言之,当传感器固定座9及底盖10安置于主体外壳11内时,若凹槽10r1与10r2对应于传感器固定座9的「缺角」,则凹槽10r1与10r2形成气流通道的一部份。相似的,当传感器固定座9及底盖10安置于主体外壳11内时,若凹槽10r3与10r4对应于传感器固定座9的「缺角」,则凹槽10r3与10r4形成气流通道的一部份。
如图6C所示,底盖10在中心轴10x1左右两侧呈现对称外型。虽然仅有底盖10一侧的凹槽可以形成气流通道,但在底盖10两侧设置对称的凹槽有其优势。呈现对称外型的底盖10可以降低组装难度。呈现对称外型的底盖10可以避免组装过程中的错误造 成主体100B的气流通道阻塞。
图7A说明根据本揭露的一些实施例的雾化装置的剖面图。
图7A显示如圖1A中所示的雾化装置100的剖面图。插管1t与油杯1b之间界定储液舱1c。储液舱1c可容纳烟油。加热组件3设置于密封连接件2及密封组件5之间。加热组件3与密封连接件2及密封组件5直接接触。加热组件3的两端可以吸收储液舱1c内的烟油。密封连接件2、密封组件5及加热组件底座6共同界定雾化室6c。加热线路31产生的气雾首先于雾化室6c内产生,随后经由插管1t被使用者吸食。
加热组件底座6包含一或多个开口6h5。在某些实施例中,加热组件底座6可包含6个开口6h5。在某些实施例中,开口6h5的孔径大小设计为让气体可以通过,但让液体难以通过。在雾化装置100的使用过程中,如果有气雾冷凝而残留于雾化室6c中,开口6h5的孔径大小设计让冷凝的液体不容易经由开口6h5进入主体100B中。开口6h5的孔径大小设计可避免主体100B内的电子组件因冷凝液产生故障。在某些实施例中,开口6h5的孔径大小在0.1mm至0.3mm的范围内。在某些实施例中,开口6h5的孔径大小在0.01mm至0.2mm的范围内。在某些实施例中,开口6h5的孔径大小在0.4mm至1.2mm的范围内。在某些实施例中,开口6h5的孔径大小約為0.55mm。
加热组件底座6的突出结构6p3及6p4可使电池组件7与加热组件底座6之间保持间隔。加热组件底座6的突出结构6p3及6p4可确保开口6h5畅通。电池组件7可与突出结构6p3及6p4接触。电池组件7可与表面9s2及9s3接触。电池组件7可固定于加热组件底座6与传感器固定座9之间。
如图7A底部所示,传感器固定座9的平坦表面9s1与主体外壳11之间具有空隙。平坦表面9s1与主体外壳11之间的空隙形成气流通道的一部份。
图7B说明根据本揭露的一些实施例的雾化装置的剖面图。图7B显示如圖2A中所示的雾化装置200的剖面图。雾化装置200与雾化装置100的差异在于密封连接件20的两侧具有鳍状结构20f1及20f2。鳍状结构20f1及20f2可与油杯部1b的内侧表面接触。鳍状结构20f1及20f2的延伸方向与加热组件3的延伸方向大致上平行。
鳍状结构20f1及20f2可在储液舱1c内产生导流的功能。在雾化装置200的持续使用过程中,当储液舱1c内的烟油存量较低时,鳍状结构20f1及20f2可促进储液舱1c内的烟油与加热组件3的接触。
鳍状结构20f1及20f2亦可避免加热组件3吸附过多的烟油。如图7B所示,鳍状结构20f1及20f2设置于加热组件3上方,可使烟油从加热组件3的侧面与加热组件3接触,避免烟油直接冲击加热组件3两端。
图8说明根据本揭露的一些实施例的雾化装置的剖面图。
支撑结构6s1及支撑结构6s2可以抵靠油杯部1b的底部。突出结构6p1及突出结构6p4可以抵靠电池组件7的顶部。电池组件7可固定于加热组件底座6与传感器固定座9之间。
图9A说明根据本揭露的一些实施例的雾化装置的气流示意图。图9B说明根据本揭露的一些实施例的雾化装置的气流示意图。
在某些实施例中,当传感器固定座9与底盖10与主体外壳11结合时,凹槽10r1及凹槽10r2在垂直方向上对应于传感器固定座9的平坦表面9s1。在某些实施例中,当传感器固定座9与底盖10与主体外壳11结合时,凹槽10r3及凹槽10r4在垂直方向上对应于传感器固定座9的平坦表面9s1。
如图9A所示,经由底盖10的开口10h1进入主体100B内的气流以f1标示。气流f1经过传感器8的底面及侧面后进入电池组件7与主体外壳11之间的空隙。进入开口10h1后,气流以f1直接与传感器8的底面接触,但并不与传感器8的顶面直接接触。气流f1可以确保使用者吸气时传感器8的顶面与底面产生压力差。气流f1可以确保使用者的吸气动作能被传感器8侦测。
传感器固定座9的气流通道设计,让传感器8的顶面与底面在使用者吸气时产生压力差。传感器固定座9的气流通道设计使传感器8能精确侦测使用者的吸气动作。传感器固定座9的气流通道设计能增进传感器8的敏感度。传感器固定座9的气流通道设计能增进传感器8的精确度。
经由凹槽10r1进入主体100B内的气流以f2标示。气流f2可以确保使用者的吸气过程中,有足够的新鲜空气进入雾化室6c中。从凹槽10r1进入主体100B内的气流,一部份沿着沟渠9t2与气流f1合流。沿着沟渠9t2进入开口9h1的气流以f3标示。
气流f1及f2从开口6h5进入雾化室6c之后(参阅图7A),经加热组件3加热产生一温度上升Tr。在某些实施例中,温度上升Tr可以在200℃至220℃的范围内。在某些实施例中,温度上升Tr可以在240℃至260℃的范围内。在某些实施例中,温度上升Tr可以在260℃至280℃的范围内。在某些实施例中,温度上升Tr可以在280℃至300℃的范围内。在某些实施例中,温度上升Tr可以在300℃至320℃的范围内。在某些实施例中,温度上升Tr可以在200℃至320℃的范围内。
从雾化室6c流出的气流进入插管1t。气流在到达开口1h1之前可产生一温度下降Tf。在某些实施例中,温度下降Tf可以在145℃至165℃的范围内。在某些实施例中,温度下降Tf可以在165℃至185℃的范围内。在某些实施例中,温度下降Tf可以在205 ℃至225℃的范围内。在某些实施例中,温度下降Tf可以在225℃至245℃的范围内。在某些实施例中,温度下降Tf可以在245℃至265℃的范围内。在某些实施例中,温度下降Tf可以在145℃至265℃的范围内。
在某些实施例中,插管1t可具有不均匀的内径。在某些实施例中,开口1h1可具有不均匀的内径。开口1h1的内径从靠近加热组件3处向远离加热组件3方向逐渐变大。开口1h1逐渐变大的内径可使气雾体积变大。
藉由调整插管1t1的内径宽度,可以控制使用者从开口1h1吸取的气雾温度。藉由调整插管1t1的内径宽度,可以控制使用者从开口1h1吸取的气雾体积。控制气雾温度可以避免用户被气雾烫伤。控制气雾体积可以提升使用者的吸气体验。
在某些实施例中,经由开口1h1被使用者吸入的气雾可以具有低于65℃的温度。在某些实施例中,经由开口1h1被使用者吸入的气雾可以具有低于55℃的温度。在某些实施例中,经由开口1h1被使用者吸入的气雾可以具有低于50℃的温度。在某些实施例中,经由开口1h1被使用者吸入的气雾可以具有低于45℃的温度。在某些实施例中,经由开口1h1被使用者吸入的气雾可以具有低于40℃的温度。在某些实施例中,经由开孔1h1被使用者吸入的气雾可以具有低于30℃的温度。
如本文中所使用,术语“近似地”、“基本上”、“基本”及“约”用于描述并考虑小变化。当与事件或情况结合使用时,所述术语可指事件或情况精确地发生的例子以及事件或情况极近似地发生的例子。如本文中相对于给定值或范围所使用,术语“约”大体上意味着在给定值或范围的±10%、±5%、±1%或±0.5%内。范围可在本文中表示为自一个端点至另一端点或在两个端点之间。除非另外规定,否则本文中所公开的所有范围包括端点。术语“基本上共面”可指沿同一平面定位的在数微米(μm)内的两个表面,例如,沿着同一平面定位的在10μm内、5μm内、1μm内或0.5μm内。当参考“基本上”相同的数值或特性时,术语可指处于所述值的平均值的±10%、±5%、±1%或±0.5%内的值。
如本文中所使用,术语“近似地”、“基本上”、“基本”和“约”用于描述和解释小的变化。当与事件或情况结合使用时,所述术语可指事件或情况精确地发生的例子以及事件或情况极近似地发生的例子。举例来说,当与数值结合使用时,术语可指小于或等于所述数值的±10%的变化范围,例如,小于或等于±5%、小于或等于±4%、小于或等于±3%、小于或等于±2%、小于或等于±1%、小于或等于±0.5%、小于或等于±0.1%,或小于或等于±0.05%。举例来说,如果两个数值之间的差小于或等于所述值的平均值的±10%(例如,小于或等于±5%、小于或等于±4%、小于或等于±3%、小于或等于±2%、小于或等于±1%、小于或等于±0.5%、小于或等于±0.1%,或小于或等于±0.05%),那么可认为 所述两个数值“基本上”或“约”相同。举例来说,“基本上”平行可以指相对于0°的小于或等于±10°的角度变化范围,例如,小于或等于±5°、小于或等于±4°、小于或等于±3°、小于或等于±2°、小于或等于±1°、小于或等于±0.5°、小于或等于±0.1°,或小于或等于±0.05°。举例来说,“基本上”垂直可以指相对于90°的小于或等于±10°的角度变化范围,例如,小于或等于±5°、小于或等于±4°、小于或等于±3°、小于或等于±2°、小于或等于±1°、小于或等于±0.5°、小于或等于±0.1°,或小于或等于±0.05°。
举例来说,如果两个表面之间的位移等于或小于5μm、等于或小于2μm、等于或小于1μm或等于或小于0.5μm,那么两个表面可以被认为是共面的或基本上共面的。如果表面相对于平面在表面上的任何两个点之间的位移等于或小于5μm、等于或小于2μm、等于或小于1μm或等于或小于0.5μm,那么可以认为表面是平面的或基本上平面的。
如本文中所使用,术语“导电(conductive)”、“导电(electrically conductive)”和“电导率”是指转移电流的能力。导电材料通常指示对电流流动呈现极少或零对抗的那些材料。电导率的一个量度是西门子/米(S/m)。通常,导电材料是电导率大于近似地10 4S/m(例如,至少10 5S/m或至少10 6S/m)的一种材料。材料的电导率有时可以随温度而变化。除非另外规定,否则材料的电导率是在室温下测量的。
如本文中所使用,除非上下文另外明确规定,否则单数术语“一(a/an)”和“所述”可包含复数指示物。在一些实施例的描述中,提供于另一组件“上”或“上方”的组件可涵盖前一组件直接在后一组件上(例如,与后一组件物理接触)的情况,以及一或多个中间组件位于前一组件与后一组件之间的情况。
如本文中所使用,为易于描述可在本文中使用空间相对术语例如“下面”、“下方”、“下部”、“上方”、“上部”、“下部”、“左侧”、“右侧”等描述如图中所说明的一个组件或特征与另一组件或特征的关系。除图中所描绘的定向之外,空间相对术语意图涵盖在使用或操作中的装置的不同定向。设备可以其它方式定向(旋转90度或处于其它定向),且本文中所使用的空间相对描述词同样可相应地进行解释。应理解,当一组件被称为“连接到”或“耦合到”另一组件时,其可直接连接或耦合到所述另一组件,或可存在中间组件。
如本文中所使用,术语“大约”、“基本上”、“大体”以及“约”用以描述和考虑小的变化。当与事件或情形结合使用时,所述术语可以指其中事件或情形明确发生的情况以及其中事件或情形极接近于发生的情况。如在本文中相对于给定值或范围所使用,术语“约”通常意指在给定值或范围的±10%、±5%、±1%或±0.5%内。范围可在本文中表示为从一个端点到另一端点或在两个端点之间。除非另外指定,否则本文中所公开的所有范 围包括端点。术语“基本上共面”可指在数微米(μm)内沿同一平面定位,例如在10μm内、5μm内、1μm内或0.5μm内沿着同一平面的的的两个表面。当参考“基本上”相同的数值或特征时,术语可指处于所述值的平均值的±10%、±5%、±1%或±0.5%内的值。
前文概述本揭露的若干实施例和细节方面的特征。本揭露中描述的实施例可容易地用作用于设计或修改其它过程的基础以及用于执行相同或相似目的和/或获得引入本文中的实施例的相同或相似优点的结构。这些等效构造不脱离本揭露的精神和范围并且可在不脱离本揭露的精神和范围的情况下作出不同变化、替代和改变。

Claims (20)

  1. 一种雾化装置,其包括:
    储油组件与主体,所述储油组件包含加热组件、支撑组件、密封组件及加热组件底座;
    所述加热组件设置于所述支撑组件的第一凹槽与第二凹槽之间,所述加热组件的一端與所述密封组件直接接觸;
    所述密封组件设置于所述加热组件底座的第一部分上;其中
    所述加热组件底座包含第一突出结构及第二突出结构,
    所述第一突出结构及所述第二突出结构朝向远离所述加热组件的方向延伸。
  2. 根据权利要求1所述的雾化装置,其中所述加热组件底座进一步包含介于所述第一突出结构及所述第二突出结构之间的第一支撑结构,所述第一支撑结构的延伸方向垂直于所述第一突出结构及所述第二突出结构的延伸方向。
  3. 根据权利要求1所述的雾化装置,其中所述主体包含电池组件,其中所述第一突出结构及所述第二突出结构接触所述电池组件的上表面。
  4. 根据权利要求3所述的雾化装置,其中所述主体进一步包含传感器固定座,所述传感器固定座包含第一凹槽及与所述第一凹槽相邻的第一表面及第二表面,其中所述电池组件的下表面与所述第一表面及所述第二表面接触。
  5. 根据权利要求3所述的雾化装置,其中所述电池组件包含第一部分及第二部分,其中所述电池组件的所述第一部分的宽度大于所述电池组件的所述第二部分的宽度。
  6. 根据权利要求1所述的雾化装置,其中所述加热组件底座的所述第一部分包含第一开口及第二开口,其中所述第一开口及所述第二开口并未贯穿所述加热组件底座的所述第一部分。
  7. 根据权利要求1所述的雾化装置,其中所述加热组件底座的所述第一部分包含第一凹槽及第二凹槽,且所述密封组件覆盖所述第一凹槽及所述第二凹槽。
  8. 根据权利要求1所述的雾化装置,其中所述主体包含传感器固定座,所述传感器固定座包含弧形表面及平坦表面,所述弧形表面及所述平坦表面共同界定所述传感器固定座第一部分的边界。
  9. 根据权利要求8所述的雾化装置,其中所述弧形表面及所述平坦表面之间包含第一角度及第二角度,所述第一角度与所述第二角度相同。
  10. 根据权利要求8所述的雾化装置,其中所述传感器固定座包含第一沟渠及第二沟渠,所述第一沟渠的延伸方向与所述第二沟渠的延伸方向垂直,所述第二沟渠在所述传感器固定座底部上从一侧延伸至第一开口。
  11. 根据权利要求10所述的雾化装置,所述传感器固定座进一步包含第一空腔,其中所述第一沟渠及所述第二沟渠与所述第一空腔连通。
  12. 根据权利要求1所述的雾化装置,所述储油组件进一步包含密封连接件,所述密封连接件包含第一凹槽及第二凹槽,其中所述密封连接件的所述第一凹槽及所述第二凹槽与所述加热组件接触。
  13. 根据权利要求12所述的雾化装置,其中所述密封连接件包含第一鳍状结构及第二鳍状结构,所述第一鳍状结构及所述第二鳍状结构的延伸方向平行于所述加热组件的延伸方向。
  14. 根据权利要求1所述的雾化装置,所述支撑组件包含金屬材質。
  15. 根据权利要求8所述的雾化装置,其中所述主体进一步包含底盖及主体外壳,所述底盖包含第一凹槽、第二凹槽、第三凹槽及第四凹槽,其中当所述传感器固定座与所述底盖与所述主体外壳结合时,所述第一凹槽及所述第二凹槽在垂直方向上对应于所述传感器固定座的所述平坦表面。
  16. 一种雾化装置,其包括:
    储油组件与主体;
    所述储油组件包含外壳、加热组件及加热组件底座;
    所述主体包含电池组件及传感器固定座;其中
    所述加热组件底座包含第一突出结构及第二突出结构,所述第一突出结构及所述第二突出结构朝向远离所述加热组件的方向延伸;
    其中所述电池组件设置于所述加热组件底座与所述传感器固定座之间。
  17. 根据权利要求16所述的雾化装置,所述传感器固定座包含第一凹槽及与所述第一凹槽相邻的第一表面及第二表面,其中所述电池组件的下表面与所述第一表面及所述第二表面接触。
  18. 根据权利要求16所述的雾化装置,其中所述第一突出结构及所述第二突出结构接触所述电池组件的上表面。
  19. 根据权利要求16所述的雾化装置,其中所述加热组件底座的第一部分包含第一开口及第二开口,其中所述第一开口及所述第二开口并未贯穿所述加热组件底座的所述第一部分。
  20. 根据权利要求19所述的雾化装置,所述储油组件進一步包含密封组件,其中所述密封组件覆蓋所述加热组件底座的所述第一开口及所述第二开口。
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