RU2808668C1 - Air intake device with two channels for air supply, power supply device and device for aerosol generation - Google Patents

Abstract

FIELD: aerosol generating devices.

SUBSTANCE: group of inventions is related to a device that generates an aerosol, in particular to an air intake device with two channels for supplying air, a power supply device and a device for generating an aerosol. An air intake device with two channels for supplying air used for an aerosol generating device is claimed. The air intake device with two air supply channels includes a base and a sensor. The base is provided with a measurement cavity, wherein the measurement cavity communicates with the air outlet channel of the aerosol generating device. A fastening part is provided in the measurement cavity, which is equipped with a fastening cavity. The sensor is installed on the fastening part and seals the fastening cavity. The base is provided with an air inlet portion and a connecting hole, wherein the air inlet portion is in communication with the measurement cavity and the surrounding atmosphere. The connecting hole communicates with the mounting cavity and the surrounding atmosphere. The fastening part is equipped with a connecting groove, which communicates with the fastening cavity and the measurement cavity. The cross-sectional area of the connecting groove and/or the cross-sectional area of the connecting hole is smaller than the cross-sectional area of each air inlet portion. According to the features of the air intake device with two air supply channels, the air pressure on both sides of the sensor can also be kept constant even under incorrect operation, thereby ensuring that the sensor will not operate accidentally. A power supply device containing an air intake device with two channels for supplying air, and an aerosol generating device including a power supply device are also claimed.

EFFECT: group of inventions ensures prevention of unintentional activation of a sensor in an air intake device.

15 cl, 7 dwg, 1 tbl

Description

CROSS REFERENCES TO RELATED APPLICATIONS

The present disclosure of the technical essence of the invention is

transition to the national phase under International Patent Application No. PCT/CN 2021/080379, filed on March 12, 2021, which establishes priority by the filing date of Chinese patent application No. 202020319370.2, filed on March 13, 2020.

TECHNICAL FIELD

This group of inventions relates to a device that generates an aerosol,

in particular to an air intake device with two channels for supplying air, a power supply device and a device for generating an aerosol.

BACKGROUND OF THE ART

The aerosol generating device is also known as an electronic vaporizer. The principle of its operation is that after turning on the power button, the power supply device supplies power to the vaporizer, and after turning on the vaporizer, it heats the aerosol-forming substrate to produce smoke that the user can inhale.

Currently, most aerosol generating devices on the market are equipped with sensors. When the user smokes, the sensor detects the difference in gas pressure on both sides. In addition, the power supply device is controlled to supply power to the evaporator. When inhalation stops, the power supply device stops supplying power to the vaporizer. Thus, automatic use is realized, which is convenient for the user during operation.

However, the air intake of traditional aerosol generating devices usually has a single air supply channel. When the user touches, packs or transports the aerosol generating device, the sensor installation space is likely to be compressed, resulting in a gas pressure difference between the two sides of the sensor. As a result, the aerosol-generating device operates involuntarily and results in loss of electrical power and aerosol-forming substrate, as well as posing certain safety hazards during packaging, transportation, and use by the user.

DISCLOSURE OF THE INVENTION

Based on this, it is necessary to provide an air intake device with two air supply channels, which can prevent the sensor from being unintentionally triggered.

It is also necessary to equip the power supply device with an air intake device with two air supply channels.

In addition, it is necessary to equip the aerosol generating device with a power supply device.

The technical solution, the essence of which is intended to solve technical problems, is as follows: an air intake device with two channels for supplying air, made for an aerosol generating device, includes a base and a sensor, while a cavity for measurements is provided in the base, in addition, a cavity for measurement is connected to the air outlet channel of the aerosol generating device, a fastening part is provided in the measurement cavity, a fastening cavity is provided in the fastening part, the sensor is installed on the fastening part and seals the fastening cavity, the base is equipped with an air inlet part and a connecting hole, the air inlet part communicates with the measurement cavity and the surrounding atmosphere, the connecting hole communicates with the fastening cavity and with the surrounding atmosphere, the fastening part is equipped with a connecting groove, while the connecting groove communicates with the fastening cavity and the measuring cavity, the cross-sectional area of the connecting groove and/or connecting hole is less cross-sectional area of the air inlet.

In addition, the upper end of the base is provided with a hole, the measurement cavity is formed by the hole in the base, the fastening part protrudes from the inner lower wall of the base, the upper end of the fastening part is provided with a hole, the fastening cavity is formed by the hole formed in the fastening part.

In addition, the abutting edge protrudes from the inner wall of the lower end of the fastening part, the sensor is adjacent to the abutting edge, a first connecting groove is formed on the abutting edge, the first connecting groove communicates with the connecting hole; the second connecting groove is made in the inner wall of the fastening part; one end of the second connecting groove extends through the upper end surface of the fastening part, the other end of the second connecting groove communicates with the first connecting groove, the connecting groove includes a first connecting groove and a second connecting groove.

In addition, the air inlet part and the connection hole are provided on the lower end surface of the base, the connection hole is located along the central axis of the fastening part, the air inlet part is provided on one side of the connection hole and is located outside the fastening part.

In addition, the upper end surface of the fastening part along the axial direction of the fastening part is cut to form a slot, wherein the slot passes through the inner and outer walls of the fastening part, the sensor wire passes into the measurement cavity after passing through the slot, and the slot is filled with sealant.

The power supply device includes an air intake device with two air supply passages described in any of the previous paragraphs, the power supply device further includes a battery housing and a battery pack, the battery pack is mounted in the housing, a base is mounted on the lower end of the battery housing , the first air outlet channel is formed between the inner wall of the battery case and the outer wall of the battery battery, the first air outlet channel is in communication with the measurement cavity, the air outlet channel includes the first air outlet channel.

In addition, the upper part of the fastening part is made with a protrusion, the connecting groove passing through the upper end surface of the fastening part is offset relative to the protrusion, the lower end surface of the battery is adjacent to the protrusion.

The aerosol generating device includes a power supply device described in any of the preceding paragraphs, the aerosol generating device further includes an evaporator, the evaporator is electrically connected to the power supply device, a second air outlet is provided in the evaporator, the second air outlet is in communication with the first air outlet channel, in addition, the air outlet channel further includes a second air outlet channel.

In addition, the evaporator includes a liquid storage element, an evaporator base, a mouthpiece and a purge pipe, the liquid storage element is connected to the battery body, the liquid storage element has a liquid storage cavity, wherein the liquid storage cavity is configured to store an aerosol-forming substrate , the evaporator base and the mouthpiece are respectively installed at opposite ends of the liquid storage member, and the purge pipe is placed in the liquid storage cavity, and the second air outlet channel is formed by the internal cavity of the purge pipe, in addition, the mouthpiece is provided with a hole for releasing smoke, and the second channel for release, the air outlet channel communicates with the hole for releasing smoke.

In addition, the evaporator further includes an evaporator assembly, a lower portion of the second air outlet space defines an evaporator cavity, the evaporator assembly is disposed in the evaporator cavity, a liquid inlet portion is provided in a side wall of the purge pipe, the liquid inlet portion is in communication with the liquid storage cavity, and evaporator cavity.

The advantages of the present invention are as follows: in the air intake device with two air supply channels, or in the power supply device, or in the aerosol generating device, which are provided by the present group of inventions, by providing a connecting hole and a connecting groove when the user unintentionally touches the connecting holes, a small amount of gas entering the mounting cavity through the connecting hole can enter the measurement cavity through the connecting groove, so that the gas pressure on both sides of the sensor remains the same, to ensure that the sensor does not operate accidentally.

BRIEF DESCRIPTION OF THE DRAWINGS

The present group of inventions will now be described with reference to the accompanying drawings and embodiments.

Fig. 1 is a perspective view of an aerosol generating device according to the present invention;

Fig. 2 is an exploded isometric view of the aerosol generating device shown in FIG. 1;

Fig. 3 is an exploded isometric view of the power supply of the aerosol generating device shown in FIG. 2;

Fig. 4 is an exploded isometric view of the air intake device with two channels for supplying air to the power supply device shown in FIG. 3 from a different angle;

Fig. 5 is a cross-sectional view of the air intake device with two air supply channels shown in FIG. 4.;

Fig. 6 is an exploded isometric view of the evaporator of the aerosol generating device shown in FIG. 2.;

Fig. 7 is a cross-sectional view of the aerosol generating device shown in FIG. 1.

In the illustrations, the following structural elements are indicated by numerical positions:

DETAILED DESCRIPTION OF THE PREFERRED OPTIONS FOR CARRYING OUT THE INVENTION

The present group of inventions will be further described in detail with reference to the accompanying drawings. These illustrations are simplified schematic representations that only schematically depict the main design features of the present group of inventions, therefore they characterize only the structural elements related to the present group of inventions.

In fig. 1 and 2 show a device for generating an aerosol. The aerosol generating apparatus includes an evaporator 100 and a power supply device 200 electrically coupled to the evaporator 100. In use, the power supply device 200 supplies electrical energy to the evaporator 100, and after the evaporator 100 is turned on, the aerosol-forming substrate is heated and evaporated by the heat. producing smoke that the user can inhale.

According to FIG. 3, the power supply device 200 includes an air intake device with two air supply passages 10, wherein the air intake device with two air supply passages 10 enables air intake. Specifically, when the user inhales, air from the environment enters into the aerosol generating device through the air intake device with two air supply channels 10, and then mixes with the generated smoke and finally enters the user's mouth.

According to FIG. 4, 5 and 7, the air intake device with two air supply channels 10 includes a base 11 and a sensor 12. The base 11 is provided with a measurement cavity 101. The measurement cavity 101 communicates with the air discharge channel of the aerosol generating device. The measurement cavity 101 is provided with a mounting portion 102. The mounting portion 102 is provided with a mounting cavity 103. The sensor 12 is mounted on the mounting portion 102 and seals the mounting cavity 103. The base 11 is provided with an air inlet portion 104 and a connection hole 105. The air inlet portion 104 communicates with the measurement cavity 101 and the surrounding atmosphere. The connecting hole 105 communicates with the mounting cavity 103 and the surrounding atmosphere. The fastening portion 102 is provided with a connecting groove 106. The connecting groove 106 communicates with the fastening cavity 103 and the measurement cavity 101. The cross-sectional area of the connecting groove 106 and/or the connecting hole 105 is less than the cross-sectional area of the air inlet portion 104.

In the prior art aerosol generating apparatus, a sensor is installed in a mounting cavity to form a closed space, and when the connecting hole is touched, the closed space is compressed, causing a difference in air pressure on both sides of the sensor, thereby triggering the sensor. In the aerosol generating device according to the present invention, a connecting hole 105 with a fastening cavity 103 is further provided on the base 11, and a connecting groove 106 with a fastening cavity 103 and a measurement cavity 101 is further provided on the fastening part 102. When the user accidentally touches the connecting hole 105 , a small amount of gas entering the mounting cavity 103 through the connecting hole 105 may enter the measurement cavity 101 through the connecting groove 106. Therefore, the gas pressure on both sides of the sensor 12 is kept the same to ensure that the sensor 12 does not operate correctly, thereby thereby increasing safety and reducing unintended consumption of electricity and aerosol-forming substrate. Meanwhile, since the cross-sectional area of the connecting groove 106 and/or the connecting hole 105 is smaller than the cross-sectional area of the air inlet portion 104, when the user takes a normal breath, the amount of air flowing through the connecting hole 105 is less than the amount of air flowing through the air inlet part of the air 104, the occurrence of a difference in gas pressure on both sides of the sensor 12 will not occur due to excess intake air, such design features ensure that the sensor 12, which has high sensitivity, will function correctly.

It should be noted that the cross-sectional area of the air inlet portion 104 is an area taken vertically in the direction in which the gas flows through the air inlet portion 104. The cross-sectional area of the connecting groove 106 is an area taken vertically in the direction in which the gas flows through the connecting groove 106. The cross-sectional area of the connecting hole 105 is an area taken vertically in the direction in which the gas flows through the connecting hole 105.

Referring to FIG. 4, in a specific embodiment of the invention, the upper end of the base 11 is provided with a hole, the measurement cavity 101 is formed by the hole in the base 11. The fastening part 102 protrudes from the center of the inner bottom wall of the base 11. Specifically, the fastening part 102 is located along the axial direction of the base 11, and the upper end of the fastening part 102 is provided with a hole, the fastening cavity 103 is formed by a hole in the fastening part 102. In this embodiment, the cross-section of the fastening part 102 is circular, and accordingly the sensor 12 has a cylindrical shape, the outer wall of the sensor 12 and the inner wall of the fastening part 102 are mated in an interference fit and are hermetically connected. It is obvious that in other embodiments of the invention, the cross-section of the fastening part 102 may also be in the shape of an ellipse, a polygon or the like, which is not limited to the example in the description.

In a particular embodiment of the invention, an annular abutting edge 107 projects inwardly from the inner wall of the lower end of the fastening part 102 along the radial direction of the fastening part 102. A first connecting groove 108 is formed on the upper end surface of the abutting edge 107. The first connecting groove 108 extends through the inner wall of the abutting edge 107 The other end of the first connecting groove 108 extends to the inner wall of the fastening part 102. The second connecting groove 109 is formed on the inner wall of the fastening part 102 along the axial direction of the fastening part 102. The upper end of the second connecting groove 109 extends through the upper end surface of the fastening part 102. The lower end the second connecting groove 109 communicates with the first connecting groove 108. The connecting groove 106 includes a first connecting groove 108 and a second connecting groove 109.

During installation, the lower end surface of the sensor 12 abuts the upper end surface of the adjacent edge 107 so that a gap is formed between the lower end surface of the sensor 12 and the inner lower wall of the base 11, as shown in FIG. 5. The gap communicates with one end of the first connecting groove 108 and the connecting hole 105, so that the gap communicates with the second connecting groove 109 through the first connecting groove 108 to further provide communication between the fastening cavity 103 and the examination cavity 101.

In a specific embodiment of the invention, the air inlet portion 104 and the connection hole 105 are provided in the lower end surface of the base 11. Specifically, the connection hole 105 is located along the central axis of the fastening portion 102, the air inlet portion 104 is located on the same side relative to the connection hole 105, and is formed on the outside of the fastening part 102. In this embodiment of the invention, the air inlet part 104 is formed by a plurality of through holes located close to each other, but there is only one connecting hole 105.

To prevent the electrical wire 121 of the sensor 12 from interfering with the installation of the sensor 12, in a particular embodiment of the invention, the upper end surface of the fastening part 102 along the axial direction of the fastening part 102 is cut out to form a slot 1021. The slot 1021 extends through the inner and outer walls of the fastening part 102. part 102 so that the slot 1021 communicates with the mounting cavity 103. When the sensor 12 is installed in the mounting cavity 103, the electrical wire 121 of the sensor 12 passes into the measurement cavity 101 after passing through the slot 1021. In addition, to prevent gas leakage, the slot 1021 is filled with sealant ( not shown in illustrations). The sealant seals and fills the gap 1021 and secures the electrical wire 121 to the fastening portion 102. Thus, the sealant also seals the gap 1021 while securing the electrical wire 121.

In addition, the support bar 1022 protrudes on the outer wall of the fastening part 102 along the axial direction of the fastening part 102. The support bar 1022 is arranged in accordance with the arrangement of the second connecting groove 109. By providing the support bar 1022, the mechanical strength of the fastening part 102 reduced by for having a second connecting groove 109, and the fastening portion 102 may be supported by a support bar 1022 to prevent deformation of the fastening portion 102.

According to FIG. 3 and fig. 7, the power supply device 200 further includes a battery case 20 and a battery 30. Here, the battery 30 is installed in the battery case 20. The base 11 is mounted on the lower end of the battery housing 20. The battery body 20 is shaped into a hollow cylindrical structure with two open ends. The first air outlet passage 201 is formed between the inner wall of the battery housing 20 and the outer wall of the battery 30. The first air outlet passage 201 extends through opposite ends of the battery housing 20. When the base 11 is installed at the lower end of the battery housing 20, the first air outlet passage 201 communicates with the measurement cavity 101. The air outlet passage includes the first air outlet passage 201.

Moreover, according to FIG. 4 and fig. 7, the upper portion of the fastening portion 102 is made protruding by the projection 1023. The connecting groove 106 extending through the upper end surface of the fastening portion 102 is configured offset from the projection 1023. When installed, the lower end surface of the battery 30 abuts the projection 1023 to prevent the battery 30 from being covered. connecting groove 106.

The power supply device 200 further includes a controller (not illustrated), and the controller is electrically coupled to the battery 30, the sensor 12, and the evaporator 100. When the user performs suction, air from the environment enters the sensing cavity 101 through the air inlet portion. 104 and the connecting hole 105, the sensor 12 detects the difference in gas pressure on both sides and generates a signal, this signal is transmitted to the controller; after the controller receives the signal, it controls the battery 30 to supply power to the evaporator 100, and the evaporator 100 heats and vaporizes the aerosol-forming substrate to produce smoke. When the user stops suction, the sensor 12 no longer generates a signal and the signal received by the controller is interrupted, at which time the battery 30 stops supplying power to the evaporator 100. In this embodiment, the sensor 12 is an air pressure sensor.

According to FIG. 6 and fig. 7, the evaporator 100 is installed at one end of the power supply device 200 opposite the air intake device with two air supply channels 10. When the evaporator 100 and the power supply device 200 are installed, the evaporator 100 is electrically connected to the positive and negative electrodes of the battery 30, so that the power supply device 200 may supply power to the evaporator 100.

In a specific embodiment, the vaporizer 100 includes a liquid storage member 40, a vaporizer base 50, a mouthpiece 60, a purge port 70, and a vaporizer assembly 80. The vaporizer base 50 and the mouthpiece 60 are respectively mounted at opposite ends of the liquid storage member 40. In the liquid storage member 40, a liquid storage cavity 401 is provided. The liquid storage cavity 401 is configured to store an aerosol-forming substrate. The purge pipe 70 is located in the liquid storage cavity 401. A second air outlet 701 is provided in the purge pipe 70. A portion of the space of the second air outlet 701 forms an evaporator cavity 702. The evaporator assembly 80 is located in the evaporator cavity 702. The evaporator cavity 702 communicates with the liquid storage cavity 401. The liquid storage member 40 is located at the upper end of the battery housing 20 to provide a connection between the evaporator 100 and the power supply device 200. When the evaporator 100 and the power supply device 200 are installed, the second air outlet passage 701 communicates with the first air outlet passage 201. The air outlet passage includes a second air outlet 701.

In a particular embodiment of the invention, the liquid storage member 40 is typically formed based on a hollow cylindrical structure with an opening at the lower end. The liquid storage cavity 401 is formed by an inner cavity of the liquid storage member 40. The evaporator base 50 is mounted on the lower end of the liquid storage member 40 and seals the liquid storage cavity 401. A mouthpiece 60 is mounted on the upper end of the liquid storage member 40. The mouthpiece 60 is provided with a smoke exhaust hole 601. The purge pipe 70 has two open ends. The second air outlet 701 is formed by the internal cavity of the purge pipe 70. The upper end of the purge pipe 70 is connected to the upper end of the liquid storage member 40, the second air outlet 701 is in communication with the smoke exhaust hole 601. The lower end of the purge pipe 70 is inserted into the through hole of the base of the evaporator 50 The base of the evaporator 50 is made of a sealing material such as silicone or rubber to improve the sealing performance and prevent leakage of the aerosol-forming substrate.

The evaporator cavity 702 is formed by the lower part of the space of the second air outlet 701. A liquid inlet 703 is provided in the side wall of the purge pipe 70. The liquid inlet 703 is in communication with the liquid storage cavity 401 and the evaporator cavity 702. In a particular embodiment, the evaporator assembly 80 includes a liquid guide element 81 and a heating element 82 that are in contact with each other. The liquid guiding member 81 has the ability to absorb an aerosol-forming substrate. The heating element 82 is electrically coupled to the battery 30 and can generate heat when power is applied. The liquid guide member 81 is attached to the inner wall of the purge pipe 70 corresponding to the liquid inlet 703 to absorb the aerosol-forming substrate entering the cavity of the evaporator 702 through the liquid inlet 703. A heating element 82 is located in the fluid guide element 81 and is configured to heat an aerosol-forming substrate absorbed on the fluid guide element 81. In this embodiment, the fluid guide element 81 is cotton and the heating element 82 is a mesh heating cylinder. type. It will be appreciated that in other embodiments not described, the liquid guide member 81 may also be a sponge, a fiber rope, a porous ceramic, or a porous graphite, etc. The heating element 82 may also be a heating sheet, a heating wire, or a heating rod. In other unspecified embodiments of the invention, the evaporator assembly 80 may also be an ultrasonic atomizing sheet or heating ceramic, etc., which is not limited to the examples of the description.

During use, the aerosol-forming substrate from the liquid storage cavity 401 enters the cavity of the evaporator 702 through the liquid inlet portion 703 and is absorbed by the liquid guide member 81. The heating element 82 heats the aerosol-forming substrate absorbed on the liquid guide member 81. The aerosol-forming substrate is evaporated by heating with generation of smoke, smoke fills the cavity of the evaporator 702. When the user inhales, air from the environment entering the measurement cavity 101 through the air inlet portion 104 and the connecting hole 105 enters the cavity of the evaporator 702 after passing through the first air outlet 201, and then mixed with the generated smoke, and the mixed gas enters the user's mouth sequentially through the second air outlet 701 and the smoke outlet 601.

In a particular embodiment of the invention, the top of the liquid storage member 40 is provided with a liquid injection hole 402. The liquid injection hole 402 communicates with the liquid storage cavity 401. The liquid injection hole 402 is configured to allow a user to perform a liquid injection operation. A sealing member 403 is installed in the liquid injection hole 402, and the sealing member 403 is configured to seal the liquid injection hole 402 to prevent leakage of the aerosol-forming substrate through the liquid injection hole 402. Obviously, the sealing member 403 is made of a sealing material such as silicone or rubber to improve sealing performance. When the user injects liquid, first the mouthpiece 60 is removed to access the sealing member 403, and then the sealing member 403 is removed to expose the liquid injection hole 402. This process can prevent improper operation and realize the child protection function.

In the air intake device with two air supply channels 10 provided by the present invention, when the user unintentionally touches the connecting hole 105, a small amount of gas entering the mounting cavity 103 through the connecting hole 105 may enter the measurement cavity 101 through the connecting groove 106, so that the gas pressure on both sides of the sensor 12 remains the same to ensure that the sensor 12 does not operate correctly. In addition, since the cross-sectional area of the connecting groove 106 and/or the connecting hole 105 is smaller than the cross-sectional area of the air inlet portion 104, gas pressure difference between both sides of the sensor 12 will not occur due to excessive air intake, the above-mentioned design features ensure that that sensor 12, having high sensitivity, will function correctly.

The power supply device 200 and the aerosol generating device provided by the present invention have the same technical advantages as the above-mentioned dual air supply path air intake device 10 since they have all the technical characteristics of the above-mentioned dual air supply path air intake device 10.

Taking the above embodiments of the group of inventions through the above description, those skilled in the art can make various changes and modifications without changing the essence of the present invention. The technical essence of the group of inventions is not limited to the information given in the description, and the scope of legal protection must be determined in accordance with the claims of the invention.

Claims (15)

1. An air intake device with two channels for supplying air, made for a device generating an aerosol, and containing a base and a sensor, wherein a cavity for measurements is provided in the base, and the cavity for measurements communicates with the channel for releasing air of the device generating an aerosol, in the measurement cavity is provided with a fastening part, wherein the fastening cavity is provided in the fastening part, the sensor is installed on the fastening part and seals the fastening cavity, the base is provided with an air inlet part and a connecting hole, in addition, the air inlet part communicates with the measurement cavity and the surrounding atmosphere, the connecting hole communicates with the fastening cavity and the surrounding atmosphere, the fastening part is equipped with a connecting groove, wherein the connecting groove communicates with the fastening cavity and the measurement cavity, and the cross-sectional area of the connecting groove and/or the connecting hole is smaller than the cross-sectional area of the inlet part for air. 2. An air intake device with two channels for supplying air according to claim 1, characterized in that the upper end of the base is provided with a hole, the measurement cavity is formed by a hole in the base, the fastening part protrudes from the inner lower wall of the base, and the upper end of the fastening part is provided with a hole, the fastening cavity is formed by a hole in the fastening part. 3. An air intake device with two channels for supplying air according to claim 2, characterized in that the adjacent edge protrudes from the inner wall of the lower end of the fastening part, the sensor is adjacent to the adjacent edge, and a first connecting groove is formed on the adjacent edge, the first connecting groove communicates with connecting hole; a second connecting groove is formed on the inner wall of the fastening part; one end of the second connecting groove extends through the upper end surface of the fastening part, the other end of the second connecting groove communicates with the first connecting groove, wherein the connecting groove includes a first connecting groove and a second connecting groove. 4. An air intake device with two channels for air supply according to claim 3, characterized in that the lower end surface of the sensor is adjacent to the upper end surface of the adjacent edge, a gap is formed between the lower end surface of the sensor and the inner lower wall of the base, which communicates with one end of the first a connecting groove and a connecting hole such that the gap communicates with the second connecting groove through the first connecting groove. 5. An air intake device with two channels for supplying air according to claim 3, characterized in that the fastening part protrudes from the center of the inner lower wall of the base and the cross-section of the fastening part is circular, the outer wall of the sensor and the inner wall of the fastening part are connected with an interference fit. 6. An air intake device with two channels for supplying air according to claim 3, characterized in that the support bar protrudes on the outer wall of the fastening part along the axial direction of the fastening part, the support bar is located in accordance with the location of the second connecting groove. 7. An air intake device with two channels for supplying air according to claim 2, characterized in that the air inlet part and the connecting hole are made on the lower end surface of the base, while the connecting hole is located along the central axis of the fastening part, and the air inlet part is located on one side relative to the connecting hole and outside the fastening part. 8. An air intake device with two air supply channels according to claim 7, characterized in that the air inlet portion is formed by a plurality of through holes located close to each other, but there is only one connecting hole. 9. An air intake device with two channels for supplying air according to claim 3, characterized in that the upper end surface of the fastening part along the axial direction of the fastening part is cut to form a slot, while the slot passes through the inner and outer walls of the fastening part, and the electrical wire of the sensor passes into the measurement cavity after passing through the gap, in addition, the gap is filled with sealant. 10. A power supply device containing an air intake device with two channels for supplying air according to any one of claims 1 to 9, characterized in that the power supply device further comprises a battery housing and a battery, wherein the battery is installed in the battery housing, the base is installed on the lower end of the battery body, a first air outlet is formed between an inner wall of the battery body and an outer wall of the battery, the first air outlet is in communication with the measurement cavity, the air outlet channel includes a first air outlet. 11. The power supply device according to claim 10, characterized in that the upper part of the fastening part is made with a protrusion, and the connecting groove passing through the upper end surface of the fastening part is offset relative to the protrusion, the lower end surface of the battery is adjacent to the protrusion. 12. An aerosol generating device comprising a power supply device according to claim 10 or 11, characterized in that the aerosol generating device further comprises an evaporator, wherein the evaporator is electrically connected to the power supply device, in addition, a second air outlet is provided in the evaporator, the second air outlet channel is in communication with the first air outlet channel, and the air outlet channel further comprises a second air outlet channel. 13. An aerosol generating device according to claim 12, characterized in that the evaporator contains a liquid storage element, an evaporator base, a mouthpiece and a purge pipe, wherein the liquid storage element is connected to the battery body, and a storage cavity is provided in the liquid storage element liquid, in addition, the liquid storage cavity is configured to store an aerosol-forming substrate, the evaporator base and the mouthpiece are respectively installed at opposite ends of the liquid storage element, the purge pipe is placed in the liquid storage cavity, the second air outlet channel is formed by the internal cavity of the purge pipe, the mouthpiece is equipped a smoke exhaust hole, the second air outlet channel is in communication with the smoke exhaust hole. 14. The aerosol generating device according to claim 13, characterized in that the evaporator further comprises an evaporator assembly, and the lower part of the space of the second air outlet channel forms an evaporator cavity, the evaporator assembly is located in the evaporator cavity, a liquid inlet portion is provided in the side wall of the purge pipe, the liquid inlet portion is in communication with the liquid storage cavity and the evaporator cavity. 15. The aerosol generating device according to claim 14, characterized in that an air intake device with two air supply channels is installed at the lower end of the power supply device, an evaporator is installed at the upper end of the power supply device, and the aerosol-forming substrate enters the liquid storage cavity into the evaporator cavity through the liquid inlet and evaporates to form smoke when the user inhales, air from the environment entering the measurement cavity through the air inlet and connecting hole enters the evaporator cavity after passing through the first air outlet and mixes with generated smoke, the mixed gas enters the user's mouth sequentially through the second air outlet and the smoke outlet.