EP3954232A1

EP3954232A1 - Atomizer having air pressure surge bin and application thereof

Info

Publication number: EP3954232A1
Application number: EP20913433.7A
Authority: EP
Inventors: Miaowen Yang; Yonghui LIN; Huifu SHUAI; Xiaohai DUAN; Zhining YIN; Huaijian GUO; Ya TIAN; Zhihui Zhang
Original assignee: Shenzen Zun Yi Pin Technology Co Ltd
Current assignee: Shenzen Zun Yi Pin Technology Co Ltd
Priority date: 2020-01-19
Filing date: 2020-08-04
Publication date: 2022-02-16
Also published as: WO2021143105A1; EP3954232A4; US20220183358A1; CN111150101A

Abstract

An atomizer having an air pressure surge bin and an application thereof. The atomizer includes a supporting housing (10); an atomization chamber (201) which is a hollow chamber with walls, and an air pressure surge bin (202) communicated with a bottom of the atomization chamber (201) is arranged below the atomization chamber (201); a smoke channel (30), with an inlet end communicated with the atomization chamber (201) and an outlet end configured for smoking; an air inlet channel (40) located below the atomization chamber (201), with an air inlet (401) configured for introducing external air and an air outlet (402) communicated with the atomization chamber (201); an e-liquid bin (50), where the e-liquid bin (50) is enclosed by an outer wall of the smoke channel (30), an outer wall of the atomization chamber (201), and an inner wall of the supporting housing (10); an e-liquid guiding member (60) arranged inside the atomization chamber (201) and communicated with the e-liquid bin (50), where the e-liquid guiding member (60) is connected to a heating component (70) for heating and atomizing e-liquid in the e-liquid guiding member (60). The atomizer prevents the supporting housing (10) from scalding hands to bring poor experience to a user, and meanwhile, the atomizer can prevent the e-liquid from leaking out, thereby improving the working effect of the atomizer and prolonging the service life of the atomizer.

Description

TECHNICAL FIELD

The disclosure relates to the field of electronic technologies, and more particularly, to an atomizer having an air pressure surge bin and an application thereof.

BACKGROUND

In 1963, Gilbert, an American engineer, applied for and obtained a patent of "smoke-free and non-tobacco cigarette", which provided a technical solution of smoking without burning tobacco leaves and cigarette paper, and through a safe and harmless smoking device, moist and fragrant smoke heated could be directly inhaled into lungs of a user. In 2003, Li Han, a Chinese pharmacist and former deputy director of Liaoning Institute of Traditional Chinese Medicine, applied for and obtained an invention patent of "non-combustible electronic atomization cigarette". In 2004, Ruyan Company founded by Li Han sold the world's first electronic cigarette.
The electronic cigarette is mainly composed of a cigarette rod with a battery and a chip, an atomizer, and a cartridge/e-liquid. Operating principle of the electronic cigarette is described below. Operating state of the electronic cigarette is controlled by an air switch controller (an airflow sensor) inside the battery. When smoking, a switch is turned on, the battery supplies power to an electric heating wire in the atomizer, the electric heating wire heats up to atomize the e-liquid attached around the electric heating wire, and generated smoke enters a mouth of a user along with an airflow, thus completing the simulation of a real smoking process. The atomizer, as the most important component of the electronic cigarette, includes an inner core heating wire, a tobacco juice bin (also called an e-liquid bin), and an air inlet hole, so as to ensure the successful completion of an atomization process.
According to the electronic cigarette, the e-liquid is usually heated and atomized by the atomizer to give out smoke for a smoker to use, and according to the electronic cigarette, the smoke is generally stored in the atomizer. Due to the high power of the electric heating wire and the large amount of heat emitted, the existing electronic cigarette with a large amount of smoke is prone to burning loss due to overhigh temperature of an atomization seat, generate scorching smell in the smoke, and lead to a hot outer shell of the electronic cigarette due to heat conduction, thus giving bad use experience to a user, and causing e-liquid leakage.
Chinese patent publication No. 201710631499.X, entitled "electronic cigarette atomizer and electronic cigarette", filed July 28, 2017 , has an operating principle as follows. A spiral electric heating wire 28 is vertically arranged on an atomization seat 25 and a liquid guiding core 27 is wrapped outside the electric heating wire 28, so that air flows through a spiral through hole of the electric heating wire 28, the spiral through hole forms an atomization chamber for atomizing the e-liquid. Since a cross section of the spiral through hole and an inner wall of the spiral through hole have a larger area, an air flux and an atomization area can be increased, so that air may be fully contacted with the e-liquid on the liquid guiding core 27, and a large amount of smoke can be generated when the power of the electric heating wire 28 is large enough.
When the power of the electric heating wire 28 is large, a lot of heat will be inevitably generated, and excess heat that has not been absorbed by the e-liquid will be transferred to the atomization seat 25 and an outer shell of the atomizer, resulting in high temperature. In a case of smoking for a long time, the liquid guiding core may be scorched and related parts of the atomizer may be burned and damaged, and it is easy to result in bad smoking experience to the smoker, such as scorching smell in the smoke and hot feeling on the electronic cigarette held.
Therefore, an air inlet groove 251 and a liquid inlet groove 255 are arranged on an outer wall of the atomization seat 25, which enables low-temperature air entering the atomizer to flow through the outer wall of the atomization seat 25 first to take away excess heat on the atomization seat 25 for cooling. Meanwhile, the low-temperature e-liquid before entering the liquid guiding core 27 flows through the outer wall of the atomization seat 25 first to take away excess heat from the atomization seat 25 to reduce the temperature, and the e-liquid is also preheated to make the e-liquid easier to flow and be atomized.
However, it is obvious that the structure of the air inlet groove and the liquid inlet groove set by the above patented technology cannot solve the problems of heat dissipation and e-liquid leakage of the atomizer at the same time. Therefore, it is necessary to further improve the prior art.

SUMMARY

In order to overcome the above defects in the prior art, the disclosure provides an atomizer having an air pressure surge bin and an application thereof, and solves the above technical problems.
The technical solutions used in the disclosure to solve problems in the prior art are described as follows.
There is provided an atomizer having an air pressure surge bin includes:

a supporting housing;
an atomization chamber, where the atomization chamber is a hollow chamber with walls, and an air pressure surge bin communicated with a bottom of the atomization chamber is arranged below the atomization chamber;
a smoke channel, where an inlet end of the smoke channel is communicated with the atomization chamber and configured for introducing smoke, and an outlet end of the smoke channel is configured for smoking;
an air inlet channel located below the atomization chamber, where an air inlet of the air inlet channel is configured for introducing external air, and an air outlet of the air inlet channel is communicated with the atomization chamber to introduce the external air into the atomization chamber;
an e-liquid bin, where the e-liquid bin is enclosed by an outer wall of the smoke channel, an outer wall of the atomization chamber, and an inner wall of the supporting housing; and
an e-liquid guiding member arranged inside the atomization chamber, communicated with the e-liquid bin, and configured for introducing e-liquid in the e-liquid guiding member into the atomization chamber, where the e-liquid guiding member is connected to a heating component for heating and atomizing the e-liquid in the e-liquid guiding member.

As a preferred solution of the disclosure, the atomizer having the air pressure surge bin further includes an atomization seat, where the atomization chamber is arranged on the atomization seat, the atomization chamber is provided with an e-liquid guiding port communicated with the e-liquid bin, and the e-liquid guiding member is configured to pass through the e-liquid guiding port from the atomization chamber and extend into the e-liquid bin.
As a preferred solution of the disclosure, the air pressure surge bin is arranged in the atomization seat, and an air outlet communicating the air pressure surge bin with the atomization chamber is arranged on the atomization seat.
As a preferred solution of the disclosure, the air inlet includes a first air inlet and a second air inlet, the first air inlet and the second air inlet are arranged at a bottom of the atomization seat and communicated with the air pressure surge bin, and the first air inlet, the second air inlet, the air pressure surge bin, and the air outlet form the air inlet channel.
As a preferred solution of the disclosure, the atomization seat is movably connected to the supporting housing, a sealing ring is arranged on a contact surface between the atomization chamber and the inner wall of the supporting housing, limiting blocks are arranged on two sides of a bottom of the atomization seat, and limiting grooves are arranged on the supporting housing matched with the limiting blocks.
As a preferred solution of the disclosure, the sealing ring includes a first sealing rubber ring and a second sealing rubber ring, the air pressure surge bin is arranged between the first sealing rubber ring and the second sealing rubber ring, and the air pressure surge bin is provided with an e-liquid return opening communicated with the inner wall of the supporting housing.
As a preferred solution of the disclosure, the e-liquid guiding member is a ceramic e-liquid guiding rod or e-liquid guiding cotton.
As a preferred solution of the disclosure, the heating component includes a heating wire, the heating wire is wound around the e-liquid guiding member, connection portions connected to external electrodes extend from two ends of the heating wire, through holes for the connection portions to pass through are arranged in the atomization seat, the through holes are separated from the air inlet and the air outlet, and the connection portions are configured to pass through the atomization seat to be connected with the external electrodes.
As a preferred solution of the disclosure, the supporting housing is provided with a detachable mouthpiece, the mouthpiece includes a mouthpiece cover connected to the supporting housing, a mouthpiece channel connected to the outlet end of the smoke channel is arranged on the mouthpiece cover, the mouthpiece channel is sheathed in the outlet end of the smoke channel, and sealing silica gel is arranged between the mouthpiece channel and the outlet end of the smoke channel connected.
An electronic cigarette includes the atomizer above.
Compared with the prior art, the disclosure has the following beneficial effects.
The atomizer having the air pressure surge bin of the disclosure is simple in structure and convenient to use. By arranging the air pressure surge bin on the atomizer, excessive smoke can converge in the air pressure surge bin, thus preventing an outer shell of the electronic cigarette from being hot and bringing bad use experience to a user. By providing the atomization seat with the first sealing rubber ring, the second sealing rubber ring and the e-liquid return opening, the e-liquid leaking from the first sealing rubber ring can return to the air pressure surge bin from the e-liquid return opening, and the second sealing rubber ring can also prevent the e-liquid that leaks from the first sealing rubber ring from leaking out of the atomization seat, so that the atomizer can prevent the e-liquid from leaking out, thus improving operating effect and service life of the atomizer.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a cross-section view of an atomizer having an air pressure surge bin in a first direction according to the disclosure;
FIG. 2 is a first structural diagram of an atomization seat of the atomizer having the air pressure surge bin according to the disclosure;
FIG. 3 is a second structural diagram of the atomization seat of the atomizer having the air pressure surge bin according to the disclosure;
FIG. 4 is a third structural diagram of the atomization seat of the atomizer having the air pressure surge bin according to the disclosure;
FIG. 5 is a fourth structural diagram of the atomization seat of the atomizer having the air pressure surge bin according to the disclosure;
FIG. 6 is a cross-section view of the atomizer having the air pressure surge bin in a second direction according to the disclosure;
FIG. 7 is an exploded view of the atomizer having the air pressure surge bin according to the disclosure;
FIG. 8 is a structural diagram of a supporting housing of the atomizer having the air pressure surge bin according to the disclosure;
FIG. 9 is a structural diagram showing connection between an e-liquid guiding member and a heating component in the atomizer having the air pressure surge bin according to the disclosure;
FIG. 10 is a structural diagram of a mouthpiece of the atomizer having the air pressure surge bin according to the disclosure; and
FIG. 11 is a structural diagram of an electronic cigarette according to the disclosure.

Numerals in the drawings are as follows: 10 refers to supporting housing; 20 refers to atomization seat; 30 refers to smoke channel; 40 refers to air inlet channel; 50 refers to e-liquid bin; 60 refers to e-liquid guiding member; 70 refers to heating component; 80 refers to sealing ring; 90 refers to mouthpiece; 100 refers to driving device; 101 refers to limiting groove; 102 refers to clamping groove; 201 refers to atomization chamber; 202 refers to air pressure surge bin; 203 refers to e-liquid guiding port; 204 refers to first depressurization chamber; 205 refers to second depressurization chamber; 206 refers to third air inlet; 207 refers to fourth air inlet; 208 refers to opening; 209 refers to sealing ring groove; 210 refers to e-liquid return opening; 211 refers to limiting block; 212 refers to clamping block; 213 refers to through hole; 301 refers to inlet end; 302 refers to outlet end; 401 refers to air inlet; 402 refers to air outlet; 701 refers to connection portion; 801 refers to first sealing rubber ring; 802 refers to second sealing rubber ring; 901 refers to mouthpiece cover; 902 refers to mouthpiece channel; 903 refers to sealing silica gel; 2091 refers to first sealing ring groove; 2092 refers to second sealing ring groove; 4011 refers to first air inlet; and 4012 refers to second air inlet.

DETAILED DESCRIPTION

The embodiments of the disclosure are further described hereinafter with reference to the accompanying drawings. It should be noted herein that the descriptions of these embodiments are used to help understand the disclosure, but do not constitute a limitation of the disclosure. In addition, the technical features involved in the embodiments of the disclosure described hereinafter may be combined with each other to derive other embodiments not explicitly described.
As shown in FIG 1, an atomizer having an air pressure surge bin includes:

a supporting housing 10, where the supporting housing 10 has an elliptical cross section, is configured for defining an inner space of the atomizer and protecting inner components of the atomizer;
an atomization chamber 201, where the atomization chamber 201 is a hollow chamber with walls, smoke is formed in the hollow chamber, an air pressure surge bin 202 communicated with a bottom of the atomization chamber 201 is arranged below the atomization chamber 201, excessive smoke formed in the atomization chamber 201 may converge in the air pressure surge bin 202, which reduces an air pressure in the atomization chamber 201, and further reduces a temperature of the atomization chamber 201;
a smoke channel 30 arranged in the supporting housing 10, where an inlet end 301 of the smoke channel is communicated with the atomization chamber 201 and configured for allowing air mixed with smoke to flow out of the atomization chamber 201, an outlet end 302 of the smoke channel is configured for smoking the air mixed with smoke, and in the embodiment, the smoke channel 30 is in a vertical structure and arranged in the middle of the supporting housing 10;
an air inlet channel 40 located below the atomization chamber 201, where an air inlet 401 of the air inlet channel is configured for introducing ambient air into the air inlet channel 40, and an air outlet 402 of the air inlet channel is communicated with the atomization chamber 201, and configured for introducing the ambient air in the air inlet channel 40 into the atomization chamber 201;
an e-liquid bin 50 configured for storing e-liquid, where the e-liquid bin 50 is enclosed by an outer wall of the smoke channel 30, an outer wall of the atomization chamber 201, and an inner wall of the supporting housing 10; and
an e-liquid guiding member 60 arranged inside the atomization chamber 201, communicated with the e-liquid bin 50, and configured for introducing the e-liquid in the e-liquid bin 50 into the atomization chamber 201, where the e-liquid guiding member 60 is connected to a heating component 70 for heating and atomizing the e-liquid in the e-liquid guiding member 60.

As shown in FIG. 2 and FIG. 3, in the embodiment, the atomizer further includes an atomization seat 20 having an elliptical cross section. The hollow atomization chamber 201 is arranged in the atomization seat 20, an e-liquid guiding port 203 communicated with the e-liquid bin 50 is arranged on the atomization chamber 201, and the e-liquid guiding member 60 is arranged in the atomization chamber 201, and passes through the e-liquid guiding port 203 and then extends into the e-liquid bin 50. The e-liquid in the e-liquid bin 50 is introduced into the e-liquid guiding member 60 in the atomization chamber 201 along two ends of the e-liquid guiding member 60, the heating component 70 arranged on the e-liquid guiding member 60 in the atomization chamber 201 heats the e-liquid guiding member 60, and the e-liquid on the e-liquid guiding member 60 is atomized into smoke. Further, in order to improve a utilization efficiency of the e-liquid, the e-liquid guiding port 203 is arranged near a bottom of the e-liquid bin 50, which reduces a vertical height from the e-liquid guiding member 60 to the bottom of the e-liquid bin 50.
Preferably, the air pressure surge bin 202 is arranged in the atomization seat 20, the air pressure surge bin 202 has a hollow chamber structure, and an air outlet 402 communicating the air pressure surge bin 202 with the atomization chamber 201 is arranged on the atomization seat 20. The air outlet 402 is configured for introducing external air into the atomization chamber 201, and meanwhile, when excessive smoke is formed in the atomization chamber 201, a part of the smoke may converge in the air pressure surge bin 202 through the air outlet 402 and take away a certain amount of heat, to form an air pressure surge structure, so that an air pressure in the atomization chamber 201 is reduced, and a temperature in the atomization chamber 201 is reduced while the air pressure is reduced.
Preferably, as shown in FIG. 2 to FIG. 4, the air inlet 401 of the air inlet channel 40 includes a first air inlet 4011 and a second air inlet 4012. The first air inlet 4011 and the second air inlet 4012 are arranged at the bottom of the atomization seat 20 and communicated with the air pressure surge bin 202. In the embodiment, the first air inlet 4011 and the second air inlet 4012 are staggered with the air outlet 402, which prevents condensed liquid formed in the atomization chamber 201 from entering the air pressure surge bin 202 along the air outlet 402 and then directly leaking out of the atomization seat 20 along the first air inlet 4011 and the second air inlet 4012. The first air inlet 4011 and the second air inlet 4012 further extend to a certain height into the air pressure surge bin 202 (not shown in the drawings), which also prevents condensed liquid in the air pressure surge bin 202 from leaking out of the atomization seat 20 along the first air inlet 4011 and the second air inlet 4012. Specifically, the first air inlet 4011, the second air inlet 4012, the air pressure surge bin 202 and the air outlet 402 form the air inlet channel 40, and external air enters the air pressure surge bin 202 from the first air inlet 4011 and the second air inlet 4012, and then enters into the atomization chamber 201 through the air outlet 402. Further, a first depressurization chamber 204 and a second depressurization chamber 205 are arranged on two sides of the air pressure surge bin 202, a third air inlet 206 communicated with the first depressurization chamber 204 is arranged on the atomization seat 20, a fourth air inlet 207 communicated with the second depressurization chamber 205 is arranged on the atomization seat 20, and a plurality of openings 208 higher than a bottom surface of the air pressure surge bin 202 are arranged between the first depressurization chamber 204 and the second depressurization chamber 205, and the air pressure surge bin 202. The first depressurization chamber 204 and the second depressurization chamber 205 are communicated with the air pressure surge bin 202 through the openings 208, so that the atomization seat 20 can be cooled by low-temperature air entering through a plurality of air inlets 401 while an air intake efficiency is improved. In other embodiments, the first depressurization chamber 204 and the second depressurization chamber 205 may also be used as trigger channels of the heating component 70, a trigger device is arranged in the first depressurization chamber 204 or the second depressurization chamber 205, and the trigger device is connected to an external power supply of the atomizer. An air pressure may be formed in the air pressure surge bin 202 when smoking, which means that an air pressure may also be formed in the first depressurization chamber 204 or the second depressurization chamber 205, and after sensing the air pressure, the trigger device arranged in the chamber controls the external power supply to work, and then controls the heating component 70 to work.
Preferably, as shown in FIG. 6 and FIG. 7, the atomization seat 20 is movably connected to the supporting housing 10, a sealing ring groove 209 is arranged on an outer wall of the atomization seat 20 contacted with an inner wall of the supporting housing10, a sealing ring 80 is mounted in the sealing ring groove 209, so as to prevent the e-liquid placed in the e-liquid bin 50 leaking out along a contact surface between the atomization seat 20 and the supporting housing 10. Further, the sealing ring groove 209 includes a first sealing ring groove 2091 and a second sealing ring groove 2092, the sealing ring 80 includes a first sealing rubber ring 801 and a second sealing rubber ring 802, and the first sealing rubber ring 801 and the second sealing rubber ring 802 are respectively mounted in the first sealing ring groove 2091 and the second sealing ring groove 2092. As shown in FIG. 5, in order to prevent a small amount of the e-liquid from leaking out of the atomization seat 20 from peripheries of the first sealing rubber ring 801 and the second sealing rubber ring 802 after being used for a long time, the air pressure surge bin 202 is arranged between the first sealing ring groove 2091 and the second sealing ring groove 2092, and the air pressure surge bin 202 is provided with an e-liquid return opening 210 communicated with the inner wall of the supporting housing 10. The e-liquid leaking from the periphery of the first sealing rubber ring 801 may enter the air pressure surge bin 200 through the e-liquid return opening 210, which further prevents the atomizer from leakage of the e-liquid.
Further, as shown in FIG. 3 and FIG. 8, limiting blocks 211 are arranged on two sides of the bottom of the atomization seat 20, and limiting grooves 101 matched with the limiting blocks 211 are arranged on the supporting housing 10. Meanwhile, a plurality of clamping blocks are further arranged on the outer wall of the atomization seat 20, and clamping grooves 102 matched with the clamping blocks are arranged on the inner wall of the supporting housing 10. When the atomization seat 20 is placed into the supporting housing 10, the limiting blocks 211 are clamped on the limiting grooves 101, and meanwhile, the clamping blocks are clamped with the clamping grooves 102 to prevent the atomization seat 20 from falling. In the embodiment, two clamping blocks are provided, which are arranged on the outer wall of the atomization seat 20 in a different orientation from the limiting blocks 211.
Preferably, as shown in FIG. 3 and FIG. 9, the e-liquid guiding member 60 is a ceramic e-liquid guiding rod or e-liquid guiding cotton. In the embodiment, the e-liquid guiding cotton is used as the e-liquid guiding member 60, the e-liquid guiding cotton contains the e-liquid, and is arranged in the atomization chamber 201, and two ends of the e-liquid guiding cotton pass through the e-liquid guiding ports 203 on the atomization seat 20 and then extend into the e-liquid bin 50. Two e-liquid guiding ports 203 are provided, and arranged at two ends of the atomization chamber 201, and the two e-liquid guiding ports 203 support the e-liquid guiding cotton at the same time. Meanwhile, in order to prevent the e-liquid in the e-liquid bin 50 from entering the atomization chamber 201 from the e-liquid guiding ports 203, the whole e-liquid guiding ports 203 need to be filled with the e-liquid guiding cotton.
Preferably, as shown in FIG. 6 and FIG. 9, the heating component 70 includes a heating wire, the heating wire is wound around the e-liquid guiding member 60, connection portions 701 connected to external electrodes extend from two ends of the heating wire, and through holes 213 for the connection portions 701 to pass through are arranged in the atomization seat 20. Further, the through holes 213 are separated from the air inlet 401 and the air outlet 402, and the through holes 213 include through holes 213 arranged on two sides of the air outlet 402, and through holes 213 located on one side of the first air inlet 4011 and one side of the second air inlet 4012 and matched with the through holes 213 on two sides of the air outlet. The connection portions 701 pass through the atomization seat 20 and then are connected to the external electrodes.
Preferably, as shown in FIG. 10, the supporting housing 10 is provided with a detachable mouthpiece 90, and the detachable mouthpiece 90 includes a mouthpiece cover 901 connected to the supporting housing 10. After the mouthpiece cover 901 is placed into the supporting housing 10, the mouthpiece cover 901 forms the e-liquid bin 50 with the inner wall of the supporting housing 10, the outer wall of the smoke channel 30 and the outer wall of the atomization seat 20, which means that after opening the mouthpiece cover 901, the e-liquid may be added into the e-liquid bin 50. Further, a mouthpiece channel 902 connected to the outlet end 302 of the smoke channel 30 is arranged on the mouthpiece cover 901, the mouthpiece channel 902 is sheathed in the outlet end 302 of the smoke channel 30, and sealing silica gel 903 is arranged between the mouthpiece channel 902 and the outlet end 302 of the smoke channel 30, so as to prevent the e-liquid placed leaking from a joint between the mouthpiece channel 902 and the outlet end 302 of the smoke channel 30.
As shown in FIG. 11, an electronic cigarette of the disclosure includes the atomizer above and a driving device 100 connected to the heating component 70 in the atomizer. The driving device 100 includes an outer shell connected to an outer shell of the supporting housing 10, a power supply and a control PCB board are arranged in the outer shell, and the power supply is connected to the heating component 70 to supply power to the heating component 70.

In order to determine whether or not the atomizer of the structure and the electronic cigarette using the atomizer will be damaged during transportation, especially to determine whether or not the e-liquid in the e-liquid bin 50 will leak out due to vibration during transportation, the atomizer and the electronic cigarette using the atomizer are tested for transportation vibration, and test results are as follows:

Table 1

Test item	Test condition and procedure	Determination standard	Phenomenon description	Determination
Transportation vibration test	Vibration amplitude: 2.45 cm; rotating speed: 200 RPM to 250 RPM; time of duration: 2 hours, 30 minutes for x, y and z axes respectively (90 minutes in total) Test quantity: 3 PCS carton products	If the products are normal in appearance, function and package, and have no process damage, the products are qualified	500 products are tested, where one product is subject to serious e-liquid leakage at a bottom, and one product is subject to slight e-liquid leakage at a bottom, so that a defective rate is 4%c	OK

It can be seen from Table 1 that after testing 30 products, one product is subject to serious e-liquid leakage at the bottom, and one product is subject to slight e-liquid leakage at the bottom, so that a defective rate is 6%. Therefore, defective rates of the atomizer of the structure and the electronic cigarette using the atomizer during transportation vibration both fall within a standard range. Therefore, when a user uses the product normally, the defective rate may be at a lower level than that during transportation vibration, which means that the atomizer of the structure has a good e-liquid leakage prevention effect.
Compared with the prior art, the disclosure has the following beneficial effects.
The atomizer having the air pressure surge bin 202 of the disclosure is simple in structure and convenient to use. By arranging the air pressure surge bin 202 on the atomizer, excessive smoke can converge in the air pressure surge bin 202, thus preventing the outer shell of the electronic cigarette from being hot and bringing bad use experience to the user. The atomization seat 20 is provided with the first sealing rubber ring 801, the second sealing rubber ring 802 and the e-liquid return opening 210, the e-liquid leaking from the first sealing rubber ring 801 can return to the air pressure surge bin 202 from the e-liquid return opening 210, and the second sealing rubber ring 802 can also prevent the e-liquid that leaks from the first sealing rubber ring 801 from leaking out of the atomization seat 20, so that the atomizer can prevent the e-liquid from leaking out, thus improving operating effect and service life of the atomizer.
Finally, it should be noted that: the above is only some embodiments of the disclosure, which are not intended to limit the disclosure. Although the disclosure is described in detail with reference to the above embodiments, those skilled in the art may still modify the technical solutions recorded in the above embodiments, or make equivalent replacements to some of the technical features. Any modification, equivalent substitution, improvement, etc. made within the gist and principle of the disclosure are included in the scope of protection of the disclosure.

Claims

An atomizer having an air pressure surge bin, comprising:
a supporting housing;

an atomization chamber, wherein the atomization chamber is a hollow chamber with walls, and an air pressure surge bin communicated with a bottom of the atomization chamber is arranged below the atomization chamber;

a smoke channel, wherein an inlet end of the smoke channel is communicated with the atomization chamber and configured for introducing smoke, and an outlet end of the smoke channel is configured for smoking;

an air inlet channel located below the atomization chamber, wherein an air inlet of the air inlet channel is configured for introducing external air, and an air outlet of the air inlet channel is communicated with the atomization chamber to introduce the external air into the atomization chamber;

an e-liquid bin, wherein the e-liquid bin is enclosed by an outer wall of the smoke channel, an outer wall of the atomization chamber, and an inner wall of the supporting housing; and

an e-liquid guiding member arranged inside the atomization chamber, communicated with the e-liquid bin, and configured for introducing e-liquid in the e-liquid bin into the atomization chamber, wherein the e-liquid guiding member is connected to a heating component for heating and atomizing the e-liquid in the e-liquid guiding member.
The atomizer having the air pressure surge bin of claim 1, further comprising an atomization seat, wherein the atomization chamber is arranged on the atomization seat, the atomization chamber is provided with an e-liquid guiding port communicated with the e-liquid bin, and the e-liquid guiding member is configured to pass through the e-liquid guiding port from the atomization chamber and extend into the e-liquid bin.
The atomizer having the air pressure surge bin of claim 2, wherein the air pressure surge bin is arranged in the atomization seat, and an air outlet communicating the air pressure surge bin with the atomization chamber is arranged on the atomization seat.
The atomizer having the air pressure surge bin of claim 3, wherein the air inlet comprises a first air inlet and a second air inlet, the first air inlet and the second air inlet are arranged at a bottom of the atomization seat and communicated with the air pressure surge bin, and the first air inlet, the second air inlet, the air pressure surge bin, and the air outlet form the air inlet channel.
The atomizer having the air pressure surge bin of claim 1, wherein the atomization seat is movably connected to the supporting housing, a sealing ring is arranged on a contact surface between the atomization chamber and the inner wall of the supporting housing, limiting blocks are arranged on two sides of a bottom of the atomization seat, and limiting grooves are arranged on the supporting housing matched with the limiting blocks.
The atomizer having the air pressure surge bin of claim 1, wherein the sealing ring comprises a first sealing rubber ring and a second sealing rubber ring, the air pressure surge bin is arranged between the first sealing rubber ring and the second sealing rubber ring, and the air pressure surge bin is provided with an e-liquid return opening communicated with the inner wall of the supporting housing.
The atomizer having the air pressure surge bin of claim 2, wherein the e-liquid guiding member is a ceramic e-liquid guiding rod or e-liquid guiding cotton.
The atomizer having the air pressure surge bin of claim 7, wherein the heating component comprises a heating wire, the heating wire is wound around the e-liquid guiding member, connection portions connected to external electrodes extend from two ends of the heating wire, through holes for the connection portions to pass through are arranged in the atomization seat, the through holes are separated from the air inlet and the air outlet, and the connection portions are configured to pass through the atomization seat to be connected with the external electrodes.
The atomizer having the air pressure surge bin of claim 7, wherein the supporting housing is provided with a detachable mouthpiece, the mouthpiece comprises a mouthpiece cover connected to the supporting housing, a mouthpiece channel connected to the outlet end of the smoke channel is arranged on the mouthpiece cover, the mouthpiece channel is sheathed in the outlet end of the smoke channel, and sealing silica gel is arranged between the mouthpiece channel and the outlet end of the smoke channel connected.
An electronic cigarette, comprising the atomizer of claims 1 to 9.