CN107087819B - Swirl electronic cigarette atomizer structure and swirl electronic cigarette atomizer - Google Patents

Abstract

The invention discloses a rotational flow electronic cigarette atomizer which comprises an atomizer cylinder body and an atomization generating device arranged in the atomizer cylinder body, wherein the upper end of the atomizer cylinder body is connected with a cigarette holder. The atomization generating device is of a lower side oil supply or side oil supply and lower side electric connection structure, the atomizer cylinder body is of a cylinder body with a circular section, and the atomization generating device is arranged at the lower part in the cylinder body; the wall surface of the atomizer cylinder body is provided with a rotational flow air inlet channel with an inner circle tangential direction. The lower part of the atomizer cylinder body is provided with a main air inlet channel, the air outlet end of the main air inlet channel is arranged at the lower side of the atomization generating device, and the air flow faces the atomization generating device. The structure of the invention can generate the rotating air flow in the atomizer, and can realize the effects of cooling the flue gas, removing large liquid drops and reducing noise under the action of the rotating air flow.

Description

Swirl electronic cigarette atomizer structure and swirl electronic cigarette atomizer

Technical Field

The invention relates to an article in the field of daily life, in particular to an electronic cigarette atomizer which can generate internal rotational flow.

Background

The electronic cigarette products in the current market are prepared by heating the electronic cigarette liquid through the electric heating wire, so that the electronic cigarette liquid is atomized to absorb the fog of the electronic cigarette, and the smoke generated by combustion is not absorbed any more, so that solid particles and liquid particles are not absorbed any more. The liquid particles are generated by manually configured electronic cigarette liquid, the content of various substances can be basically controlled accurately, and substances which are harmful to human bodies and are the tar generated during combustion can not be generated.

Currently known electronic cigarette atomizing devices generally place electronic cigarette liquid in a liquid storage cigarette cartridge, and an atomizing core for heating is directly installed in the cigarette cartridge, so that the atomizing core is located in the electronic cigarette liquid. If the electronic cigarette atomization core is electrified, the atomization core heats, so that electronic cigarette liquid is atomized, and the atomized electronic cigarette liquid is sucked out through the smoke channel to produce the effect of smoking samples. Since smoke needs to be sucked out, air needs to be introduced to cause the flow of the air stream. One or more air inlet holes are arranged at the bottom of the atomizing core, and the arrangement position of the air inlet holes can generate the following defects which cannot be overcome.

As shown in fig. 10, in a typical prior art atomizer structure, an atomizer outer cylinder a also serves as a shell of a cartridge, a flue cylinder B is further disposed in the atomizer outer cylinder a, a suction flue is disposed in the flue cylinder B, and an annular space is formed between the flue cylinder B and the outer cylinder a for accommodating tobacco tar. The atomizing core C is arranged at the lower part of the inner part of the outer barrel A, and the smoke outlet of the atomizing core C is connected to the flue barrel B. The lateral wall of atomizing core C is provided with inlet port D, and atomizing core C's bottom is provided with air inlet E simultaneously. Thus forming a complete atomizer. The inside of the atomization core C is provided with a spiral heating wire, the spiral of the spiral heating wire is internally provided with an oil guiding cotton, and the oil guiding cotton passes through the oil inlet D and is communicated with the tobacco tar accommodating space. When the atomizer with the structure is used, tobacco tar needs to be led in from the oil inlet D, air is led in from the air inlet E, and atomized smoke generated by heating is sucked into the oral cavity of a person through the tobacco bomb A.

The disadvantage of such atomizers is that: (1) the atomizer is overheated in operation, resulting in scalding the hand and scalding the mouth; (2) the noise generated is loud, causing uncomfortable feeling; (3) pollution and waste caused by oil leakage; (4) the oil injection causes waste and uncomfortable feeling during sucking. These problems have not been fundamentally solved. Particularly, if the oil injection is very hot, the respiratory tract of a user can be directly scalded, and the body injury is caused. The air inlet channel can also leak tobacco tar in the use process, so that the environment is polluted.

The concrete steps are as follows:

(1) When the atomizer works, the heating wire is continuously electrified to generate heat, and the current structure is a straight-tube type flue, so that the flue gas is also a linear type air flow, and the heat exchange efficiency is low. When the heating wire continuously heats and the generated heat is not continuously taken away, the temperature is continuously increased, the temperature is quickly increased, the heat is conducted to the wiring electrode through the wiring terminal of the heating wire and then is conducted to the metal part of the atomizer, and the heat conduction is quick, so that the atomizer can quickly heat integrally.

(2) The smoking noise is generated, various different sounds can be generated when the electronic cigarette works, such as when the atomization core works, and the heating wire can generate a blasting-like sound when the tobacco tar is atomized in the moment due to relatively large temperature change in the heating process. Secondly, because the design of the air passage is not reasonable, whistle or friction sound can be locally generated in the whole air passage of the air inlet and the air outlet, when the air passage is changed in path, the phenomenon that the negative pressure is changed into high pressure from the negative pressure can be in a high pressure area, and the noise can be particularly obvious.

(3) The atomizer oil spout produces when the relation of atomizer oil feed volume and atomizing volume mismatch, and the oil feed volume is too big, can cause the atomizing insufficient, will have great tobacco tar granule in the smog, and tobacco tar granule can directly inhale and get into the oral cavity along with the linear type air current, produces uncomfortable sense and extravagant. This phenomenon is more pronounced when the atomizer has just been filled with oil, there is excess oil in the vicinity of the heater wire, and when the atomizer has just been started, the oil will be instantaneously vaporized due to the temperature difference, and a large number of droplets are produced at the same time.

In view of the defects and shortcomings, the invention starts from changing the airflow structure in the atomizer so as to change the airflow state, improve the cooling effect, reduce the noise during smoking as much as possible and remove larger liquid drops generated during atomization. The atomizer structure with the rotary airflow is designed, and the problems can be well solved.

Disclosure of Invention

The invention aims to provide a rotational flow electronic cigarette atomizer, which enables atomized smoke to rotate in the atomizer through a rotational flow generating device, thereby improving the cooling effect and separating larger liquid drops.

According to the structure of the swirl electronic cigarette atomizer, the atomizer is of a circular cross-section structure, the atomizer cylinder is arranged, the atomization generating device is arranged in the atomizer cylinder, the inner circular tangential swirl air inlet holes are formed in the wall surface of the atomizer cylinder, and the horizontal position of the swirl air inlet holes is equal to or higher than the horizontal position of the atomization generating device of the atomizer.

In the above-mentioned swirl electronic cigarette atomizer structure, atomizer barrel lower part is provided with main intake duct, main intake duct gives vent to anger the end and sets up in atomizing generating device's downside, and the air current is towards atomizing generating device.

In the above-mentioned swirl electronic cigarette atomizer structure, atomization generation device is downside oil feed or side oil feed's structure, and the power is downside electricity structure, and atomizer barrel upper portion is circular smooth air flue, and circular smooth air flue upper end sets up the cigarette holder.

The invention discloses a swirl electronic cigarette atomizer which comprises an atomizer cylinder body and an atomization generating device arranged in the atomizer cylinder body, wherein the upper end of the atomizer cylinder body is connected with a cigarette holder. The atomization generating device is of a lower side oil supply or side oil supply and lower side or side electricity connection structure, the atomizer cylinder body is of a cylinder body with a circular section, and the atomization generating device is arranged at the lower position in the cylinder body; the wall surface of the atomizer cylinder body is provided with a rotational flow air inlet channel with an inner circle tangential direction; the lower part of the atomizer cylinder body is provided with a main air inlet channel, the air outlet end of the main air inlet channel is arranged at the lower side of the atomization generating device, and the air flow faces the atomization generating device.

In the above-mentioned swirl electronic cigarette atomizer, the horizontal position of the tangential swirl air inlet is higher than or equal to the horizontal height of the atomization generating device.

In the above-mentioned swirl electronic cigarette atomizer, the atomizer cylinder is composed of an upper section and a lower section, and the upper section and the lower section are detachably connected; the cyclone air inlet channel is arranged on the upper portion of the lower section or the lower portion of the upper section, a cyclone air inlet adjusting ring is arranged on the outer edge of the atomizer cylinder body where cyclone air is introduced, the cyclone air inlet adjusting ring can rotate along the axis, an air inlet adjusting hole is formed in the cyclone air inlet adjusting ring, and the position of the air inlet adjusting hole corresponds to that of the cyclone air inlet channel.

In the above-mentioned swirl electronic cigarette atomizer, swirl air inlets are a plurality of, and every swirl air inlet all sets up on atomizer barrel wall surface, and these swirl air inlets set up on the tangential direction of atomizer barrel interior circle.

Above-mentioned in the whirl electron smog spinning disk atomiser, the inside upper end of atomizer barrel is provided with the spiral-flow seat of reverse taper, and this reverse taper spiral-flow seat cone top is down, and the awl end is upwards, and upper end awl bottom sets up axial air vent, and axial air vent is connected with the cigarette holder to set up several tangential spiral-flow air vent at this axial air vent tangential direction, spiral-flow air vent runs through reverse taper spiral-flow seat lateral wall face, and awl end edge and atomizer barrel sealing connection.

In the above-mentioned swirl electronic cigarette atomizer, the side face of the inverted cone is an inward concave cambered surface.

Because the invention adopts the structure that the tangential air inlet is arranged on the wall surface of the atomizer cylinder body, the rotary air flow can be generated to enter the atomizer during smoking and can be rotated and lifted in the atomizer cylinder body. I.e. wherein the main air passage is a vertical upward air passage for supplying air to the aerosol generating device. The other is a side tangential direction rotational flow air inlet channel which can lead the rotational air flow into the atomizer and realize the rotational ascending air flow in the atomizer. The rotating air flow can generate a negative pressure area on the upper side of the atomization generating device, and a cyclone separation area is formed on the inner wall of the atomizer cylinder. The negative pressure area is favorable for sucking away the atomized smoke generated by the atomization generating device, the cyclone separation area can effectively separate larger liquid drops through centrifugal action, and the liquid drops are concentrated on the inner wall of the barrel of the atomizer and cannot enter the oral cavity.

Drawings

FIG. 1 is a schematic diagram of the construction of a swirl atomizer of the present invention;

FIG. 2 is a schematic cross-sectional view of the swirl inlet structure of FIG. 1 in A-A direction according to the present invention;

FIG. 3 is a schematic view of the airflow conditions of the swirl atomizer structure of the present invention;

FIG. 4 is a schematic view of the appearance of a nebulizer according to an embodiment of the invention;

FIG. 5 is a schematic view showing an exploded perspective view of an atomizer according to an embodiment of the present invention;

FIG. 6 is a schematic cross-sectional view of an atomizer according to an embodiment of the invention;

FIG. 7 is a schematic diagram showing a cross-sectional structure and an airflow state of an atomizer according to an embodiment of the present invention;

FIG. 8 is a schematic cross-sectional view of a swirl seat of an atomizer according to an embodiment of the invention;

FIG. 9 is a schematic view of a base structure of an atomizer according to an embodiment of the invention;

fig. 10 is a schematic cross-sectional structure of a prior art atomizer.

The figure shows: 1 is a cigarette holder; 2 is an atomizer cylinder; 3 is a cyclone separation zone; 4 is a central negative pressure area; 5 is a rotational flow air inlet channel; 6 is an atomization generating device; 7 is a main air inlet channel; 8 is a rotational flow air inlet adjusting ring; 9 is the lower section of the atomizer cylinder; 10 is a wiring electrode rod; 11 is a compression ring; 12 is a cyclone seat; 13 is an axial vent; 14 is a swirl seat air inlet channel; 15 is the side of the cyclone seat; 16 is a rotational flow air inlet regulating hole; 17 is a heating wire bracket; 18 is the atomizer base; 19 is an oil storage area, and 20 is a main air inlet channel outlet; 21 is a heating wire bracket mounting groove; 22 is a main inlet duct; 23 is the main inlet duct inlet.

101 is cigarette holder rotational flow smoke; 102 is in-cavity smoke; 201 is cigarette holder center straight line smoke; 202, center straight smoke in the cavity; 300 inlet airflow; 301 atomizes the smoke.

Detailed Description

The following detailed description of the invention refers to the accompanying drawings and specific examples, which are included to provide a further understanding of the invention, and are not intended to limit the scope of the invention.

As shown in fig. 1, 2 and 3, the structure principle diagram of the swirl electronic cigarette atomizer of the invention is shown.

The invention discloses a swirl electronic cigarette atomizer structure, which is of a circular cross-section structure, and is provided with an atomizer cylinder 2, and a cigarette holder 1 is connected with the upper end of the atomizer cylinder 2. An atomization generating device 6 is provided inside the atomizer cylinder 2, and the atomization generating device 6 is provided at a lower position inside the atomizer cylinder 2.

The wall surface of the atomizer cylinder 2 is provided with a rotational flow air inlet channel 5, and the rotational flow air inlet channel 5 is arranged in the tangential direction of the inner wall of the atomizer cylinder. The two ends (which may be called an air inlet end and an air outlet end) of the swirl air inlet channel 5 are respectively located on the outer wall and the inner wall of the atomizer cylinder 2, wherein one end on the inner wall, namely the air outlet end, is arranged along the tangential direction of the inner wall of the atomizer cylinder 2. The air inlet 5 may be two or more than two air inlets uniformly distributed on the circumference of the cylinder 2, and the axis of the air inlet 5 shown in fig. 1 is set in a horizontal direction, that is, the air inlet end and the air outlet end of the air inlet 5 are located on the same plane, and the plane is perpendicular to the axis of the cylinder 2.

Of course, the axis of the air inlet channel 5 can also have an inclined angle with the axis of the cylinder 2 to form a structure that the air inlet end is slightly lower than the air outlet end, so that the introduced air flow has an upward angle, and the upward swirling effect can be better realized.

As shown in fig. 1 and 3, the atomization generating device 6 is disposed at the lower position inside the atomizer cylinder 2, and is configured to supply oil downwards or laterally, and meanwhile, the atomization generating device 6 is also configured to be powered downwards or electrically, so that no other components are disposed on the upper side of the atomization generating device 6, so as to avoid affecting the flow direction and flow velocity of the rotating airflow.

At the bottom of the atomizer cylinder 2 at the lower side of the atomization generating device 6, a main air inlet 7 is provided, and air introduced by the main air inlet 7 directly flows through the atomization generating device 6 so as to bring away the smoke generated by the atomization generating device 6.

As shown in fig. 3, during smoking, air is sucked into the main air inlet 7, and the air flow 300 flows through the atomization generating device 6 to carry away the smoke generated by atomization and continue to flow upwards. Because the tangential swirl air inlet 5 formed on the side wall of the atomizer cylinder 2 exists, the rotating air flow enters the atomizer cylinder 2 from the swirl air inlet 5, is ejected along the tangential direction of the inner wall, and forms a spiral rising rotating air flow 102 inside. The helically ascending gas flow 102 rotates upwards, in which case a temporary negative pressure zone 4 is formed directly above the atomizing generating device 6. And a rotating airflow is formed at the periphery of the negative pressure zone 4, the rotating airflow has a centrifugal separation effect, and larger liquid drops can be separated by the centrifugal rotating airflow, which is called a cyclone separation zone 3.

Due to the existence of the negative pressure area 4, the smoke generated by the atomization generating device 6 can be better sucked away, and the atomization effect is improved. Due to the existence of the cyclone separation area 3, the smoke airflow 202 rising in a straight line can be partially transferred into the rotary airflow 102, so that larger liquid drops in the atomized smoke can be separated onto the inner wall of the atomizer cylinder 2, the liquid drops can not be inhaled into the oral cavity by a user, uncomfortable feeling of the user is reduced, meanwhile, tobacco tar can be saved, and the separated tobacco tar on the inner wall of the atomizer cylinder 2 can be used continuously after being refluxed.

The remainder of the straight rising airflow 202 will continue to flow upward, forming a central straight smoke 201 into the mouth. And the smoke 102 is rotated until the mouthpiece 1 portion enters the mouth in the form of a rotating smoke 101. The whole smoking process is completed.

Examples: fig. 4 to 9 show an embodiment of a swirl atomizer according to the present invention.

As shown in fig. 4, 5 and 6, the atomizer of the present embodiment mainly comprises a cigarette holder 1, an upper section 2 of the atomizer barrel, a lower section 9 of the atomizer barrel and a base 18, wherein the upper section 2 of the atomizer barrel and the lower section 9 of the atomizer barrel are detachably connected, such as threaded connection or sealed plug-in snap connection. The base 18 is detachably and hermetically connected with the lower section 9 of the atomizer cylinder. The cigarette holder 1 is connected with the upper section 2 of the atomizer cylinder body through a compression ring 11 and an inverted cone-shaped cyclone seat 12.

The heating wire 6 of the atomizing device is arranged on the heating wire bracket 17, the heating wire bracket 17 is fixedly arranged on the base 18, and the power supply of the heating wire 6 is introduced from the outside of the base 18 through the electrode rod 10.

As shown in fig. 4 and 5, a swirl air inlet 5 is provided at the joint between the upper and lower sections of the atomizer cylinder, the swirl air inlet 5 penetrates through the side wall of the lower section 9 of the cylinder, is a tangential air inlet of the inner wall, the swirl air inlet 5 is provided with an air inlet end and an air outlet end, and air flow can enter through the air inlet end and then flow out from the air outlet end, so that a rotary air flow is formed in the lower section 9 of the atomizer cylinder. In order to achieve the adjustment of the intake air amount of the swirl intake duct 5, a swirl intake air adjusting ring 8 is further provided, and the swirl intake air adjusting ring 8 is provided with an intake air adjusting hole 16 corresponding to the position of the swirl intake duct 5. And the air inlet adjusting ring 8 can rotate along the outer wall of the lower section 9 of the atomizer cylinder body by taking the axis as a shaft. Thus, the size of the opening of the air inlet end of the swirl air inlet passage 5 can be adjusted to adjust the amount of the rotary air flow.

As shown in fig. 5, 6 and 8, in order to better achieve the effect that the rotating airflow can reach, in this embodiment, a secondary cyclone device is added, that is, a cyclone seat 12 is disposed inside the upper section 2 of the atomizer cylinder, the cyclone seat 12 is in an inverted conical structure, and is disposed inside the upper end of the upper section 2 of the atomizer cylinder, the cone top is downward, the cone bottom is upward, the cone bottom edge is in sealing connection with the upper section 2 of the atomizer cylinder, an axial vent hole 13 is formed in the cone bottom of the cyclone seat 12, and a plurality of cyclone seat air inlets 14 in tangential directions are formed in the side wall of the vent hole 13, and these cyclone seat air inlets 14 are tangentially combined with the inner wall of the vent hole 13. The side surface of the inverted cone-shaped cyclone seat 12 is an inward concave cambered surface 15, and the cambered surface 15 is more suitable for a rotary rising path of the rotary airflow.

As shown in fig. 5 and 9, the base 18 is connected to the lower section 9 of the atomizer cylinder, an air inlet 7 is provided at the bottom of the base 18, the air inlet 7 is composed of an air inlet outlet 20, an air inlet body 22 and an inlet 23, the air inlet 23 is arranged on the side wall of the base and is horizontally arranged, and an air inlet adjusting ring can be arranged on the outer side of the air inlet. The outlet of the air inlet channel is arranged in a vertical state so that the inlet air flow can be blown to the atomization heating wire 6 directly. The air inlet body 22 is disposed in an inclined state to minimize the right angle change of the air flow direction and reduce noise.

The heating wire bracket 17 may be disposed in a mounting groove 21 provided inside the base 18.

As shown in fig. 9, an oil storage area 19 may be disposed inside the base 18 for storing tobacco oil and supplying oil to the atomization heating wire, and the simplest method is to seal the oil storage area 19 inside the base, and then guide the tobacco oil into the heating wire 6 through the oil guiding cotton.

As shown in fig. 7, a schematic diagram of the smoke flow state in this embodiment is shown. When smoking, firstly, the air flow entering from the main air inlet channel takes away the smoke generated by the atomization heating wire 6 and flows upwards. When reaching the height of the cyclone air inlet channel 5, the large liquid drops in the atomized smoke are trapped by the inner wall of the inner barrel of the atomizer and then flow down along the inner wall of the inner barrel of the atomizer, so that the atomized smoke cannot enter the oral cavity, and the temperature of the atomized smoke is reduced in the process of rotating and rising the airflow. When the smoke gas flow 102 rises to the bottom of the cyclone seat 12 in a rotating way, the smoke gas enters the vent hole 13 again along the tangential direction of the inlet channel 14 of the cyclone seat, continues to rise in the vent hole 13 and the cigarette holder 1 in a rotating way until the smoke gas is inhaled into the oral cavity, and the smoking process is completed.

The atomizer structure of the invention can overcome the defects in the prior art and realize the following

The beneficial effects are that:

1. the heat dissipation is fast, and the flue gas temperature is controllable. The traditional atomizer air flow is simple single straight-line air flow, the heat exchange efficiency is low, the main air inlet is designed at the bottom of the heating wire, the air flow blows from bottom to top, meanwhile, due to the rotary air flow entering in the tangential direction, a negative pressure area is formed in the middle of the main air flow, and the air flow of the main air inlet is accelerated. Therefore, heat exchange is carried out on the heat source area of the heating wire effectively, the temperature of the heating area can not continuously rise without limitation, meanwhile, the negative pressure of the air flow can be adjusted through the air inlet size of the tangential direction air inlet channel, the temperature of the atomized smoke can be controlled, when the rotating air flow is increased, the flow speed of the air flow is weakened, the rotating speed is reduced, and the negative pressure is reduced, and vice versa. The speed of the air flow is thus controlled to adjust the temperature of the atomizer and the atomizing temperature suitable for the user's preference.

(2) The main air flow is not injected, and rises due to high-speed rotation, once the atomizer is insufficiently atomized, large-particle oil drops are reserved, the air flow which rotates at high speed is separated from the inner wall of the atomizer cylinder body, and then the air flow returns to the oil storage chamber, so that the air flow cannot be sucked to the respiratory tract of a user, scalding cannot occur, and the air flow is relatively safer.

(3) The main air inlet and the rotational flow air inlet adopt the angle form tangent to the inner circle, and atomization sound and friction sound generated during the work of the atomizer are generally transmitted along the inlet and the outlet of the air passage.

(4) The atomization effect is good, and tobacco tar is saved, and because the high-speed spiral air current is adopted, particles after atomization are coarsely dropped out of the main air passage in the rising process, remain on the inner wall, and then return to the oil storage cup for atomization again, so that the consumption of the tobacco tar is saved, and meanwhile, only fine particles after atomization enter the respiratory tract of a user. The taste is finer. At the same time, the atomized smoke is sucked up by the negative pressure, so that the atomized smoke is sucked out more completely.

(5) The atomized particles enter the respiratory tract of a user through sorting, so that the atomized particles are finer in taste, spirally enter the respiratory tract, and have stronger sensory impact on the user.

(6) According to the invention, through adjusting the size of the rotational flow air inlet channel 5, the speed of rotational air flow can be adjusted, meanwhile, the size of atomized particles is also adjusted, the faster the rotational air flow speed is, the finer the separated atomized particles are, meanwhile, the atomizing temperature is also adjusted, the air inlet channel is turned down, the rotating speed of the rotational air flow is slowed down, the heat exchange of a heating wire is slowed down, the temperature of atomized smoke is increased, meanwhile, the atomized particles are enlarged, and the sweet taste (original taste of tobacco tar components) is increased. The speed of the air inlet channel is increased, atomized particles of tobacco tar become small, the taste is thin and greasy, the sweet feeling disappears, and the impact feeling is increased. Therefore, the favorite taste of the user can be adjusted according to the favorite of the user.

Claims (9)

1. A whirl electron smog spinning disk atomiser structure, its characterized in that: the atomizer structure is of a circular cross-section structure and is provided with an atomizer cylinder, the atomizer cylinder is of a circular cross-section cylinder, an atomization generating device is arranged in the atomizer cylinder, an inner circular tangential rotational flow air inlet channel is arranged on the wall surface of the atomizer cylinder, and the horizontal position of the rotational flow air inlet channel is equal to or higher than the horizontal position of the atomization generating device; the lower part sealing connection of atomizer barrel has the base, the bottom of base is provided with main intake duct, the end of giving vent to anger of main intake duct sets up atomizing generating device's downside, so that follow the air current that the end of giving vent to anger of main intake duct flows can blow to atomizing generating device.

2. The swirl e-cigarette atomizer structure according to claim 1, characterized in that: the atomizer structure comprises a cigarette holder, a base and an atomizer cylinder body, wherein the atomizer cylinder body consists of an atomizer cylinder body upper section and an atomizer cylinder body lower section, the atomizer cylinder body upper section is detachably connected with the atomizer cylinder body lower section, the base is in sealing connection with the atomizer cylinder body lower section, the cigarette holder is connected with the atomizer cylinder body upper section, and the swirl air inlet channel is arranged on the upper part of the atomizer cylinder body lower section or the lower part of the atomizer cylinder body upper section; the atomization generating device comprises a heating wire support, a spiral heating wire and oil guiding cotton arranged in the heating wire, an oil storage area for storing tobacco tar and supplying oil to the heating wire is arranged in the base, the heating wire is arranged on the heating wire support, the heating wire support is fixedly arranged on the base, the oil guiding cotton is used for guiding the tobacco tar stored in the oil storage area into the heating wire, an electrode rod is arranged at the bottom of the base, and the electrode rod is connected with a wiring terminal of the heating wire.

3. The swirl e-cigarette atomizer structure according to claim 2, characterized in that: the main air inlet comprises an air inlet, an air inlet body and an air inlet outlet which are sequentially communicated, wherein the air inlet is horizontally arranged on the side wall of the base, the air inlet body is arranged in an inclined state, and the air inlet outlet is arranged in a vertical state;

and/or the number of the groups of groups,

the inside upper end of atomizer barrel is provided with the inverted cone shape whirl seat, the inverted cone shape whirl seat cone top is down, the awl end is upwards, the upper end awl bottom position of inverted cone shape whirl seat is provided with axial vent, axial vent with the cigarette holder intercommunication, and be provided with a plurality of whirl seat intake ducts on the tangential direction of axial vent, whirl seat intake duct run through behind the lateral wall face of inverted cone shape whirl seat with axial vent is linked together, the awl bottom edge of inverted cone shape whirl seat with atomizer barrel sealing connection.

4. The utility model provides a whirl electron smog spinning disk atomiser, is in including atomizer barrel, setting the inside atomization generating device of atomizer barrel, the upper end connection of atomizer barrel is provided with cigarette holder, its characterized in that: the atomization generating device is of a structure of lower side oil supply or side oil supply, lower power connection or side power connection, the atomizer cylinder body is of a cylinder body with a circular section, and the atomization generating device is arranged at the lower part in the atomizer cylinder body; the wall surface of the atomizer cylinder body is provided with an inner circular tangential rotational flow air inlet channel, and the horizontal position of the rotational flow air inlet channel is higher than or equal to the horizontal position of the atomization generating device; the lower part of atomizer barrel is provided with main intake duct, the end of giving vent to anger of main intake duct sets up atomizing generating device's downside, so that follow the air current that the end of giving vent to anger of main intake duct flows can blow to atomizing generating device.

5. The swirl e-cigarette atomizer of claim 4 wherein: the lower part of the atomizer cylinder body is connected with a base in a sealing way, the bottom of the base is provided with a main air inlet channel, the main air inlet channel comprises an air inlet channel inlet, an air inlet channel body and an air inlet channel outlet which are sequentially communicated, the air inlet channel inlet is horizontally arranged on the side wall of the base, the air inlet channel body is in an inclined state, and the air inlet channel outlet is in a vertical state;

and/or the number of the groups of groups,

the axis of the rotational flow air inlet channel and the axis of the atomizer cylinder body are provided with an inclined angle, so that the air inlet end of the rotational flow air inlet channel is lower than the air outlet end of the rotational flow air inlet channel.

6. The swirl e-cigarette atomizer of claim 4 wherein: the atomizer cylinder body consists of an atomizer cylinder body upper section and an atomizer cylinder body lower section, and the atomizer cylinder body upper section is detachably connected with the atomizer cylinder body lower section; the rotational flow air inlet channel is arranged at the upper part of the lower section of the atomizer cylinder or the lower part of the upper section of the atomizer cylinder, the outer edge of the atomizer cylinder at the rotational flow air inlet channel is provided with a rotational flow air inlet adjusting ring, the rotational flow air inlet adjusting ring can rotate along the axis of the atomizer cylinder body, an air inlet adjusting hole is formed in the rotational flow air inlet adjusting ring, and the position of the air inlet adjusting hole corresponds to the position of the rotational flow air inlet channel.

7. The swirl e-cigarette atomizer of claim 6 wherein: the cyclone air inlets are multiple, each cyclone air inlet is arranged on the wall surface of the atomizer cylinder, and the multiple cyclone air inlets are arranged along the tangential direction of the inner wall of the atomizer cylinder.

8. The swirl e-cigarette atomizer of claim 6 or 7 wherein: the inside upper end of atomizer barrel is provided with the reverse conical whirl seat, reverse conical whirl seat cone top is down, the awl end is upwards, the upper end awl bottom position of reverse conical whirl seat is provided with axial air vent, axial air vent with the cigarette holder is connected, and be in the tangential direction of axial air vent sets up a plurality of whirl seat intake ducts, whirl seat intake duct run through reverse conical whirl seat's lateral wall face and with axial air vent is linked together, reverse conical whirl seat's awl bottom edge with atomizer barrel sealing connection.

9. The swirl e-cigarette atomizer of claim 8 wherein: the side surface of the inverted conical cyclone seat is an inward concave cambered surface.