CN108420112B - Hybrid electronic atomization device - Google Patents

Abstract

The invention relates to a hybrid electronic atomization device which comprises an atomization component, a suction nozzle base and a power supply component. The atomization component comprises a shell, an atomization base, a baking type atomizer and a tobacco tar type atomizer. After the power supply assembly supplies power to the baking type atomizer and the tobacco tar type atomizer, the baking type atomizer can bake solid tobacco to generate smoke, and the tobacco tar type atomizer can atomize liquid tobacco tar to generate fog. The generated smoke enters the mixing cavity through the first air outlet hole and the first air guide channel, and the generated fog enters the mixing cavity through the second air outlet hole and the second air guide channel. The mixing cavity is internally provided with a movable stirring element, and the flowing action flow of the air flow generated during smoking can sufficiently drive the stirring element to move in the mixing cavity, so that the smoke and the mist are fully and uniformly mixed. The design does not need to additionally apply external force to uniformly mix the flue gas and the mist, the structural design is simple, and the limited space of the atomization device is fully utilized.

Description

Hybrid electronic atomization device

Technical Field

The invention relates to the technical field of electronic cigarettes, in particular to a hybrid electronic atomization device.

Background

Modern humans have become aware of the hazards to human health from cigarettes, and the pollution of cigarette smoke to the atmosphere, especially the indoor environment. With the improvement of life quality, people gradually increase the attention on self health and the attention on external environment, particularly indoor environment pollution, and smoking cessation is imperative. In order to solve the problem of excessive dependence of 'addict men' on traditional cigarettes, electronic cigarettes have come into play in recent years.

The atomization device of the traditional electronic cigarette generally atomizes liquid tobacco tar through a heating wire to generate mist for a user to suck. However, the smoke generated by the tobacco tar type electronic cigarette lacks the smoke smell and taste of cigarette burning, so that the electronic cigarette cannot be quickly adapted to the beginning of smoking cessation for most of smokers with heavy smoking addiction, is easy to reject and cannot achieve the effect of gradually quitting smoking. There is therefore a need for an improved tobacco tar type electronic cigarette that is capable of producing the appropriate amount of smoke flavor for cigarette combustion. However, due to the limitation of the small volume of the electronic cigarette, it is difficult to mix the mist generated by the tobacco tar and the smoke generated by the solid tobacco uniformly.

Disclosure of Invention

Therefore, there is a need for a hybrid electronic atomizer which has a simple structure, can atomize tobacco tar to generate mist and bake solid tobacco to generate smoke, and can uniformly mix the mist and the smoke.

A hybrid electronic atomizer device comprising:

the atomization assembly comprises a shell, an atomization base, a baking type atomizer and a tobacco tar type atomizer, wherein the shell is arranged on the atomization base, a containing cavity is formed inside the shell, the baking type atomizer and the tobacco tar type atomizer are arranged in the containing cavity and are respectively arranged on the atomization base, a baking cavity is arranged in the baking type atomizer and can bake tobacco to generate smoke, the baking type atomizer is provided with a first air outlet communicated with the baking cavity, an atomization cavity is arranged in the tobacco tar type atomizer and can atomize tobacco tar to generate fog, and the tobacco tar type atomizer is provided with a second air outlet communicated with the atomization cavity;

the suction nozzle base is arranged on the shell in a matched mode and seals the accommodating cavity, a smoke channel is formed in the suction nozzle base, the smoke channel is provided with an outlet end and an inlet end which are opposite to each other, the outlet end is communicated with the outside, the inlet end extends to form a mixing cavity, a first air guide channel and a second air guide channel are further formed in the suction nozzle base, one end of the first air guide channel is communicated with the first air outlet hole, the other end of the first air guide channel is communicated with the mixing cavity, one end of the second air guide channel is communicated with the second air outlet hole, the other end of the second air guide channel is communicated with the mixing cavity, a movable stirring element is arranged in the mixing cavity, and the flowing effect of air flow generated during sucking is enough to drive the stirring element to move in the mixing cavity; and

and the power supply assembly is used for supplying power to the baking type atomizer and the tobacco tar type atomizer.

In one embodiment, the stirring element is configured with a hollow spherical configuration.

In one embodiment, the number of the stirring elements is two or more, and each of the stirring elements is independently disposed within the mixing chamber.

In one embodiment, an orthographic projection of the agitating element on a plane of the inlet end can obscure the inlet end of the smoke passage.

In one embodiment, the mixing chamber is provided with a barrier at a location adjacent to the inlet end to prevent the stirring element from entering the smoke channel.

In one embodiment, the flue gas mixing device further comprises a filter element, wherein the filter element is arranged in the first gas guide channel to filter the flue gas and then enter the mixing cavity.

In one embodiment, the inner wall of the first air guide channel is provided with a plurality of first protruding bodies which are arranged at intervals, and the inner wall of the second air guide channel is provided with a plurality of second protruding bodies which are arranged at intervals.

In one embodiment, the first protruding body extends along the first outlet hole in the direction of the mixing chamber, and the second protruding body extends along the second outlet hole in the direction of the mixing chamber.

In one embodiment, the power supply assembly includes a power supply housing and a power supply, a power supply cavity with an open end is formed inside the power supply housing, the power supply is disposed in the power supply cavity, the open end of the power supply housing is hermetically connected with one end of the atomizing base, which is far away from the mouthpiece base, the power supply is electrically connected with the baking type atomizer and the tobacco tar type atomizer respectively, and the atomizing base is provided with a release hole, which penetrates through the atomizing base to communicate the power supply cavity with the accommodating cavity.

In one embodiment, the bake-type atomizer comprises:

the baking assembly comprises a shell, a baking core and an electric connecting piece, the baking cavity is formed in the shell, the baking core is arranged in the baking cavity and connected with the electric connecting piece, and the electric connecting piece is connected with the power supply assembly; and

the air lock, with casing adaptation is connected and sealed toast the chamber, the inside cushion chamber of having seted up of air lock, the cushion chamber has open end and air lock bottom, the open end forms first venthole, the cushion hole has been seted up on the air lock bottom, the cushion hole runs through the air lock bottom in order to incite somebody to action the cushion chamber with toast the chamber intercommunication, the size in cushion hole is less than first venthole.

The hybrid electronic atomization device comprises an atomization component, a suction nozzle base and a power supply component. The atomization component comprises a shell, an atomization base, a baking type atomizer and a tobacco tar type atomizer. After the power supply assembly supplies power to the baking type atomizer and the tobacco tar type atomizer, the baking type atomizer can bake solid tobacco to generate smoke, and the tobacco tar type atomizer can atomize liquid tobacco tar to generate fog. The generated smoke enters the mixing cavity through the first air outlet hole and the first air guide channel, and the generated fog enters the mixing cavity through the second air outlet hole and the second air guide channel. The mixing cavity is internally provided with a movable stirring element, and the flowing action flow of the air flow (including the smoke and the mist) generated during smoking can sufficiently drive the stirring element to move in the mixing cavity, so that the smoke and the mist are fully and uniformly mixed. The design does not need to additionally apply external force to uniformly mix the flue gas and the mist, the structural design is simple, and the limited space of the atomization device is fully utilized. The smoke and the mist form uniformly mixed gas under the action of the stirring element to enter the smoke channel to be sucked by a user, the mixed gas has good smell stability and has proper smoke smell and taste similar to those of cigarettes during combustion, so that the user can adapt to the smoke quitting quickly when starting to quit smoking, and the proportion of the smoke and the mist can be adjusted by adjusting the power supply proportion of the power supply assembly to the baking type atomizer and the tobacco tar type atomizer to achieve the effect of gradually quitting smoking.

Drawings

Fig. 1 is a schematic structural diagram of a hybrid electronic atomizer according to an embodiment;

FIG. 2 is a cross-sectional view of the hybrid electronic atomizer of FIG. 1 taken along plane A-A;

fig. 3 is a sectional view of a partial structure of the hybrid electronic atomizer of fig. 1;

FIG. 4 is an exploded view of a nozzle mount of the hybrid electronic atomizer of FIG. 1;

FIG. 5 is a block diagram of a nozzle housing of the nozzle mount of FIG. 4;

FIG. 6 is a cross-sectional view of the nozzle housing of FIG. 5 taken along plane B-B;

FIG. 7 is a schematic view of a nozzle base of the nozzle base of FIG. 5;

FIG. 8 is a schematic diagram of an atomizing base of the hybrid electronic atomizer shown in FIG. 1;

fig. 9 is a schematic structural view of an electrode holder of the hybrid electronic atomizer of fig. 1;

figure 10 is a cross-sectional view of the electrode holder of figure 9 taken along plane C-C;

FIG. 11 is a schematic diagram of a bake-type atomizer of the hybrid electronic atomizer of FIG. 1;

FIG. 12 is a cross-sectional view of the bake form atomizer of FIG. 11 taken along plane D-D;

FIG. 13 is a schematic diagram of a bake core of the bake-type atomizer of FIG. 11;

FIG. 14 is a schematic diagram of a smoke type atomizer of the hybrid electronic atomizer of FIG. 1;

FIG. 15 is a cross-sectional view of the tobacco-based atomizer of FIG. 14 taken along plane E-E;

FIG. 16 is a sectional view of a part of the structure of the smoke type atomizer of FIG. 1;

fig. 17 is a schematic flow diagram of the smoke-type atomizer of fig. 1.

Detailed Description

In order to facilitate understanding of the invention, the invention is described in further detail below, mainly with reference to specific drawings and specific examples. Preferred embodiments of the present invention are shown in the drawings. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.

Referring to fig. 1 and 2, a hybrid electronic atomizer 10 according to an embodiment includes a mouthpiece 100, an atomizing assembly 200, and a power assembly 300.

The atomizing assembly 200 includes a housing 210, an atomizing base 220, a bake-type atomizer 230, and a tar-type atomizer 240. The housing 210 is disposed on the atomizing base 220, a housing chamber 2001 is formed inside the housing 210, and the grill type atomizer 230 and the tobacco tar type atomizer 240 are disposed in the housing chamber 2001 and disposed on the atomizing base 220, respectively. The power supply assembly 300 is used to power the bake-type atomizer 230 and the tar-type atomizer 240.

Referring to fig. 2 and fig. 3, a baking cavity 2002 is disposed in the baking type atomizer 230, and a first air outlet 2301 communicated with the baking cavity 2002 is further disposed on the baking type atomizer 230. Tobacco, such as tobacco leaves, cut tobacco, tobacco stems, etc., can be cured in the curing chamber 2002 to produce smoke, and the tobacco produces a suitable amount of smoke under the curing action of the curing atomizer 230 to be guided out of the curing chamber 2002 through the first air outlet 2301. The atomization cavity 2003 is arranged in the tobacco oil type atomizer 240, the atomization cavity 2003 can be used for atomizing tobacco oil to generate fog, the tobacco oil is also called as tobacco liquid, the tobacco oil is atomized to generate the fog like a cigarette by heating the tobacco oil type atomizer 240, harmful substances such as nicotine and the like are not generated or are less generated in the tobacco oil through atomization, and the harm of smoking to the health of a human body is reduced. The second air outlet hole 2401 communicated with the atomizing cavity 2003 is formed in the tobacco tar type atomizer 240. The tobacco tar is atomized into mist under the heating action of the tobacco tar type atomizer 230, and the mist is guided out of the atomizing chamber 2003 through the second air outlet holes 2401.

Referring to fig. 2 and fig. 4 to 6, the nozzle holder 100 is disposed on the housing 210 and seals the accommodating cavity 2001, the nozzle holder 100 is formed with a smoke passage 101, and the smoke passage 101 has an outlet end 1011 and an inlet end 1013 opposite to each other. The outlet end 1011 communicates with the environment and the inlet end 1013 extends upwardly to form the mixing chamber 102. The nozzle holder 100 is further provided with a first air guide channel 103 and a second air guide channel 104. One end of the first air guide passage 103 communicates with the first air outlet 2301, and the other end of the first air guide passage 103 communicates with the mixing chamber 102. One end of the second air guide channel 104 communicates with the second air outlet hole 2401, and the other end of the second air guide channel 104 communicates with the mixing chamber 102. The mixing chamber 102 is provided with a movable stirring element 110, and the flow action of the air flow (including the smoke and the mist) generated by inhaling the hybrid electronic atomizer 10 is enough to drive the stirring element 110 to move in the mixing chamber 102.

In the present embodiment, the smoke passage 101 is opened along the axial direction of the nozzle holder 100, and the mixing chamber 102 is provided with the inlet end 1013 of the smoke passage 101. The first air guide passage 103 and the second air guide passage 104 are designed to be perpendicular to the smoke passage 101, and the first air guide passage 103 and the second air guide passage 104 are disposed to be opposite to each other. Of course, in other embodiments, other air flow through designs are possible. In the present embodiment, the smoke passage 101, the first air guide passage 103, and the second air guide passage 104 are formed like an inverted "T" shape. A mixing chamber 102 is provided at the intersection of the three channels. The convection action of the flue gas and the mist is designed in such a way that the stirring element 110 moves faster, the mixing effect is enhanced, meanwhile, the heat exchange between the flue gas and the mist can be realized, the temperature of the air flow at the outlet end 1011 of the smoke channel 101 is reduced, and the taste sense of a user is improved.

Specifically, in the present embodiment, referring to fig. 4 to 6, the nozzle base 100 includes a nozzle housing 120 and a nozzle base 130, and the nozzle housing 120 and the nozzle base 130 are hermetically sleeved and connected with each other. The nozzle housing 120 and the nozzle base 130 are separately provided to facilitate the opening of the smoke passage 101, the mixing chamber 102, the first air guide passage 103, the second air guide passage 104, and the like.

In this embodiment, referring to fig. 5 and fig. 6, a stepped groove 1201 is formed on the bottom surface of the nozzle housing 120, the stepped groove 1201 is formed by recessing the bottom surface of the nozzle housing 120, and the nozzle base 130 is nested in the stepped groove 1201. The smoke channel 101, the mixing chamber 10, the first air guide channel 103 and the second air guide channel 104 are all arranged at the bottom of the stepped groove 1201. The nozzle base 130 is provided with a first air guide hole 105 and a second air guide hole 106. The first air-guide hole 105 corresponds to the first air-guide passage 103, and the second air-guide hole 106 corresponds to the second air-guide passage 104. After assembly, the nozzle base 130 is fittingly disposed on the housing 210 and hermetically seals the accommodating cavity 2001, and the first air guide holes 105 are matched with the first air outlet 2301, and the second air guide holes 106 are matched with the second air outlet 2401. The design ensures that the suction nozzle shell 120 and the suction nozzle base 130 are firmly matched and installed, and the limited space of the atomizing device is fully utilized.

Further, the number of the first air holes 105 is plural, and the number of the second air holes 106 is plural. The pore diameter of each of the first air-guide holes 105 and the second air-guide holes 106 is small, for example, 0.5mm to 5mm in diameter. The first air guide holes 105 with small hole diameters can enable smoke coming out of the baking cavity 2002 to slowly rise, reduce the temperature and enable the smoke to be mixed more uniformly. The second air guide holes 106 with small hole diameters can enable the fog coming out of the atomization cavity 2003 to slowly rise, reduce the temperature, enable the fog to be mixed more uniformly, and meanwhile improve the fine and greasy feeling of the fog; can also prevent tobacco tar from sputtering.

Specifically, referring to fig. 6 and 7, the mixing chamber 102 is formed by a first stirring groove 1021 formed on the nozzle housing 120 and a second stirring groove 1023 formed on the nozzle base 130, and after the nozzle housing 120 and the nozzle base 130 are covered, the first stirring groove 1021 and the second stirring groove 1023 enclose the mixing chamber 102. This design facilitates the formation of the mixing chamber 102 with slotted holes and the process of placing or replacing the stirring element 110 is simple and convenient.

Preferably, the mixing chamber 10 is a spherical chamber, which is designed to facilitate reducing resistance to movement of the stirring element 110 within the mixing chamber 102.

Specifically, the radial dimension of the mixing chamber 102 is slightly larger than the radial dimension of the stirring element 110, so that the stirring element 110 can move and simultaneously achieve the purpose of uniformly mixing the flue gas and the mist. For example, when the mixing chamber 102 is a spherical cavity and the stirring element 110 is a solid or hollow spherical structure made of a lightweight material, the diameter of the stirring element 110 is smaller than the inner diameter of the mixing chamber 102.

Further, the outer shape of the stirring member 110 is configured as a hollow spherical structure. This is advantageous in that the mass of the stirring element 110 is reduced and the moving resistance of the stirring element 110 is smaller. The stirring element 110 can be driven to move only under the flowing action of the smoke and the mist, the stirring effect is achieved, external force is not required to be additionally applied to uniformly mix the smoke and the mist, and the structural design is simple. Of course, in other embodiments, the stirring element 110 may be solid, for example, made of a lightweight material.

In the present embodiment, the number of the stirring elements 110 is more than two, for example, two, three, four, five, etc., and each stirring element 110 is independently disposed in the mixing chamber 102. The two or more stirring elements 110 stir simultaneously, which can further enhance the mixing effect of the flue gas and the mist. Of course, in other embodiments, the number of stirring elements 110 may be only one.

In this embodiment, the number of the stirring members 110 is two, and the stirring members 110 have a hollow spherical structure. When the electronic cigarette is smoked, the two stirring elements 110 are mutually and rapidly stirred in a rolling manner under the suction action of smoke, mist and air, so that the mixing effect is further enhanced, and the taste and aroma of the mixed gas are improved.

In this embodiment, the aperture of the mixing chamber 102 is larger than the aperture of the smoke channel 101. For example when the mixing chamber 102 is a spherical cavity structure and the smoke channel 101 is hollow cylindrical. The mixing chamber 102 has an inner diameter greater than the inner diameter of the smoke channel 101. The design enables the smoke and the mist to stay in the mixing cavity 102 and uniformly mix in the smoke channel 101.

In one embodiment, the orthographic projection of the agitating member 110 on the plane of the inlet end 1013 can obscure the inlet end 1013 of the smoke passageway 101. I.e., the diameter of the ball of the agitating member 110 is slightly larger than the diameter of the bore of the inlet end 1013, to prevent the agitating member 110 from entering the smoke passage 101.

In another embodiment, and with continued reference to fig. 5, the mixing chamber 102 is provided with a baffle 111 adjacent to the inlet end 1013, the baffle 111 preventing the stirring element 110 from entering the smoke channel 101. With this design, even if the size of the stirring member 110 is smaller than the opening of the inlet end 1013, the stirring member 110 can be prevented from entering the smoke passage 101 by the action of the barrier 111. The size of the stirring element 110 is small, the relative mass can be lighter, the movement in the mixing chamber 102 is smoother, and the mixing effect on the smoke and the mist is enhanced.

Specifically, there are a plurality of the blocking strips 111, and the plurality of the blocking strips 111 are arranged in parallel at intervals, so as to prevent the stirring element 110 from entering the smoke passage 101 and ensure smooth airflow.

Preferably, the first air guide passage 103 has a first protuberance 1031 on an inner wall thereof. The first protrusions 1031 are a plurality of protrusions 1031 spaced apart from each other, the plurality of first protrusions 1031 are spaced apart from each other to form a plurality of first air vent grooves 1033, and the smoke generated in the baking chamber 2002 enters the mixing chamber 102 through the first air guide holes 105 and the first air vent grooves 1033. The inner wall of the second air guide channel 104 is provided with a plurality of second protuberances 1041, the plurality of second protuberances 1041 are arranged at intervals to form a plurality of second air through grooves 1043, and the mist generated in the atomizing chamber 2003 enters the mixing chamber 102 through the second air guide holes 106 and the second air through grooves 1043. The arrangement of the first protuberance 1031 and the second protuberance 1041 can increase the surface area of the inner walls of the first air guide channel 103 and the second air guide channel 104, increase the heat exchange area, effectively reduce the temperature of smoke and mist, and prevent the oral cavity from being scalded.

In this embodiment, the first protuberance 1031 extends in the direction of the mixing chamber 102 along the first air outlet 2301, and the second protuberance 1041 extends in the direction of the mixing chamber 102 along the second air outlet 2401. The design does not obstruct the flow of the smoke and the fog and is beneficial to the through of the airflow.

Preferably, the electronic atomization device 10 further includes a filter element 140, and the filter element 140 is disposed in the first air guide channel 103 to filter the flue gas into the mixing chamber 102. The filter element 140 can filter out particles in the smoke and harmful substances such as tar generated by tobacco baking.

Specifically, the filter element 140 is disposed at the position of the first air guide hole 105, and the filter element 140 is a spherical body having a honeycomb micropore shape, such as a porous carbon fiber ball, a porous ceramic ball, a porous diatomite ball, a glass fiber ball, and the like, preferably a carbon fiber ball, and is designed into a honeycomb micropore shape, so that the filter element 140 has a good adsorption effect, can well absorb harmful substances such as tar, and ensure smooth airflow.

In the present embodiment, the grill type atomizer 230 and the tobacco tar type atomizer 240 are provided one each. Of course, it is understood that in other embodiments, the number of the bake-type atomizer 230 and the oil-type atomizer 240 may be plural, and the number of the first air-guide holes 105 and the second air-guide holes 106 is correspondingly matched with the number of the corresponding atomizers.

In the present embodiment, referring to fig. 8, the atomizing base 220 is provided with a first mounting hole 221 and a second mounting hole 223. The grill type atomizer 230 is disposed in the first mounting hole 221, and the soot type atomizer 240 is disposed in the second mounting hole 223. Preferably, the first and second mounting holes 221 and 223 are horizontally symmetrically disposed. In summary, the number of the mounting holes is the sum of the number of the grill-type atomizers 230 and the smoke-type atomizers 240.

Specifically, a convex column 225 is disposed on the side wall of the atomizing base 220, and an inner groove 211 matched with the convex column 225 is correspondingly disposed on the inner wall of the lower end of the housing 210. Referring to fig. 3 and 8, during installation, the protruding column 225 is engaged with the inner recess 211, so as to connect the housing 210 and the atomizing base.

In the present embodiment, the atomizing base 220 is made of an electrically insulating material, and accordingly, one electrode holder 227 is provided in each of the first mounting hole 221 and the second mounting hole 223 to electrically connect the bake-type atomizer 230 and the soot-type atomizer 240 to the electrode assembly 300.

Specifically, referring to fig. 9 and 10, the electrode seat 227 is a circular tube structure. One electrode base 227 fits within the first mounting hole 221 and the other electrode base 227 fits within the second mounting hole 223. The electrode holder 227 serves to electrically connect the power module 300 to the grill type atomizer 230 and the tobacco tar type atomizer 240, respectively. This design is simple in construction and facilitates electrical connection of power module 300 to both the bake-type atomizer 230 and the tobacco tar-type atomizer 240.

In this embodiment, a vertical surface 22701 is further disposed on the outer surface of the electrode holder 227. Accordingly, a first vertical wall 22101 is provided at an inner wall of the first mounting hole 221. The inner wall of the second mounting hole 223 is provided with a second vertical wall 22301. When installed, the vertical face 22701 of one electrode holder 227 is in mating abutting contact with the first vertical wall 22101, and the vertical face 22701 of the other electrode holder 227 is in mating abutting contact with the second vertical wall 22301. This is designed to be easily assembled and prevent the electrode holder 227 from rotating in the first mounting hole 221 and/or the second mounting hole 223.

Specifically, the inner surface of the upper end of the electrode holder 227 is provided with an internal thread 2271, and the grill-type atomizer 230 is threadedly coupled to the electrode holder 227. Similarly, the oil atomizer 240 is screwed to the other electrode holder 227. The inner cavity of the electrode holder 227 is further provided with a blocking portion 2273, and the blocking portion 2273 can be used for playing a role of blocking when the roasting atomizer 230 and/or the tobacco tar atomizer 240 are installed, so as to prevent the lower end of the roasting atomizer 230 and/or the tobacco tar atomizer 240 from being excessively pressed down, which may damage the electrode holder 227 and the roasting atomizer 230 and/or the tobacco tar atomizer 240.

In the present embodiment, a notch 2006 is provided on the upper end surface of the electrode holder 227, and the notch 2006 is an intake passage. The external air sequentially enters the baking type atomizer 230 and the tobacco tar type atomizer 240 through the air inlet holes 2101 and the notch 2006 on the housing 210, and the external air drives the smoke and the mist to flow towards the suction nozzle holder 100 and enter the mist channel 101.

Referring to fig. 11 and 12, in one embodiment, the bake-out atomizer 230 includes a bake-out assembly 231 and an air lock 233. The bakeout assembly 231 includes a housing 2311, a bakeout core 2313, and an electrical connector 2315. The casing 2311 is internally provided with a baking cavity 2002, the baking core 2313 is arranged in the baking cavity 2002 and is connected with an electric connecting piece 2315, and the electric connecting piece 2315 is connected with the power supply assembly 300. The air plug 233 is in fit connection with the housing 2311 and seals the baking cavity 2002, the buffer cavity 2004 is formed in the air plug 233, the buffer cavity 2004 is provided with an open end and an air plug bottom, the open end forms a first air outlet 2301, and the air plug bottom is provided with a buffer hole 2303. The buffer holes 2303 penetrate the bottom of the air plug to communicate the buffer chamber 2004 with the baking chamber 2002, and the size of the buffer holes 2303 is smaller than that of the first air outlet holes 2301. The flue gas can be temporarily stored and stayed in the buffer cavity 2004 and then enters the mixing cavity 102 from the first gas outlet 2301 and the first gas guide channel 103, so that the temperature of the flue gas is effectively reduced.

Further, the case body 2311 includes a baked outer case 23101 and a baked inner case 23103. In this embodiment, the baking outer casing 23101 is tubular and the baking inner casing 23103 is cup-shaped. The baking outer shell 23101 is fittingly sleeved on the outer wall of the baking inner shell 23103 and plays a role in protecting the baking inner shell 23103. Meanwhile, the shell body 2311 is divided into the baking outer shell 23101 and the baking inner shell 23103, so that the heat generated by baking of the baking cavity 2002 can be reduced from scalding a user in use.

Specifically, referring to fig. 13, the toasting core 2313 has a structure with a small top and a large bottom, and in this embodiment, the toasting core 2313 is substantially conical. This design facilitates full contact of the solid tobacco with the baked cores 2313 and uniform heating. The bottom of the bake core 2313 is provided with two electrical connection pins 23301.

Specifically, the electrical connector 2315 comprises an electrical connection seat 23501 and an electrode column 23503, wherein the electrode column 23503 is sleeved in an electrode hole of the electrical connection seat 23501 and is insulated by an insulating rubber plug 001. During installation, the baking core 2313 is fixedly arranged at the bottom of the baking inner shell 23103, one of two electric connecting pins 23301 on the baking core 2313 is connected with the electrode column 23503, and the other one is clamped between the insulating rubber plug 001 and the electric connecting seat 23501 so as to be electrically connected with the electric connecting seat 23501. The electrode column 23503 is electrically connected to the positive pole of the power source 320 and the electrical connector 23501 is electrically connected to the negative pole of the power source 320. The baking inner shell 23103 is provided with an airflow hole 2005 at the bottom, and the airflow hole 2005 is communicated with a notch 2006 arranged on the upper end face of the electric connecting seat 23501 in an airflow mode. Ambient air enters the baking chamber 2002 through the notch 2006 and the airflow aperture 2005.

When in use, tobacco leaves or cut tobacco and the like are stuffed into the baking cavity 2002, and then the air plug 233 is covered on the upper end of the baking inner shell 23103. The cigarette gas emitted from the tobacco leaves or the cut tobacco and the like baked by the baking core 2313 enters the buffer cavity 2004 through the buffer hole 2303, then enters the mixing cavity 102 through the first gas outlet 2301 and the first gas guide channel 103, is mixed with the mist in the mixing cavity 102, and then enters the mist channel 101 for smoking in use.

In this embodiment, referring to fig. 14 and 15, the tobacco tar type atomizer 240 includes an atomizing shell 241, an atomizing core 243 and an electrical connector 245. The inside tobacco tar chamber 2403 that has seted up of atomizing shell 241, the tobacco tar in tobacco tar chamber 2403 passes through tobacco tar hole 2405 and gets into atomizing core 243 to produce the fog through atomizing core 243 atomizing, derive through atomizing chamber 2003 and second venthole 2401.

It is understood that the tobacco tar type atomizer 240 may be an atomizer with other structures as long as it can atomize tobacco tar, and thus, the description thereof is omitted.

Referring again to fig. 1 and 2, power module 300 includes a power housing 310 and a power source 320. The power source 320 may be a rechargeable battery or the like. The power supply housing 310 has a power supply cavity 3001 formed therein with one end open. The power source 320 is disposed in the power source cavity 3001, the open end of the power source housing 310 is hermetically connected to an end of the atomizing base 220 away from the mouthpiece base 100, the power source 320 is electrically connected to the roasting atomizer 230 and the tobacco tar atomizer 240, a release hole 2007 is disposed on the atomizing base 220, and the release hole 2007 penetrates through the atomizing base 220 to communicate the power source cavity 3001 with the accommodating cavity 2001. Due to the design, the cavity in the power supply assembly 300 is combined with the cavity in the atomization assembly 200, the power supply cavity 3001 is ingeniously combined with the accommodating cavity 2001, and the explosion-proof function is achieved.

The power supply assembly 300 is electrically connected with the roasting atomizer 230 and the tobacco tar atomizer 240 respectively, and the power supply assembly 300 controls the output power of the roasting atomizer 230 and the tobacco tar atomizer 240 to adjust the proportion of the smoke of the roasting atomizer 230 and the tobacco tar atomizer 2400 according to the power, namely, the proportion of the smoke and the fog can be adjusted according to the requirement, so that the effect of gradually quitting smoking is achieved.

Specifically, power module 300 further includes a circuit board 330 and a charging interface 331. The circuit board 330 is electrically connected to the power source 320, and the charging interface 331 is electrically connected to the circuit board 330. The charging interface 331 is disposed at the bottom of the lower end of the whole hybrid electronic atomizer 10, and the charging interface 331 may be a USB interface, a MINIUSB interface, a Lighting interface, or the like.

In use, referring to fig. 16 and 17, the power module 300 supplies power to the grill atomizer 230 and the tobacco tar atomizer 240, respectively. The flue gas generated by the roasting atomizer 230 roasting tobacco and the like enters the mixing chamber 102 through the first air outlet 2301 and the first air guide channel 103. The mist generated by the liquid smoke atomized by the smoke type atomizer 240 enters the mixing chamber 102 through the second outlet hole 2401 and the second air guiding channel 104 (as shown by the dashed arrows in fig. 17). An agitation element 110 is disposed within the mixing chamber 102. The stirring element 110 is light in weight and can freely move in the mixing chamber 102, and the airflow flowing action during smoking can sufficiently drive the stirring element 110 to move in the mixing chamber 102, so that the smoke and the mist are fully mixed. The design does not need to additionally apply external force to uniformly mix the flue gas and the mist, the structural design is simple, and the limited space of the atomization device is fully utilized. The smoke and the mist form uniformly mixed gas under the action of the stirring element 110, the mixed gas enters the smoke channel 101 for a user to suck, the smell of the mixed gas is good in stability, and the mixed gas has a proper amount of smoke smell and taste similar to those of a cigarette when the cigarette is burnt, so that the mixed gas can be quickly adapted when the user starts smoking cessation.

In use, the hybrid electronic atomizer 10 supplies power to the grill atomizer 230 and the tobacco tar atomizer 240, respectively, via the power module 300. The flue gas generated by the roasting atomizer 230 roasting tobacco and the like enters the mixing chamber 102 through the first air outlet 2301 and the first air guide channel 103. The mist generated by the liquid smoke atomized by the smoke type atomizer 240 enters the mixing chamber 102 through the second air outlet hole 2401 and the second air guiding channel 104. The airflow during smoking drives the stirring element 110 in the mixing cavity 102 to move in the mixing cavity 102, so that the smoke and the mist are fully and uniformly mixed. The design does not need to additionally apply external force to uniformly mix the flue gas and the mist, the structural design is simple, and the limited space of the atomization device is fully utilized. The smoke and the mist form a uniformly mixed gas under the action of the stirring element 110, and the uniformly mixed gas enters the smoke channel 101 for the user to suck. The mixed gas has good smell stability and has a proper amount of smoke smell and taste similar to those of cigarettes during combustion, so that a user can adapt to the smoking cessation quickly when starting to quit smoking, and the proportion of smoke and fog can be adjusted by adjusting the power supply proportion of the power supply component to the baking type atomizer 230 and the tobacco tar type atomizer 240, thereby achieving the effect of gradually quitting smoking.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (10)

1. A hybrid electronic atomizer device comprising:

the atomization assembly comprises a shell, an atomization base, a baking type atomizer and a tobacco tar type atomizer, wherein the shell is arranged on the atomization base, a containing cavity is formed inside the shell, the baking type atomizer and the tobacco tar type atomizer are arranged in the containing cavity and are respectively arranged on the atomization base, a baking cavity is arranged in the baking type atomizer and can bake tobacco to generate smoke, the baking type atomizer is provided with a first air outlet communicated with the baking cavity, an atomization cavity is arranged in the tobacco tar type atomizer and can atomize tobacco tar to generate fog, and the tobacco tar type atomizer is provided with a second air outlet communicated with the atomization cavity; and

a power supply assembly for powering the bake-type atomizer and the tobacco tar-type atomizer;

it is characterized in that the preparation method is characterized in that,

the hybrid electronic atomization device further comprises a suction nozzle seat, the suction nozzle seat is arranged on the shell in a matched manner and is used for sealing the accommodating cavity, a smoke channel is formed in the suction nozzle seat, the smoke channel is provided with an outlet end and an inlet end which are opposite, the outlet end is communicated with the outside, the inlet end extends to form a mixing cavity, a first air guide channel and a second air guide channel are further formed in the suction nozzle seat, one end of the first air guide channel is communicated with the first air outlet hole, the other end of the first air guide channel is communicated with the mixing cavity, one end of the second air guide channel is communicated with the second air outlet hole, the other end of the second air guide channel is communicated with the mixing cavity, the first air guide channel and the second air guide channel are designed to be perpendicular to the smoke channel, and the first air guide channel and the second air guide channel are arranged oppositely, a movable stirring element is arranged in the mixing cavity, and the flowing action of the airflow generated during sucking is enough to drive the stirring element to move in the mixing cavity.

2. A hybrid electronic atomizer device according to claim 1, wherein the stirring element is configured as a hollow sphere.

3. A hybrid electronic atomizer device according to claim 1 or 2, wherein the number of said stirring elements is two or more, each of said stirring elements being independently disposed within said mixing chamber.

4. A hybrid electronic atomizer device according to claim 1, wherein an orthographic projection of said agitating element onto a plane of said inlet end is capable of obscuring said inlet end of said smoke channel.

5. A hybrid electronic atomizer device according to claim 1, wherein a barrier is provided in said mixing chamber adjacent to said inlet end to prevent said stirring element from entering said vapor passageway.

6. A hybrid electronic atomizer device according to claim 1, further comprising a filter element disposed within the first air guide channel to filter the flue gas into the mixing chamber.

7. A hybrid electronic atomizer device according to claim 1, wherein said first air guide channel has a plurality of spaced first protrusions on an inner wall thereof, and said second air guide channel has a plurality of spaced second protrusions on an inner wall thereof.

8. A hybrid electronic atomizer according to claim 7, wherein said first protrusion extends in a direction toward said mixing chamber along said first vent hole, and said second protrusion extends in a direction toward said mixing chamber along said second vent hole.

9. The hybrid electronic atomizer of claim 1, wherein the power supply assembly comprises a power supply housing and a power supply, the power supply housing has a power supply cavity formed therein, the power supply is disposed in the power supply cavity, the open end of the power supply housing is hermetically connected to an end of the atomizing base away from the mouthpiece, the power supply is electrically connected to the bake-type atomizer and the oil-type atomizer, respectively, and the atomizing base has a release hole formed therein, the release hole penetrates through the atomizing base to communicate the power supply cavity with the accommodating cavity.

10. A hybrid electronic atomizer according to claim 1, wherein said bake-type atomizer comprises:

the baking assembly comprises a shell, a baking core and an electric connecting piece, the baking cavity is formed in the shell, the baking core is arranged in the baking cavity and connected with the electric connecting piece, and the electric connecting piece is connected with the power supply assembly; and

the air lock, with casing adaptation is connected and sealed toast the chamber, the inside cushion chamber of having seted up of air lock, the cushion chamber has open end and air lock bottom, the open end forms first venthole, the cushion hole has been seted up on the air lock bottom, the cushion hole runs through the air lock bottom in order to incite somebody to action the cushion chamber with toast the chamber intercommunication, the size in cushion hole is less than first venthole.

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