CN111165909A - Molecular resonance combined smoking set - Google Patents

Abstract

The invention discloses a molecular resonance composite smoking set which comprises a host (1), a molecular resonance atomizer (2) and a molecular resonance heater (3). The molecular resonance atomizer (2) and the molecular resonance heater (3) are arranged on the upper part of the main machine (1), and a separation plate (4) is arranged in the middle and is communicated through the airflow channel (5). The molecular resonance combined smoking set provided by the invention can be used for fully mixing the tobacco tar atomized smoke and the cigarette baking smoke generated based on the molecular resonance energy and then providing the mixture for a user to smoke, and has the advantages of no cotton design, non-contact atomization, good thermal uniformity, high heat utilization efficiency, high heating rate and the like.

Description

Molecular resonance combined smoking set

Technical Field

The invention belongs to the technical field of fusion of electronic cigarettes and low-temperature cigarettes, and particularly relates to a molecular resonance composite smoking set.

Background

In recent years, the development of traditional cigarettes has been increasingly restricted under the dual pressures of global forms of smoking control and public health opinion. The composite product is used as a novel low-harm cigarette substitute, the potential audience is quite large, and the market is continuously increased.

The composite product organically combines the electronic cigarette with the traditional cigarette, the low-temperature cigarette, the flavoring particles or the tobacco fragments and the like on the premise of ensuring the normal smoking function of the electronic cigarette so as to achieve the purposes of online flavoring and blending and improving the smoking quality. At present, the composite smoking set is mainly represented by an electronic cigarette and traditional cigarette type smoking set, an electronic cigarette and low-temperature cigarette type smoking set, an electronic cigarette and flavor-enhancing granule type smoking set and an electronic cigarette and tobacco fragment type smoking set. The electronic cigarette and the low-temperature cigarette are popular among consumers by virtue of the advantages of rich and coordinated aroma, strong physiological satisfaction, good smoking comfort and the like. However, the smoking set of "electronic cigarette + low-temperature cigarette" still has the following problems: (1) tobacco tar atomization portion: the metal heating wire is wrapped with the oil guide cotton to realize the atomization of the tobacco tar, and the oil guide cotton is easy to carbonize to generate burnt smell when being dry-burned or unevenly heated; the tobacco tar atomization belongs to contact atomization, and the tobacco tar is easy to sinter and adhere on the surface of the metal heating wire, so that harmful ingredients can be pyrolyzed and released or the electric heating performance and the service life of the metal heating wire are influenced; when the tobacco tar is in long-term contact with the metal heating wire, heavy metals can be leached and transferred to aerosol, and the health hidden danger is large. (2) Cigarette heating part: utilize stainless steel pipe outsourcing flexible circuit board to realize the circumference heating of low temperature cigarette, stainless steel pipe with the heat from low temperature cigarette periphery to inside conduction in, can expand the heat dissipation to reverse one side of low temperature cigarette, lead to cigarette heating portion heat utilization efficiency low, low temperature cigarette heating rate slow.

The present invention has been made to solve the above problems.

Disclosure of Invention

The invention provides a molecular resonance combined smoking set, which utilizes molecular resonance energy to realize tobacco oil atomization and cigarette heating and can effectively overcome the problems that oil guide cotton is easy to be burnt, tobacco oil is easy to be sintered and adhered by contact atomization and heavy metal can be leached in a tobacco oil atomization part of the existing combined smoking set, and the technical defects of low heat utilization efficiency and low-temperature cigarette heating rate in a cigarette heating part.

The technical scheme adopted by the invention for solving the technical problems is as follows: a molecular resonance combined smoking set comprises a host 1, a molecular resonance atomizer 2 provided with a tobacco tar atomizer 21 and an air inlet 22, a molecular resonance heater 3 provided with a cigarette heater 31, a partition board 4 and an air flow channel 5. The molecular resonance atomizer 2 and the molecular resonance heater 3 are arranged on the upper part of the main machine 1 in parallel, and a separation plate 4 is arranged in the middle. The tobacco tar atomized smoke produced by the tobacco tar atomizer 21 of the molecular resonance atomizer 2 and the tobacco tar baking smoke produced by the tobacco tar heater 31 of the molecular resonance heater 3 are conducted through the airflow channel 5.

Preferably, the housing 10 of the host 1 is internally provided with a microcontroller 11, a power supply battery 12 and a support 13, and the side of the housing 10 is provided with a main button 14, a display screen 15 and a charging interface 16.

Preferably, the tobacco atomizer 21 includes an atomizing unit 212, a first upper end cap 211 axially fitted to the upper and lower ends thereof and provided with a first elastic cushion 2111, and a first lower end cap 213 provided with a second elastic cushion 2131 and a first base 2132.

Preferably, the atomizing unit 212 is a multi-layer coaxial cylindrical structure, and includes, in order from outside to inside, a first thermal insulation layer 2121, a first heat generating body 2122, a first electrothermal conversion wave generating body 2123, a first molecular resonance cavity 2124, a first one-way heat conducting pipe 2125, and a porous oil storage assembly 2126. The atomizing unit 212 may also be a multi-layer cylinder with a regular polygon wall, such as a regular hexagonal cylinder or a regular octagonal cylinder.

Preferably, the cigarette heater 31 includes a heating unit 312, a second upper cover 311 axially fitted to the upper and lower ends thereof and provided with a cigarette insertion hole 3111 and a third elastic cushion 3112, and a second lower cover 313 provided with a fourth elastic cushion 3131 and a second base 3132.

Preferably, the heating unit 312 is a multi-layer coaxial cylindrical structure, and includes, in order from outside to inside, a second heat insulating layer 3121, a second heat generating body 3122, a second electrothermal conversion wave generating body 3123, a second molecule resonance cavity 3124, a second unidirectional heat conducting pipe 3125, and a cigarette heating cavity 3126. The heating unit 312 may also be a multi-layer cylinder with a regular polygon wall, such as a regular hexagonal cylinder or a regular octagonal cylinder.

Preferably, the first thermal insulation layer 2121 and the second thermal insulation layer 3121 are made of light high temperature resistant materials such as vacuum glass, aerogel felt, rubber and plastic, aluminum silicate, glass wool or rock wool, and the peripheries of the first thermal insulation layer 2121 and the second thermal insulation layer 3121 are respectively provided with a housing.

Preferably, the first heating element 2122 and the second heating element 3122 are made of a polyimide electrothermal film, a carbon fiber electrothermal film, a carbon crystal electrothermal film, a graphene electrothermal film, a ceramic heating sheet, a metal or alloy mesh sheet, and the like, which are rolled into a cylindrical shape, and are respectively attached to the peripheries of the first electrothermal conversion wave generator 2123 and the second electrothermal conversion wave generator 3123.

Preferably, the first electrothermal conversion wave generator 2123 and the second electrothermal conversion wave generator 3123 are opal quartz glass tubes or high temperature resistant insulating tubes coated with wave generating materials, and are used for generating infrared light waves with a certain wavelength.

Preferably, the first electrothermal conversion wave-generating body 2123 and the first unidirectional heat conduction pipe 2125 are separated by a first elastic cushion 2111 and a second elastic cushion 2131 to form the first molecular resonant cavity 2124; the second electric-to-heat conversion wave-generating body 3123 and the second unidirectional heat conduction pipe 3125 are separated by a third elastic cushion 3112 and a fourth elastic cushion 3131 to form the second molecule resonance cavity 3124.

Preferably, the first molecular resonant cavity 2124 and the second molecular resonant cavity 3124 are filled with a gas-phase medium or a liquid-phase medium.

Preferably, the gas phase medium filled in the first molecular resonant cavity 2124 and the second molecular resonant cavity 3124 is a single gas or a mixed gas whose main component is composed of polar gas molecules, and the liquid phase medium is alcohols or ethers.

Preferably, the first unidirectional heat pipe 2125 and the second unidirectional heat pipe 3125 conduct heat radially inward and are made of microcrystalline glass, carbon fiber unidirectional reinforced composite material, or other unidirectional heat conducting material.

Preferably, the porous oil storage component 2126 has oil storage and oil locking functions, is made of ceramics such as alumina or zirconia, and has a porosity ranging from 40% to 60%, a pore diameter ranging from 10 μm to 20 μm, and a mechanical strength greater than 10 Mpa.

Preferably, a cigarette inserting hole 3111 is formed in the second upper end cover 311, and the cigarette heating cavity 3126 is communicated with the cigarette inserting hole 3111.

Compared with the prior art, the invention has the beneficial effects that:

1. the molecular resonance combined smoking set transfers the heat effect generated by the molecular resonance absorption action between the infrared light waves and the gas-phase medium or the liquid-phase medium to the porous oil storage component and the low-temperature cigarette through the one-way heat conduction pipe, so as to realize tobacco tar atomization and cigarette heating, wherein the atomization and heating mode is different from that of the existing 'electronic cigarette + low-temperature cigarette' combined smoking set.

2. The molecular resonance composite smoking set disclosed by the invention adopts the wear-resistant, corrosion-resistant and high-temperature-resistant porous oil storage component 2126 to realize oil storage and oil locking, so that not only can the scorching smell introduced by the oil guide cotton be eliminated, but also the mouthfeel of the tobacco tar is higher; secondly, the first heating element 2122 is not in direct contact with the tobacco tar, so that the problems of sintering adhesion of the tobacco tar on the first heating element 2122 and leaching of heavy metals do not exist; in addition, due to the non-contact atomization characteristic of the molecular resonance atomizer 2, the natural perfume raw materials with high sugar content can be properly added into the tobacco tar, so that the application range of the natural perfume raw materials is widened, the aroma and taste of the tobacco tar are enriched, and the health risk of the tobacco tar is reduced.

3. The molecular resonance combined smoking set of the invention preferably selects a milky white quartz glass tube to manufacture the second electrothermal conversion wave-generating body 3123, the spectral radiance of the second electrothermal conversion wave-generating body in the infrared wavelength range of 2.5-25 μm is up to more than 95%, the second electrothermal conversion wave-generating body is matched with the resonance absorption spectrum of the gas phase medium or the liquid phase medium in the second molecular resonance cavity 3124, the gas phase medium or the liquid phase medium can strongly absorb the infrared light wave energy due to the molecular resonance effect, so as to promote the dipole molecules to reciprocate in high frequency, generate 'internal friction heat', further to rapidly raise the temperature of the gas phase medium or the liquid phase medium, and transmit the gas phase medium or the liquid phase medium to the low-temperature cigarette through the second one-way heat conduction pipe 3125 along the radial direction, the second one-way heat conduction pipe 3125 forms 360-degree omnibearing and large-area contact with the periphery of the low-temperature cigarette, The thermal uniformity is good.

4. The elastic buffer pads are respectively arranged at the top and the bottom of the molecular resonance cavity of the molecular resonance combined smoking set, so that the molecular resonance combined smoking set has a separation effect, and can effectively decompose and buffer instantaneous pressure generated in the molecular resonance process, and the safety and the reliability of the molecular resonance combined smoking set are greatly improved.

5. The molecular resonance composite smoking set of the invention adopts the power supply battery to provide power for the heating element, and the heating electrothermal conversion wave-generating body generates infrared light waves with the wavelength similar to the molecular resonance absorption wavelength of a gas-phase medium or a liquid-phase medium, so the molecular resonance composite smoking set of the invention has no electromagnetic radiation, and is safe and environment-friendly.

6. The molecular resonance composite smoking set has the advantages of no cotton design, non-contact atomization, good thermal uniformity, high thermal utilization efficiency, high heating rate and the like.

Drawings

FIG. 1 is a schematic structural diagram of the molecular resonance composite smoking set of the present invention.

FIG. 2 is a schematic structural decomposition diagram of the molecular resonance atomizer of the molecular resonance composite smoking set of the present invention.

FIG. 3 is a schematic structural diagram of a molecular resonance heater of the molecular resonance composite smoking set of the present invention.

Description of reference numerals: 1. a host; 10. a housing; 11. a microcontroller; 12. a power supply battery; 13. a support member; 14. a main key; 15. a display screen; 16. a charging interface; 2. a molecular resonance atomizer; 21. a tobacco tar atomizer; 211. a first upper end cap; 2111. a first resilient cushion; 212. an atomizing unit; 2121. a first heat preservation and insulation layer; 2122. a first heat generating body; 2123. a first electrothermal conversion wave generator; 2124. a first molecular resonant cavity; 2125. a first one-way heat conductive pipe; 2126. a porous oil storage component; 213. a first lower end cap; 2131. a second resilient cushion; 2132. a first base; 22. an air inlet; 3. a molecular resonance heater; 31. a cigarette heater; 311. a second upper end cap; 3111. cigarette inserting holes; 3112. a third resilient cushion; 312. a heating unit; 3121. a second heat insulation layer; 3122. a second heating element; 3123. a second electrothermal conversion wave generator; 3124. a second molecular resonant cavity; 3125. a second one-way heat conduction pipe; 3126. a cigarette heating cavity; 313. a second lower end cap; 3131. a fourth resilient cushion; 3132. a second base; 4. a separator plate; 5. an air flow channel.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the accompanying drawings and embodiments.

The schematic structural diagram of the molecular resonance composite smoking set of the embodiment of the invention is shown in fig. 1, and the smoking set comprises a host 1, a molecular resonance atomizer 2, a molecular resonance heater 3, a partition plate 4 and an air flow channel 5.

The shell 10 of the host 1 is internally provided with a microcontroller 11 for capturing and acquiring a user command in real time and performing dynamic analysis, a power supply battery 12 for providing power support, and a support 13 serving as a back plate of a main key 14, a display screen 15 and a charging interface 16 and having a supporting function. The side of the shell 10 of the host 1 is provided with a main key 14 for realizing operations such as startup and shutdown, normal suction and initialization, a display screen 15 for displaying heating power, suction time, electric quantity service conditions and the like, and a Micro-USB or Type-C charging interface 16 with charging and firmware upgrading functions.

The molecular resonance atomizer 2 and the molecular resonance heater 3 are arranged on the upper part of the main machine 1 in parallel, and a separation plate 4 is arranged in the middle. The molecular resonance atomizer 2 is provided with a tobacco tar atomizer 21 and an air inlet 22; the molecular resonance heater 3 is provided with a cigarette heater 31. The air current is followed the inlet port 22 flows in, will the tobacco tar atomizing smog that the tobacco tar atomizer 21 of molecule resonance atomizer 2 produced passes through air flow channel 5 transmits for molecule resonance heater 3, tobacco tar atomizing smog and then cigarette heater 31 of flowing through to toast smog intensive mixing with cigarette, mix smog at last and deliver for the user through a cigarette filter.

The structural exploded schematic diagrams of the tobacco tar atomizer 21 and the tobacco rod heater 31 are respectively shown in fig. 2 and fig. 3. The tobacco tar atomizer 21 comprises a first upper end cover 211, an atomizing unit 212 and a first lower end cover 213; the atomization unit 212 is closely attached to the first upper end cover 211 and the first lower end cover 213 in the axial direction; a first elastic buffer 2111 in a roughly annular shape is arranged at the bottom of the first upper end cover 211; the first lower end cap 213 is provided with a substantially annular second elastic cushion 2131 and a first base 2132 having a bottom portion provided with a through hole. The cigarette heater 31 comprises a second upper end cover 311, a heating unit 312 and a second lower end cover 313. The heating unit 312 is closely attached to the second upper end cover 311 and the second lower end cover 313 in the axial direction; the second upper end cover 311 includes a cigarette insertion hole 3111 penetrating the second upper end cover 311 and a third elastic cushion 3112 having a substantially ring shape; the second bottom end cap 313 is provided with a substantially annular fourth elastic cushion 3131 and a second base 3132 having a through hole at the bottom.

The atomizing unit 212 is a multi-layer coaxial cylindrical structure, and includes, in order from outside to inside, a first thermal insulation layer 2121 for thermal insulation, a first heating element 2122 for heating, a first electrothermal conversion wave generating element 2123 for generating infrared waves with a certain wavelength, a first molecular resonant cavity 2124 filled with a gas-phase medium or a liquid-phase medium, a first one-way heat pipe 2125 for conducting heat radially inward, and a porous oil storage assembly 2126 having both oil storage and oil locking functions. The heating unit 312 has a structure similar to that of the atomizing unit 212, and sequentially includes, from outside to inside, a second heat-insulating layer 3121, a second heating element 3122, a second electrothermal conversion wave generator 3123, a second molecule resonant cavity 3124, a second unidirectional heat-conducting pipe 3125, and a cigarette heating cavity 3126. The first heat-insulating layer 2121 and the second heat-insulating layer 3121 are made of light high-temperature-resistant materials such as vacuum glass, aerogel felt, rubber and plastic, aluminum silicate, glass wool or rock wool, and a shell is arranged on the periphery of the first heat-insulating layer and the second heat-insulating layer to play a role in heat insulation, so that the heat utilization efficiency of the molecular resonance atomizer 2 and the molecular resonance heater 3 is improved, and the shell temperatures of the molecular resonance atomizer 2 and the molecular resonance heater 3 can be effectively reduced to prevent a user from being scalded. In the embodiment of the present invention, the first thermal insulation layer 2121 and the second thermal insulation layer 3121 are preferably double-layer vacuum glass tubes, and the gap between the two layers of glass is 0.1-0.2 mm. The first heating element 2122 and the second heating element 3122 are made of a polyimide electrothermal film, a carbon fiber electrothermal film, a carbon crystal electrothermal film, a graphene electrothermal film, a ceramic heating sheet, a metal or alloy mesh sheet and the like which are curled into a cylindrical shape, and are respectively tightly attached to the peripheries of the first electrothermal conversion wave generating body 2123 and the second electrothermal conversion wave generating body 3123; in a specific embodiment of the present invention, the first heat-generating body 2122 and the second heat-generating body 3122 have a preferential specific resistance of 10^-6The graphene electric heating film is made of graphene electric heating films with the heat conductivity coefficient of 5300W/m.K, and electrode leads are arranged outside and are electrically connected with the host 1 through the first base 2132 and the second base 3132 respectively. The first electrothermal conversion wave generator 2123 and the second electrothermal conversion wave generator 3123 are preferably opal quartz glass tubes,under the electric heating action of the first heating element 2122 and the second heating element 3122, the infrared light wave with a certain wavelength can be generated, and the wavelength range of more than 95% of the infrared light wave energy is 2.5-25 μm. The first molecular resonance cavity 2124 is located between the first electrothermal conversion wave generator 2123 and the first one-way heat pipe 2125, the second molecular resonance cavity 3124 is located between the second electrothermal conversion wave generator 3123 and the second one-way heat pipe 3125, and a gas-phase medium (a single gas or a mixed gas mainly containing polar gas molecules, preferably air) or a liquid-phase medium (alcohols or ethers, preferably propylene glycol or glycerol) is filled in the cavity. The top and bottom of the first molecule resonance cavity 2124 are embedded with a first elastic cushion 2111 and a second elastic cushion 2131, and the top and bottom of the second molecule resonance cavity 3124 are embedded with a third elastic cushion 3112 and a fourth elastic cushion 3131, so as to decompose and buffer the instantaneous pressure generated during the molecule resonance process, thereby improving the safety and reliability of the molecule resonance composite smoking set. The radial thermal conductivity of the first one-way heat-conducting pipe 2125 and the second one-way heat-conducting pipe 3125 is greater than the axial thermal conductivity, preferably a microcrystalline glass pipe, which transmits the molecular resonance energy generated between the infrared light wave and the gas phase medium or the liquid phase medium radially inward to the porous oil storage assembly 2126 and the low-temperature cigarette in the cigarette heating chamber 3126, respectively. The porous oil storage component 2126 has oil storage and oil locking functions, is preferably made of alumina ceramics, has the porosity ranging from 40 to 60 percent, the pore diameter ranging from 10 to 20 mu m and the mechanical strength>10 MPa. The cigarette heating cavity 3126 with cigarette patchhole 3111 intercommunication, cigarette heating cavity 3126 supports and adopts reconstituted tobacco or traditional cigarette tobacco to carry out the low temperature cigarette of orderly or unordered packing to and adopt the low temperature cigarette of adding fragtant granule or solid-state smoking stick as substrate of fuming.

When the molecular resonance combined smoking set is used, the microcontroller 11 detects the key action in real time, and when the main key 14 is continuously pressed for two times, the host 1 vibrates for the first time to remind that the microcontroller 11 triggers the cigarette heater 31 to work and preheats the low-temperature cigarettes in the cigarette heating cavity 3126; after preheating is completed, the host 1 vibrates again to remind, and at this time, the user can activate the tobacco tar atomizer 21 by pressing the main key 14 for a long time, and then the mixed smoke is sucked.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention. It will be understood by those skilled in the art that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (7)

1. A molecular resonance combined smoking set, characterized in that, it includes: a molecular resonance atomizer (2) and a molecular resonance heater (3);

a tobacco tar atomizer (21) is arranged in the molecular resonance atomizer (2), and the tobacco tar atomizer (21) comprises an atomizing unit (212), and a first upper end cover (211) and a first lower end cover (213) which are axially matched with the upper end and the lower end of the atomizing unit (212); a first elastic buffer pad (2111) is arranged between the upper end face of the atomizing unit (212) and the first upper end cover (211); a second elastic buffer cushion (2131) is arranged between the lower end surface of the atomization unit (212) and the first lower end cover (213); the atomization unit (212) is of a multi-layer coaxial cylindrical structure and sequentially comprises a first heat preservation and insulation layer (2121), a first heating body (2122), a first electrothermal conversion wave generating body (2123), a first molecular resonant cavity (2124), a first one-way heat conduction pipe (2125) and a porous oil storage component (2126) from outside to inside;

a cigarette heater (31) is arranged in the molecular resonance heater (3), and the cigarette heater (31) comprises a heating unit (312) and a second upper end cover (311) and a second lower end cover (313) which are axially matched with the upper end and the lower end of the heating unit (312); a third elastic buffer pad (3112) is arranged between the upper end face of the heating unit (312) and the second upper end cover (311); a fourth elastic cushion pad (3131) is arranged between the lower end face of the heating unit (312) and the second lower end cover (313); the heating unit (312) is of a multi-layer coaxial cylindrical structure and sequentially comprises a second heat-insulation layer (3121), a second heating body (3122), a second electrothermal conversion wave generator (3123), a second molecular resonance cavity (3124), a second one-way heat-conduction pipe (3125) and a cigarette heating cavity (3126) from outside to inside.

2. The molecular resonance composite smoking set according to claim 1, wherein the first and second electrothermal converting wave bodies (2123, 3123) are temperature-resistant insulating tubes capable of generating infrared light waves.

3. The molecular resonance composite smoking set according to claim 1, wherein the first electrothermal conversion wave body (2123) and the first unidirectional heat conducting pipe (2125) are separated by a first elastic buffer pad (2111) and a second elastic buffer pad (2131) to form the first molecular resonant cavity (2124); the second electric heating conversion wave generator (3123) and the second unidirectional heat conduction pipe (3125) are separated by a third elastic cushion (3112) and a fourth elastic cushion (3131) to form the second molecule resonance cavity (3124); the first molecular resonant cavity (2124) and the second molecular resonant cavity (3124) are filled with gas phase medium or liquid phase medium.

4. The molecular resonance composite smoking set according to claim 1, wherein the porosity of the porous oil storage component (2126) is 40-60%, the pore size is 10-20 μm, and the mechanical strength is greater than 10 Mpa.

5. The molecular resonance composite smoking set according to claim 1, wherein the second upper end cover (311) is provided with a cigarette insertion hole (3111), and the cigarette heating chamber (3126) is communicated with the cigarette insertion hole (3111).

6. The molecular resonance composite smoking set according to claim 1, further comprising a main machine (1), wherein the molecular resonance atomizer (2) and the molecular resonance heater (3) are arranged on the upper part of the main machine (1), a separation plate (4) is arranged between the molecular resonance atomizer and the molecular resonance heater, and the two are communicated through an airflow channel (5); the molecular resonance atomizer (2) is provided with an air inlet hole (22).

7. The molecular resonance combined type smoking set according to claim 6, wherein the microcontroller (11), the power supply battery (12) and the support member (13) are arranged inside the housing (10) of the main machine (1), and the main button (14), the display screen (15) and the charging interface (16) are arranged on the side surface of the housing (10).

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