KR20240024658A - Aerosol generator - Google Patents

Abstract

According to one aspect of the embodiment, a housing forming an exterior; Upper and lower covers coupled to the upper and lower surfaces of the housing and provided with a hollow portion through which air flows; a hygroscopic body accommodated in the space formed between the housing and the upper/lower covers and moisture-absorbing the liquid aerosol-generating substrate; a transfer pipe disposed at the center of the moisture absorber to communicate with the hollow portion of the upper cover; A ceramic heater is mounted between the hygroscopic body and the lower cover so as to communicate with the transfer pipe and the hollow portion of the lower cover, and heats the liquid aerosol-generating substrate impregnated in the hygroscopic body. .

Description

Aerosol generator {Aerosol generator}

The embodiment relates to an aerosol generator that can induce abundant aerosol generation by heating the liquid phase and prevent loss of the liquid phase even if the flow path structure is simplified.

Recently, various types of aerosol generating devices that can improve the side effects that may occur when smoking cigarettes have been developed. These aerosol generators are broadly divided into a type that generates an aerosol by compressing tobacco leaves and heating a cigarette wrapped in paper with a cover, and a liquid type that generates an aerosol by vaporizing the liquid filled in a liquid type cartridge.

Aerosol generators using paper coils have a good nicotine hit and the unique taste of tobacco, but they emit more harmful substances and are not sufficient for atomization.

Aerosol generators using liquid cartridges have abundant atomization, but the flow path for liquid supply and the flow path structure for flowing air are complex. Not only does the inhalation resistance increase due to the complicated flow path structure, but the aerosol liquefies on the flow path. There is a problem with liquid being lost inside the device.

Therefore, there is a need for the development of an aerosol generator that can heat the liquid to form abundant aerosol and prevent loss of the liquid even if the flow path structure is simplified.

The embodiments aim to solve the above-described problems and other problems.

Another purpose of the embodiment is to provide an aerosol generating device that can induce abundant aerosol generation by heating the liquid phase and prevent loss of the liquid phase even if the flow path structure is simplified.

According to one aspect of the embodiment, a housing forming an exterior; Upper and lower covers coupled to the upper and lower surfaces of the housing and provided with a hollow portion through which air flows; a hygroscopic body accommodated in the space formed between the housing and the upper/lower covers and moisture-absorbing the liquid aerosol-generating substrate; a transfer pipe disposed at the center of the moisture absorber to communicate with the hollow portion of the upper cover; A ceramic heater is mounted between the hygroscopic body and the lower cover so as to communicate with the transfer pipe and the hollow portion of the lower cover, and heats the liquid aerosol-generating substrate impregnated in the hygroscopic body. .

According to one aspect of the embodiment, the outer peripheral surface of the middle portion of the ceramic heater may be mounted so as to contact the inner peripheral surface of the moisture absorber.

According to one aspect of the embodiment, the upper outer peripheral surface of the ceramic heater may be sealed and mounted on the inner peripheral surface of the transfer pipe, and the lower outer peripheral surface of the ceramic heater may be sealed and installed on the inner peripheral surface of the lower cover.

According to one aspect of the embodiment, the ceramic heater may include a ceramic body having a stepped cylindrical shape, and a heating wire disposed on the ceramic body and generating heat as power is supplied from the device side.

According to one aspect of the embodiment, the ceramic body includes a cylindrical lower portion that is sealed and mounted on the inner peripheral surface of the lower cover, a disk-shaped middle portion that is integrally provided on an upper side of the lower cover and is mounted in contact with the inner peripheral surface of the moisture absorber, It may be composed of a cylindrical upper part that is integrally provided on the upper side of the middle part and is sealed on the inner peripheral surface of the transfer pipe.

According to one aspect of the embodiment, a sealing rubber may be installed between the inner peripheral surface of the transfer pipe and the upper outer peripheral surface of the ceramic body.

According to one aspect of the embodiment, the ceramic body may be made of a porous ceramic material.

According to one aspect of the embodiment, the ceramic body may be provided with at least one pair of airflow holes penetrating in the axial direction in the middle portion so as to communicate with the upper hollow portion and the lower hollow portion.

According to one aspect of the embodiment, the lower cover has an intake port through which external air is sucked and guides the intake airflow to the airflow holes, and at least one disposed below the airflow holes and storing liquid falling from the airflow holes. It may include a pair of liquid storage grooves.

According to one aspect of the embodiment, the heating wire is exposed on the upper surface of the middle portion of the ceramic body and may be connected to a pair of connection terminals installed to penetrate axially through both the middle portion and the lower portion of the ceramic body.

According to an embodiment, by providing a flow path structure through which liquid is supplied in the radial direction of the ceramic heater and air passes in the axial direction of the ceramic heater, the liquid supply flow path and air flow path can be simplified, and the abundant supply of liquid and air Since the flow resistance can be minimized, there is an advantage in inducing excellent aerosol generation.

In addition, even if the aerosol is liquefied, it is stored in the liquid storage grooves provided in the lower cover, which has the advantage of preventing the liquid from being lost inside the device.

1 is a side cross-sectional view showing an aerosol generating device according to an embodiment.
Figure 2 is a side cross-sectional view showing in detail the ceramic heater structure of an aerosol generating device according to an embodiment.
Figure 3 is a side cross-sectional view showing in detail the airflow on the ceramic heater side of the aerosol generating device according to the embodiment.
4 to 5 are a perspective view and a plan view of a ceramic heater according to an embodiment as seen from above.
Figure 6 is a perspective view showing a heating wire and connection terminal structure applied to a ceramic heater according to an embodiment.

Hereinafter, this embodiment will be examined in detail with reference to the accompanying drawings.

Figure 1 is a side cross-sectional view showing an aerosol generating device according to an embodiment.

The aerosol generating device of the embodiment may include a housing 110, an upper cover 120 and a lower cover 130, a transfer pipe 140, a moisture absorber 150, and a ceramic heater 160, A stick made of the above components can be detachably placed on the upper side of the device, and when an electric signal is input and the ceramic heater 160 is activated, the liquid moistened in the moisture absorber 140 is heated to generate an aerosol. You can.

The housing 110 forms an exterior appearance and may provide space for mounting other components. The housing 110 may be shaped like a cigarette into a long cylindrical shape surrounding the moisture absorber 150, and may be made of aluminum or coated with an aluminum material to prevent the liquid stored in the moisture absorber 150 from flowing out. However, its formation and material may vary and are not limited.

The upper cover 120 is mounted to cover the upper side of the housing 110, and may be provided with a hollow discharge port 120h that guides the aerosol to the user's mouth. The discharge port 120h is provided in a form penetrating the axial center of the upper cover 120, and may be configured to form a straight line with the suction port 130h and the transfer pipe hollow portion 140h, which will be described below.

The lower cover 130 is mounted to block the lower side of the housing 110, and is provided with an intake port 130h, which is a hollow part through which air flows, and is provided with at least one pair of liquid storage grooves 131 outside the intake port 130h. It can be. The inlet 130h is provided in a penetrating form in the axial center of the lower cover 130, and the liquid storage grooves 131 are located below the airflow holes 161h provided in the heater 160, which will be described below. As a result, the liquid falling from the airflow holes 161h can be stored.

The transfer pipe 140 has a cylindrical shape smaller than the housing 110, and may be mounted inside the housing 110 to communicate with the discharge port 120h. The transfer pipe 140 can guide the aerosol generated by the heater 160 to the discharge port 120h along with the airflow.

The moisture absorbent 150 is made of a material that can moisturize an aerosol-generating substrate in a liquid or gel state, such as natural or synthetic materials such as cotton, silica, woven fabric, non-woven fabric, silicon carbide, ceramic, tobacco leaf, green tea leaf, and buckwheat leaf. etc. can be used. The moisture absorber 150 may be embedded between the housing 110, the upper cover 120, the lower cover 130, and the transfer pipe 140, and may be configured to prevent the liquid from flowing to the outside. However, the lower inner peripheral surface of the moisture absorber 150 is installed so as to contact the outer peripheral surface of the ceramic heater 160, which will be described below, so that the liquid moistened in the moisture absorber 150 is supplied only through the outer peripheral surface of the ceramic heater 160. .

The ceramic heater 160 may be configured to receive current from the device side and generate heat. The ceramic heater 160 of the embodiment may be composed of a ceramic body 161, a heating wire 163, and a pair of connection terminals 165, which will be described in detail below. The ceramic heater 160 may be disposed in the axial direction between the lower part of the transfer pipe 140 and the lower cover 130, and the outer peripheral surface of the ceramic heater 160 may be disposed to contact the inner peripheral surface of the moisture absorber 150.

Accordingly, the air forms a simple straight airflow in the axial direction along the lower cover 130, the ceramic heater 160, and the transfer pipe 140, thereby minimizing the flow resistance, and the liquid of the moisture absorber 150 flows through the ceramic heater. After flowing in through the entire outer peripheral surface of (160), abundant aerosol can be generated as it is heated.

Figures 2 and 3 are side cross-sectional views showing the ceramic heater structure and air flow flow of the aerosol generating device according to the embodiment in detail, respectively, and Figures 4 and 5 are a perspective view and plan view of the ceramic heater according to the embodiment viewed from the top, Figure 6 is a perspective view showing the structure of a heating wire and a connection terminal applied to a ceramic heater according to an embodiment.

The ceramic heater 160 of the embodiment is configured to receive the liquid stored in the moisture absorber 150 in a radial direction and form an airflow in the axial direction with the transfer pipe 140 between the suction port 130h and the discharge port 120h. , can be configured to generate abundant aerosol.

In detail, the ceramic heater 160 includes a ceramic body 161 that receives and holds the liquid, a heating wire 163 that heats the ceramic body 161 to generate aerosol, and a heating wire 163 that supplies current to the heating wire 163. It may consist of a pair of connection terminals 165.

The ceramic body 161 may be made of a porous ceramic material such as silicate or alumina that can hold liquid. The ceramic body 161 of the embodiment includes a cylindrical upper portion 161a, a disk-shaped middle portion 161b with a larger diameter than the outer diameter of the upper portion 161a, and a cylindrical lower portion 161c having an outer diameter equal to the diameter of the middle portion 161b. ) can be composed of.

The ceramic body 161 is provided with at least one pair of airflow holes 161h through which airflow can pass. The pair of airflow holes 161h is vertically formed so as to penetrate the middle portion 161b of the ceramic body in the axial direction. It can be provided. The upper ends of the airflow holes 161h may communicate with the heater hollow portion 161H provided at the top of the ceramic body, and the lower ends of the airflow holes 161h may be arranged to communicate with the lower cover side suction port 130H. Therefore, the flow path through the lower cover side suction port (130h), the ceramic heater side airflow holes (161h) and heater hollow portion (161H), the transfer pipe hollow portion (140h), and the upper cover side discharge port (120h) can be straightened. , it is possible to generate and discharge abundant aerosol by minimizing the resistance of the air flow path.

The heating wire 163 may be exposed to the heater hollow portion 161H as it is mounted on the upper surface of the middle portion 161b of the ceramic body. In order to increase heat generation performance, the heating wire 163 can be made long and densely arranged, and can be arranged perpendicular to the airflow. When manufacturing the ceramic body 161, it may be manufactured with the heating wire 163 inserted, but is not limited thereto.

The connection terminals 165 are connected to both ends of the heating wire 163, and the connection terminals 165 may be installed to be exposed from the ceramic body 161 to the outside of the lower cover 130. The connection terminals 165 exposed to the outside of the lower cover 130 may be electrically connected to a power supply on the device side.

The ceramic heater 160 of this configuration is disposed between the lower cover 130 and the transfer pipe 140 to contact the moisture absorber 150, and the liquid stored in the moisture absorber 150 is disposed between the upper cover 120 and the lower cover. Leakage to the outside can be prevented by the sealing structure applied to 130 and the ceramic heater 160.

The upper cover 120 and the lower cover 130 are made of a material with a predetermined elasticity, and are configured to have a separate sealing structure on the outer peripheral surface of the upper cover 120 and a portion of the outer peripheral surface of the lower cover 130, The cover 120 and the lower cover 130 may be sealingly coupled to the inner peripheral surface of the housing 110. Even if the moisture absorbent 150 is built between the housing 110 and the upper cover 120 and the lower cover 130, the liquid of the moisture absorbent 150 may leak between the upper part of the housing 110 and the upper cover 120, or Leakage between the lower part of the housing 110 and the lower cover 130 can be prevented.

The ceramic heater 160 is also mounted to have a sealing structure with respect to adjacent components, and a ring-shaped sealing rubber (R) seals and secures the space between the outer peripheral surface of the upper portion (161a) of the ceramic body and the lower inner peripheral surface of the transfer pipe 140. , the radially expanded portion at the bottom of the sealing rubber (R) may seal between the lower end of the transfer pipe 140 and the upper surface of the middle portion 161b of the ceramic body.

On the other hand, the outer peripheral surface of the middle portion 161b of the ceramic body and the lower inner peripheral surface of the moisture absorber 150 are in close contact with each other, and the liquid of the moisture absorber 150 is supplied abundantly along the outer peripheral surface of the middle portion 161b of the ceramic body. do.

In addition, the outer peripheral surface of the lower part 161c of the ceramic body and the upper inner peripheral surface of the lower cover 130 are sealed and fixed so as to contact each other, so that the ceramic main body 161 can be stably fixed and sealed to the lower cover 130.

Of course, even if the ceramic heater 160 is mounted using a sealing structure, the connection terminals 165 are exposed to the outside of the lower cover 130, and a separate sealing agent (S) is applied to the connection terminals 165 and the lower cover ( 130) The space between them can be sealed.

Meanwhile, the aerosol generated by the ceramic heater 160 may be liquefied while rising along a straight flow path, but a pair of liquid storage grooves 131 are provided inside the lower filter 130 to prevent liquid from leaking. It can be provided. The liquid storage grooves 131 are disposed below the airflow holes 161h and can store the liquid falling from the airflow holes 161h. The shapes and configurations of the liquid storage grooves 131 can be configured in various ways. , is not limited.

The process by which the ceramic heater 160 applied to the aerosol generating device generates an aerosol as described above is as follows.

When the liquid of the moisture absorber 150 is abundantly supplied throughout the entire outer peripheral surface of the middle portion 161b of the ceramic body, and the heating wire 163 is supplied with power to heat the ceramic body 161, an abundant aerosol can be generated. . At the same time, air forms an upward airflow along the lower cover side inlet (130h), the ceramic heater side airflow holes (161h), the heater hollow part (160H), the transfer pipe hollow part (140h), and the upper cover side discharge port (120h). And, the aerosol may be provided to the user with an updraft. By providing a flow path to simplify and straighten the flow of air, air flow resistance can be minimized and more abundant aerosol can be generated.

Meanwhile, even if part of the aerosol is liquefied and falls through the airflow holes 161h on the ceramic body, it flows into the liquid storage grooves 131 on the lower cover side, and the liquid can be prevented from leaking and flowing into the device.

The above description is merely an illustrative explanation of the technical idea of the present invention, and various modifications and variations will be possible to those skilled in the art without departing from the essential characteristics of the present invention.

Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but rather to explain it, and the scope of the technical idea of the present invention is not limited by these embodiments.

The scope of protection of the present invention should be interpreted in accordance with the claims below, and all technical ideas within the equivalent scope should be construed as being included in the scope of rights of the present invention.

110: Housing 120: Top cover
120h: Discharge port 130: Lower cover
130h: Inlet 131: Liquid storage groove
140: transfer pipe 140h: transfer pipe hollow part
150: moisture absorber 160: ceramic heater
161: Ceramic body 161H: Heater hollow part
161h: Airflow hole 163: Heating wire
165: connection terminal

Claims (10)

a housing forming an exterior appearance;
Upper and lower covers coupled to the upper and lower surfaces of the housing and provided with a hollow portion through which air flows;
a hygroscopic body accommodated in the space formed between the housing and the upper/lower covers and moisture-absorbing the liquid aerosol-generating substrate;
a transfer pipe disposed at the center of the moisture absorber to communicate with the hollow portion of the upper cover;
An aerosol generating device comprising: a ceramic heater mounted between the hygroscopic body and the lower cover so as to communicate with the transfer pipe and the hollow portion of the lower cover, and heating the liquid aerosol-generating substrate moistened in the hygroscopic body. According to paragraph 1,
An aerosol generating device installed so that the outer peripheral surface of the middle portion of the ceramic heater is in contact with the inner peripheral surface of the moisture absorber. According to paragraph 1,
The upper outer peripheral surface of the ceramic heater is sealed and mounted on the inner peripheral surface of the transfer pipe,
An aerosol generating device in which the lower outer peripheral surface of the ceramic heater is sealed and mounted on the inner peripheral surface of the lower cover. According to paragraph 1,
The ceramic heater is,
A ceramic body in a stepped cylindrical shape,
An aerosol generating device disposed on the ceramic body and including a heating element that generates heat as power is supplied from the device. According to paragraph 4,
The ceramic body is,
A cylindrical lower part sealed on the inner peripheral surface of the lower cover,
a disk-shaped middle portion integrally provided on the upper side of the lower portion and mounted in contact with the inner peripheral surface of the moisture absorber;
An aerosol generating device consisting of a cylindrical upper part that is integrally provided on the upper side of the middle part and sealed on the inner peripheral surface of the transfer pipe. According to clause 5,
An aerosol generating device in which a sealing rubber is mounted between the inner peripheral surface of the transfer pipe and the upper outer peripheral surface of the ceramic body. According to clause 5,
The ceramic body is,
An aerosol generator made of porous ceramic material. According to clause 5,
The ceramic body is,
An aerosol generating device comprising at least one pair of airflow holes extending axially through the middle portion to communicate with the upper hollow portion and the lower hollow portion. According to clause 8,
The lower cover is,
an intake port through which external air is sucked and the intake airflow is guided to the airflow holes;
An aerosol generating device disposed below the airflow holes and including at least one pair of liquid storage grooves for storing liquid falling from the airflow holes. According to clause 5,
The heating wire is,
Exposed to the upper middle surface of the ceramic body,
An aerosol generating device connected to a pair of connection terminals installed to penetrate axially through both the middle and lower portions of the ceramic body.

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