KR20240053264A - Aerosol generator - Google Patents

Abstract

The present invention relates to an aerosol generating device, and more specifically, to an aerosol generating device that can increase the amount of aerosol generated by heating the air flowing in through the airflow passage and allowing it to penetrate the cigarette. An aerosol generating device according to an embodiment of the present invention includes a susceptor in which a hollow is formed into which a cigarette is inserted; a first coil installed to surround the upper part of the susceptor and spaced apart from the susceptor by a predetermined distance; an airflow pipe that communicates with the susceptor and is connected to the bottom of the susceptor to introduce external air; a second coil spaced apart from the susceptor by a predetermined distance, installed to surround the lower portion of the susceptor, and installed to surround the airflow pipe; first alternating current supply means for supplying alternating current to the first coil; second alternating current supply means for supplying alternating current to the second coil; a battery supplying power to the first alternating current supply means and/or the second alternating current supply means; It includes a microcontroller that selectively controls the first AC supply means and the second AC supply means.

Description

Aerosol generator {AEROSOL GENERATOR}

The present invention relates to an aerosol generating device, and more specifically, to an aerosol generating device that can increase the amount of aerosol generated by heating the air flowing in through the airflow passage and allowing it to penetrate the cigarette.

Aerosols are small liquid or solid particles that exist in suspension in the atmosphere and usually have a size of 0.001 to 1.0 ㎛. In particular, there are cases where people inhale aerosols derived from various types of cigarettes for various purposes.

Figure 1 is a cross-sectional view schematically showing an embodiment of an aerosol generating device of the prior art. Referring to FIG. 1, the aerosol generator 10 includes a heater 14 that generates heat by resistance when current is applied, a battery 16 that can instantly supply high power to the heater 14, and a heater 14. ) includes a microcontroller 15 for controlling. The heater 14 generates an aerosol by heating the vaporization material contained in the cavity 13 containing a material (vaporizing material) that vaporizes when heated above a certain temperature. For example, when a cigarette 11 filled with paper impregnated with an inhalation substance or buried on the surface is inserted into the cavity 13 through the opening 12, the heater 14 is heated to vaporize the inhalation substance inside the cigarette 11. If so, the user can inhale the vaporized inhalation substance through the filter part of the cigarette 11. However, the method of heating the inside of the cigarette 11 as described above has a problem in that although the inside of the cigarette 11 can be effectively heated, the outside and areas near the outside of the cigarette 11 are not heated well.

In addition, Republic of Korea Patent Publication No. 10-2020-0109705 discloses a heat-resistant pipe into which an aerosol-generating substrate can be inserted; A heating pattern formed on the surface of the pipe; and a pad portion formed at both ends of the heating pattern circuit to which a power line can be soldered. A heater structure for an aerosol generating device including a pad portion is disclosed. However, in the heater structure described above, the method of heating the outside of the aerosol-generating substrate inserted into the heat-resistant pipe can effectively heat the outside and the parts near the outside of the aerosol-generating substrate, but the inner central portion of the aerosol-generating substrate cannot be heated well. There is a problem that does not exist.

Republic of Korea Patent Publication No. 10-2020-0109705

The purpose of the present invention is to provide an aerosol generating device that can increase the amount of aerosol generated by heating air introduced through an airflow passage and allowing it to penetrate into the cigarette.

In addition, the purpose of the present invention is to provide an aerosol generating device that can efficiently heat the upper part of the susceptor, the lower part of the susceptor, and the airflow pipe with only two coils.

An aerosol generating device according to an embodiment of the present invention includes a susceptor in which a hollow is formed into which a cigarette is inserted; a first coil installed to surround the upper part of the susceptor and spaced apart from the susceptor by a predetermined distance; an airflow pipe that communicates with the susceptor and is connected to the bottom of the susceptor to introduce external air; a second coil spaced apart from the susceptor by a predetermined distance, installed to surround the lower portion of the susceptor, and installed to surround the airflow pipe; first alternating current supply means for supplying alternating current to the first coil; second alternating current supply means for supplying alternating current to the second coil; a battery supplying power to the first alternating current supply means and/or the second alternating current supply means; It includes a microcontroller that selectively controls the first AC supply means and the second AC supply means.

In addition, according to the embodiment, the first AC supply means and the second AC supply means each include a power boosting circuit that amplifies the direct current voltage supplied from the battery under the control of a microcontroller, and a power supply boosting circuit under the control of the microcontroller. It includes induction logic and a capacitor that converts direct current into alternating current.

In addition, depending on the embodiment, the airflow pipe is made of a material that can emit heat energy by generating an eddy current by a magnetic field, and the second coil is installed to surround the airflow pipe and spaced a predetermined distance apart from the airflow pipe.

In addition, depending on the embodiment, it includes a first temperature sensor that is connected to the microcontroller and detects the temperature of the first coil, and a second temperature sensor that is connected to the microcontroller and detects the temperature of the second coil, and the microcontroller Controls the first AC supply means according to the detection signal input from the first temperature sensor, and controls the second AC supply means according to the detection signal input from the second temperature sensor.

According to an embodiment of the present invention, the upper part of the susceptor is heated with one coil, and the other coil is controlled to heat the lower part of the susceptor and the airflow pipe that introduces external air into the cigarette inserted into the susceptor, thereby heating the cigarette. By heating the inside and outside evenly, the amount of aerosol generated can be increased.

In addition, according to an embodiment of the present invention, the lower part of the susceptor and the airflow pipe can be wound with one coil, thereby shortening the assembly process and reducing the use of unnecessary coils and heating parts.

In addition, according to an embodiment of the present invention, nicotine and glycerin contained in the cigarette can be smoothly moved by heated air that penetrates the inside of the cigarette while the user inhales the cigarette.

1 is a cross-sectional view schematically showing an embodiment of an aerosol generating device of the prior art;
2 is a diagram conceptually illustrating an aerosol generating device according to an embodiment of the present invention;
Figure 3 is a block diagram for explaining an aerosol generating device according to an embodiment of the present invention;
Figure 4 is a table explaining the effect of applying two coils according to an embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the drawings.

Figure 2 is a diagram for conceptually explaining an aerosol generating device according to an embodiment of the present invention, and Figure 3 is a block diagram for explaining an aerosol generating device according to an embodiment of the present invention.

Referring to Figures 2 and 3, the aerosol generating device 100 according to an embodiment of the present invention includes a susceptor 102 in which a hollow is formed and the cigarette 101 is inserted, and a predetermined distance from the susceptor 102. A first coil 103 that is spaced apart and installed to surround the upper part of the susceptor 102, and an airflow pipe 104 that communicates with the susceptor 102 and is connected to the lower end of the susceptor 102 to introduce external air. And, an alternating current is applied to the second coil 105, which is installed to surround the lower part of the susceptor 102 at a predetermined distance from the susceptor 102 and to surround the airflow pipe 104, and the first coil 103. First AC supply means 106 for supplying alternating current, second AC supply means 107 for supplying alternating current to the second coil 105, and first AC supply means 106 and/or second AC supply means It includes a battery 108 that supplies power to 107, and a microcontroller 109 that selectively controls the first AC supply means 106 and the second AC supply means 107. The susceptor 102 is made of a material that can emit heat energy by generating an eddy current by a magnetic field. Depending on the embodiment, the susceptor 102 is made of a magnetic material. According to the embodiment, a tube 111 is installed on the outer circumference of the susceptor 102 to surround the susceptor 102, and the first coil 103 and the second coil 105 are spaced apart from the outer circumference of the susceptor 102. It is installed to surround the tube 111. External air may be drawn in through the airflow pipe 104 and flow into the susceptor 102. For example, external air may flow into the airflow pipe 104 through the air passage 112 formed in the aerosol generator 100. It may be introduced into the susceptor 102. With the cigarette 101 inserted into the susceptor 102, an alternating current is supplied to the first coil 103 from the first alternating current supply means 106 under the control of the microcontroller 109 to supply the susceptor 102. The upper part is inductively heated, and an alternating current is supplied to the second coil 105 from the second alternating current supply means 107, so that the lower part of the susceptor 102 is inductively heated and the airflow pipe 104 is heated. Accordingly, the first AC supply means 106 and the second AC supply means 107 are power boosting circuits 106a and 107a that amplify the DC voltage supplied from the battery 108 under the control of the microcontroller 109, respectively. and induction logic (106b, 107b) and capacitors (106c, 107c) that convert the direct current supplied from the power boosting circuits (106a, 107a) into alternating current under the control of the microcontroller (109). The microcontroller 109 controls the power boosting circuits 106a and 107a to amplify the direct current voltage supplied from the battery 108 for induction heating and converts it to the induction logic 106b and 107b. Supply direct current. The power boosting circuits 106a and 107a are applied to provide a stable power supply for inductive heating of the susceptor 102 when the battery 108 is used as a power source for induction heating. Microcontroller 109 also inputs PWM signals to induction logic 106b and 107b, respectively. The induction logic (106b, 107b) performs a switching operation according to the PWM signal respectively input from the microcontroller (109), and the direct current supplied from the power boosting circuit (106a, 107a), respectively, is transmitted to the induction logic (106b, 107b) and the capacitor (106c). , 107c) are converted into alternating currents and supplied to the first coil 103 and the second coil 105, respectively, so that alternating magnetic fields are generated in the first coil 103 and the second coil 105, respectively. The upper part of the susceptor 102 is inductively heated by the alternating magnetic field generated from the first coil 103, and the lower part of the susceptor 102 is heated by the alternating magnetic field generated from the second coil 105, thereby forming the susceptor 102. The cigarette 101 inserted into is heated. In addition, the airflow pipe 104 is heated by the second coil 105, and the air drawn into the airflow pipe 104 is heated and flows into the susceptor 102, and the cigarette 101 inserted into the susceptor 102 ) Heated air penetrates inside. Therefore, while the user inhales the cigarette 101, the nicotine and glycerin contained in the cigarette 101 can be smoothly moved by the heated air that penetrates into the cigarette 101. According to the embodiment, the air flow pipe 104 is made of a material that can emit heat energy by generating an eddy current by a magnetic field, and the second coil 105 is spaced a predetermined distance from the air flow pipe 104 to generate an eddy current. It is installed to surround the pipe 104, and the airflow pipe 104 may be inductively heated by an alternating magnetic field generated from the second coil 105. Depending on the embodiment, the airflow pipe 104 is made of a magnetic material. According to the embodiment, when inductively heating the upper part of the susceptor 102 by the first AC supply means 106 and the first coil 103, the resonance frequency and the second AC supply means 107 and the second coil 105 When inductively heating the lower portion of the susceptor 102 and/or the airflow pipe 104, the resonance frequencies may be designed differently.

In addition, depending on the embodiment, a first temperature sensor 113 is connected to the microcontroller 109 and detects the temperature of the first coil 103, and is connected to the microcontroller 109 and a second coil 105. It includes a second temperature sensor 114 that detects the temperature, and the microcontroller 109 controls the first AC supply means 106 according to the detection signal input from the first temperature sensor 113. 2 The second alternating current supply means 107 is controlled according to the detection signal input from the temperature sensor 114. For example, the microcontroller 109 recognizes the temperature according to the detection signal input from the first temperature sensor 113, and if there is a deviation compared to the preset temperature, the induction logic ( The induction heating temperature can be adjusted by adjusting the alternating current supplied to the first coil 103 by adjusting the duty of the PWM signal input to 106b). In addition, the microcontroller 109 recognizes the temperature according to the detection signal input from the second temperature sensor 114, and if there is a deviation compared to the preset temperature, the induction logic 107b of the second AC supply means 107 ) can be adjusted to adjust the duty of the PWM signal input to the alternating current supplied to the second coil 105, thereby controlling the induction heating temperature.

In addition, depending on the embodiment, the first coil 103 and the second coil 105 may be formed integrally, and when the first coil 103 and the second coil 105 are formed integrally, one alternating current supply Alternating current may be supplied to the first coil 103 and the second coil 105 by means. In addition, when the first coil 103 and the second coil 105 are formed as one body, the induction heating area of the susceptor 102 is wider than when the first coil 103 and the second coil 105 are separated. It is possible to design the target temperature to be set higher. For example, the temperature can be set 20 to 30°C higher than when the first coil 103 and the second coil 105 are separated.

Figure 4 is a table explaining the effect of applying two coils according to an embodiment of the present invention.

Referring to FIG. 4, a first coil 103 that heats the upper part of the susceptor 102 and a second coil 105 that heats the lower part of the susceptor 102 and the heating pipe 104 according to an embodiment of the present invention. When applied, the current consumption is lower than when three coils are applied by separating the coil heating the upper part of the susceptor 102, the coil heating the lower part of the susceptor 102, and the coil heating the heating pipe 104, The amount of haze was higher.

The present invention is not limited to the specific preferred embodiments described above, and various modifications can be made by anyone skilled in the art without departing from the gist of the invention as claimed in the claims. Of course, such changes are within the scope of the claims.

Claims (5)

A susceptor that is hollow and into which a cigarette is inserted;
a first coil installed to surround the upper part of the susceptor and spaced apart from the susceptor by a predetermined distance;
an airflow pipe that communicates with the susceptor and is connected to the bottom of the susceptor to introduce external air;
a second coil spaced apart from the susceptor by a predetermined distance, installed to surround the lower portion of the susceptor, and installed to surround the airflow pipe;
first alternating current supply means for supplying alternating current to the first coil;
second alternating current supply means for supplying alternating current to the second coil;
a battery supplying power to the first alternating current supply means and/or the second alternating current supply means;
An aerosol generating device comprising a microcontroller that selectively controls the first AC supply means and the second AC supply means. According to paragraph 1,
The first AC supply means and the second AC supply means each include a power boosting circuit that amplifies the direct current voltage supplied from the battery under the control of a microcontroller, and a power boosting circuit that amplifies the direct current voltage supplied from the power boosting circuit under the control of the microcontroller, respectively. An aerosol generator comprising an induction logic and a capacitor that converts to . According to claim 1 or 2,
The airflow pipe is made of a material that can emit heat energy by generating an eddy current by a magnetic field, and the second coil is installed to surround the airflow pipe at a predetermined distance from the airflow pipe. According to paragraph 3,
An aerosol generator wherein the susceptor and the airflow pipe are made of a magnetic material. According to claim 1 or 2,
It includes a first temperature sensor that is connected to the microcontroller and detects the temperature of the first coil, and a second temperature sensor that is connected to the microcontroller and detects the temperature of the second coil, and the microcontroller uses the first temperature sensor as the first temperature sensor. An aerosol generating device, characterized in that the first AC supply means is controlled according to a detection signal input from the and the second AC supply means is controlled according to a detection signal input from a second temperature sensor.