KR20210026092A - Smart aerosol generator - Google Patents

Abstract

The present invention relates to an aerosol generation device provided with a liquid cartridge. More specifically, the present invention relates to an aerosol generation device, wherein the amount of haze can be corrected according to a usage environment and/or a user′s pattern, and the amount of haze can be automatically adjusted optimally according to the user′s preference by artificial intelligence learning. A smart aerosol generation device according to an embodiment of the present invention is a device for generating aerosol, and comprises: a liquid cartridge for filling a liquid; a heater for gasifying the liquid filled in the liquid cartridge; a heater unit for generating an electrical signal to the heater; a sensor for recognizing a usage environment; a sensor for recognizing a usage pattern of a user; and a microcontroller for controlling the heater unit to correct a haze amount according to a signal inputted from a sensor for recognizing a usage environment and/or a signal inputted from a sensor for recognizing the user′s usage pattern.

Description

Smart aerosol generator {SMART AEROSOL GENERATOR}

The present invention relates to an aerosol generating device equipped with a liquid cartridge, and more particularly, the amount of mist can be corrected according to the usage environment and/or the user's pattern, and the amount of mist is optimally suited to the user's preference through artificial intelligence learning. It relates to an aerosol generating device capable of automatically controlling the.

Aerosols are small particles of liquid or solid that are suspended in the atmosphere and usually have a size of 0.001 to 1.0 µm. In particular, there are cases in which humans inhale aerosols derived from various types of liquids for various purposes. For example, nebulizers are known for treating diseases.

In general, a device for generating an aerosol by electric heating includes a battery and a control electronic device to be portable and convenient to use, a cartridge storing a liquid phase for forming an aerosol, and an atomizer operated by electricity ( atomizer). The combination of these cartridges and atomizers into one assembly is called a “cartomizer”. Korean Patent Publication No. 10-1081481 is disclosed as a technical document related to such a conventional cartomizer, and referring to FIG. 1, a liquid phase provided in the liquid tank 1 and the atomizer 3 and transmitted through the wick 4 When an excessive amount of liquid essence flows through the heating element 6 that heats and vaporizes the essence and the power terminal 5 and the wick 4 electrically connected to the heating element 6, it absorbs the excessively introduced essence. A configuration comprising a cotton ball 7 serving as a function and a smoke flow tube 2 through which smoke vaporized by the heating element 6 flows is disclosed. However, in the prior art as described above, the amount of mist vaporized by the heating element may be changed according to the use environment such as the external environment and the remaining amount of the liquid in the liquid tank, and also according to the user's pattern such as the use interval, use time, and suction pressure. There is a problem in that it is difficult to provide a satisfactory sense of inhalation to the user because there is no function to control the amount of mist.

Korean Registered Patent Publication 10-1081481

An object of the present invention is to provide an aerosol generating device capable of adjusting the amount of mist that varies depending on the use environment and/or the user's use pattern.

An object of the present invention is to provide an aerosol generating device capable of automatically correcting the amount of fogging without the user's awareness by sensing a use environment or a user's use pattern and predicting the amount of fog that varies due to this.

An object of the present invention is to provide an aerosol generator that automatically fits the amount of mist according to the user's optimal preference through artificial intelligence learning.

A smart aerosol generating device according to an embodiment of the present invention is a device for generating an aerosol, comprising: a liquid cartridge for filling a liquid phase; A heater for vaporizing the liquid phase filled in the liquid cartridge; A heater unit for generating an electric signal to the heater; A sensor for recognizing a usage environment; a sensor for recognizing a usage pattern of a user; And a microcontroller for controlling the heater to correct the amount of fogging according to a signal input from a sensor recognizing a usage environment and/or a signal input from a sensor recognizing a user's usage pattern.

The present invention can provide an aerosol generating device capable of adjusting the amount of mist that varies depending on the usage environment and/or the usage pattern of the user.

According to the present invention, it is possible to provide an aerosol generating device that senses a usage environment and/or a user's usage pattern, predicts the amount of mist that varies due to this, and automatically corrects the amount of mist without the user's awareness.

According to the present invention, it is possible to provide an aerosol generating device that automatically fits the amount of mist according to the user's optimal preference through artificial intelligence learning.

1 is a view for explaining the prior art.
2 is a schematic cross-sectional view for explaining a smart aerosol generating device according to an embodiment of the present invention.
3 is a block diagram illustrating a smart aerosol generating device according to an embodiment of the present invention.

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

2 is a schematic cross-sectional view for explaining a smart aerosol generating device according to an embodiment of the present invention. 3 is a block diagram illustrating a smart aerosol generating device according to an embodiment of the present invention.

2 to 3, the smart aerosol generator 100 according to an embodiment of the present invention includes a liquid cartridge 10 for filling a liquid phase and a heater 40 for vaporizing the liquid phase filled in the liquid cartridge 10. ) And a heater unit 30 for generating an electrical signal to the heater 40 and a microcontroller 50 for controlling the heater unit 30. Air entering from the air inlet 12 passes through the passage 11 and enters the transfer unit 20 through the heater unit 30. The user is provided with an aerosol generated when the liquid filled in the liquid cartridge 10 is heated and vaporized by the heater 40 in the liquid cartridge 10 and communicated with the heater 40 through the transfer unit 20 ( It can be inhaled through 13). The heater 40 is supplied with power from the battery 60 through the heater unit 30. According to the embodiment, the heater unit 30 includes a FET electrically connected to the heater 40 and the microcontroller 50. , The power supplied to the heater 40 can be controlled while being turned on and off according to the PWM signal output from the microcontroller 50, and the amount of mist can be adjusted accordingly. The smart aerosol generating device 100 includes a sensor that recognizes the use environment, and according to the embodiment, the sensor that recognizes the use environment is a temperature sensor 14, and the microcontroller 50 is detected by the temperature sensor 14. The heater unit 30 is controlled by controlling the PWM signal output to the heater unit 30 so as to determine the temperature change according to the set signal and correct the fog amount according to the fog amount data to be corrected according to the preset temperature change. According to the embodiment, the sensor for recognizing the use environment is the humidity sensor 15, and the microcontroller 50 determines the humidity change according to the signal sensed by the humidity sensor 15 and corrects it according to the preset humidity change. The heater unit 30 is controlled by adjusting the PWM signal output to the heater unit 30 to correct the amount of fogging according to the amount of smoke data. According to an embodiment, the sensor for recognizing the use environment is a residual amount recognition sensor 17 for recognizing the remaining amount of liquid, for example, the residual amount recognition sensor 17 is a sensor that recognizes the remaining amount of liquid using optics. It can be installed at a predetermined position on the inner or outer surface of 10). According to an embodiment, the residual amount recognition sensor 17 includes a light emitting unit and a light receiving unit, and the light incident through the light emitting unit is scattered by the remaining amount of liquid and may recognize the remaining amount of liquid through the amount of light received by the light receiving unit. The microcontroller 50 determines the change in the remaining amount of liquid according to the signal sensed by the remaining amount recognition sensor 17, and corrects the amount of mist according to the amount of smoke that needs to be corrected according to the change in the amount of remaining liquid. The heater unit 30 is controlled by controlling the PWM signal output to the controller. According to an embodiment, the sensor for recognizing the use environment is a gas sensor 19 for sensing the taste of the aerosol, and the gas sensor 19 detects the gas component of the aerosol. The taste of the aerosol is sensed according to the ratio. If a specific gas component generated when the taste is burnt is detected, the gas sensor 19 may sense the burnt taste. The microcontroller 50 adjusts the PWM signal output to the heater 30 to correct the amount of fumes according to preset data when, for example, when a tan taste is detected according to a signal sensed by the gas sensor 19, Control 30. According to an embodiment, the sensor for recognizing the use environment is a fragrance sensor 21 capable of sensing the fragrance of an aerosol, and generates a signal according to, for example, a fragrance component or a fragrance component ratio. The microcontroller 50 is a PWM output to the heater unit 30 to correct the amount of fogging according to the fog amount data to be corrected according to a preset fragrance component or a fragrance component ratio according to a signal input from the fragrance sensor 21. When it is determined that the scent component detected according to the signal input from the scent sensor 21 is different from the preset scent component by controlling the signal, the PWM signal output to the heater 30 is outputted. It is controlled so that the heater 40 does not operate by blocking.

In addition, the smart aerosol generating device 100 includes a sensor that recognizes the user's usage pattern, and according to the embodiment, the sensor that recognizes the user's usage pattern is a pressure sensor 16 for recognizing the user's inhalation. Accordingly, the pressure sensor 16 communicates with the heater unit 30 and is electrically connected to the microcontroller 50. The microcontroller 50 determines the change in pressure according to the signal sensed by the pressure sensor 16 and stores information on the user pattern, such as the user's suction pressure, suction time, and suction interval, in the internal memory. The heater unit 30 may be controlled by adjusting the PWM signal output to the heater unit 30 to correct the amount of fogging according to the data. The microcontroller 50 determines whether the user is inhaling according to the signal input from the pressure sensor 16, and divides the amount of power while the user is inhaling and the amount of power while the user is waiting without inhaling to adjust the amount of mist. have. For example, while the user is inhaling, the amount of smoke is increased by adjusting the PWM signal output to the heater unit 30, and while the user is not inhaling and waiting, the amount of the smoke is adjusted by adjusting the PWM signal output to the heater unit 30. Can be reduced. In addition, the microcontroller 50 determines whether the user is inhaling according to the signal input from the pressure sensor 16, and applies power from the time when the user starts inhaling, but can adjust the amount of mist by adjusting the total power application time. It is also possible to control the amount of mist by applying power from the time when the user starts inhalation to the time when inhalation is finished, but by changing the reference pressure size setting, which is determined when the inhalation starts and ends. According to the embodiment, the sensor for recognizing the user's usage pattern is the fog amount detecting sensor 18, for example, the fog amount detecting sensor 18 is installed at a predetermined position in the airflow passage 13 to have a light emitting part and a light receiving part. And detects the amount of haze by the amount of light incident on the light-emitting unit and received by the light-receiving unit. The microcontroller 50 controls the PWM signal output to the heater unit 30 to correct the amount of fog according to the preset data by determining the change in the amount of fog according to the signal sensed by the fog amount measuring sensor 18. Control the unit 30.

In addition, the microcontroller 50 predicts the amount of fogging according to preset data according to a signal input from a sensor that recognizes a usage environment and/or a sensor that recognizes a user's usage pattern according to the above-described embodiments. In order to correct the zero amount, the power supplied to the heater 40 from the battery 60 may be adjusted by controlling the heater unit 30 by adjusting the PWM signal output to the heater unit 30.

In addition, the smart aerosol generating device 100 according to an embodiment of the present invention transmits the above-described sensing values of sensors for recognizing various types of use environments and the sensing values of sensors for recognizing a user's use pattern to the microcontroller 50. The sensor's sensing value and the user's usage pattern are stored in the built-in memory or in a separate memory, and the user's evaluation information is collected and stored to recognize the various types of use environments described above through artificial intelligence learning such as deep learning. AI learning is performed to calculate the optimal amount of fumes for various combinations of sensing values of the sensor that recognizes and stores the learned information in memory.

In addition, the smart aerosol generator 100 according to an embodiment of the present invention includes a wireless communication module 70 such as a ZigBee communication module or a Bluetooth communication module, and wireless communication with the smartphone 200 For example, the sensing value of the sensor recognizing the above-described various types of use environments, the sensing value of the sensor recognizing the user's usage pattern, and the user's evaluation information are transmitted to the smartphone 200 and the smartphone Using the artificial intelligence learning app in (200), in real time to calculate the optimal amount of mist for various combinations of the sensing values of the sensors that recognize the various types of use environments described above and the sensing values of the sensors that recognize the user's use pattern. After performing artificial intelligence learning, the learned information is transmitted to the smart aerosol generating device 100 through wireless communication, and when the user inhales an aerosol using the smart aerosol generating device 100, according to various environments by artificial intelligence learning. It can be adjusted to the optimum amount of mist.

The present invention is not limited to the specific preferred embodiments described above, and any person having ordinary knowledge in the technical field to which the present invention pertains without departing from the gist of the present invention claimed in the claims can implement various modifications. Of course, such changes are intended to be within the scope of the description of the claims.

1: liquid tank 2: smoke flow pipe
3: atom donation 4: wick
5: power terminal part 6: heating element
7: Sommoongchi
100: smart aerosol generator
200: smartphone
10: liquid cartridge 20: transfer unit
30: heater part 40: heater
50: microcontroller 60: battery
70: wireless communication module 11: air passage
12: air inlet 13: air flow passage
14: temperature sensor 15: humidity sensor
16: pressure sensor 17: residual amount recognition sensor
18: fog amount detection sensor 19: gas sensor
21: fragrance sensor

Claims (25)

In the device for generating an aerosol,
A liquid cartridge for filling a liquid phase;
A heater for vaporizing the liquid phase filled in the liquid cartridge;
A heater unit for generating an electric signal to the heater;
At least one sensor that recognizes the usage environment and:
At least one sensor for recognizing a user's usage pattern;
Smart aerosol generator comprising a; a microcontroller for controlling the heater to correct the amount of mist according to a signal input from a sensor that recognizes the usage environment and/or a signal input from a sensor that recognizes a user's usage pattern .
The method of claim 1,
A smart aerosol generating device comprising a temperature sensor as a sensor that recognizes the use environment.
The method of claim 1,
A smart aerosol generator equipped with a humidity sensor as a sensor that recognizes the use environment.
The method of claim 1,
Smart aerosol generator, characterized in that it comprises a residual amount recognition sensor for recognizing the remaining amount of the liquid filled in the liquid cartridge as a sensor that recognizes the use environment.
The method of claim 4,
The residual amount recognition sensor is a smart aerosol generator, characterized in that to recognize the residual amount of the liquid using optics.
The method of claim 5,
A smart aerosol generator, characterized in that the residual amount recognition sensor has a light-emitting unit and a light-receiving unit, and the light incident through the light-emitting unit is scattered by the remaining amount of liquid and recognizes the remaining amount of liquid through the amount of light received by the light-receiving unit.
The method of claim 1,
Smart aerosol generating device, characterized in that it comprises a gas sensor that senses the taste of the aerosol with a sensor that recognizes the use environment.
The method of claim 7,
The gas sensor is a smart aerosol generating device, characterized in that sensing the tan taste.
The method of claim 1,
Smart aerosol generating device, characterized in that it has a fragrance sensor capable of sensing the scent of the aerosol with a sensor that recognizes the use environment.
The method of claim 9,
The microcontroller is a smart aerosol generator, characterized in that when it is determined that the fragrance component detected according to the signal input from the fragrance sensor is different from the preset fragrance component, the heater is not operated.
The method of claim 1,
A smart aerosol generating device comprising a pressure sensor that recognizes a user's inhalation as a sensor that recognizes a user's usage pattern.
The method of claim 11,
The microcontroller is a smart aerosol generator, characterized in that it determines the change in pressure according to the signal sensed by the pressure sensor and stores information on the user pattern such as the user's suction pressure, suction time, and suction interval in the internal memory accordingly. .
The method of claim 11,
The microcontroller is a smart aerosol, characterized in that it determines the presence or absence of the user's inhalation according to the signal input from the pressure sensor, and controls the amount of mist by dividing the amount of power during the user's inhalation and the amount of power during the user's standby without inhaling. Generator.
The method of claim 11,
The microcontroller is a smart aerosol generator, characterized in that it determines the presence or absence of the user's inhalation according to the signal input from the pressure sensor, and applies power from the time when the user starts inhalation, but adjusts the amount of mist by adjusting the total power application time.
The method of claim 14,
The microcontroller is a smart aerosol generator, characterized in that the amount of mist is adjusted by changing the reference pressure size setting, which is determined when the user starts inhalation and when inhalation ends, while applying power from the time when inhalation starts to the inhalation end time. .
The method of claim 1,
Smart aerosol generating device, characterized in that it comprises a sensor for detecting the amount of smoke as a sensor for recognizing a user's usage pattern.
The method of claim 16,
A smart aerosol generator, characterized in that the fog amount detection sensor is installed at a predetermined position in the airflow passage, has a light emitting part and a light receiving part, and detects the amount of fog by the amount of light incident from the light emitting part and received by the light receiving part.
The method of claim 1,
It is equipped with a temperature sensor, a humidity sensor, a residual amount recognition sensor that recognizes the remaining amount of liquid charged in the liquid cartridge, a gas sensor that senses the taste of an aerosol, and a scent sensor that can sense the aerosol scent. And a pressure sensor that recognizes a user's inhalation as a sensor that recognizes a user's usage pattern, and a fume amount detection sensor.
The method of claim 18,
The microcontroller is a smart aerosol generator, characterized in that it determines the change in pressure according to the signal sensed by the pressure sensor and stores information on the user pattern such as the user's suction pressure, suction time, and suction interval in the internal memory accordingly. .
The method of claim 18,
The microcontroller is a smart aerosol, characterized in that it determines the presence or absence of the user's inhalation according to the signal input from the pressure sensor, and controls the amount of mist by dividing the amount of power during the user's inhalation and the amount of power during the user's standby without inhaling. Generator.
The method of claim 18,
The microcontroller is a smart aerosol generator, characterized in that it determines the presence or absence of the user's inhalation according to the signal input from the pressure sensor, and applies power from the time when the user starts inhalation, but adjusts the amount of mist by adjusting the total power application time.
The method of claim 21,
The microcontroller is a smart aerosol generator, characterized in that the amount of mist is adjusted by changing the reference pressure size setting, which is determined when the user starts inhalation and when inhalation ends, while applying power from the time when inhalation starts to the inhalation end time. .
The method according to any one of claims 1 to 22,
The microcontroller predicts the amount of fogging according to a signal input from a sensor that recognizes the use environment and/or a sensor that recognizes the user's use pattern, and controls the heater to correct the amount of fog accordingly. Device.
The method according to any one of claims 1 to 22,
The sensing value of the sensor that recognizes the usage environment and the sensing value of the sensor that recognizes the user's usage pattern are stored in the memory built into the microcontroller or in a separate memory, and collect and store the user's evaluation. It features artificial intelligence learning to calculate the optimal amount of fumes for various combinations of the sensor's sensing value that recognizes the type of usage environment and the sensor's sensing value that recognizes the user's usage pattern, and stores the learned information in memory. Smart aerosol generator.
The method of claim 24
A smart aerosol-generating device comprising a wireless communication module and performing wireless communication with a smartphone to perform artificial intelligence learning in real time using an app.

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