KR102819162B1 - Aerosol generating device - Google Patents

Abstract

An aerosol generating device is disclosed. The aerosol generating device of the present disclosure includes: a housing having an insertion space formed therein; a heater for heating a stick inserted into the insertion space; at least one sensor for outputting a signal corresponding to the insertion space; a power circuit electrically connected to the heater and transmitting power to the heater; and a signal circuit electrically connected to the sensor and transmitting a signal corresponding to the sensor, wherein the power circuit may include a low pass filter.

Description

Aerosol generating device {AEROSOL GENERATING DEVICE}

The present disclosure relates to an aerosol generating device.

An aerosol generating device is intended to extract a certain component from a medium or substance through an aerosol. The medium may contain substances of various components. The substances contained in the medium may be flavoring substances of various components. For example, the substances contained in the medium may contain nicotine components, herbal components, and/or coffee components. Recently, much research has been conducted on such aerosol generating devices.

The present disclosure aims to solve the above-mentioned and other problems.

Another purpose may be to provide an aerosol generating device capable of preventing noise components from being generated in a signal circuit due to power supply through a power circuit.

Another purpose may be to provide an aerosol generating device that can accurately determine whether a stick is inserted or removed from an insertion space.

According to one aspect of the present disclosure for achieving the above-described purpose, an aerosol generating device comprises: a housing having an insertion space formed therein; a heater for heating a stick inserted into the insertion space; at least one sensor for outputting a signal corresponding to the insertion space; a power circuit electrically connected to the heater and transmitting power to the heater; and a signal circuit electrically connected to the sensor and transmitting a signal corresponding to the sensor, wherein the power circuit may include a low pass filter.

According to at least one embodiment of the present disclosure, it is possible to prevent noise components from being generated in a signal circuit due to power supply through a power circuit.

According to at least one embodiment of the present disclosure, it is possible to accurately determine whether a stick is inserted or removed from an insertion space.

Further scope of the applicability of the present disclosure will become apparent from the detailed description below. However, since various changes and modifications within the spirit and scope of the present disclosure will become apparent to those skilled in the art, it should be understood that the detailed description and specific embodiments, such as the preferred embodiments of the present disclosure, are given by way of example only.

FIG. 1 is a block diagram of an aerosol generating device according to one embodiment of the present disclosure.
FIGS. 2 to 4 are drawings for reference in the description of an aerosol generating device according to embodiments of the present disclosure.
FIGS. 5 and 6 are drawings for reference in the description of a stick according to embodiments of the present disclosure.
FIGS. 7 to 11 are drawings for reference in explaining the configuration of an aerosol generating device according to one embodiment of the present disclosure.
FIGS. 12 and 13 are drawings for reference in explaining the operation of an aerosol generating device according to one embodiment of the present disclosure.

Hereinafter, embodiments disclosed in this specification will be described in detail with reference to the attached drawings. Regardless of the drawing numbers, identical or similar components are given the same reference numbers and redundant descriptions thereof will be omitted.

The suffixes "module" and "part" used for components in the following description may be given or used interchangeably only for the convenience of writing the specification. "Module" and "part" do not have distinct meanings or roles in themselves.

In addition, when describing the embodiments disclosed in this specification, if it is determined that a detailed description of a related known technology may obscure the gist of the embodiments disclosed in this specification, the detailed description thereof will be omitted. In addition, the attached drawings are only intended to facilitate easy understanding of the embodiments disclosed in this specification, and the technical ideas disclosed in this specification are not limited by the attached drawings. It should be understood that the attached drawings include all modifications, equivalents, and substitutes included in the spirit and technical scope of the present disclosure.

Terms that include ordinal numbers, such as first, second, etc., may be used to describe various components. However, the components are not limited by the terms. The terms are used only for the purpose of distinguishing one component from another.

When it is said that a component is "connected" or "connected" to another component, it should be understood that it may be directly connected or connected to that other component, although it should be understood that there may be other components in between. On the other hand, when it is said that a component is "directly connected" or "directly connected" to another component, it should be understood that there are no other components in between.

Singular expressions include plural expressions unless the context clearly indicates otherwise.

FIG. 1 is a block diagram of an aerosol generating device according to one embodiment of the present disclosure.

Referring to FIG. 1, the aerosol generating device (10) may include a communication interface (11), an input/output interface (12), an aerosol generating module (13), a memory (14), a sensor module (15), a battery (16), and/or a control unit (17).

In one embodiment, the aerosol generating device (10) may be composed of only the main body. In this case, the components included in the aerosol generating device (10) may be located in the main body. In another embodiment, the aerosol generating device (10) may be composed of a cartridge containing an aerosol generating material and the main body. In this case, the components included in the aerosol generating device (10) may be located in at least one of the main body and the cartridge.

The communication interface (11) may include at least one communication module for communication with an external device and/or a network. For example, the communication interface (11) may include a communication module for wired communication such as a universal serial bus (USB). For example, the communication interface (11) may include a communication module for wireless communication such as wireless fidelity (WiFi), Bluetooth, Bluetooth low energy (BLE), Zigbee, and near field communication (NFC).

The input/output interface (12) may include an input device that receives a command from a user and/or an output device that outputs information to the user. For example, the input device may include a touch panel, a physical button, a microphone, etc. For example, the output device may include a display device that outputs visual information such as a display or a light emitting diode (LED), an audio device that outputs auditory information such as a speaker or a buzzer, a motor that outputs tactile information such as a haptic effect, etc.

The input/output interface (12) can transmit data corresponding to a command input from a user through an input device to other component(s) of the aerosol generator (10). The input/output interface (12) can output information corresponding to data received from other component(s) of the aerosol generator (10) through an output device.

The aerosol generating module (13) can generate an aerosol from an aerosol generating material. Here, the aerosol generating material can mean one material or a combination of two or more materials in various states such as a liquid state, a solid state, and a gel state that can generate an aerosol.

The liquid aerosol generating material may be a liquid comprising a tobacco-containing material including volatile tobacco flavor components according to one embodiment. The liquid aerosol generating material may be a liquid comprising a non-tobacco material according to another embodiment. For example, the liquid aerosol generating material may comprise water, a solvent, nicotine, plant extracts, flavorings, flavoring agents, a vitamin mixture, and the like.

The solid aerosol generating material may include a solid material based on tobacco raw materials such as a leaf sheet, a tobacco stick, or a granule. In addition, the solid aerosol generating material may include a solid material containing a taste modifier, a flavoring agent, or the like. For example, the taste modifier may include calcium carbonate, sodium bicarbonate, calcium oxide, or the like. For example, the flavoring agent may include a natural material such as herbal granules, or silica, zeolite, dextrin, or the like containing a flavoring component.

Additionally, the aerosol generating material may further comprise an aerosol forming agent, such as glycerin or propylene glycol.

The aerosol generating module (13) may include at least one heater.

The aerosol generating module (13) may include an electrical resistive heater. For example, the electrical resistive heater may include at least one electrically conductive track. The electrical resistive heater may be heated by a current flowing through the electrically conductive track. At this time, the aerosol generating material may be heated by the heated electrical resistive heater.

The electrically conductive track may include an electrically resistive material. As an example, the electrically conductive track may be formed of a metallic material. As another example, the electrically conductive track may be formed of a ceramic material, carbon, a metal alloy, or a composite material of a ceramic material and a metal.

The electrical resistive heater may include electrically conductive tracks formed in various shapes. For example, the electrically conductive tracks may be formed in any one of a tubular shape, a plate shape, a needle shape, a rod shape, and a coil shape.

The aerosol generating module (13) may include a heater that uses an induction heating method. For example, the induction heating heater may include an electrically conductive coil. The induction heating heater may generate an alternating magnetic field whose direction changes periodically by controlling a current flowing in the electrically conductive coil. At this time, when the alternating magnetic field is applied to a magnetic body, energy loss may occur in the magnetic body due to eddy current loss and hysteresis loss. In addition, as the lost energy is released as heat energy, an aerosol generating material adjacent to the magnetic body may be heated. Here, an object that generates heat by a magnetic field may be named a susceptor.

Meanwhile, the aerosol generating module (13) can generate an aerosol from an aerosol generating material by generating ultrasonic vibration.

The aerosol generating module (13) may be named a cartomizer, an atomizer, a vaporizer, etc.

The memory (14) can store programs for each signal processing and control within the control unit (17). The memory (14) can store data processed in the control unit (17) and data to be processed.

For example, the memory (14) can store application programs designed for the purpose of performing various tasks that can be processed by the control unit (17). The memory (14) can selectively provide some of the stored application programs upon request from the control unit (17).

For example, the memory (14) may store the operating time of the aerosol generator (10), the maximum number of puffs, the current number of puffs, the number of times the battery (16) has been charged, the number of times the battery (16) has been discharged, at least one temperature profile, data on the user's inhalation pattern, data on charging/discharging, etc. Here, a puff may mean an inhalation by the user. Inhalation may mean a situation in which the user draws air into the user's oral cavity, nasal cavity, or lungs through the mouth or nose.

The memory (14) may include at least one of volatile memory (e.g., DRAM, SRAM, SDRAM, etc.) or non-volatile memory (e.g., flash memory, hard disk drive (HDD), solid-state drive (SSD), etc.).

The sensor module (15) may include at least one sensor.

For example, the sensor module (15) may include a sensor that detects a puff (hereinafter, a puff sensor). At this time, the puff sensor may be implemented by a proximity sensor such as an IR sensor, a pressure sensor, a gyro sensor, an acceleration sensor, a magnetic field sensor, etc.

For example, the sensor module (15) may include a sensor (hereinafter, temperature sensor) that detects the temperature of the heater included in the aerosol generating module (13), the temperature of the aerosol generating material, etc. At this time, the heater included in the aerosol generating module (13) may also function as a temperature sensor. For example, the electrically resistive material of the heater may be a material having a temperature coefficient of resistance. The sensor module (15) may sense the temperature of the heater by measuring the resistance of the heater that varies depending on the temperature.

For example, if a stick can be inserted into the main body of the aerosol generating device (10), the sensor module (15) may include a sensor that detects the insertion of the stick (hereinafter, “stick detection sensor”).

For example, if the aerosol generator (10) includes a cartridge, the sensor module (15) may include a sensor (hereinafter, cartridge detection sensor) that detects mounting/detaching, position, etc. of the cartridge with respect to the main body.

At this time, the stick detection sensor and/or the cartridge detection sensor can be implemented by an inductance-based sensor, a capacitive sensor, a resistance sensor, a Hall sensor (hall IC) using the Hall effect, etc.

For example, the sensor module (15) may include a voltage sensor for detecting voltage applied to a component (e.g., battery (16)) provided in the aerosol generating device (10) and/or a current sensor for detecting current.

The battery (16) can supply power used for the operation of the aerosol generator (10) under the control of the control unit (17). The battery (16) can supply power to other components provided in the aerosol generator (10). For example, the battery (16) can supply power to a communication module included in the communication interface (11), an output device included in the input/output interface (12), a heater included in the aerosol generator module (13), etc.

The battery (16) may be a rechargeable battery or a disposable battery. For example, the battery (16) may be a lithium-ion battery or a lithium polymer (Li-Polymer) battery, but is not limited thereto. For example, if the battery (16) is rechargeable, the charge rate (C-rate) of the battery (16) may be 10C, and the discharge rate (C-rate) may be 10C to 20C, but is not limited thereto. In addition, for stable use, the battery (16) may be manufactured so that 80% or more of the total capacity can be secured even when charging/discharging is performed 2000 times.

The aerosol generator (10) may further include a protection circuit module (PCM), which is a circuit for protecting the battery (16). The protection circuit module (PCM) may be arranged adjacent to the upper surface of the battery (16). For example, the protection circuit module (PCM) may block the electric path to the battery (16) when a short circuit occurs in a circuit connected to the battery (16), when an overvoltage is applied to the battery (16), when an overcurrent flows to the battery (16), etc., in order to prevent overcharge and overdischarge of the battery (16).

The aerosol generator (10) may further include a charging terminal into which power supplied from the outside is input. For example, a charging terminal may be formed on one side of the main body of the aerosol generator (10). The aerosol generator (10) may charge the battery (16) using power supplied through the charging terminal. At this time, the charging terminal may be configured as a wired terminal for USB communication, a pogo pin, or the like.

The aerosol generator (10) can also wirelessly receive power supplied from an external source through a communication interface (11). For example, the aerosol generator (10) can wirelessly receive power using an antenna included in a communication module for wireless communication. The aerosol generator (10) can charge a battery (16) using the power supplied wirelessly.

The control unit (17) can control the overall operation of the aerosol generating device (10). The control unit (17) can be connected to each component provided in the aerosol generating device (10). The control unit (17) can control the overall operation of each component by transmitting and/or receiving signals between each component.

The control unit (17) may include at least one processor. The control unit (17) may control the overall operation of the aerosol generating device (10) using the processor. Here, the processor may be a general processor such as a CPU (central processing unit). Of course, the processor may be a dedicated device such as an ASIC or another hardware-based processor.

The control unit (17) can perform any one of the multiple functions of the aerosol generator (10). For example, the control unit (17) can perform any one of the multiple functions of the aerosol generator (10) (e.g., preheating function, heating function, charging function, cleaning function, etc.) according to the status of each component provided in the aerosol generator (10), a user command received through the input/output interface (12), etc.

The control unit (17) can control the operation of each component provided in the aerosol generating device (10) based on the data stored in the memory (14). For example, the control unit (17) can control a predetermined power to be supplied from the battery (16) to the aerosol generating module (13) for a predetermined period of time based on data on the temperature profile, the user's inhalation pattern, etc. stored in the memory (14).

The control unit (17) can determine whether a puff is present through the puff sensor included in the sensor module (15). For example, the control unit (17) can check temperature changes, flow changes, pressure changes, voltage changes, etc. within the aerosol generating device (10) based on the sensing values of the puff sensor. The control unit (17) can determine whether a puff is present based on the results checked based on the sensing values of the puff sensor.

The control unit (17) can control the operation of each component provided in the aerosol generating device (10) depending on whether a puff is generated and/or the number of puffs. For example, the control unit (17) can control the temperature of the heater to be changed or maintained based on the temperature profile stored in the memory (14).

The control unit (17) can control power supply to the heater to be cut off according to predetermined conditions. For example, when the stick is removed, when the cartridge is separated, when the number of puffs reaches the preset maximum number of puffs, when no puffs are detected for a preset time or longer, when the remaining capacity of the battery (16) is less than a preset value, etc., the control unit (17) can control power supply to the heater to be cut off.

The control unit (17) can calculate the remaining power capacity (hereinafter, “remaining power amount”) stored in the battery (16). For example, the control unit (17) can calculate the remaining power amount of the battery (16) based on the sensing values of the voltage sensor and/or current sensor included in the sensor module (15).

The control unit (17) can control power to be supplied to the heater by using at least one of the pulse width modulation (PWM) method and the proportional-integral-differential (PID) method.

For example, the control unit (17) can control a current pulse having a predetermined frequency and duty ratio to be supplied to the heater using the PWM method. At this time, the control unit (17) can control the power supplied to the heater by adjusting the frequency and duty ratio of the current pulse.

For example, the control unit (17) can determine the target temperature that is the target of control based on the temperature profile. At this time, the control unit (17) can control the power supplied to the heater by using the PID method, which is a feedback control method using the difference value between the temperature of the heater and the target temperature, the integrated value of the difference value over time, and the differentiated value of the difference value over time.

Meanwhile, the PWM method and the PID method have been described as examples of control methods for supplying power to the heater, but the present invention is not limited thereto, and various control methods such as the Proportional-Integral (PI) method and the Proportional-Differential (PD) method can be used.

Meanwhile, the control unit (17) can control power to be supplied to the heater according to preset conditions. For example, if a cleaning function for cleaning the space where the stick is inserted is selected according to a command input from the user through the input/output interface (12), the control unit (17) can control power to be supplied to the heater.

FIGS. 2 to 6 are drawings for reference in the description of an aerosol generating device according to embodiments of the present disclosure.

According to various embodiments of the present invention, the aerosol generating device (10) may include a main body (100) and/or a cartridge (200).

Referring to FIG. 2, an aerosol generating device (10) according to one embodiment may include a main body (100) configured such that a stick (20) can be inserted into a space formed by a housing (101).

The stick (20) may be similar to a typical combustible cigarette. For example, the stick (20) may be divided into a first portion containing an aerosol generating substance and a second portion containing a filter or the like. Alternatively, the second portion of the stick (20) may also contain an aerosol generating substance. For example, an aerosol generating substance in the form of granules or capsules may be inserted into the second portion.

The entire first part may be inserted into the inside of the aerosol generating device (10), and the second part may be exposed to the outside. Alternatively, only a part of the first part may be inserted into the inside of the aerosol generating device (10), or parts of the first part and the second part may be inserted. The user may inhale the aerosol while holding the second part in his mouth. At this time, the aerosol is generated by external air passing through the first part, and the generated aerosol may be delivered to the user's mouth by passing through the second part.

The main body (100) may be formed in a structure in which external air can flow into the interior of the main body (100) when the stick (20) is inserted. At this time, the external air that flows into the main body (100) can flow through the stick (20) to the user's mouth.

The heater may be placed in a position within the body (100) corresponding to the position of the stick (20) when the stick (20) is inserted into the body (100). In this drawing, the heater is illustrated as an electrically conductive heater (110) including a needle-shaped electrically conductive track, but the present invention is not limited thereto.

The heater can heat the inside and/or outside of the stick (20) using power supplied from the battery (16). At this time, an aerosol can be generated from the heated stick (20). At this time, the user can inhale the aerosol containing tobacco flavor by inhaling one end of the stick (20) with the mouth.

Meanwhile, the control unit (17) can control power to be supplied to the heater even when the stick (20) is not inserted, according to preset conditions. For example, when a cleaning function for cleaning the space where the stick (20) is inserted is selected according to a command input from a user through the input/output interface (12), the control unit (17) can control power to be supplied to the heater.

The control unit (17) can monitor the number of puffs based on the sensing value of the puff sensor from the time the stick (20) is inserted.

The control unit (17) can initialize the current number of puffs stored in the memory (14) when the inserted stick (20) is removed.

Referring to FIG. 3, an aerosol generating device (100) according to one embodiment may include a main body (100) that supports a cartridge (200) and a cartridge (200) that holds an aerosol generating material.

The cartridge (200) may be configured to be detachable from the main body (100) according to one embodiment. The cartridge (200) may be configured integrally with the main body (100) according to another embodiment. For example, at least a portion of the cartridge (200) may be inserted into an internal space formed by the housing (101) of the main body (100), so that the cartridge (200) may be mounted on the main body (100).

The main body (100) may be formed in a structure in which external air can flow into the interior of the main body (100) while the cartridge (200) is inserted. At this time, the external air that flows into the main body (100) can pass through the cartridge (200) and flow into the user's mouth.

The control unit (17) can determine whether the cartridge (200) is mounted/removed through the cartridge detection sensor included in the sensor module (15). For example, the cartridge detection sensor can transmit a pulse current through one terminal connected to the cartridge (200). At this time, the cartridge detection sensor can detect whether the cartridge (200) is connected based on whether a pulse current is received through another terminal.

The cartridge (200) may include a heater (210) for heating an aerosol generating material and/or a storage (220) for holding the aerosol generating material. For example, a liquid delivery means impregnated with (containing) the aerosol generating material may be placed inside the storage (220). The electrically conductive track of the heater (210) may be formed in a structure for winding the liquid delivery means. At this time, as the liquid delivery means is heated by the heater (210), an aerosol may be generated. Here, the liquid delivery means may include a wick such as cotton fiber, ceramic fiber, glass fiber, or porous ceramic.

The cartridge (200) may include an insertion space (230) configured to allow the stick (20) to be inserted. For example, the cartridge (200) may include an insertion space formed by an inner wall (not shown) extending circumferentially along the direction in which the stick (20) is inserted. At this time, the insertion space may be formed by the inner side of the inner wall being open upward and downward. The stick (20) may be inserted into the insertion space (230) formed by the inner wall.

The insertion space into which the stick (20) is inserted can be formed in a shape corresponding to the shape of a portion of the stick (20) inserted into the insertion space. For example, when the stick (20) is formed in a cylindrical shape, the insertion space can be formed in a cylindrical shape.

When the stick (20) is inserted into the insertion space, the outer surface of the stick (20) is surrounded by the inner wall and can come into contact with the inner wall.

A portion of the stick (20) can be inserted into the insertion space (230) of the cartridge (200), and the remaining portion can be exposed to the outside.

The user can inhale the aerosol by holding one end of the stick (20) in his mouth. The aerosol generated by the heater (210) can pass through the stick (20) and be delivered to the user's mouth. At this time, while the aerosol passes through the stick (20), a substance contained in the stick (20) can be added to the aerosol, and the aerosol added with the substance can be inhaled into the user's mouth through one end of the stick (20).

Referring to FIG. 4, an aerosol generating device (100) according to one embodiment may include a main body (100) that supports a cartridge (200) and a cartridge (200) that holds an aerosol generating material. The main body (100) may be configured such that a stick (20) can be inserted into an insertion space (130).

The aerosol generating device (100) may include a first heater that heats an aerosol generating material stored in a cartridge (200). For example, when a user inhales one end of the stick (20) with his/her mouth, the aerosol generated by the first heater may pass through the stick (20). At this time, while the aerosol passes through the stick (20), a flavor may be added to the aerosol. The flavored aerosol may be inhaled into the user's mouth through one end of the stick (20).

Meanwhile, according to another embodiment, the aerosol generating device (100) may include a first heater for heating an aerosol generating substance stored in a cartridge (200) and a second heater for heating a stick (20) inserted into the main body (100), respectively. For example, the aerosol generating device (100) may generate an aerosol by heating the aerosol generating substance stored in the cartridge (200) and the stick (20), respectively, through the first heater and the second heater.

FIG. 5 and FIG. 6 are drawings for reference in the description of a stick according to embodiments of the present disclosure. Detailed descriptions of overlapping contents in FIG. 5 and FIG. 6 will be omitted.

Referring to FIG. 5, a cigarette (20) according to one embodiment may include a tobacco rod (21) and a filter rod (22). The first part described above with reference to FIG. 2 may include the tobacco rod (21). The second part described above with reference to FIG. 2 may include the filter rod (22).

In Fig. 5, the filter load (22) is illustrated as a single segment, but is not limited thereto. In other words, the filter load (22) may be composed of a plurality of segments. For example, the filter load (22) may include a first segment for cooling the aerosol and a second segment for filtering a predetermined component contained in the aerosol. In addition, if necessary, the filter load (22) may further include at least one segment for performing another function.

The diameter of the stick (20) is within the range of 5 mm to 9 mm, and the length may be about 48 mm, but is not limited thereto. For example, the length of the tobacco rod (21) may be about 12 mm, the length of the first segment of the filter rod (22) may be about 10 mm, the length of the second segment of the filter rod (22) may be about 14 mm, and the length of the third segment of the filter rod (22) may be about 12 mm, but is not limited thereto.

The stick (20) may be wrapped by at least one wrapper (24). The wrapper (24) may have at least one hole formed through which outside air is introduced or internal gas is discharged. As an example, the stick (20) may be wrapped by one wrapper (24). As another example, the stick (20) may be wrapped by two or more wrappers (24) in an overlapping manner. For example, the tobacco rod (21) may be wrapped by the first wrapper (241). For example, the filter rod (22) may be wrapped by the wrappers (242, 243, 244). The tobacco rod (21) and the filter rod (22) wrapped by individual wrappers may be combined. The entire stick (20) may be repackaged by the third wrapper (245). If each filter load (22) is composed of multiple segments, each segment can be wrapped by an individual wrapper (242, 243, 244). The entire stick (20) in which the segments wrapped by the individual wrappers are combined can be repackaged by another wrapper.

The first wrapper (241) and the second wrapper (242) can be made of general filter paper. For example, the first wrapper (241) and the second wrapper (242) can be porous paper or non-porous paper. In addition, the first wrapper (241) and the second wrapper (242) can be made of oil-resistant paper and/or aluminum composite packaging material.

The third wrapper (243) may be made of hard paper. For example, the weight of the third wrapper (243) may be within a range of 88 g/m2 to 96 g/m2. For example, the weight of the third wrapper (243) may be within a range of 90 g/m2 to 94 g/m2. In addition, the thickness of the third wrapper (243) may be within a range of 120 um to 130 um. For example, the thickness of the third wrapper (243) may be 125 um.

The fourth wrapper (244) may be made of a hard paper having a high oil resistance. For example, the weight of the fourth wrapper (244) may be included in a range of 88 g/m2 to 96 g/m2. For example, the weight of the fourth wrapper (244) may be included in a range of 90 g/m2 to 94 g/m2. In addition, the thickness of the fourth wrapper (244) may be included in a range of 120 um to 130 um. For example, the thickness of the fourth wrapper (244) may be 125 um.

The fifth wrapper (245) may be made of sterilized paper (MFW). Here, the sterilized paper (MFW) may mean paper that is specially manufactured to have improved tensile strength, water resistance, smoothness, etc. compared to general paper. For example, the basis weight of the fifth wrapper (245) may be within a range of 57 g/m2 to 63 g/m2. For example, the basis weight of the fifth wrapper (245) may be 60 g/m2. In addition, the thickness of the fifth wrapper (245) may be within a range of 64 um to 70 um. For example, the thickness of the fifth wrapper (245) may be 67 um.

The fifth wrapper (245) may have a predetermined material added thereto. Here, an example of the predetermined material may be silicon, but is not limited thereto. For example, silicon may have properties such as heat resistance that is less affected by temperature, oxidation resistance that does not oxidize, resistance to various chemicals, water repellency, or electrical insulation. However, even if it is not silicon, any material having the above-described properties may be applied or coated on the fifth wrapper (245) without limitation.

The fifth wrapper (245) can prevent the stick (20) from burning. For example, if the tobacco rod (21) is heated by the heater (110), there is a possibility that the stick (20) will burn. Specifically, if the temperature rises above the ignition point of any one of the materials included in the tobacco rod (21), the stick (20) may burn. Even in this case, since the fifth wrapper (245) includes a non-combustible material, the stick (20) can be prevented from burning.

In addition, the fifth wrapper (245) can prevent the main body (100) from being contaminated by substances generated from the stick (20). Liquid substances can be generated within the stick (20) by the user's puff. For example, liquid substances (e.g., moisture, etc.) can be generated by cooling the aerosol generated from the stick (20) by external air. As the fifth wrapper (245) wraps the stick (20), liquid substances generated within the stick (20) can be prevented from leaking out of the stick (20).

The tobacco rod (21) may include an aerosol generating material. For example, the aerosol generating material may include, but is not limited to, at least one of glycerin, propylene glycol, ethylene glycol, dipropylene glycol, diethylene glycol, triethylene glycol, tetraethylene glycol, and oleyl alcohol. In addition, the tobacco rod (21) may contain other additives such as a flavoring agent, a humectant, and/or an organic acid. In addition, a flavoring liquid such as menthol or a humectant may be added to the tobacco rod (21) by spraying it onto the tobacco rod (21).

The tobacco rod (21) can be manufactured in various ways. For example, the tobacco rod (21) can be manufactured as a sheet. For example, the tobacco rod (21) can be manufactured as a strand. For example, the tobacco rod (21) can be manufactured as a tobacco sheet cut into small pieces. For example, the tobacco rod (21) can be surrounded by a heat-conducting material. For example, the heat-conducting material can be a metal foil such as aluminum foil, but is not limited thereto. For example, the heat-conducting material surrounding the tobacco rod (21) can evenly distribute heat transferred to the tobacco rod (21) to improve the heat conductivity applied to the tobacco rod. This can improve the taste of the tobacco. The heat-conducting material surrounding the tobacco rod (21) can function as a susceptor heated by an induction heater. At this time, although not shown in the drawing, the tobacco rod (21) may further include an additional susceptor in addition to the heat-conducting material surrounding the outside.

The filter rod (22) may be a cellulose acetate filter. Meanwhile, there is no limitation on the shape of the filter rod (22). For example, the filter rod (22) may be a cylindrical rod. For example, the filter rod (22) may be a tube rod having a hollow portion therein. For example, the filter rod (22) may be a recessed rod. When the filter rod (22) is composed of a plurality of segments, at least one of the plurality of segments may be manufactured in a different shape.

The first segment of the filter rod (22) may be a cellulose acetate filter. For example, the first segment may be a tube-shaped structure having a hollow space therein. When the heater (110) is inserted through the first segment, the phenomenon of the internal material of the tobacco rod (21) being pushed back may be prevented, and a cooling effect of the aerosol may also be generated. The diameter of the hollow space included in the first segment may be adopted as an appropriate diameter within a range of 2 mm to 4.5 mm, but is not limited thereto.

The length of the first segment may be any appropriate length within the range of 4 mm to 30 mm, but is not limited thereto. For example, the length of the first segment may be 10 mm, but is not limited thereto.

The second segment of the filter rod (22) cools the aerosol generated by the heater (110) heating the tobacco rod (21). Accordingly, the user can inhale the aerosol cooled to an appropriate temperature.

The length or diameter of the second segment can be determined variously depending on the shape of the stick (20). For example, the length of the second segment can be appropriately employed within a range of 7 mm to 20 mm. Preferably, the length of the second segment can be about 14 mm, but is not limited thereto.

The second segment can be made by weaving polymer fibers. In this case, a flavoring agent can be applied to the fibers made of the polymer. Alternatively, a separate fiber to which a flavoring agent has been applied and a fiber made of the polymer can be woven together to make the second segment. Alternatively, the second segment can be formed by a crimped polymer sheet.

For example, the polymer can be made of a material selected from the group consisting of polyethylene (PE), polypropylene (PP), polyvinyl chloride (PVC), polyethylene terephthalate (PET), polylactic acid (PLA), cellulose acetate (CA), and aluminum foil.

As the second segment is formed by a woven polymer fiber or a crimped polymer sheet, the second segment may include a single or a plurality of longitudinally extending channels. Here, a channel may mean a passage through which a gas (e.g., air or an aerosol) passes.

For example, the second segment comprised of the compressed polymer sheet can be formed from a material having a thickness of between about 5 μm and about 300 μm, for example between about 10 μm and about 250 μm. Furthermore, the total surface area of the second segment can be between about 300 mm2/mm and about 1000 mm2/mm. Additionally, the aerosol-cooling element can be formed from a material having a specific surface area of between about 10 mm2/mg and about 100 mm2/mg.

Meanwhile, the second segment may include a thread containing a volatile flavor component. Here, the volatile flavor component may be menthol, but is not limited thereto. For example, the thread may be filled with a sufficient amount of menthol to provide 1.5 mg or more of menthol to the second segment.

The third segment of the filter load (22) may be a cellulose acetate filter. The length of the third segment may be appropriately adopted within a range of 4 mm to 20 mm. For example, the length of the third segment may be about 12 mm, but is not limited thereto.

The filter rod (22) may be manufactured to generate a flavor. As an example, a flavoring agent may be sprayed onto the filter rod (22). As an example, a separate fiber coated with a flavoring agent may be inserted into the interior of the filter rod (22).

In addition, the filter load (22) may include at least one capsule (23). Here, the capsule (23) may perform a function of generating a flavor. The capsule (23) may also perform a function of generating an aerosol. For example, the capsule (23) may have a structure in which a liquid including a flavor is wrapped with a film. The capsule (23) may have a spherical or cylindrical shape, but is not limited thereto.

Referring to FIG. 6, the stick (30) according to one embodiment may further include a shear plug (33). The shear plug (33) is located on one side of the tobacco rod (31) facing the filter rod (32). The shear plug (33) can prevent the tobacco rod (31) from escaping to the outside. The shear plug (33) can prevent liquefied aerosol from the tobacco rod (31) from flowing into the aerosol generating device (100) during smoking.

The filter load (32) may include a first segment (321) and a second segment (322). The first segment (321) may correspond to the first segment of the filter load (22) of Fig. 5. The second segment (322) may correspond to the third segment of the filter load (22) of Fig. 5.

The diameter and total length of the stick (30) may correspond to the diameter and total length of the stick (20) of Fig. 5. For example, the length of the shear plug (33) may be about 7 mm, the length of the tobacco rod (31) may be about 15 mm, the length of the first segment (321) may be about 12 mm, and the length of the second segment (322) may be about 14 mm, but is not limited thereto.

The stick (30) may be wrapped by at least one wrapper (35). The wrapper (35) may have at least one hole formed through which outside air is introduced or internal gas is discharged. For example, the shear plug (33) may be wrapped by the first wrapper (351), the tobacco rod (31) may be wrapped by the second wrapper (352), the first segment (321) may be wrapped by the third wrapper (353), and the second segment (322) may be wrapped by the fourth wrapper (354). Then, the entire stick (30) may be repackaged by the fifth wrapper (355).

In addition, at least one perforation (36) may be formed in the fifth wrapper (355). For example, the perforation (36) may be formed in an area surrounding the tobacco rod (31), but is not limited thereto. For example, the perforation (36) may serve to transfer heat formed by the heater (210) illustrated in FIG. 3 to the interior of the tobacco rod (31).

In addition, the second segment (322) may include at least one capsule (34). Here, the capsule (34) may perform a function of generating a flavor. The capsule (34) may also perform a function of generating an aerosol. For example, the capsule (34) may be a structure in which a liquid including a flavor is wrapped with a film. The capsule (34) may have a spherical or cylindrical shape, but is not limited thereto.

The first wrapper (351) may be a general filter paper combined with a metal foil such as aluminum foil. For example, the overall thickness of the first wrapper (351) may be included in a range of 45 um to 55 um. For example, the overall thickness of the first wrapper (351) may be 50.3 um. In addition, the thickness of the metal foil of the first wrapper (351) may be included in a range of 6 um to 7 um. For example, the thickness of the metal foil of the first wrapper (351) may be 6.3 um. In addition, the basis weight of the first wrapper (351) may be included in a range of 50 g/m2 to 55 g/m2. For example, the basis weight of the first wrapper (351) may be 53 g/m2.

The second wrapper (352) and the third wrapper (353) can be made of general filter paper. For example, the second wrapper (352) and the third wrapper (353) can be porous paper or non-porous paper.

For example, the porosity of the second wrapper (352) may be 35000 CU, but is not limited thereto. In addition, the thickness of the second wrapper (352) may be included in a range of 70 um to 80 um. For example, the thickness of the second wrapper (352) may be 78 um. In addition, the basis weight of the second wrapper (352) may be included in a range of 20 g/m2 to 25 g/m2. For example, the basis weight of the second wrapper (352) may be 23.5 g/m2.

For example, the porosity of the third wrapper (353) may be 24000 CU, but is not limited thereto. In addition, the thickness of the third wrapper (353) may be included in a range of 60 um to 70 um. For example, the thickness of the third wrapper (353) may be 68 um. In addition, the basis weight of the third wrapper (353) may be included in a range of 20 g/m2 to 25 g/m2. For example, the basis weight of the third wrapper (353) may be 21 g/m2.

The fourth wrapper (354) may be made of PLA laminate. Here, the PLA laminate may mean three-ply paper including a paper layer, a PLA layer, and a paper layer. For example, the thickness of the fourth wrapper (354) may be included in a range of 100 um to 120 um. For example, the thickness of the fourth wrapper (354) may be 110 um. In addition, the basis weight of the fourth wrapper (354) may be included in a range of 80 g/m2 to 100 g/m2. For example, the basis weight of the fourth wrapper (354) may be 88 g/m2.

The fifth wrapper (355) may be made of sterilized paper (MFW). Here, the sterilized paper (MFW) may mean paper that is specially manufactured to have improved tensile strength, water resistance, smoothness, etc. compared to general paper. For example, the basis weight of the fifth wrapper (355) may be within a range of 57 g/m2 to 63 g/m2. For example, the basis weight of the fifth wrapper (355) may be 60 g/m2. In addition, the thickness of the fifth wrapper (355) may be within a range of 64 um to 70 um. For example, the thickness of the fifth wrapper (355) may be 67 um.

The fifth wrapper (355) may have a predetermined material added thereto. Here, an example of the predetermined material may be silicon, but is not limited thereto. For example, silicon has properties such as heat resistance that is less affected by temperature, oxidation resistance that does not oxidize, resistance to various chemicals, water repellency, or electrical insulation. However, even if it is not silicon, any material having the above-described properties may be applied (or coated) to the fifth wrapper (355) without limitation.

The shear plug (33) can be made of cellulose acetate. For example, the shear plug (33) can be made by adding a plasticizer (e.g., triacetin) to cellulose acetate tow. The mono denier of the filaments constituting the cellulose acetate tow can be included in a range of 1.0 to 10.0. For example, the mono denier of the filaments constituting the cellulose acetate tow can be included in a range of 4.0 to 6.0. For example, the mono denier of the filaments of the shear plug (33) can be 5.0. In addition, the cross section of the filaments constituting the shear plug (33) can be Y-shaped. The total denier of the shear plug (33) can be included in a range of 20,000 to 30,000. For example, the total denier of the shear plug (33) may be within a range of 25,000 to 30,000. For example, the total denier of the shear plug (33) may be 28,000.

Additionally, if necessary, the shear plug (33) may include at least one channel. The cross-sectional shape of the channel of the shear plug (330) may be manufactured in various ways.

The tobacco rod (31) may correspond to the tobacco rod (21) described above with reference to Fig. 5. Therefore, a detailed description of the tobacco rod (31) will be omitted below.

The first segment (321) can be made of cellulose acetate. For example, the first segment can be a tube-shaped structure including a hollow space therein. The first segment (321) can be made by adding a plasticizer (e.g., triacetin) to cellulose acetate tow. For example, the mono denier and total denier of the first segment (321) can be the same as the mono denier and total denier of the shear plug (33).

The second segment (322) may be made of cellulose acetate. The mono denier of the filaments constituting the second segment (322) may be included in a range of 1.0 to 10.0. For example, the mono denier of the filaments of the second segment (322) may be included in a range of 8.0 to 10.0. For example, the mono denier of the filaments of the second segment (322) may be 9.0. In addition, the cross section of the filaments of the second segment (322) may be Y-shaped. The total denier of the second segment (322) may be included in a range of 20,000 to 30,000. For example, the total denier of the second segment (322) may be 25,000.

FIGS. 7 to 11 are drawings for reference in explaining the configuration of an aerosol generating device according to one embodiment of the present disclosure.

Referring to FIG. 7, it may include a housing (101) having an insertion space (130) formed therein, a heater (110), a sensor (150), a battery (16), and/or a printed circuit board (700).

The insertion space (130) may be a space formed within the housing (101) that constitutes the exterior of the aerosol generating device (10). The insertion space (130) may have one end open to form an opening. The insertion space (130) may be exposed to the outside through the opening. The opening may be defined as one end of the insertion space (130).

The stick (20) can be inserted into the insertion space (130). The insertion space (130) can be formed in a shape corresponding to the shape of the stick (20). For example, when the cross-section of the stick (20) is formed in a cylindrical shape, the insertion space (130) can be formed in a cylindrical shape. A part of the stick (20) can be inserted into the insertion space (130). The remaining part of the stick (20) except for the part inserted into the insertion space (130) can be exposed to the outside.

The heater (110) may be placed adjacent to the insertion space (130). The heater (110) may heat the inside and/or the outside of the stick (20) using power supplied from the battery (16). The heater (110) may be composed of an electrically conductive heater and/or an induction heating heater.

The sensor (150) may be an inductive sensor. In the present embodiment, the sensor (150) is described as being an inductive sensor, but is not limited thereto.

The inductive sensor (150) may include at least one coil. The coil of the inductive sensor (150) may be arranged adjacent to the insertion space (130). For example, when a magnetic field changes around a coil through which current flows, the characteristics of the current flowing in the coil may change according to Faraday's law of electromagnetic induction. Here, the characteristics of the current flowing in the coil may include the frequency of the alternating current, the current value, the voltage value, the inductance value, the impedance value, etc.

The inductive sensor (150) can output a signal corresponding to the characteristics of the current flowing in the coil. For example, the inductive sensor (150) can output a signal corresponding to the inductance value of the coil. For example, when a stick (20) including a first wrapper (241) made of a metal material is inserted into the insertion space (230), a magnetic field can change around the coil due to the first wrapper (241). At this time, the inductance value of the coil can change in response to the change in the magnetic field due to the first wrapper (241).

Each component provided in the aerosol generating device (10) may be mounted on one side and/or the other side of the printed circuit board (700). The components mounted on the printed circuit board (700) may transmit or receive signals to each other through the wiring layer of the printed circuit board (700). The control unit (17) may be mounted on the printed circuit board (700). At least some of the components included in the power circuit that transmits power to the heater (110) may be mounted on the printed circuit board (700). At least some of the components included in the signal circuit that transmits a signal corresponding to the inductive sensor (150) may be mounted on the printed circuit board (700).

The printed circuit board (700) may be positioned adjacent to the battery (16). For example, the printed circuit board (700) may be positioned so that one side faces the battery (16). The printed circuit board (700) may be electrically connected to the battery (16).

The heater (110) can be electrically connected to a printed circuit board (700) through a first flexible printed circuit board (FPCB) (710) that constitutes a power circuit. Power stored in the battery (16) can be supplied to the heater (110) through the printed circuit board (700) and the first flexible circuit board (710).

The inductive sensor (150) can be electrically connected to the printed circuit board (700) through the second flexible circuit board (720) that constitutes the signal circuit. A signal output from the inductive sensor (150) can be transmitted to the control unit (17) mounted on the printed circuit board (700) through the second flexible circuit board (720).

Referring to FIGS. 8 to 10, the aerosol generating device (10) may include an upper body (810) and/or a lower body (820). The upper body (810) and/or the lower body (820) may constitute the outer shape of the aerosol generating device (10).

Hereinafter, the direction of the aerosol generator (10) can be defined based on the rectangular coordinate system. In the rectangular coordinate system, the x-axis direction can be defined as the left-right direction of the aerosol generator (10). At this time, with the origin as the reference, the direction toward +x can mean the right direction, and the direction toward -x can mean the left direction. The y-axis direction can be defined as the front-back direction of the aerosol generator (10). With the origin as the reference, the direction toward +y can mean the front direction, and the direction toward -y can mean the rear direction. The z-axis direction can be defined as the up-down direction of the aerosol generator (10). At this time, with the origin as the reference, the direction toward +z can mean the upward direction, and the direction toward -z can mean the downward direction.

The upper body (810) can accommodate various components necessary for generating an aerosol, such as a heater (110) and a sensor (150), inside. The upper body (810) can have an insertion port (811). The insertion port (811) can be formed by opening the upper side of the upper body (810). The insertion port (811) can be formed at a position corresponding to the insertion space (130). The insertion port (811) can be connected to one end or the upper end of the insertion space (130). The insertion space (130) can be formed in the upper body (810).

The upper body (810) may include a cover (813). The cover (813) may open and close the insertion space (130). The cover (813) may open and close an opening that exposes the insertion space (130) to the outside. The cover (813) may be installed adjacent to the opening of the insertion space (130).

The cover (813) can be installed movably. The cover (813) can be moved to open and close the insertion space (130). For example, the cover (813) can slide backward along the upper surface of the upper body (810) so that the insertion space (130) is opened. For example, the cover (813) can slide forward along the upper surface of the upper body (810) so that the insertion space (130) is closed. Meanwhile, however, the movement method of the cover (813) is not limited to the sliding movement method. For example, the cover (813) can open and close the insertion space (130) not only by a non-rotational method such as sliding movement, but also by a rotational method such as tilt or hinge.

The upper body (810) can be placed on the upper side of the lower body (820). The upper body (810) can be coupled to the lower body (820).

The lower body (820) can accommodate various components required for power supply or control, such as a battery (16), a control unit (17), and a printed circuit board (700). The lower body (820) can include a mount (821) that supports the upper body (810). The mount (821) can be configured to cover the upper side of the lower body (820).

The mount (821) may include a through hole (823). The first flexible printed circuit board (710) and the second flexible printed circuit board (720) may be arranged to pass through the through hole (823). The first flexible printed circuit board (710) and the second flexible printed circuit board (720) may be arranged adjacent to each other in the through hole (823). The first flexible printed circuit board (710) and the second flexible printed circuit board (720) may be electrically isolated from each other.

The first flexible printed circuit board (710) and/or the second flexible printed circuit board (720) disposed through the through hole (823) may be electrically connected to the printed circuit board (700) disposed inside the lower body (820). For example, the first flexible printed circuit board (710) and the second flexible printed circuit board (720) may be respectively coupled to a plurality of connectors mounted on the printed circuit board (700). One end of the first flexible printed circuit board (710) may be electrically connected to the heater (110). The other end of the first flexible printed circuit board (710) may be electrically connected to the first connector corresponding to the battery (16) among the components mounted on the printed circuit board (700). One end of the second flexible printed circuit board (720) can be electrically connected to the inductive sensor (150). The other end of the second flexible printed circuit board (720) can be electrically connected to a second connector corresponding to the control unit (17) of the components mounted on the printed circuit board (700).

Meanwhile, according to one embodiment, a sealing member may be arranged inside the upper body (810). The sealing member may be composed of an elastic material. For example, the sealing member may be manufactured from a material such as rubber or silicone. The sealing member may be arranged between components arranged inside the upper body (810). The sealing member may prevent liquid substances generated inside the upper body (810) during the process of generating an aerosol from leaking through gaps between components arranged inside the upper body (810). The sealing member may include a through hole. The first flexible printed circuit board (710) and the second flexible printed circuit board (720) may be arranged to penetrate the through hole (823). The first flexible printed circuit board (710) and the second flexible printed circuit board (720) may be arranged adjacent to each other in the through hole (823). The first flexible printed circuit board (710) and the second flexible printed circuit board (720) may be arranged to penetrate the through hole of the sealing member. The first flexible printed circuit board (710) and the second flexible printed circuit board (720) may be arranged adjacent to each other in the through hole of the sealing member.

Meanwhile, when the power circuit and the signal circuit are arranged adjacently, the spatial utilization related to the arrangement of the components arranged inside the aerosol generator (10) can be improved. In addition, when the power circuit and the signal circuit are arranged together in one through hole, the gap between the components arranged inside the aerosol generator (10) can be minimized, thereby minimizing the influence of liquid substances generated during the process of generating the aerosol. However, when the power circuit and the signal circuit are arranged adjacently, noise components may be generated in the signal circuit due to the power supply through the power circuit even though the two circuits are electrically disconnected. For example, when the power circuit and the signal circuit are arranged adjacently and AC power is supplied through the power circuit, noise components may be generated in the signal circuit due to electromagnetic waves radiated into the space from the power circuit or mutual inductance formed between the two circuits. At this time, the judgment of the control unit (17) based on the signal received through the signal circuit may become inaccurate due to the noise components generated in the signal circuit.

FIG. 11 and FIG. 12 are diagrams illustrating graphs of signals output from an inductive sensor (150) according to one embodiment of the present disclosure. In the present disclosure, it will be described as an example that the inductive sensor (150) includes a plurality of coils. For example, a first signal (1110, 1210) may correspond to a first coil corresponding to an upper side of an insertion space (130), and a second signal (1120, 1220) may correspond to a second coil corresponding to a lower side of an insertion space (130).

Referring to Fig. 11, while the power supply to the heater (110) is cut off, the control unit (17) can check the signal (1110, 1120) output from the inductive sensor (150). While the power supply to the heater (110) is cut off, noise components due to the power circuit may not be generated in the signal circuit.

In this case, at time t1 when the stick (20) is inserted into the insertion space (130) or at time t2 when the stick (20) is removed from the insertion space (130), the inductance value corresponding to the signal of the inductive sensor (150) may change by a predetermined value or more. In addition, while the state in which the stick (20) is inserted into the insertion space (130) or the state in which the stick (20) is removed from the insertion space (130) is maintained, the inductance value corresponding to the signal of the inductive sensor (150) may be maintained at a predetermined level.

Meanwhile, at time t3 when the amount of change in the inductance value corresponding to the signal of the inductive sensor (150) is less than a predetermined value, the control unit (17) can determine that the state of the insertion space (130) related to the stick (20) has not changed. In addition, at time t4 when the inductance value corresponding to the first signal (1110) has changed by a predetermined value or more and the inductance value corresponding to the second signal (1120) has changed by a value less than a predetermined value, the control unit (17) can also determine that the state of the insertion space (130) related to the stick (20) has not changed.

Meanwhile, referring to Fig. 12, while power is supplied to the heater (110), noise components may be generated in the signal circuit due to power supply through the power circuit. In this case, regardless of whether the actual stick (20) is inserted or removed, the inductance value corresponding to the signal of the inductive sensor (150) transmitted to the control unit (17) may be changed due to the noise components generated in the signal circuit.

Due to the change in the inductance value corresponding to the signal of the inductive sensor (150), even though the stick (20) is inserted into the insertion space (130), the control unit (17) can determine that the insertion and removal of the stick (20) are repeated in the insertion space (130). As a result, the start and stop of heating of the heater (110) can be repeated. For example, if the power of the aerosol generator (10) is set to be turned on/off in response to the insertion and removal of the stick (20), the power of the aerosol generator (10) can be repeatedly turned on/off.

Taking this into consideration, a filter for removing noise components may be placed in the power circuit that supplies power to the heater (110).

Referring to FIG. 13, the power circuit (1310) may include a switching element (1311), a low pass filter (1313), etc. The power circuit (1310) may further include a capacitor (C3), a diode element (D), etc., which are electrically connected to both ends of the heater (110).

The switching element (1311) can perform a switching operation under the control of the control unit (17). At this time, power can be supplied from the battery (16) to the heater (110) according to the operation of the switching element (1311). For example, the switching element (1311) can be a field effect transistor (FET). Meanwhile, in the present embodiment, the switching element (1311) is described as being implemented as a field effect transistor (FET), but is not limited thereto. For example, the switching element (1311) can be implemented as a bipolar junction transistor (BJT), etc.

The control unit (17) can control the operation of the switching element (1311). For example, the control unit (17) can control the operation of the switching element (1311) using the PWM method so that a current pulse having a predetermined frequency and duty ratio is supplied to the heater (110). At this time, the control unit (17) can control the power supplied to the heater (110) by adjusting the frequency and duty ratio of the current pulse.

The low-pass filter (1113) may include at least one inductor (L1, L2), at least one capacitor (C1, C2), etc.

At least one inductor (L1, L2) may be placed between the battery (16) and the heater (110). Among the power components flowing in the power circuit (1310), low-frequency components can pass through the inductors (L1, L2) relatively easily. On the other hand, among the power components flowing in the power circuit (1310), high-frequency components can pass through the inductors (L1, L2) relatively difficultly. Therefore, among the power components flowing in the power circuit (1310), low-frequency components lower than the cutoff frequency can be transmitted to the heater (110) or the battery (16).

At least one capacitor (C1, C2) may be placed between the heater (110) and the ground terminal. Among the power components flowing in the power circuit (1310), low-frequency components may have relatively difficulty passing through the capacitors (C1, C2). On the other hand, among the power components flowing in the power circuit (1310), high-frequency components may pass through the capacitors (C1, C2) relatively easily. Therefore, among the power components flowing in the power circuit (1310), high-frequency components higher than the cutoff frequency may be removed through the ground terminal.

The cutoff frequency of the low-pass filter (1113) may correspond to the frequency of the current flowing in the heater (110). The cutoff frequency of the low-pass filter (1113) may be higher than the frequency of the current flowing in the heater (110). For example, the cutoff frequency of the low-pass filter (1113) may be 120 kHz, which is higher than 60 kHz, which is the frequency of the current pulse flowing in the heater (110). For example, the cutoff frequency of the low-pass filter (1113) may be determined in response to harmonics of the current pulse flowing in the heater (110). The inductance value of at least one inductor (L1, L2) and/or the capacitance value of at least one capacitor (C1, C2) included in the low-pass filter (1113) may be determined according to the cutoff frequency of the low-pass filter (1113).

The signal circuit (1320) may be electrically connected to the sensor (150). The sensor (150) may be an inductive sensor. The frequency of the alternating current flowing in the coil included in the inductive sensor may exceed the frequency of the current pulse flowing in the heater (110). For example, the frequency of the alternating current flowing in the coil may be 3 MHz, which is greater than the frequency of the current pulse flowing in the heater (110), which is 60 kHz.

The signal circuit (1320) may include a converter (1325) that converts a signal output from the sensor (150). The converter (1325) may be an analog-to-digital converter (ADC) that converts an analog signal output from the sensor (150) into a digital signal.

The control unit (17) can perform a judgment on a signal corresponding to the sensor (150). For example, the control unit (17) can determine that the stick (20) is inserted into the insertion space (130) when the inductance value corresponding to the signal of the inductive sensor (150) is greater than or equal to a predetermined value. For example, the control unit (17) can determine that the stick (20) is inserted into the insertion space (130) when the amount of change in the inductance value corresponding to the signal of the inductive sensor (150) is greater than or equal to a predetermined amount of change.

As described above, according to at least one of the embodiments of the present disclosure, it is possible to prevent noise components from being generated in the signal circuit (1320) due to power supply through the power circuit (1310).

Additionally, according to at least one of the embodiments of the present disclosure, it is possible to accurately determine whether the stick (20) is inserted or removed from the insertion space (130).

Additionally, according to at least one embodiment of the present disclosure, an error in judgment regarding the insertion of a stick can be accurately determined based on various conditions corresponding to a plurality of sections in which power is supplied to the heater.

Referring to FIGS. 1 to 13, an aerosol generating device (10) according to one aspect of the present disclosure includes a housing (101) having an insertion space (130) formed therein; a heater (110) for heating a stick (20) inserted into the insertion space (130); at least one sensor (150) for outputting a signal corresponding to the insertion space (130); a power circuit (1310) electrically connected to the heater (110) and transmitting power to the heater (110); and a signal circuit (1320) electrically connected to the sensor (150) and transmitting a signal corresponding to the sensor (150), and the power circuit (1310) may include a low pass filter (1313).

Additionally, according to another aspect of the present disclosure, the cutoff frequency of the low-pass filter may exceed the frequency of the current flowing in the heater (110).

Additionally, according to another aspect of the present disclosure, the power circuit (1310) and the signal may be placed adjacently while being electrically isolated from each other.

In addition, according to another aspect of the present disclosure, the power circuit (1310) includes a first flexible printed circuit board (710) electrically connected to the heater (110), the signal circuit (1320) includes a second flexible printed circuit board (720) electrically connected to the sensor (150), and the first flexible printed circuit board (710) and the second flexible printed circuit board (720) can be disposed adjacent to each other while being electrically disconnected from each other.

In addition, according to another aspect of the present disclosure, the housing (101) may further include a battery (16) electrically connected to the power circuit (1310); and a control unit (17) electrically connected to the signal circuit (1320), wherein the housing (101) may include an upper body (810) in which the heater (110) and the sensor (150) are disposed; and a lower body (820) in which the battery (16) and the control unit (17) are disposed.

In addition, according to another aspect of the present disclosure, the lower body (820) includes a mount (821) arranged on one side of the lower body (820) to support the upper body (810), the mount (821) includes a through hole (823), and the power circuit (1310) and the signal circuit (1320) can be arranged to pass through the through hole (823).

In addition, according to another aspect of the present disclosure, the power circuit (1310) may further include a battery (16) electrically connected to the power circuit (1310), and the low-pass filter (1313) may include at least one inductor (L1, L2) disposed between the battery (16) and the heater (110); and at least one capacitor (C1, C2) disposed between the heater (110) and a ground terminal.

In addition, according to another aspect of the present disclosure, the device further includes a control unit (17) electrically connected to the signal circuit (1320), and the control unit (17) determines whether the stick (20) is inserted based on a signal corresponding to the sensor (150) received through the signal circuit (1320), and controls power to be supplied to the heater (110) based on the insertion of the stick (20).

Any of the embodiments or other embodiments of the present disclosure described above are not mutually exclusive or distinct. Any of the embodiments or other embodiments of the present disclosure described above may have their respective components or functions combined or used together.

For example, it means that a configuration A described in a particular embodiment and/or drawing can be combined with a configuration B described in another embodiment and/or drawing. That is, even if a combination between configurations is not directly described, it means that a combination is possible, except in cases where a combination is described as impossible.

The above detailed description should not be construed as restrictive in all respects but should be considered as illustrative. The scope of the invention should be determined by a reasonable interpretation of the appended claims, and all changes coming within the equivalent scope of the invention are intended to be embraced within the scope of the invention.

Claims (8)

Upper body with formed insertion space;
A lower body supporting the upper body;
A mount disposed on one side of the lower body so as to be in contact with the upper body and including a first through hole;
A sealing member disposed inside the upper body and including a second through hole;
A heater disposed on the upper body and heating a stick inserted into the insertion space;
At least one sensor arranged in the upper body and outputting a signal corresponding to the insertion space;
A battery placed in the lower body;
A control unit arranged in the above lower body;
A power circuit including a first flexible printed circuit board electrically connected to the heater and the battery; and
A signal circuit including a second flexible circuit board electrically connected to the sensor and the control unit,
The first flexible circuit board and the second flexible circuit board are electrically disconnected from each other and are placed adjacent to each other through the first through hole and the second through hole.
The above power circuit includes a low pass filter,
The first frequency of the current flowing in the power circuit is less than the second frequency of the current flowing in the signal circuit,
An aerosol generating device, characterized in that the cutoff frequency of the low-pass filter exceeds the first frequency. delete delete delete delete delete In the first paragraph,
The above low pass filter is,
At least one inductor disposed between the battery and the heater; and
An aerosol generating device characterized by comprising at least one capacitor disposed between the heater and the ground terminal. In the first paragraph,
The above control unit,
Based on the signal corresponding to the sensor received through the signal circuit, it is determined whether the stick is inserted,
An aerosol generating device characterized in that power is supplied to the heater through the power circuit based on the insertion of the stick.

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