WO2019082282A1 - エアロゾル生成装置 - Google Patents
エアロゾル生成装置Info
- Publication number
- WO2019082282A1 WO2019082282A1 PCT/JP2017/038394 JP2017038394W WO2019082282A1 WO 2019082282 A1 WO2019082282 A1 WO 2019082282A1 JP 2017038394 W JP2017038394 W JP 2017038394W WO 2019082282 A1 WO2019082282 A1 WO 2019082282A1
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- WO
- WIPO (PCT)
- Prior art keywords
- value
- aerosol
- load
- source
- resistor
- Prior art date
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Classifications
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- A—HUMAN NECESSITIES
- A24—TOBACCO; CIGARS; CIGARETTES; SIMULATED SMOKING DEVICES; SMOKERS' REQUISITES
- A24F—SMOKERS' REQUISITES; MATCH BOXES; SIMULATED SMOKING DEVICES
- A24F40/00—Electrically operated smoking devices; Component parts thereof; Manufacture thereof; Maintenance or testing thereof; Charging means specially adapted therefor
- A24F40/50—Control or monitoring
-
- A—HUMAN NECESSITIES
- A24—TOBACCO; CIGARS; CIGARETTES; SIMULATED SMOKING DEVICES; SMOKERS' REQUISITES
- A24F—SMOKERS' REQUISITES; MATCH BOXES; SIMULATED SMOKING DEVICES
- A24F40/00—Electrically operated smoking devices; Component parts thereof; Manufacture thereof; Maintenance or testing thereof; Charging means specially adapted therefor
- A24F40/50—Control or monitoring
- A24F40/57—Temperature control
-
- A—HUMAN NECESSITIES
- A24—TOBACCO; CIGARS; CIGARETTES; SIMULATED SMOKING DEVICES; SMOKERS' REQUISITES
- A24F—SMOKERS' REQUISITES; MATCH BOXES; SIMULATED SMOKING DEVICES
- A24F40/00—Electrically operated smoking devices; Component parts thereof; Manufacture thereof; Maintenance or testing thereof; Charging means specially adapted therefor
- A24F40/50—Control or monitoring
- A24F40/51—Arrangement of sensors
-
- A—HUMAN NECESSITIES
- A24—TOBACCO; CIGARS; CIGARETTES; SIMULATED SMOKING DEVICES; SMOKERS' REQUISITES
- A24F—SMOKERS' REQUISITES; MATCH BOXES; SIMULATED SMOKING DEVICES
- A24F40/00—Electrically operated smoking devices; Component parts thereof; Manufacture thereof; Maintenance or testing thereof; Charging means specially adapted therefor
- A24F40/50—Control or monitoring
- A24F40/53—Monitoring, e.g. fault detection
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61M—DEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
- A61M11/00—Sprayers or atomisers specially adapted for therapeutic purposes
- A61M11/04—Sprayers or atomisers specially adapted for therapeutic purposes operated by the vapour pressure of the liquid to be sprayed or atomised
- A61M11/041—Sprayers or atomisers specially adapted for therapeutic purposes operated by the vapour pressure of the liquid to be sprayed or atomised using heaters
- A61M11/042—Sprayers or atomisers specially adapted for therapeutic purposes operated by the vapour pressure of the liquid to be sprayed or atomised using heaters electrical
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61M—DEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
- A61M15/00—Inhalators
- A61M15/0065—Inhalators with dosage or measuring devices
- A61M15/0068—Indicating or counting the number of dispensed doses or of remaining doses
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61M—DEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
- A61M15/00—Inhalators
- A61M15/06—Inhaling appliances shaped like cigars, cigarettes or pipes
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J7/00—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
- H02J7/0063—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries with circuits adapted for supplying loads from the battery
-
- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05B—ELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
- H05B1/00—Details of electric heating devices
- H05B1/02—Automatic switching arrangements specially adapted to apparatus ; Control of heating devices
- H05B1/0227—Applications
- H05B1/023—Industrial applications
- H05B1/0244—Heating of fluids
-
- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05B—ELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
- H05B3/00—Ohmic-resistance heating
- H05B3/0019—Circuit arrangements
-
- A—HUMAN NECESSITIES
- A24—TOBACCO; CIGARS; CIGARETTES; SIMULATED SMOKING DEVICES; SMOKERS' REQUISITES
- A24F—SMOKERS' REQUISITES; MATCH BOXES; SIMULATED SMOKING DEVICES
- A24F40/00—Electrically operated smoking devices; Component parts thereof; Manufacture thereof; Maintenance or testing thereof; Charging means specially adapted therefor
- A24F40/10—Devices using liquid inhalable precursors
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61M—DEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
- A61M2205/00—General characteristics of the apparatus
- A61M2205/36—General characteristics of the apparatus related to heating or cooling
- A61M2205/3653—General characteristics of the apparatus related to heating or cooling by Joule effect, i.e. electric resistance
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61M—DEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
- A61M2205/00—General characteristics of the apparatus
- A61M2205/82—Internal energy supply devices
- A61M2205/8206—Internal energy supply devices battery-operated
- A61M2205/8212—Internal energy supply devices battery-operated with means or measures taken for minimising energy consumption
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J2207/00—Indexing scheme relating to details of circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
- H02J2207/20—Charging or discharging characterised by the power electronics converter
-
- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05B—ELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
- H05B2203/00—Aspects relating to Ohmic resistive heating covered by group H05B3/00
- H05B2203/021—Heaters specially adapted for heating liquids
Definitions
- the present invention relates to an aerosol generating device.
- a system has been proposed for generating inhalable vapors in an electronic vaporizer (e.g. U.S. Pat. No. 5,075,015).
- it is determined whether vaporization has occurred by monitoring the power to the coil corresponding to the heater that atomizes the aerosol source. If the power required to hold the coil at the adjusted temperature is reduced, it is said to indicate that there is not enough liquid in the fluid core to cause normal vaporization.
- the power or energy supplied to the heating element necessary to maintain the temperature of the heating element configured to heat the aerosol forming substrate that contains the aerosol source or corresponds to the aerosol source to the target temperature.
- An aerosol generating device has been proposed that detects the presence of an aerosol forming substrate in proximity to the heating element by comparing the with the threshold value (e.g., Patent Document 2).
- the power supply from the power supply to the heater is controlled such that the temperature of the heater is close to the boiling point of the aerosol source.
- the power supplied from the power source to the heater exhibits a constant value or a continuous change.
- the power supplied from the power supply to the heater is used. Indicates a constant value or a continuous change.
- the remaining amount of aerosol source is an important variable used for various control of the aerosol generation device. As an example, if the remaining amount of the aerosol source is not detected or can not be detected with sufficient accuracy, power supply from the power source to the heater is continued even though the aerosol source is already depleted, and the storage amount of the power source is wasted There is a risk of
- Patent Documents 3 and 4 As another method of detecting the remaining amount of the aerosol source, those using the temperature of the heater or the electric resistance value of the heater in Patent Documents 3 and 4 have been proposed. These are known to exhibit different values when the remaining amount of the aerosol source is sufficiently remaining and when it is depleted. However, it is difficult to accurately estimate the remaining amount of the aerosol source or the depletion thereof because each requires a dedicated sensor and a plurality of sensors.
- this invention aims at reducing the production
- the aerosol generating apparatus comprises a power source, and a load for generating aerosol by atomizing the aerosol source or heating the flavor source by supplying power from the power source, the resistance value changing according to the temperature, and the load
- a sensor that includes a resistor connected in series and outputs a measured value that is a current value flowing in the resistor or a voltage value applied to the resistor, controls power supply from the power supply to the load, and controls receiving the sensor output
- the resistor has a resistance value such that the response of the change in measurement value to the change in temperature of the resistance value falls within a predetermined range.
- the resistor has a resistance such that the response of the change in measurement to the change in temperature of the resistance falls within a predetermined range. For example, if the response is high, the detection performance by the sensor is improved, but an aerosol may be generated during measurement. Conversely, if the responsiveness is low, the generation of aerosol during measurement can be reduced, but the detection performance by the sensor also decreases. According to the configuration as described above, it is possible to set a balanced resistance value.
- the resistor is based on the first condition that the amount of aerosol generated by the load is equal to or less than the threshold and the change in the remaining amount of the aerosol source or the flavor source during the feeding period. It is also possible to have a resistance value that satisfies at least one of the second condition that the control unit becomes detectable. According to such a first condition, the generation of aerosol during measurement can be reduced, and according to the second condition, the accuracy of estimation of the remaining amount of the aerosol source by the aerosol generation device can be improved.
- the resistance value may be a value that satisfies the first condition. That is, the suction end may be provided at the end of the device and may be a suction end for releasing the aerosol, and the threshold may be a value at which the aerosol is not released from the suction end during the power feeding period. In other words, the threshold may be a value at which the heat generated at the load is not used for the heat of vaporization of the aerosol source or the flavor source. Also, the resistance value may be a value that does not generate an aerosol due to the heat generation at the load.
- the resistance value may be a value that satisfies the second condition. That is, the resistance value is a value that makes the control unit distinguish between the measured value at the start of energization to the load and the measured value when the remaining amount of the aerosol source or flavor source is equal to or less than the predetermined amount. It is also good.
- the resistance value is the absolute value of the difference between the measured value at the start of energization to the load and the measured value when the remaining amount of the aerosol source or flavor source is less than the predetermined amount, larger than the resolution of the control unit It may be a value that Further, the resistance value may be a value that makes the control unit distinguish between the measured value at the time of aerosol generation and the measured value when the remaining amount of the aerosol source or the flavor source is equal to or less than a predetermined amount. Also, the resistance value is a value that makes the absolute value of the difference between the measured value at the time of aerosol generation and the measured value when the remaining amount of the aerosol source or flavor source is less than a predetermined amount, larger than the resolution of the control unit It is also good.
- the resistance value may be a value that makes the measured value at the start of energization of the load different from the measured value at the time of aerosol generation to the extent that the control unit can distinguish. Further, the resistance value may be a value that makes the absolute value of the difference between the measured value at the start of energization to the load and the measured value at the time of aerosol generation larger than the resolution of the control unit.
- the resistance value is a value satisfying the first condition and the second condition.
- the resistance value may be a value closer to the maximum value satisfying the second condition among the minimum value satisfying the first condition and the maximum value satisfying the second condition. In this way, the resolution of residual amount detection can be improved as much as possible while reducing the generation of aerosol during measurement. That is, the resolution can be further improved as much as possible while simultaneously solving the two contradictory problems, so that the accuracy of the remaining amount of the aerosol source estimated by the aerosol generation device can be maximized.
- the power supply and the load may be electrically connected, and the power supply circuit may include a first feed path feeding power to the load without passing through the sensor and a second feed path feeding power to the load via the sensor. Good. Specifically, such a configuration can be adopted.
- the feeding circuit is connected to the power supply and includes a first node branching into a first feeding path and a second feeding path, and a second node in which the first feeding path and the second feeding path merge downstream of the first node.
- a node and a linear regulator provided between the first node and the sensor in the second feed path may be provided. In this way, the conversion loss due to the linear regulator is eliminated in the first feed path, and the accuracy of remaining amount detection can be improved in the second feed path.
- An aerosol generating apparatus has a power supply, and a load for changing the resistance according to the temperature, atomizing the aerosol source by supplying power from the power source, or heating the flavor source to generate aerosol.
- a sensor having a resistor connected in series with a load and outputting a measured value which is a current value flowing in the resistor or a voltage value applied to the resistor, and controls power supply from the power supply to the load;
- the controller receives the first condition under which the amount of aerosol generated by the load is equal to or less than the threshold during the power feeding period in which the resistor is fed from the power source, and the change in the remaining amount of the aerosol source or flavor source A resistance value satisfying at least one of the second condition that the control unit can detect based on the measurement value.
- the generation of aerosol during measurement can be reduced, and according to the second condition, the accuracy of estimation of the remaining amount of the aerosol source by the aerosol generation device can be improved.
- the aerosol generating apparatus has a power supply, a load whose resistance value changes according to the temperature, atomizes the aerosol source by supplying power from the power source, or generates an aerosol by heating the flavor source, And a sensor for outputting a measured value, which is a current value flowing through a resistance value or a voltage value applied to the resistor, and a resistor connected in series with the resistor, and 1 for adjusting the magnitude of the current supplied to the load
- the resistance of the resistor and the adjustment resistor is supplied from the power supply to the load, including the above-mentioned adjustment resistor, and the control unit that controls the power supply from the power supply to the load and receives the output of the sensor.
- the first condition that the amount of aerosol generated by the load is less than a predetermined threshold during the period, and the resistance of the resistor to the change in temperature of the resistance falls within the predetermined range. Have a resistance value
- the resistance of the resistor may be greater than the resistance of the load. For example, in this way, the generation of aerosol can be reduced during the measurement.
- the contents described in the means for solving the problems can be combined as much as possible without departing from the problems and technical ideas of the present invention.
- the contents of the means for solving the problems can be provided as a system including a device or a plurality of devices including a computer, a processor or an electrical circuit, a method executed by the device, or a program executed by the device.
- the program can also be executed on a network.
- a recording medium for holding the program may be provided.
- the generation of aerosol during measurement can be reduced, or the accuracy of estimation of the remaining amount of the aerosol source by the aerosol generation device can be improved.
- FIG. 1 is a perspective view showing an example of the appearance of an aerosol generating device.
- FIG. 2 is an exploded view showing an example of the aerosol generation device.
- FIG. 3 is a schematic view showing an example of the internal structure of the aerosol generation device.
- FIG. 4 is a circuit diagram showing an example of the circuit configuration of the aerosol generation device.
- FIG. 5 is a block diagram for explaining a process of estimating the amount of the aerosol source stored in the storage unit.
- FIG. 6 is a process flow diagram showing an example of the remaining amount estimation process.
- FIG. 7 is a timing chart showing an example of a state in which the user uses the aerosol generating device.
- FIG. 8 is a diagram for explaining an example of how to determine the length of the determination period.
- FIG. 1 is a perspective view showing an example of the appearance of an aerosol generating device.
- FIG. 2 is an exploded view showing an example of the aerosol generation device.
- FIG. 3 is a schematic view showing an example of the
- FIG. 9 is a diagram showing another example of the change of the current value flowing through the load.
- FIG. 10 is a process flow diagram showing an example of a process of setting a determination period.
- FIG. 11 is a diagram schematically illustrating energy consumed in the storage unit, the supply unit, and the load.
- FIG. 12 is a graph schematically showing the relationship between the energy consumed at load and the amount of aerosol generated.
- FIG. 13 is an example of a graph showing the relationship between the remaining amount of aerosol and the resistance value of the load.
- FIG. 14 is a view showing a modified example of the circuit provided in the aerosol generation device.
- FIG. 15 is a view showing another modified example of the circuit included in the aerosol generation device.
- FIG. 1 is a perspective view showing an example of the appearance of an aerosol generating device.
- FIG. 2 is an exploded view showing an example of the aerosol generation device.
- the aerosol generating device 1 is an electronic cigarette, a nebulizer, or the like, generates an aerosol in response to the user's suction, and provides the user with the aerosol.
- one continuous suction which a user performs shall be called a "puff.”
- the aerosol generating device 1 adds a component such as flavor to the generated aerosol and releases it into the oral cavity of the user.
- the aerosol generating device 1 includes a main body 2, an aerosol source holding unit 3, and an additive component holding unit 4.
- the main body 2 supplies power and controls the operation of the entire apparatus.
- the aerosol source holding unit 3 holds an aerosol source for atomization to generate an aerosol.
- the additive component holding unit 4 holds components such as flavor and nicotine.
- the user can hold the suction port, which is the end on the side of the additive component holding unit 4, and can suction the aerosol to which the flavor and the like are added.
- the aerosol generation device 1 is formed by the user or the like assembling the main body 2, the aerosol source holding unit 3 and the additive component holding unit 4.
- the main body 2, the aerosol source holding unit 3 and the additive component holding unit 4 each have a cylindrical shape or a truncated cone shape having a predetermined size, and the main body 2, the aerosol source holding unit 3, and the addition
- the components can be combined in the order of the component holding unit 4.
- the main body 2 and the aerosol source holder 3 are coupled, for example, by screwing an external thread portion and an internal thread portion provided at the respective end portions.
- the aerosol source holding unit 3 and the additive component holding unit 4 fit, for example, the additive component holding unit 4 tapered on the side surface into a cylindrical portion provided at one end of the aerosol source holding unit 3 Are combined by
- the aerosol source holding unit 3 and the additive component holding unit 4 may be disposable replacement parts.
- FIG. 3 is a schematic view showing an example of the inside of the aerosol generating device 1.
- the main body 2 includes a power supply 21, a control unit 22, and a suction sensor 23.
- the control unit 22 is electrically connected to the power supply 21 and the suction sensor 23, respectively.
- the power source 21 is a secondary battery or the like, and supplies power to the electric circuit included in the aerosol generation device 1.
- the control unit 22 is a processor such as a micro controller (MCU: Micro-Control Unit), and controls the operation of the electric circuit provided in the aerosol generation device 1.
- the suction sensor 23 is an air pressure sensor, a flow sensor, or the like.
- the suction sensor 23 When the user sucks from the suction port of the aerosol generating device 1, the suction sensor 23 outputs a value corresponding to the negative pressure and the flow rate of gas generated inside the aerosol generating device 1. That is, the control unit 22 can detect suction on the basis of the output value of the suction sensor 23.
- the aerosol source holding unit 3 of the aerosol generation device 1 includes a storage unit 31, a supply unit 32, a load 33, and a remaining amount sensor 34.
- the storage unit 31 is a container for storing a liquid aerosol source that is atomized by heating.
- the aerosol source is, for example, a polyol-based material such as glycerin or propylene glycol.
- the aerosol source may be a mixed liquid (also referred to as a “flavor source”) further containing a nicotine liquid, water, a flavor and the like. It is assumed that such an aerosol source is stored in advance in the storage section 31.
- the aerosol source may be a solid that does not require the reservoir 31.
- the feed section 32 includes a wick formed by twisting a fiber material such as glass fiber, for example.
- the supply unit 32 is connected to the storage unit 31. Further, the supply unit 32 is connected to the load 33 or at least a part of the supply unit 32 is disposed in the vicinity of the load 33.
- the aerosol source penetrates the wick by capillary action, and the heating by the load 33 moves the aerosol source to a portion where it can be atomized. In other words, the supply unit 32 sucks up the aerosol source from the storage unit 31 and carries it to the load 33 or in the vicinity thereof. In addition, it may replace with glass fiber and may use porous ceramic for a wick.
- the load 33 is, for example, a coiled heater, and generates heat when a current flows. Also, for example, the load 33 has a positive temperature coefficient (PTC) characteristic, and its resistance value is approximately in direct proportion to the heat generation temperature. The load 33 does not have to have positive temperature coefficient characteristics, as long as there is a correlation between the resistance value and the heat generation temperature. As an example, the load 33 may have a negative temperature coefficient (NTC) characteristic.
- NTC negative temperature coefficient
- the load 33 may be wound around the outside of the wick, or conversely, the wick may cover the periphery of the load 33. Power supply to the load 33 is controlled by the control unit 22.
- the control unit 22 supplies power to the load 33 to generate an aerosol.
- the aerosol source in a sufficient amount is also supplied to the load 33, and the heat generated in the load 33 is transported to the aerosol source. Since the heat generated at the load 33 is used to heat and vaporize the aerosol source, the temperature of the load 33 almost never exceeds the previously designed predetermined temperature.
- the supply amount of the aerosol source to the load 33 per hour decreases.
- the heat generated by the load 33 is not transported to the aerosol source.
- the load 33 is overheated. Also rise.
- the remaining amount sensor 34 outputs sensing data for estimating the remaining amount of the aerosol source stored in the storage unit 31 based on the temperature of the load 33.
- the remaining amount sensor 34 includes a resistor (shunt resistor) for current measurement connected in series with the load 33, and a measuring device connected in parallel with the resistor and measuring a voltage value of the resistor.
- the resistor is a predetermined constant value whose resistance value hardly changes with temperature. Thus, based on the known resistance value and the measured voltage value, the current value flowing through the resistor is determined.
- the Hall element may replace with the measuring device using the shunt resistance mentioned above, and may use the measuring device using a Hall element.
- the Hall element is provided in series with the load 33. That is, around the conductive wire connected in series with the load 33, a gap core provided with a Hall element is arranged. Then, the Hall element detects the magnetic field generated by the current flowing therethrough.
- the “current flowing through itself” is a current flowing through a conductor disposed at the center of the gap core and not in contact with the Hall element, and the current value is the same as the current flowing through the load 33 .
- the remaining amount sensor 34 outputs the current value flowing to the resistor.
- a value obtained by performing a predetermined operation on this may be used instead of the voltage value applied to both ends of the resistor, or the value of the current value or the voltage value itself.
- the measurement value that can be used instead of the current value flowing to these resistors is a value whose value changes according to the current value flowing to the resistor. That is, the remaining amount sensor 34 may output a measured value corresponding to the value of the current flowing through the resistor.
- using these measured values instead of the current value flowing to the resistor is included in the technical concept of the present invention.
- the additive-component holding unit 4 of the aerosol generation device 1 holds a cut tobacco leaf and a flavor component 41 such as menthol inside.
- the additive component holding unit 4 is provided with a vent in the suction port side and in a portion coupled to the aerosol source holding unit 3, and when the user sucks from the suction port, negative pressure is generated inside the additive component holding unit 4.
- the aerosol generated in the holding unit 3 is aspirated, and components such as nicotine and flavor are added to the aerosol in the additional component holding unit 4 and released into the oral cavity of the user.
- the internal configuration shown in FIG. 3 is an example.
- the aerosol source holder 3 may be in the form of a torus provided along the side of a cylinder and having a cavity along the center of the circular cross section.
- the supply unit 32 and the load 33 may be disposed in the central cavity.
- an output unit such as a light emitting diode (LED) or a vibrator may be further provided.
- LED light emitting diode
- FIG. 4 is a circuit diagram showing an example of a portion related to detection of the remaining amount of the aerosol source and control of power supply to the load in the circuit configuration in the aerosol generation device.
- the aerosol generation device 1 includes a power supply 21, a control unit 22, a voltage conversion unit 211, switches (switching elements) Q 1 and Q 2, a load 33, and a remaining amount sensor 34.
- a portion including the switches Q1 and Q2 and the voltage conversion unit 211, which connects the power supply 21 and the load 33, is also referred to as a "feed circuit" according to the present invention.
- the power supply 21 and the control unit 22 are provided in the main body 2 of FIGS.
- the aerosol source holding unit 3 of FIGS. Provided in Further, by connecting the main body 2 and the aerosol source holder 3, the internal components are electrically connected, and a circuit as shown in FIG. 4 is formed. For example, at least a part of the voltage conversion unit 211, the switches Q1 and Q2, and the remaining amount sensor 34 may be provided in the main body 2.
- the aerosol source holding unit 3 or the additive component holding unit 4 is configured as a disposable replacement part, the cost of the replacement part can be reduced as the number of components included in the disposable source replacement part decreases.
- the power supply 21 is electrically connected directly or indirectly to each component to supply power to the circuit.
- the control unit 22 is connected to the switches Q1 and Q2 and the remaining amount sensor 34. Further, the control unit 22 acquires the output value of the remaining amount sensor 34, calculates an estimated value of the aerosol source remaining in the storage unit 31, or based on the calculated estimated value, the output value of the suction sensor 23, etc. It controls the opening and closing of the switches Q1 and Q2.
- the switches Q1 and Q2 are semiconductor switches such as MOSFETs (Metal-Oxide-Semiconductor Field-Effect Transistors) or the like. Further, one end of the switch Q 1 is connected to the power supply 21, and the other end is connected to the load 33. Then, by closing the switch Q1, the load 33 can be supplied with power to generate an aerosol. For example, when detecting a suction operation by the user, the control unit 22 closes the switch Q1.
- route which passes switch Q1 and the load 33 shall also be called "aerosol production path
- one end of the switch Q2 is connected to the power supply 21 via the voltage conversion unit 211, and the other end is connected to the load 33 via the remaining amount sensor 34. Then, the output value of the remaining amount sensor 34 can be obtained by closing the switch Q2.
- the path that passes through the switch Q2, the remaining amount sensor 34, and the load 33 and the remaining amount sensor 34 outputs a predetermined measured value is the "remaining amount detection path" and the "second power feeding path" according to the present invention. I shall call.
- the remaining amount sensor 34 does not need to be connected to the switch Q2 and the load 33, and provided so as to be able to output a predetermined measured value between the switch Q2 and the load 33. I hope there is. In other words, the wire connecting the switch Q2 and the load 33 may pass through the Hall element.
- a second node 52 As described above, in the circuit illustrated in FIG. 4, the first node 51 that branches from the power supply 21 to the aerosol generation path and the remaining amount detection path, the aerosol generation path and the remaining amount detection path merge and are connected to the load 33. And a second node 52.
- the voltage conversion unit 211 can convert the voltage output from the power supply 21 and output the converted voltage to the load 33. Specifically, it is a voltage regulator such as an LDO (Low Drop-Out) regulator shown in FIG. 4 and outputs a constant voltage. One end of the voltage conversion unit 211 is connected to the power supply 21, and the other end is connected to the switch Q2.
- the voltage conversion unit 211 also includes a switch Q3, resistors R1 and R2, capacitors C1 and C2, a comparator Comp, and a constant voltage source that outputs a reference voltage V REF .
- the output voltage Vout is obtained by the following equation (1).
- V out R 2 / (R 1 + R 2 ) ⁇ V REF (1)
- the switch Q3 is a semiconductor switch or the like, and is opened and closed according to the output of the comparator Comp. Further, one end of the switch Q3 is connected to the power supply 21, and the output voltage is changed by the opening / closing duty ratio of the switch Q3.
- the output voltage of the switch Q3 is divided by the resistors R1 and R2 connected in series and applied to one input terminal of the comparator Comp. Further, the reference voltage V REF is applied to the other input terminal of the comparator Comp. Then, a signal indicating the comparison result of the reference voltage V REF and the output voltage of the switch Q3 is output.
- the output voltage of the switch Q3 can be made constant by receiving feedback from the comparator Comp as long as the voltage value is equal to or greater than the predetermined value.
- the comparator Comp and the switch Q3 are also referred to as a "voltage converter" according to the present invention.
- One end of the capacitor C1 is connected to the end on the power supply 21 side in the voltage conversion unit 211, and the other end is connected to the ground.
- the capacitor C1 stores power and protects the circuit from surge voltage.
- One end of the capacitor C2 is connected to the output terminal of the switch Q3 to smooth the output voltage.
- the voltage conversion unit 211 can supply a constant voltage even when the power supply voltage fluctuates to some extent.
- Remaining amount sensor 34 includes a shunt resistor 341 and a voltmeter 342.
- One end of the shunt resistor 341 is connected to the voltage conversion unit 211 via the switch Q2.
- the other end of the shunt resistor 341 is connected to the load 33. That is, the shunt resistor 341 is connected in series to the load 33.
- the voltmeter 342 is connected in parallel to the shunt resistor 341, and can measure the amount of voltage drop in the shunt resistor 341.
- the voltmeter 342 is also connected to the control unit 22, and outputs the measured voltage drop amount in the shunt resistor 341 to the control unit 22.
- FIG. 5 is a block diagram for explaining the process of estimating the amount of the aerosol source stored in the storage unit 31.
- voltage Vout which the voltage conversion part 211 outputs shall be a constant.
- the resistance value R shunt of the shunt resistor 341 is a known constant. Therefore, using the voltage V shunt across the shunt resistor 341, the current value I shunt flowing through the shunt resistor 341 can be obtained by the following equation (2).
- I shunt V shunt / R shunt (2)
- the current value I HTR flowing through the load 33 connected in series to the shunt resistor 341 is the same as I shunt .
- the shunt resistor 341 is connected in series to the load 33, and a value corresponding to the value of the current flowing through the load is measured.
- V out I shunt ⁇ (R shunt + R HTR ) (3)
- R HTR V out / I shunt -R shunt (4)
- the load 33 has a positive temperature coefficient (PTC) characteristic described above, the resistance value R HTR of the load 33 as shown in FIG. 5 is substantially proportional to the temperature T HTR load 33. Therefore, the temperature THTR of the load 33 can be calculated based on the resistance value RHTR of the load 33.
- PTC positive temperature coefficient
- information indicating the relationship between the resistance value RHTR of the load 33 and the temperature THTR is stored, for example, in a table in advance. Therefore, the temperature THTR of the load 33 can be estimated without using a dedicated temperature sensor. Even when the load 33 has a negative temperature coefficient characteristic (NTC), based on the resistance value R HTR and information indicating the relationship between the temperature T HTR, is possible to estimate the temperature T HTR load 33 it can.
- NTC negative temperature coefficient characteristic
- the load via the supply unit 32 33 the load via the supply unit 32 33
- the aerosol source continues to be supplied. Therefore, if the remaining amount of the aerosol source in the storage unit 31 is equal to or more than a predetermined amount, the temperature of the load 33 does not generally increase significantly beyond the boiling point of the aerosol source. However, when the remaining amount of the aerosol source in the storage unit 31 decreases, the amount of the aerosol source supplied to the load 33 via the supply unit 32 also decreases accordingly, and the temperature of the load 33 exceeds the boiling point of the aerosol source Will rise further.
- Such information indicating the relationship between the remaining amount of the aerosol source and the temperature of the load 33 is assumed to be known in advance by experiment or the like. Then, based on the information and the calculated temperature THTR of the load 33, the remaining amount Quantity of the aerosol source held by the storage unit 31 can be estimated. The remaining amount may be obtained as a ratio of the remaining amount to the capacity of the storage section 31.
- the temperature of the load 33 is a temperature using the threshold of the temperature of the load 33 corresponding to the threshold of the predetermined remaining amount. It can be determined that the aerosol source of the reservoir 31 is depleted when the threshold of Furthermore, since there is a correspondence also between the resistance value of the load 33 and the temperature, the aerosol of the storage section 31 when the resistance value of the load 33 exceeds the threshold value of the resistance value corresponding to the above-described temperature threshold. It can also be judged that the source has been exhausted.
- the threshold value of the current value corresponding to the threshold value of the above-described resistance value is also uniquely determined.
- the current value I shunt flowing through the shunt resistor 341 is the same as the current value I HTR flowing through the load 33. Therefore, when the current value I HTR flowing through the load 33 indicates a value less than a predetermined current value threshold value, it can be determined that the aerosol source of the reservoir 31 has been depleted.
- a measured value such as a current value to be supplied to the load 33, for example, a target value or target range in a state where the aerosol source sufficiently remains is determined, and the measured value belongs to a predetermined range including the target value or target range Therefore, it can be determined whether the remaining amount of the aerosol source is sufficient.
- the predetermined range can be determined, for example, using the above-described threshold value.
- the resistance value R shunt of the load 33 can be calculated using one measurement value of the value I shunt of the current flowing through the shunt resistor 341.
- the current value I shunt of the shunt resistor 341 can be determined by measuring the voltage V shunt across the shunt resistor 341, as shown in equation (2).
- measurement values output from the sensor include various errors such as an offset error, a gain error, a hysteresis error, and a linearity error.
- the voltage conversion unit 211 that outputs a constant voltage, it is possible to estimate whether the remaining amount Quantity of the aerosol source held by the storage unit 31 or the aerosol source of the storage unit 31 has been depleted.
- the variables to be assigned measurement values are one. Therefore, for example, the accuracy of the resistance value R shunt of the calculated load 33 is improved as compared to a method of calculating the resistance value or the like of the load by substituting the output values of different sensors into a plurality of variables. As a result, the remaining amount of the aerosol source estimated based on the resistance value R shunt of the load 33 also improves the accuracy.
- FIG. 6 is a process flow diagram showing an example of the remaining amount estimation process.
- FIG. 7 is a timing chart showing an example of a state in which the user uses the aerosol generating device.
- the direction of the arrow indicates the passage of time t (s)
- the graphs indicate the opening and closing of the switches Q1 and Q2, the value I HTR of the current flowing through the load 33, the calculated temperature T HTR of the load 33, and the aerosol It shows the change of the remaining quantity Quantity of the source.
- the thresholds Thre1 and Thre2 are predetermined thresholds for detecting the depletion of the aerosol source.
- the aerosol generation device 1 executes estimation of the remaining amount when the user uses the aerosol generation device 1, and performs predetermined processing when a decrease in the aerosol source is detected.
- the control unit 22 of the aerosol generation device 1 determines whether the user has performed the suction operation based on the output of the suction sensor 23 (FIG. 6: S1). In this step, when the control unit 22 detects the generation of negative pressure, a change in flow rate, or the like based on the output of the suction sensor 23, it is determined that the suction of the user is detected. When the suction is not detected (S1: No), the process of S1 is repeated. The suction of the user may be detected by comparing the change in the negative pressure or the flow rate with a non-zero threshold value.
- the control unit 22 performs pulse width control (PWM, Pulse Width Modulation) on the switch Q1 (FIG. 6: S2). For example, it is assumed that suction is detected at time t1 in FIG. After time t1, the control unit 22 opens and closes the switch Q1 at a predetermined cycle. Further, with the opening and closing of the switch Q1, a current flows through the load 33, and the temperature THTR of the load 33 rises to about the boiling point of the aerosol source. Also, the aerosol source is heated by the temperature of the load 33 and evaporates, and the remaining quantity Quantity of the aerosol source decreases.
- PFM pulse frequency control
- control unit 22 determines whether the user has finished the suction operation based on the output of the suction sensor 23 (FIG. 6: S3). In this step, the control unit 22 determines that the user has finished suction when generation of a negative pressure, a change in flow rate, or the like is not detected based on the output of the suction sensor 23. If the suction has not ended (S2: No), the control unit 22 repeats the process of S2. The end of suction by the user may be detected by comparing the change in negative pressure or flow rate with a non-zero threshold. Alternatively, when a predetermined time has elapsed since the user's suction was detected in step S1, the process may proceed to step S4, regardless of the determination in step S3.
- the control unit 22 stops the PWM control of the switch Q1 (FIG. 6: S4).
- the switch Q1 is in the open state (OFF), and the power supply to the load 33 is stopped.
- the aerosol source is supplied to the load 33 from the storage unit 31 via the supply unit 32, and the temperature THTR of the load 33 gradually decreases due to heat radiation. Then, the evaporation of the aerosol source is stopped by the decrease of the temperature THTR of the load 33, and the decrease of the remaining quantity Quantity is also stopped.
- the control unit 22 continuously closes the switch Q2 for a predetermined period (FIG. 6: S5).
- a current flows in the remaining amount detection path shown in FIG. 4 in S5 to S10 surrounded by the dotted rounded rectangle in FIG.
- the switch Q2 is in the closed state (ON).
- a shunt resistor 341 is connected in series with the load 33. Therefore, since the shunt resistance 341 is added, the resistance value on the remaining amount detection path is larger than that on the aerosol generation path, and the current value I HTR flowing through the load 33 is lower.
- the control unit 22 obtains a measured value from the remaining amount sensor 34, and detects a current value flowing through the shunt resistor 341 (FIG. 6: S6).
- the current value I shunt of the shunt resistor 341 is calculated by the above-described equation (2).
- the current value I shunt of the shunt resistor 341 is the same as the current value I HTR flowing through the load 33.
- the control unit 22 determines whether the value of the current flowing through the load 33 indicates a value smaller than a predetermined current threshold (FIG. 6: S7). That is, the control unit 22 determines whether the measured value belongs to a predetermined range including the target value or the target range.
- the threshold value of the current (FIG. 7: Thre1) is a value corresponding to the predetermined threshold value of the remaining amount of the aerosol source (FIG. 7: Thre2) which should be judged that the aerosol source of the reservoir 31 has been depleted. is there. That is, when the current value I HTR flowing through the load 33 indicates a value smaller than the threshold Thre1, it can be determined that the remaining amount of the aerosol source has become a value smaller than the threshold Thre2.
- the control unit 22 detects depletion of the aerosol source and performs predetermined processing (FIG. 6: S8). If the voltage value measured in S6 and the current value obtained based on this are smaller than the predetermined threshold value, the remaining amount of the aerosol source is small, so the voltage value measured in S6 and the value obtained based thereon In this step, control is performed so that the current value to be
- the control unit 22 stops the operation of the aerosol generation device 1 by, for example, stopping the operation of the switch Q1 or the switch Q2 or cutting off the power supply to the load 33 using a power fuse (not shown). You may
- the current value I HTR is larger than the threshold value Thre1.
- the control unit 22 opens the switch Q2 (FIG. 6: S9).
- the switch Q2 is turned off since the predetermined period has elapsed and the current value I HTR is equal to or greater than the threshold value Thre1.
- the predetermined period for closing switch Q2 (corresponding to time t3 to t4 in FIG. 7) is shorter than the period for closing switch Q1 in S2 to S4 (corresponding to time t1 to t2 in FIG. 7).
- the switching duty ratio is adjusted in the opening / closing (S2) of the switch Q1 when suction is detected (S1: Yes)
- the current value (measured value) calculated in S6 is controlled to converge to the target value or target range.
- the measured value is better than the control of the feed circuit for causing the measured value to converge to the target value or the target range (also referred to as “first control mode” according to the present invention).
- the amount of current flowing to the load 33 is reduced (also referred to as the “second control mode” according to the present invention) when the amount of current flowing to the load 33 does not belong to the predetermined range To be controlled.
- the suction operation of the user is detected (FIG. 6: S1: Yes), and PWM control of the switch Q1 is started. Further, at time t6 in FIG. 7, it is determined that the user's suction operation is completed (FIG. 6: S3: Yes), and the PWM control of the switch Q1 is stopped. Then, at time t7 in FIG. 7, the switch Q2 is turned on (FIG. 6: S5), and the current value of the shunt resistor is calculated (FIG. 6: S6). Thereafter, as shown at time t7 after 7, the remaining amount of the aerosol source Quantity is less than the threshold thre2, the temperature T HTR load 33 is rising.
- the control unit 22 detects that the current value I HTR indicates a value smaller than the threshold Thre2 (FIG. 6: S7: Yes).
- the control unit 22 prevents the switch Q1 from being opened or closed even if the user's suction is detected after time t8, for example.
- the switch Q2 is turned off (FIG. 6: S9).
- the control unit 22 may turn off the switch Q2 at time t8 when the current value I HTR indicates a value smaller than the threshold value Thre2.
- an error mixed in a variable used for control is reduced in estimating the remaining amount of the aerosol source or its depletion, for example, the aerosol source
- the accuracy of control can be improved according to the remaining amount of
- the control unit 22 continuously turns on the switch Q2 for a predetermined period to obtain the measurement value of the remaining amount sensor 34.
- a period during which the switch Q2 is closed is referred to as a "power supply sequence" for supplying power to the remaining amount sensor 34 and the load 33.
- a “determination period” for determining the remaining amount may be used. The determination period is, for example, included in the power supply sequence on the time axis, and its length is variable.
- FIG. 8 is a diagram for explaining an example of how to determine the length of the determination period.
- the horizontal axis indicates the passage of time t
- the vertical axis indicates the current value I HTR flowing through the load 33.
- the current value I HTR accompanying the opening and closing of the switch Q1 is omitted, and only the current value I HTR flowing through the load 33 is shown in the feeding sequence in which the switch Q2 is closed.
- Period p1 of FIG. 8 is a power feeding sequence at a normal time, and the current value I HTR shown on the left is a schematic profile when the remaining amount of the aerosol source is sufficient.
- the determination period is assumed to be the same as the feeding sequence (p1).
- the temperature T HTR load 33 due to the energization is increased, the increase in the resistance value R HTR resistance load 33 of the load 33 due to this, although the current value I HTR gradually decreases, less than a threshold Thre1 Does not indicate a value. In such a case, the determination period is not changed.
- the current value I HTR shown at the center represents an example in the case where the current value I HTR shows a value less than the threshold Thre1 in the determination period (p1).
- a period p2 from the start of the power supply sequence to the time when the current value I HTR indicates a value smaller than the threshold Thre1 is taken as the length of the determination period included in the subsequent power supply sequence. That is, the determination period in the subsequent feeding sequence is adjusted based on the time when the current value I HTR in the previous feeding sequence indicates a value smaller than the threshold value Thre1. In other words, the determination period is set shorter as the aerosol source is more likely to be depleted.
- the possibility of exhaustion of the aerosol source is the threshold (see the second aspect of the present invention. It may be determined that the threshold value is exceeded. In other words, it can be said that the determination period is shorter than the power supply sequence only when the possibility of depletion of the aerosol source is equal to or higher than the threshold.
- the current value I HTR shown on the right represents an example in the case where the current value I HTR indicates a value less than the threshold Thre1 in the determination period (p2). While the aerosol generation device 1 is in use, the amount of the aerosol source held in the reservoir 31 is decreasing. Therefore, when the aerosol source is depleted, it can be generally said that the period from the start of power feeding to the time when the current value I HTR exhibits a value less than the threshold Thre1 becomes shorter. In the example of FIG. 8, when the case in which the current value I HTR is less than the threshold Thre1 in the determination period changed as described above occurs continuously in excess of the predetermined number in the repeated determination period, It shall be judged that the aerosol source has been depleted (ie, abnormal). When the aerosol source is depleted, power supply to the remaining amount detection circuit may be stopped as shown in FIG.
- FIG. 9 is a diagram showing another example of the change of the current value flowing through the load. Changes in the left and center current values I HTR shown in FIG. 9 are the same as in FIG.
- the current value I HTR shown on the right of FIG. 9 is the same as the profile when the remaining amount of the aerosol source is sufficient, and the current value I HTR does not indicate a value less than the threshold Thre1 within the determination period (p2) .
- the supply of the aerosol source from the storage section 31 to the supply section 32 is performed by capillary action depending on the structure and the manner of suction by the user. Therefore, it is difficult to control this by the control unit 22 or the like.
- the aerosol from the vicinity of the load 33 is temporarily more than normal.
- the amount of source may be reduced.
- the current value I HTR may indicate a value less than the threshold Thre1 in the determination period.
- the current value I HTR does not show a value less than the threshold Thre1 within the determination period as shown on the right of FIG. Therefore, in the example of FIG. 9, since the case where the current value I HTR shows a value less than the threshold Thre1 in the determination period does not continuously exceed the predetermined number in the repeated determination period, the aerosol stored in the storage section 31 It is judged that the source is not depleted.
- the determination period as described above, it is possible to further improve the accuracy of the determination as to whether or not the aerosol source has been depleted. That is, by changing the determination period, the reference in the determination operation can be adjusted, and the accuracy of the determination can be improved.
- FIG. 10 is a process flow diagram showing an example of a process of setting a determination period.
- the control unit 22 executes the determination process of FIG. 10 instead of the processes of S5 to S9 in the remaining amount estimation process shown in FIG.
- control unit 22 of the aerosol generation device 1 turns on the switch Q2 (FIG. 10: S5). This step is the same as S5 of FIG.
- control unit 22 starts a timer and starts counting the elapsed time t (FIG. 10: S11).
- the control unit 22 determines whether the elapsed time t is equal to or longer than the determination period (FIG. 10: S12). If the elapsed time t is not longer than the determination period (S12: No), the control unit 22 counts the elapsed time (FIG. 10: S21). In this step, a difference ⁇ t in elapsed time from the timer activation or the previous processing of S21 is added to t.
- control unit 22 detects a current value I HTR flowing through the load 33 (FIG. 10: S6).
- the process of this step is the same as S6 of FIG.
- the control unit 22 determines whether the calculated current value I HTR is smaller than a predetermined threshold value Thre1 (FIG. 10: S7). This step is similar to S7 of FIG. If the current value I HTR is greater than or equal to the threshold value Thre1 (S7: No), the process returns to S12.
- the control unit 22 adds 1 to the counter for counting the number of determination periods in which the depletion is detected (FIG. 10: S22). ).
- the control unit 22 determines whether the counter exceeds a predetermined value (threshold) (S23). When it is determined that the counter has exceeded the predetermined value (S23: Yes), the control unit 22 determines that the depletion of the aerosol source is detected, and performs a predetermined process (FIG. 10: S8). This step is the same as S8 in FIG.
- the control unit 22 determines whether the power feeding sequence has ended (FIG. 10: S31). If the power supply sequence has not elapsed (S31: No), the control unit 22 updates the elapsed time t and returns to the process of S31.
- the control unit 22 updates the determination period (FIG. 10: S32).
- an elapsed time t at which it is determined that the current value I HTR is smaller than the threshold Thre1 in S7 is set as a new determination period. That is, based on the time in which the measured value indicates a value less than the threshold value in the previous feeding sequence, the determination period in the subsequent feeding sequence is adjusted. In other words, the length of the determination period in the later feed sequence is adjusted based on the measured values in the previous feed sequence. It can also be said that the length of the determination period in the future feed sequence is adjusted based on the measured values in the current feed sequence.
- the control unit 22 determines whether the power supply sequence has ended (FIG. 10: S13). If the power supply sequence has not ended (S13: No), the control unit 22 continues the power supply until the power supply sequence ends.
- the determination period has elapsed, and the state in which the power supply sequence has not elapsed is after the period p2 has elapsed and before the period p1 has elapsed in the period shown on the right of FIG.
- control unit 22 sets the length of the determination period to be equal to the length of the power feeding sequence (FIG. 10: S14).
- control unit 22 resets the counter (FIG. 10: S15). That is, in the determination period defined along with the power supply period, the current value I HTR does not indicate a value less than the threshold value Thre1, so the counter for counting the number of consecutive determination periods in which the exhaustion is detected is reset. ing. Alternatively, without resetting the counter, when the number of determination periods in which the exhaustion is detected exceeds a predetermined threshold, it may be determined as abnormal.
- control unit 22 turns off the switch Q2 (FIG. 10: S9). This step is the same as S9 in FIG.
- variable determination period shown in FIGS. 8 and 9 can be realized.
- the control unit 22 causes the remaining amount detection path to function during a period in which the user does not suction the aerosol generation device 1, and estimates the remaining amount of the aerosol source.
- the aerosol is released from the mouth during a period when the user is not inhaling. That is, the amount of evaporation of the aerosol source by the load 33 during the period in which the switch Q2 is closed is preferably as small as possible.
- the control unit 22 can accurately detect the change of the remaining amount. That is, it is desirable that the measurement value of the remaining amount sensor 34 is increased in resolution as it largely changes according to the remaining amount of the aerosol source. Based on these viewpoints, the resistance value of the shunt resistor will be described below.
- FIG. 11 is a diagram schematically illustrating energy consumed in the storage unit, the supply unit, and the load.
- Q 1 is the calorific value of the wick of the supply unit 32
- Q 2 is the calorific value of the coil of the load 33
- Q 3 is the heat required for the temperature rise of the aerosol source of the liquid
- Q 4 is the state change of the aerosol source from liquid to gas heat required to
- Q 5 represents the heat generation of the air by radiation.
- the energy Q consumed is the sum of Q 1 to Q 5 .
- the heat capacity C (J / K) of the object is the product of the mass m (g) of the object and the specific heat c (J / g ⁇ K). Further, the heat quantity Q (J / K) for changing the temperature of the object by T (K) can be expressed as m ⁇ C ⁇ T. Therefore, the energy C consumed, when the temperature T HTR load 33 is lower than the boiling point T b of the aerosol source, can be represented schematically by the following equation (6).
- m 1 is the mass of the wick of the supply unit 32
- C 1 is the specific heat of the wick of the supply unit 32
- m 2 is the mass of the coil of the load 33
- C 2 is the specific heat of the coil of the load 33
- m 3 is the liquid aerosol
- the source mass C 3 is the specific heat of the liquid aerosol source
- T 0 is the initial value of the load 33 temperature.
- Q (m 1 C 1 + m 2 C 2 + m 3 C 3 ) (T HTR- T 0 ) (6)
- the energy C consumed, when the temperature T HTR load 33 is not less than the boiling point T b of the aerosol source, can be expressed by the following equation (7).
- m 4 is the mass of the evaporation source of the liquid aerosol source
- H 4 is the heat of evaporation of the liquid aerosol source.
- Q (m 1 C 1 + m 2 C 2 ) (T HTR- T 0 ) + m 3 C 3 (T b- T 0 ) + m 4 H 4 ... (7)
- the threshold E thre needs to satisfy the condition as shown in the following equation (8).
- E thre ⁇ (m 1 C 1 + m 2 C 2 + m 3 C 3 ) (T b- T 0 ) (8)
- FIG. 12 is a graph schematically showing the relationship between energy (electric energy) consumed by the load 33 and the amount of aerosol generated.
- the horizontal axis of FIG. 12 shows energy, and the vertical axis shows TPM (Total Particle Matter: amount of substance forming aerosol).
- TPM Total Particle Matter: amount of substance forming aerosol.
- the vertical axis in FIG. 12 may not necessarily be the amount of aerosol generated by the load 33.
- it may be the amount of aerosol generated from evaporation of the aerosol source.
- it may be the amount of aerosol emitted from the mouthpiece.
- the energy E HTR consumed by the load 33 can be expressed by the following equation (9).
- W HTR is the work rate of the load 33
- t Q2_ON is the time (s) during which the switch Q2 is on.
- the switch Q2 needs to be turned on only for a certain period of time to measure the current value of the shunt resistor.
- E HTR W HTR ⁇ t Q2 _ON (9)
- Equation (10) when the equation (9) is deformed using the current value I Q2 flowing through the remaining amount detection path, the resistance value R HTR (T HTR ) that changes according to the temperature T HTR of the load 33, and the measurement voltage V meas of the shunt resistance , Equation (10) below.
- resistance value R shunt of shunt resistance is a value which satisfies a formula (12), since an aerosol will not be generated in the amount estimating process, it is desirable.
- the resistance value of the shunt resistor is preferably as low as several tens of milliohms.
- the lower limit of the resistance value of the shunt resistance as described above is determined from the viewpoint of suppressing the generation of the aerosol.
- the lower limit value is preferably a value larger than the resistance value of the load 33, for example, about several ohms.
- the adjustment resistance may be added in series with the shunt resistor in order to increase the overall resistance without increasing the resistance value of the shunt resistor. In this case, the voltage across the adjusting resistor to be added may not be measured.
- FIG. 13 is an example of a graph showing the relationship between the remaining amount Quantity of aerosol and the resistance value of the load 33.
- the horizontal axis indicates the remaining amount of the aerosol source
- the vertical axis indicates the resistance value determined according to the temperature of the load 33.
- R HTR T Depletion
- R HTR T RT
- the accuracy of estimation of the remaining amount of the aerosol source is improved by appropriately setting the measurement range of the voltage and current, and hence the resistance value and temperature of the load 33 with respect to the resolution of the control unit 22 including the number of bits. .
- the difference ⁇ I Q2 _ON obtained by subtracting the current value I Q2 _ON (T Depletion ) from the current value I Q2 _ON (T RT ) can be expressed by the following equation (15).
- the resistance value R shunt of the shunt resistor is determined such that the difference ⁇ I Q2 _ON becomes larger than the desired threshold value ⁇ I thre .
- a difference ⁇ I Q2 _ON between the current value I Q2 _ON (T RT ) flowing through the load 33 at room temperature and the current value I Q2 _ON (T Depletion ) flowing through the load 33 when the aerosol source is depleted The resistance value R shunt was set so as to have a size that can be detected. Instead of this, for example, the difference between the current value flowing to the load 33 in the vicinity of the boiling point of the aerosol source and the current value flowing to the load 33 when the aerosol source is depleted is such that the control unit 22 can detect it.
- the resistance value R shunt may be set to In general, the smaller the temperature difference corresponding to the current difference that can be detected by the control unit 22, the better the estimation accuracy for the remaining amount of the aerosol source.
- the resolution Resolution of the control unit 22 can be expressed by the following equation (18).
- control unit 22 can detect the value represented by the following equation (20) and its integral multiple as the voltage difference over the range of 0 to ⁇ V Q 2 _ON .
- control unit 22 sets the value represented by the following equation (21) and the integer multiple thereof to the temperature of the load 33 in the case where the remaining amount of the aerosol source is exhausted from room temperature. It can be detected as temperature.
- the control unit 22 depletes the remaining amount of the aerosol source, which is the temperature at the time of non-control by the control unit 22 and at the start of control.
- the temperature of the case needs to be at least distinguishable. That is, it is necessary that the measurement value of the remaining amount sensor 34 at room temperature and the measured value of the remaining amount sensor 34 at the temperature when the remaining amount of the aerosol source is depleted have a significant difference that allows the control unit 22 to distinguish. is there.
- the resolution for the temperature of the load 33 of the control unit 22 needs to be equal to or less than the difference between the temperature when the remaining amount of the aerosol source is depleted and the room temperature.
- the control unit 22 can distinguish the boiling point of the aerosol source and the temperature when the remaining amount of the aerosol source is depleted. That is, the measurement value of the remaining amount sensor 34 at the boiling point of the aerosol source and the measurement value of the remaining amount sensor 34 at the temperature when the remaining amount of the aerosol source is depleted have a significant difference that allows the control unit 22 to distinguish. Is preferred. In other words, the resolution for the temperature of the load 33 of the control unit 22 is preferably equal to or less than the difference between the temperature when the remaining amount of the aerosol source is depleted and the boiling point of the aerosol source.
- the control unit 22 does not Preferably, the boiling point of the aerosol source can be distinguished from room temperature, which is the temperature at control and start of control. That is, it is preferable that the measurement value of the remaining amount sensor 34 at room temperature and the measurement value of the remaining amount sensor at the boiling point of the aerosol source have a significant difference that allows the control unit 22 to distinguish.
- the resolution for the temperature of the load 33 of the control unit 22 is preferably equal to or less than the difference between the boiling point of the aerosol source and the room temperature.
- the resolution for the temperature of the load 33 of the control unit 22 is 10 ° C. or less. More preferably, the temperature is 5 ° C. or less. Still more preferably, the temperature is 1 ° C. or less. Also, if it is intended to accurately distinguish between when the remaining amount of the aerosol source is depleted and when the remaining amount of the aerosol source is actually depleted, the resolution for the temperature of the load 33 of the control unit 22 is the aerosol source Preferably, it is a divisor of the difference between the temperature and room temperature when the remaining amount of H is depleted.
- the control unit 22 can detect the first condition in which the amount of aerosol generated by the load 33 becomes equal to or less than the predetermined threshold and the decrease in the remaining amount of the aerosol source based on the output value of the remaining amount sensor 34
- the resistance value of the shunt resistor may be determined so as to satisfy at least one of the second condition, and it is more preferable if the resistance value satisfies both conditions. Further, it may be a value closer to the maximum value satisfying the second condition among the minimum value satisfying the first condition and the maximum value satisfying the second condition. In this way, the resolution of residual amount detection can be improved as much as possible while reducing the generation of aerosol during measurement. As a result, since the remaining amount of the aerosol source can be estimated not only with high accuracy but also in a short period, the generation of aerosol during measurement can be further reduced.
- both the first condition and the second condition relate to the responsiveness of the change of the current value flowing to the load 33 which is the measured value of the remaining amount sensor 34 with respect to the change of the temperature of the load 33.
- the load 33 is dominant in the combined resistance of the shunt resistor 341 and the load 33 connected in series. That is, since the resistance value R shunt of the shunt resistor is a small value, the second condition is easily satisfied, but the first condition is hardly satisfied.
- the shunt resistance 341 is dominant in the combined resistance of the shunt resistor 341 and the load 33 connected in series. That is, since the resistance value R shunt of the shunt resistor is a large value, the first condition is easily satisfied, but the second condition is hardly satisfied.
- the responsiveness of the change in the value of the current flowing through the load 33 to the change in the temperature of the load 33 needs to be equal to or less than the predetermined upper limit.
- the responsiveness of the change in the value of the current flowing through the load 33 to the change in the temperature of the load 33 needs to be equal to or greater than a predetermined lower limit.
- the responsiveness of the change of the current value flowing to the load 33 to the change of the temperature of the load 33 needs to belong to the range defined by the predetermined upper limit and lower limit There is.
- FIG. 14 is a view showing a modified example of the circuit included in the aerosol generation device 1.
- the remaining amount detection path doubles as an aerosol generation path. That is, the voltage conversion unit 211, the switch Q2, the remaining amount sensor 34, and the load 33 are connected in series. Then, the generation of the aerosol and the estimation of the remaining amount are performed in one path. Even with such a configuration, the remaining amount can be estimated.
- FIG. 15 is a view showing another modification of the circuit included in the aerosol generation device 1.
- a voltage conversion unit 212 which is a switching regulator is provided instead of the linear regulator.
- the voltage conversion unit 212 is a boost converter, and includes an inductor L1, a diode D1, a switch Q4, and capacitors C1 and C2 that function as smoothing capacitors.
- the voltage conversion unit 212 is provided before branching from the power supply 21 to the aerosol generation path and the remaining amount detection path. Therefore, when the control unit 22 controls the opening and closing of the switch Q4 of the voltage conversion unit 212, voltages of different magnitudes can be output to the aerosol generation path and the remaining amount detection path.
- the switching regulator may be provided at the same position as the linear regulator in FIG.
- the power loss when functioning the aerosol generation path with less restrictions on the applied voltage may be controlled to be smaller than the power loss in the case of causing the detection path to function. This can suppress waste of the storage amount of the power supply 21.
- the control unit 22 controls the remaining amount detection path so that the current flowing through the load 33 is smaller than the aerosol generation path. This makes it possible to suppress the generation of the aerosol source in the load 33 while operating the remaining amount detection path to estimate the remaining amount of the aerosol source.
- the switching regulator may be operated in the “direct connection mode” (also referred to as “direct connection state”) in which the switching of the low side switch Q4 is stopped and kept on. . That is, the duty ratio of the switch Q4 may be 100%. Losses caused by switching the switching regulator include conduction loss and transition loss and switching loss associated with switching. However, by operating the switching regulator in the direct connection mode, the loss in the switching regulator can be made to be only the conduction loss, so that the utilization efficiency of the storage amount of the power supply 21 is increased. In addition, the switching regulator may be operated in the direct connection mode only in part while the aerosol generation path is functioning.
- the switching regulator when the storage amount of the power supply 21 is sufficient and the output voltage thereof is high, the switching regulator is operated in the direct connection mode. On the other hand, when the storage amount of the power supply 21 decreases and the output voltage thereof is low, switching of the switching regulator may be performed. Even with such a configuration, the remaining amount can be estimated, and the loss can be reduced more than when a linear regulator is used. Note that instead of the step-up type, a step-down or step-up / down converter may be used.
- the subject to which the aerosol generating device heats up may be a flavor source of liquid including nicotine and other additive materials.
- the user aspirates the generated aerosol without passing through the added component holding unit. Even when such a flavor source is used, the remaining amount can be accurately estimated by the above-described aerosol generating device.
- control unit 22 controls not to turn on the switches Q1 and Q2 simultaneously. That is, control is performed so that the aerosol generation path and the remaining amount detection path do not function at the same time. Furthermore, when switching the open / close state of the switches Q1 and Q2, a dead time may be provided in which both are turned off. In this way, current flow in the two paths can be suppressed. On the other hand, it is preferable that the dead time be short so as not to lower the temperature of the load 33 as much as possible in the dead time.
- the remaining amount estimation process is performed once for one puff performed by the user.
- one remaining amount estimation process may be alternately performed on a plurality of puffs instead of one.
- the remaining amount estimation process may be started after a predetermined number of puffs. That is, the frequency of energization may be smaller in the remaining amount detection path than in the aerosol generation path. In this way, excessive residual amount estimation processing is suppressed and executed only at appropriate timing, so that the utilization efficiency of the storage amount of the power supply 21 is improved.
- Aerosol generation device 2 Main body 21: Power supply 211: Power supply circuit 212: Power supply circuit 22: Control unit 23: Suction sensor 3: Aerosol source holding unit 31: Reservoir 32: Supply unit 33: Load 34: Remaining amount sensor 341 Shunt resistance 342: voltmeter 4: additive component holder 41: flavor component 51: first node 52: second node
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Abstract
Description
図1は、エアロゾル生成装置の外観の一例を示す斜視図である。図2は、エアロゾル生成装置の一例を示す分解図である。エアロゾル生成装置1は、電子シガレットやネブライザー等であり、使用者の吸引に応じてエアロゾルを生成し、使用者に提供する。なお、使用者が行う1回の連続した吸引を「パフ」と呼ぶものとする。また、本実施形態では、エアロゾル生成装置1は、生成したエアロゾルに対し、香味等の成分を添加して使用者の口腔内に放出する。
図3は、エアロゾル生成装置1の内部の一例を示す概略図である。本体2は、電源21と、制御部22と、吸引センサ23とを備える。制御部22は、電源21及び吸引センサ23とそれぞれ電気的に接続されている。電源21は、二次電池等であり、エアロゾル生成装置1が備える電気回路に電力を供給する。制御部22は、マイクロコントローラ(MCU:Micro-Control Unit)等のプロセッサであり、エアロゾル生成装置1が備える電気回路の動作を制御する。また、吸引センサ23は、気圧センサや流量センサ等である。使用者がエアロゾル生成装置1の吸口から吸引すると、吸引センサ23は、エアロゾル生成装置1の内部に生じる負圧や気体の流量に応じた値を出力する。すなわち、制御部22は、吸引センサ23の出力値に基づいて吸引を検知することができる。
図4は、エアロゾル生成装置内の回路構成のうち、エアロゾル源の残量の検知、及び負荷への給電の制御に関わる部分の一例を示す回路図である。エアロゾル生成装置1は、電源21と、制御部22と、電圧変換部211と、スイッチ(スイッチング素子)Q1及びQ2と、負荷33と、残量センサ34とを備える。電源21と負荷33とを接続する、スイッチQ1及びQ2並びに電圧変換部211を含む部分を、本発明に係る「給電回路」とも呼ぶ。例えば、電源21及び制御部22は、図1~3の本体2に設けられ、電圧変換部211、スイッチQ1及び22、負荷33並びに残量センサ34は、図1~3のエアロゾル源保持部3に設けられる。また、本体2とエアロゾル源保持部3とを結合することにより、内部の構成要素が電気的に接続され、図4に示すような回路が形成される。なお、例えば電圧変換部211やスイッチQ1及びQ2、残量センサ34の少なくとも一部を本体2に設けるようにしてもよい。エアロゾル源保持部3や添加成分保持部4を使い捨ての交換部品として構成した場合、これらに含まれる構成品が少なければ少ないほど、交換部品のコストを下げられる。
Vout=R2/(R1+R2)×VREF ・・・(1)
図5は、貯留部31に貯留されているエアロゾル源の量を推定する処理を説明するためのブロック図である。なお、電圧変換部211が出力する電圧Voutは、定数であるものとする。また、シャント抵抗341の抵抗値Rshuntは既知の定数である。よって、シャント抵抗341の両端電圧Vshuntを用いて、シャント抵抗341に流れる電流値Ishuntは以下の式(2)で求められる。
Ishunt=Vshunt/Rshunt ・・・(2)
Vout=Ishunt×(Rshunt+RHTR) ・・・(3)
RHTR=Vout/Ishunt-Rshunt ・・・(4)
上述の実施形態では、残量判定処理において、制御部22は、スイッチQ2を所定の期間、継続してオンにして、残量センサ34の測定値を取得していた。なお、スイッチQ2を閉じる期間を、残量センサ34及び負荷33へ給電するための「給電シーケンス」と呼ぶものとする。ここで、エアロゾル源の残量の判定を行うために、残量を判定するための「判定期間」を用いるようにしてもよい。判定期間は、例えば給電シーケンスに時間軸において内包され、その長さは可変とする。
図10は、判定期間の設定を行う処理の一例を示す処理フロー図である。本変形例では、制御部22は、図6に示した残量推定処理のうち、S5~S9の処理に代えて、図10の判定処理を実行する。
制御部22は、使用者がエアロゾル生成装置1を吸引していない期間に残量検出経路を機能させ、エアロゾル源の残量を推定する。しかしながら、使用者が吸引していない期間に吸口からエアロゾルが放出されることは好ましくない。すなわち、スイッチQ2を閉じている期間に負荷33がエアロゾル源を蒸発させる量は、少ないほど望ましい。
Q=(m1C1+m2C2+m3C3)(THTR-T0) ・・・(6)
Q=(m1C1+m2C2)(THTR-T0)+m3C3(Tb-T0)+m4H4
・・・(7)
Ethre<(m1C1+m2C2+m3C3)(Tb-T0) ・・・(8)
EHTR=WHTR×tQ2_ON ・・・(9)
図14は、エアロゾル生成装置1が備える回路の変形例を示す図である。図14の例では、残量検出経路がエアロゾル生成経路を兼ねている。すなわち、電圧変換部211、スイッチQ2、残量センサ34、負荷33が直列に接続されている。そして、エアロゾルの生成と、残量の推定とを1つの経路で行う。このような構成であっても、残量の推定を行うことができる。
図15は、エアロゾル生成装置1が備える回路の他の変形例を示す図である。図15の例では、リニアレギュレータに代えてスイッチングレギュレータである電圧変換部212を備える。一例として電圧変換部212は、昇圧型のコンバータであり、インダクタL1と、ダイオードD1と、スイッチQ4と、平滑コンデンサとして機能するキャパシタC1及びC2とを備える。電圧変換部212は、電源21からエアロゾル生成経路と残量検出経路とに分岐する前に設けられている。よって、制御部22が電圧変換部212のスイッチQ4の開閉を制御することにより、エアロゾル生成経路と残量検出経路とにそれぞれ異なる大きさの電圧を出力することができる。なお、リニアレギュレータに代えてスイッチングレギュレータを用いる場合でも、図14におけるリニアレギュレータと同様の位置にスイッチングレギュレータを設けてもよい。
エアロゾル生成装置が過熱する対象は、ニコチンやその他の添加材料を含む液体の香味源であってもよい。この場合、添加成分保持部を通過させずに、生成されたエアロゾルを使用者が吸引する。このような香味源を利用する場合も、上述のエアロゾル生成装置によれば残量を精度よく推定できる。
2 :本体
21 :電源
211:給電回路
212:給電回路
22 :制御部
23 :吸引センサ
3 :エアロゾル源保持部
31 :貯留部
32 :供給部
33 :負荷
34 :残量センサ
341:シャント抵抗
342:電圧計
4 :添加成分保持部
41 :香味成分
51 :第1ノード
52 :第2ノード
Claims (20)
- 電源と、
温度に応じて抵抗値が変化し、前記電源からの給電によりエアロゾル源を霧化又は香味源を加熱してエアロゾルを生成するための負荷と、
前記負荷と直列接続された抵抗器を備え、前記抵抗器に流れる電流値又は前記抵抗器に印加される電圧値である計測値を出力するセンサと、
前記電源から前記負荷への給電を制御し、前記センサの出力を受取る制御部と、を含み、
前記抵抗器は、前記抵抗値の温度の変化に対する前記計測値の変化の応答性が既定の範囲に属するような、抵抗値を有する
エアロゾル生成装置。 - 前記抵抗器は、
前記電源から前記抵抗器へ給電される給電期間において、前記負荷が生成するエアロゾル量が閾値以下となる第1条件と、
前記エアロゾル源又は前記香味源の残量の変化を、前記計測値に基づいて前記制御部が検知可能になるという第2条件と、
のうち少なくとも一方を満たす抵抗値を有する
請求項1に記載のエアロゾル生成装置。 - 前記抵抗値は、前記第1条件を満たす値である
請求項2に記載のエアロゾル生成装置。 - 自装置の端部に設けられ、前記エアロゾルを放出するための吸口端を含み、 前記閾値は、前記給電期間において、前記吸口端から前記エアロゾルが放出されない値である
請求項3に記載のエアロゾル生成装置。 - 前記閾値は、前記負荷へ給電されたエネルギーが前記エアロゾル源又は前記香味源の蒸発熱に用いられない値である
請求項3に記載のエアロゾル生成装置。 - 前記閾値は、前記負荷における発熱に由来して前記エアロゾルが生成されない値である
請求項3に記載のエアロゾル生成装置。 - 前記抵抗値は、前記第2条件を満たす値である
請求項2に記載のエアロゾル生成装置。 - 前記抵抗値は、前記負荷への通電開始時における前記計測値と、前記エアロゾル源又は前記香味源の残量が既定量以下の場合における前記計測値とを、前記制御部が区別できる程度に異ならせる値である
請求項7に記載のエアロゾル生成装置。 - 前記抵抗値は、前記負荷への通電開始時における前記計測値と、前記エアロゾル源又は前記香味源の残量が既定量以下の場合における前記計測値との差分の絶対値を、前記制御部の分解能より大きくさせる値である
請求項7に記載のエアロゾル生成装置。 - 前記抵抗値は、エアロゾル生成時における前記計測値と、前記エアロゾル源又は前記香味源の残量が既定量以下の場合における前記計測値とを、前記制御部が区別できる程度に異ならせる値である
請求項7に記載のエアロゾル生成装置。 - 前記抵抗値は、エアロゾル生成時における前記計測値と、前記エアロゾル源又は前記香味源の残量が既定量以下の場合における前記計測値との差分の絶対値を、前記制御部の分解能より大きくさせる値である
請求項7に記載のエアロゾル生成装置。 - 前記抵抗値は、前記負荷への通電開始時における前記計測値と、前記エアロゾル生成時における前記計測値とを、前記制御部が区別できる程度に異ならせる値である
請求項8から11のいずれか1項に記載のエアロゾル生成装置。 - 前記抵抗値は、前記負荷への通電開始時における前記計測値と、前記エアロゾル生成時における前記計測値との差分の絶対値を、前記制御部の分解能より大きくさせる値である
請求項8から11のいずれか1項に記載のエアロゾル生成装置。 - 前記抵抗値は、前記第1条件と前記第2条件を満たす値である
請求項2に記載のエアロゾル生成装置。 - 前記抵抗値は、前記第1条件を満たす最小値と前記第2条件を満たす最大値のうち、前記第2条件を満たす最大値により近い値である
請求項14に記載のエアロゾル生成装置。 - 前記電源と前記負荷とを電気的に接続し、前記センサを経由せずに前記負荷へ給電する第1給電路、及び前記センサを経由して前記負荷へ給電する第2給電路を備える給電回路を含む、
請求項1から15のいずれか1項に記載のエアロゾル生成装置。 - 前記給電回路は、
前記電源に接続され前記第1給電路と前記第2給電路とに分岐する第1ノードと、該第1ノードより下流で前記第1給電路と前記第2給電路とが合流する第2ノードと、
前記第2給電路において前記第1ノードと前記センサの間に設けられるリニア・レギュレータと、を備える
請求項16に記載のエアロゾル生成装置。 - 電源と、
温度に応じて抵抗値が変化し、前記電源からの給電によりエアロゾル源を霧化又は香味源を加熱してエアロゾルを生成するための負荷と、
前記負荷と直列接続された抵抗器を備え、前記抵抗器に流れる電流値又は前記抵抗器に印加される電圧値である計測値を出力するセンサと、
前記電源から前記負荷への給電を制御し、前記センサの出力を受取る制御部と、を含み、
前記抵抗器は、
前記電源から前記抵抗器へ給電される給電期間において、前記負荷が生成するエアロゾル量が閾値以下となる第1条件と、
前記エアロゾル源又は前記香味源の残量の変化を、前記計測値に基づいて前記制御部が検知可能になるという第2条件と、
のうち少なくとも一方を満たす抵抗値を有する
エアロゾル生成装置。 - 電源と、
温度に応じて抵抗値が変化し、前記電源からの給電によりエアロゾル源を霧化又は香味源を加熱してエアロゾルを生成する負荷と、
前記負荷と直列接続された抵抗器を備え、前記抵抗値を流れる電流値又は前記抵抗器に印加される電圧値である計測値を出力するセンサと、
前記負荷へ供給される電流の大きさを調整するための1以上の調整用抵抗器と、
前記電源から前記負荷への給電を制御し、且つ前記センサの出力を受取る制御部と、を含み、
前記抵抗器及び前記調整用抵抗器の抵抗値は、前記電源から前記負荷へ給電される給電期間において、前記負荷が生成するエアロゾル量が所定の閾値以下となる値であるという第1条件と、
前記抵抗器は、前記抵抗値の温度の変化に対する前記計測値の変化の応答性が既定の範囲に属するような、抵抗値を有する
エアロゾル生成装置。 - 前記抵抗器の抵抗値は、前記負荷の抵抗値より大きい
請求項1から19のいずれか1項に記載のエアロゾル生成装置。
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KR1020207008794A KR102499471B1 (ko) | 2017-10-24 | 2017-10-24 | 에어로졸 생성 장치 |
JP2019549724A JP6923666B2 (ja) | 2017-10-24 | 2017-10-24 | エアロゾル生成装置 |
CN201780096081.1A CN111246760B (zh) | 2017-10-24 | 2017-10-24 | 气溶胶生成装置 |
CA3077663A CA3077663C (en) | 2017-10-24 | 2017-10-24 | Aerosol generating apparatus |
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US16/850,014 US11632988B2 (en) | 2017-10-24 | 2020-04-16 | Aerosol generating apparatus |
JP2021078758A JP6936414B2 (ja) | 2017-10-24 | 2021-05-06 | エアロゾル生成装置 |
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EP3701819A4 (en) | 2021-11-10 |
KR20200044911A (ko) | 2020-04-29 |
US11632988B2 (en) | 2023-04-25 |
KR102499471B1 (ko) | 2023-02-13 |
EA202090952A1 (ru) | 2020-10-23 |
CA3077663C (en) | 2024-01-02 |
EP3701819A1 (en) | 2020-09-02 |
JP6936414B2 (ja) | 2021-09-15 |
US20200237013A1 (en) | 2020-07-30 |
JP2021129571A (ja) | 2021-09-09 |
CN111246760B (zh) | 2023-06-20 |
CN111246760A (zh) | 2020-06-05 |
CA3077663A1 (en) | 2019-05-02 |
JP6923666B2 (ja) | 2021-08-25 |
JPWO2019082282A1 (ja) | 2020-11-26 |
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