TW201642770A - Non-burning type fragrance inhaler - Google Patents

Abstract

This invention provides a non-burning type fragrance inhaler, comprising: a housing having a air flow path continuous from an inlet to an outlet; an atomization unit which atomizes aerosol without burning; a sensor which outputs a value changed according to an puff action of a user; and a control unit which controls a power output to the atomization unit according to an absolute value of a slope constituted of two or more response values derived from the value outputted from the sensor, in a manner that an aerosol amount, which is the amount of aerosol atomized by the atomization unit in one energization of the atomization unit, falls within a desired range.

Description

Non-combustible flavor applicator

The present invention relates to a non-combustion type flavor extractor having an atomizing portion that atomizes an aerosol source without accompanying combustion.

There has been known a non-combustion type flavor extractor for absorbing flavor without accompanying combustion. The non-combustion type flavor extracting device has an atomizing portion that atomizes the gas gel source without combustion (for example, Patent Documents 1 and 2).

[Previous Technical Literature] [Patent Document]

Patent Document 1: WO2013/116558

The first feature is to provide a non-combustion type flavor applicator, which is intended to be provided with: a housing having an air flow path from an inlet to an outlet; an atomizing portion to The gas gel source is atomized without combustion; the sensor outputs a value that varies according to a user's puff action; and the control unit is derived from the value outputted from the sensor The slope formed by the response value of 2 or more The absolute value is used to control the power output of the atomizing portion in such a manner that the amount of the gas gel falls within a desired range, wherein the amount of the gas gel is atomized by the aforesaid atomization of the atomizing portion The amount of gas gel atomized by the Ministry.

The second feature is the first feature, wherein the control unit controls the power output to the atomizing unit such that the amount of the gas gel falls within the desired range in accordance with the absolute value of the slope. The size.

The third feature is the second feature, wherein the control unit increases the power output of the atomizing unit as the absolute value of the slope increases.

According to a second aspect of the present invention, in the second aspect, the control unit is configured to use a predetermined size as a magnitude of a power supply output to the atomizing unit when the absolute value of the slope is within the predetermined range. When the absolute value of the slope is larger than the predetermined range, the magnitude of the power output to the atomizing portion is increased more than the predetermined size.

The fifth feature is the third feature or the fourth feature, and is intended to increase the rate of the power output of the atomizing unit by more than 1 and not more than 3.

The sixth feature is any one of the first to fifth features, wherein the control unit is configured to cause the gas gel amount to fall within the desired range, after the energization of the atomizing unit is started. When the supply duration is passed, the energization of the atomizing unit is stopped, and the supply duration is measured by the standard of the user during the pumping period. Below the upper limit of the suction period.

The seventh feature is the sixth feature, wherein the control unit is configured to shorten the supply duration while the absolute value of the slope is larger.

The eighth feature is the sixth feature, wherein the control unit uses the predetermined duration as the supply duration when the absolute value of the slope is within the predetermined range; the control unit is in the absolute value of the slope When the value is larger than the slope of the predetermined range, the aforementioned supply duration is shortened to be shorter than the aforementioned predetermined duration.

The ninth feature is in the seventh feature or the eighth feature, and is intended to mean that the shortening rate of the supply duration is 1/3 or more and less than 1.

The tenth feature is any one of the sixth to ninth features, wherein the power supply output of the atomizing unit is in a first pumping operation in which the absolute value of the slope is an absolute value of the first slope. The size is represented by PX ₁ , and the supply duration is represented by TX ₁ , and the atomization is performed in the second pumping operation in which the absolute value of the slope is greater than the absolute value of the second slope which is larger than the absolute value of the first slope. The size of the power supply output is indicated by PX ₂ , the supply duration is represented by TX ₂ , and the TX ₂ is calculated based on the formula of TX ₂ = (PX ₁ / PX ₂ ) × TX ₁ .

In any one of the first to tenth aspects, the control unit is characterized in that the control unit is a time period after the energization of the atomizing unit is started in the energization of the atomizing unit once. The longer the length, the smaller the size of the power output to the atomizing unit.

The twelfth feature is any one of the first feature to the eleventh feature In the feature, the control unit is configured to stop the atomizing unit when the supply duration is elapsed after the energization of the atomizing unit is started, so that the amount of the gas gel falls within the desired range. When the power is supplied, the control unit determines the supply duration based on the learning result of the required time of the user's pumping operation.

In the above feature, the power supply output (hereinafter, also referred to as the amount of supplied electric power) supplied to the atomizing unit is expressed by, for example, E = {(D ₂ × V) ² / R} × D ₁ × t. E is the amount of supplied electric power, and V is an output voltage value which is a value of a voltage applied from the power source for accumulating electric energy to the atomizing unit, and R is a resistance value of the atomizing unit. D ₁ is an energy ratio (for example, pulse width / 1 cycle (here, 1 cycle = pulse width + pulse interval)), and D ₂ is a correction coefficient of the output voltage value. The time elapsed after the T system starts energizing the atomizing unit. Further, in the case where the energy rate control is not performed, D ₁ can be regarded as 1 and in the case where the output voltage value is not corrected, D ₂ can be regarded as 1.

In the above feature, the magnitude of the power supply output supplied to the atomizing unit can be expressed, for example, by P = {(D ₂ × V) ² / R} × D ₁ . P is the magnitude of the power output supplied to the aforementioned atomizing section. The meaning of the other tokens is as described above. Further, in the case where the energy rate control is not performed, D ₁ can be regarded as 1 and in the case where the output voltage value is not corrected, D ₂ can be regarded as 1 as described above.

In the above aspect, the control unit starts energizing the atomizing unit when the start of the pumping operation is detected by the sensor, and detects the pumping action by the sensor. End At this time, the energization of the atomizing unit is stopped. However, the control unit stops energizing the atomizing unit even during the suction operation while the supply is being continued.

In the above feature, the PX ₁ and the TX ₁ are previously stored by the control unit, and the PX ₂ is determined based on the second slope absolute value.

In the above feature, the increase rate of the magnitude of the power output of the atomizing unit is an increase rate of the power output of the second pumping operation of the first pumping operation (PX ₂ /PX). _1).

In the above-described features, during the shortening of the supply lines with respect to shortening duration (TX ₂ / TX ₁₎ during the supply of the first suction operation of the pumping action of the second duration.

In the above feature, the response value derived from the value outputted by the sensor may be the output value outputted by the sensor, or may be a value obtained by a predetermined conversion of the output value. . For example, the output value may be a value (such as a voltage value or a current value) indicating an environment (for example, a voltage value or a current value) of a change in a user's pumping action, or may be a predetermined conversion from the value. The value obtained (for example, the flow rate value). For example, the response value may be a value (such as a voltage value or a current value) indicating an environment that changes according to a user's pumping action, or may be a value obtained by a predetermined conversion according to the value (for example, a flow rate value).

In the above-described feature, the non-combustion type flavor applicator is provided with a holding body for holding the gas gel source, and a gas gel source having an amount capable of suctioning over a plurality of suction operations is held on the holder.

10‧‧‧Power supply

20‧‧‧ sensor

21‧‧‧ sensor body

22‧‧‧ Cover

22A‧‧‧ openings

30‧‧‧ button

33‧‧‧Substrate

40‧‧‧Lighting elements

50‧‧‧Control circuit

51‧‧‧Sucking Inspection Department

52‧‧‧Lighting Element Control Department

53‧‧‧Heat Source Control Department

60‧‧‧ Keeping Department

70‧‧‧Acceptor

80‧‧‧heat source

90‧‧‧Destruction Department

100‧‧‧Non-burning fragrance applicator

110‧‧‧Electrical unit

111‧‧‧Female connector

120‧‧‧Atomization unit

121‧‧‧ Male connector

122‧‧‧Air flow path

123‧‧‧Ceramics

124‧‧‧ outer wall

125‧‧‧Air introduction hole

126‧‧‧ partition member

130‧‧‧Capsule unit

131‧‧‧ Cigarette source

132‧‧‧Filter

133‧‧‧Predetermined film

140‧‧‧sucker unit

141‧‧‧Sucking hole

A‧‧‧Predetermined direction

X‧‧‧The increase in voltage in phase 1

Y‧‧‧The second increase in voltage

θ 1‧‧‧ Gradient of the initial stage of the pumping action series

θ 2‧‧‧ Gradient of the mid-stage of the pumping action series

Fig. 1 is a schematic view showing a non-combustion type flavor applicator 100 according to the first embodiment.

Fig. 2 is a schematic view showing the atomizing unit 120 of the first embodiment.

Fig. 3 is a schematic view showing the sensor 20 of the first embodiment.

Fig. 4 is a block diagram showing the control circuit 50 of the first embodiment.

Fig. 5 is a schematic view for explaining the detection of the suction section of the first embodiment.

Fig. 6 is a schematic view showing an example of the light-emitting aspect of the first embodiment.

Fig. 7 is a schematic view showing an example of the light-emitting aspect of the first embodiment.

Fig. 8 is a view showing an example of control of the magnitude of the power supply output in the pumping operation sequence of the first embodiment.

Fig. 9 is a view showing an example of control of the magnitude of the power supply output in the pumping operation sequence of the first embodiment.

Fig. 10 is a view showing an example of control of the magnitude of the power supply output per one suction operation in the first embodiment.

Fig. 11 is a view showing an example of control of the magnitude of the power supply output per one suction operation in the first embodiment.

Fig. 12 is a schematic diagram showing an example of control of the magnitude of the power supply output in the pumping operation sequence of the first modification of the first embodiment.

Fig. 13 is a view showing the suction operation sequence of the second modification of the first embodiment. A schematic diagram of one example of control over the duration of supply in a column.

Fig. 14 is a schematic view for explaining control of the magnitude of the power output of the fourth modification of the first embodiment.

Fig. 15 is a schematic view for explaining control of the magnitude of the power output of the fifth modification of the first embodiment.

Fig. 16 is a schematic view for explaining control of power supply output in a fifth modification of the first embodiment.

Fig. 17 is a schematic view for explaining control of the magnitude of the power output of the sixth modification of the first embodiment.

Fig. 18 is a schematic view for explaining control of the magnitude of the power output of the sixth modification of the first embodiment.

Fig. 19 is a schematic view for explaining control of power supply output in a seventh modification of the first embodiment.

Hereinafter, an embodiment will be described. In the following description, the same or similar symbols are attached to the same or similar parts. However, it should be noted that the drawing is a schematic diagram, and the ratio of each size is different from the real thing.

Therefore, the specific dimensions and the like should be judged by considering the following description. Further, of course, even the drawings contain portions in which the relationship or ratio of the sizes differs from each other.

[Summary of Embodiments]

The non-combustion type scent suction device involved in the prior art is used in each In the case where the user's pumping action is different, or the suction action of each pumping action of the same user is different, it is difficult to properly and quickly control the user in each case. The total amount of gas gel inhaled by the suction action of one time.

The non-combustion type flavor applicator of the embodiment includes a casing having an air flow path continuous from the intake port to the exhaust port, and an atomization unit that atomizes the gas gel source without combustion; the sensor, Outputting a value that varies according to a user's pumping operation; and an absolute value of a slope formed by the control unit based on a response value of two or more derived from a value output from the sensor (hereinafter referred to as an absolute value of the slope) a value or an absolute value of the slope), and controlling the power supply output to the atomizing portion so that the amount of the gas gel atomized by the atomizing portion in the primary energization of the atomizing portion falls within a desired range Inside.

In the embodiment, the control unit controls the power supply output to the atomizing unit in accordance with the absolute value of the slope so that the amount of the gas gel falls within a desired range. That is, depending on the absolute value of the slope, the suction operation is estimated for each suction operation, whereby the gas glue sucked by the user in each suction operation can be appropriately and quickly controlled. Total amount.

[First Embodiment]

(non-combustion type scent suction device)

Hereinafter, the non-combustion type flavor applicator of the first embodiment will be described. Fig. 1 is a schematic view showing a non-combustion type flavor applicator 100 according to the first embodiment. Fig. 2 is a view showing the atomizing unit 120 of the first embodiment. Schematic diagram.

In the first embodiment, the non-combustion type flavor applicator 100 has a shape that absorbs the fragrance without burning, and has a shape that extends from the non-suction side toward the mouth side and along the predetermined direction A. In the first embodiment, the "suction side" can also be considered as "downstream" with the flow of the gas gel, and the "non-suction side" can also be regarded as synonymous with "upstream" of the flow of the gas gel.

As shown in Fig. 1, the non-combustion type flavor extractor 100 has an electric unit 110 and an atomizing unit 120. The electric unit 110 has a female connector 111 at a portion adjacent to the atomizing unit 120, and the atomizing unit 120 has a male connector 121 at a portion adjacent to the electric unit 110. The female connector 111 has a spiral groove extending in a direction orthogonal to the predetermined direction A, and the male connector 121 has a spiral protrusion extending in a direction orthogonal to the predetermined direction A. The atomization unit 120 and the electric unit 110 are connected by the screwing of the female connector 111 and the male connector 121. The atomizing unit 120 is configured to be attachable and detachable to the electric unit 110.

The electric unit 110 has a power source 10, a sensor 20, a button 30, a light-emitting element 40, and a control circuit 50.

The power source 10 is, for example, a lithium ion battery. The power source 10 accumulates electric energy required to apply a voltage to each of the components of the non-combustion type flavor extractor 100. For example, the power source 10 accumulates electrical energy for applying a voltage to the sensor 20, the light emitting element 40, and the control circuit 50. For example, the power source 10 accumulates electric energy for applying a voltage to a heat source 80 to be described later.

The sensor 20 outputs a value (for example, a voltage value or a current value) that changes in accordance with the air sucked by the non-suction side toward the suction side (that is, the suction operation of the user). In the first embodiment, the sensor 20 has a capacitor and outputs a value indicating the capacitance of the capacitor that changes in accordance with the air sucked from the non-suction side toward the suction side (that is, the suction operation of the user). Here, the value output by the sensor 20 is a voltage value. The sensor 20 is, for example, a condenser microphone sensor.

Specifically, as shown in FIG. 3, the sensor 20 has a sensor body 21, a cover 22, and a substrate 33. The sensor body 21 is, for example, composed of a capacitor, and the capacitance of the sensor body 21 is the air sucked by the air introduction hole 125 (that is, the air sucked from the non-suction side toward the suction side). The resulting vibration (pressure) changes. The cover 22 is provided on the suction side with respect to the sensor body 21, and has an opening 22A. By providing the cover 22 having the opening 22A, it is easy to change the capacitance of the sensor body 21, and the response characteristics of the sensor body 21 are improved. The substrate 33 outputs a value (here, a voltage value) indicating the capacitance of the sensor body 21 (capacitor).

Further, in the third embodiment, the lid body 22 covers only the suction port side end of the sensor body 21, but the first embodiment is not limited thereto. For example, the cover 22 may cover the side of the sensor body 21 in addition to the suction side end of the sensor body 21. In the third embodiment, an example in which the air introduction hole 125 is provided closer to the suction port side than the sensor 20 is exemplified, but the first embodiment is not limited thereto. For example, the air introduction hole 125 may be disposed closer to the non-suction side than the sensor 20.

Returning to Fig. 1, the button 30 is configured to be pushed in from the outer side of the non-combustion type flavor extractor 100. In the first embodiment, the push button 30 is provided at the non-suction end of the non-burning flavor applicator 100, and is configured to be press-fitted from the non-suction end toward the suction end (that is, the predetermined direction A). For example, in the case where the button 30 is continuously pressed in a predetermined number of times, the power source of the non-combustion type flavor extractor 100 is input. Further, the power source of the non-combustion type flavor extractor 100 may be turned off in a case where a predetermined time has elapsed after the suction operation is performed and the suction operation is not performed.

The light-emitting element 40 is, for example, a light source such as an LED or an electric lamp. The light emitting element 40 is disposed on a side wall that extends along a predetermined direction. Light-emitting element 40 is preferably a side wall disposed adjacent the non-suction end. Thereby, the user can easily recognize the light-emitting pattern of the light-emitting element 40 in the suction operation as compared with the case where the light-emitting element is provided only on the end face of the non-suction end on the axis of the predetermined direction A. The light-emitting pattern of the light-emitting element 40 is a pattern for notifying the user of the state of the non-combustion-type flavor absorber 100.

The control circuit 50 controls the operation of the non-combustion type flavor extractor 100. Specifically, the control circuit 50 controls the light emitting pattern of the light emitting element 40 and controls the power output supplied to the heat source 80.

As shown in FIG. 2, the atomizing unit 120 has a holding portion 60, an absorber 70, a heat source 80, and a breaking portion 90. The atomizing unit 120 has a capsule unit 130 and a mouthpiece unit 140. Here, the atomizing unit 120 has an air introduction hole 125 for introducing outside air into the inside, an air flow path 122 communicating with the electric unit 110 (sensor 20) through the male connector 121, and a ceramic 123 , is configured in a cylindrical shape. Atomization The unit 120 has a cylindrical outer wall 124 for forming an outer shape of the atomizing unit 120. The space surrounded by the ceramic 123 forms an air flow path. The ceramic 123 is made of, for example, alumina as a main component.

The holder 60 has a cylindrical shape and holds a source of a gas gel for generating a gas gel. The gas gel source is a liquid such as glycerin or propylene glycol. The holder 60 is made of, for example, a porous body impregnated with a gas gel source. The pore body is, for example, a resin web.

Further, in the first embodiment, the ceramics 123 described above are disposed inside the holder 60, and the volatilization of the gas gel held by the holder 60 can be suppressed.

The absorber 70 is provided adjacent to the holder 60 and is constituted by a substance that sucks the gas gel source upward from the holder 60. The absorber 70 is made of, for example, glass fiber.

The heat source 80 heats the gas gel source without accompanying combustion. That is, the heat source 80 is an example of an atomizing portion that atomizes the gas gel source without accompanying combustion. For example, the heat source 80 is a heating wire wound around the absorber 70. The heat source 80 heats the gas gel source that is sucked up by the absorber 70.

In the first embodiment, as the heat source 80, a heating type member that atomizes a gas gel source by heating is exemplified. However, the atomization unit may have a function of atomizing the gas gel source, and may be an ultrasonic type component that atomizes the gas gel source by ultrasonic waves.

The breaking portion 90 is a member for breaking a portion of the predetermined film 133 in a state in which the capsule unit 130 is mounted. In the embodiment, the breaking portion 90 is used to apply the atomizing unit 120 and the capsule unit 130. The spaced apart partition members 126 are held. The partition member 126 is, for example, a polyacetal resin. The breaking portion 90 is, for example, a cylindrical hollow needle that extends in a predetermined direction A. By spurting the tip of the hollow needle to the predetermined film 133, a portion of the predetermined film 133 can be broken. Further, the air flow path of the air type atomizing unit 120 and the capsule unit 130 is formed by the inner space of the hollow needle. Here, in the inside of the hollow needle, it is preferable to provide a mesh having a thickness such that the material constituting the cigarette source 131 does not pass. The thickness of the mesh is, for example, below the mesh number (mesh) and below the mesh number (mesh).

In such an example, the depth at which the hollow needle penetrates into the capsule unit 130 is preferably 1.0 mm or more and 5.0 mm or less, more preferably 2.0 mm or more and 3.0 mm or less. Thereby, since the portion other than the desired portion of the predetermined film 133 is not damaged, the detachment of the cigarette source 131 filled in the space defined by the predetermined film 133 and the filter 132 can be suppressed. Further, since the separation of the hollow needle from the space can be suppressed, it is possible to preferably maintain an appropriate air flow path from the hollow needle to the filter 132.

In the cross section perpendicular to the predetermined direction A, the cross-sectional area of the vertical needle is preferably 2.0 mm ² or more and 3.0 mm ² or less. Thereby, when the hollow needle is pulled out, the cigarette source 131 can be prevented from falling off from the capsule unit 130.

The tip end of the hollow needle preferably has an inclination of 30 or more and 45 or less with respect to a direction perpendicular to the predetermined direction A.

However, the embodiment is not limited thereto, and the breaking portion 90 may be a portion adjacent to the predetermined film 133 in a state in which the capsule unit 130 is attached. A portion of the predetermined film 133 can also be broken by the user applying pressure to such a portion.

The capsule unit 130 is configured to be detachable from the main body unit. The capsule unit 130 has a cigarette source 131, a filter 132, and a predetermined film 133. Further, the cigarette source 131 is filled in the space defined by the predetermined film 133 and the filter 132. Here, the term "main body unit" means a unit constituted by a portion other than the capsule unit 130. For example, the body unit includes the above-described electric unit 110, the holder 60, the absorber 70, and the heat source 80.

The cigarette source 131 is disposed closer to the mouth side than the holder 60 holding the gas gel source, and produces a flavor that is absorbed by the user together with the gas gel generated from the gas gel source. Here, it should be noted that the cigarette source 131 is constituted by a solid substance so as not to flow out from the space defined by the predetermined film 133 and the filter 132. As the cigarette source 131, shredded tobacco, a molded body in which a cigarette raw material is formed into a pellet shape, and a molded body in which a cigarette raw material is formed into a sheet shape can be used. A fragrance such as menthol may be imparted to the cigarette source 131.

Further, in the case where the cigarette source 131 is composed of a cigarette material, since the cigarette material is away from the heat source 80, the flavor can be absorbed without heating the cigarette material. In other words, it should be noted that it is possible to suppress the absorption of unwanted substances due to the heating of the raw materials of the cigarette.

In the first embodiment, the amount of the cigarette source 131 filled in the space defined by the filter 132 and the predetermined film 133 is preferably 0.15 g/cc or more and 1.00 g/cc or less. The volume occupied by the cigarette source 131 in the space partitioned by the filter 132 and the predetermined film 133 is preferably 50% or more and 100% or less. In addition, by the filter 132 The volume of the space defined by the predetermined film 133 is preferably 0.6 ml or more and 1.5 ml or less. Thereby, the cigarette source 131 can be accommodated to the extent that the user can sufficiently taste the fragrance while maintaining the capsule unit 130 at an appropriate size.

In a state where one of the predetermined films 133 is broken by the breaking portion 90, and the atomizing unit 120 and the capsule unit 130 are already in communication, from the front end portion (destroyed portion) of the capsule unit 130 to the end of the filter 132, at 1050 cc / The flow resistance of min is the ventilation resistance (pressure loss) of the capsule unit 130 when the air is sucked, and the whole is preferably 10 mmAq or more and 100 mmAq or less, more preferably 20 mmAq or more and 90 mmAq or less. By setting the ventilation resistance of the cigarette source 131 within the above preferred range, the phenomenon that the gas gel is excessively filtered by the cigarette source 131 can be suppressed, and the fragrance can be efficiently supplied to the user. Further, since the 1 mmAq system corresponds to 9.806665 Pa, the above-mentioned ventilation resistance can also be expressed by Pa.

The filter 132 is adjacent to the mouthpiece side with respect to the cigarette source 131, and is constituted by a substance having air permeability. The filter 132 is preferably, for example, an acetate filter. The filter 132 preferably has a thickness that does not allow passage of the raw material constituting the cigarette source 131.

The ventilation resistance of the filter 132 is preferably 5 mmAq or more and 20 mmAq or less. Thereby, the vapor component generated by the cigarette source 131 can be efficiently adsorbed, and the gas gel can be efficiently passed, whereby an appropriate flavor can be supplied to the user. Moreover, the user can be provided with an appropriate sense of air resistance.

The ratio (mass ratio) of the mass of the cigarette source 131 to the mass of the filter 132 is preferably in the range of 3:1 to 20:1, more preferably 4:1. To the range of 6:1.

The predetermined film 133 is integrally formed with the filter 132, and is constituted by a member having no air permeability. The predetermined film 133 covers a portion other than the portion adjacent to the filter 132 in the outer surface of the cigarette source 131. The predetermined film 133 includes at least one compound selected from the group consisting of gelatin, polypropylene, and polyethylene terephthalate. Gelatin, polypropylene, polyethylene and polyethylene terephthalate are not ventilating and are suitable for the formation of films. Further, gelatin, polypropylene, polyethylene, and polyethylene terephthalate provide sufficient resistance to moisture contained in the cigarette source 131. Polypropylene, polyethylene and polyethylene terephthalate are particularly excellent in water resistance. Further, since gelatin, polypropylene, and polyethylene have anti-alkaline properties, even when the cigarette source 131 has an alkaline component, it is not easily deteriorated by the alkaline component.

The film thickness of the predetermined film 133 is preferably 0.1 μm or more and 0.3 μm or less. Thereby, it is possible to easily break a part of the predetermined film 133 while maintaining the function of protecting the cigarette source 131 by the predetermined film 133.

As described above, although the predetermined film 133 is integrally formed with the filter 132, the predetermined film 133 is attached to the filter 132 by, for example, a paste or the like. Alternatively, the predetermined shape of the predetermined film 133 may be set to be smaller than the outer shape of the filter 132 in a direction perpendicular to the predetermined direction A, and the filter 132 may be inserted into the predetermined film 133 by the filter 132. The restoring force fits the filter 132 into the predetermined film 133. Alternatively, the engaging portion for engaging the predetermined film 133 may be provided to the filter 132.

Here, although the shape of the predetermined film 133 is not particularly limited, it is preferably a cross section perpendicular to the predetermined direction A and has a concave shape. In this case, after the cigarette source 131 is filled inside the predetermined film 133 having a concave shape, the opening of the predetermined film 133 filled with the cigarette source 131 is closed by the filter 132.

In the cross section perpendicular to the predetermined direction A, the predetermined film 133 has a concave shape, and the largest cross-sectional area of the cross-sectional area of the space surrounded by the predetermined film 133 (that is, the cross-section of the opening through which the filter 132 is fitted) The area is preferably 25 mm ² or more and 80 mm ² or less, more preferably 25 mm ² or more and 55 mm ² or less. In such an example, in the vertical cross section opposed to the predetermined direction A, the cross-sectional area of the filter 132 is preferably 25 mm ² or more and 55 mm ² or less. The thickness of the filter 132 in the predetermined direction A is preferably 3.0 mm or more and 7.0 mm or less.

The mouthpiece unit 140 has a mouthpiece hole 141. The suction opening 141 is an opening for exposing the filter 132. The user sucks the gas gel from the mouthpiece 141, thereby absorbing the fragrance together with the gas gel.

In the first embodiment, the mouthpiece unit 140 is configured to be detachable from the outer wall 124 of the atomizing unit 120. For example, the mouthpiece unit 140 has a cup shape configured to be fitted to the inner surface of the outer wall 124. However, the embodiment is not limited to this. The mouthpiece unit 140 can also be rotatably attached to the outer wall 124 by a hinge or the like.

In the first embodiment, the mouthpiece unit 140 is provided in a different body from the capsule unit 130. That is, the mouthpiece unit 140 forms part of the body unit. However, the embodiment is not limited to this. Suction list The element 140 can also be provided integrally with the capsule unit 130. In such a case, it should be noted that the mouthpiece unit 140 forms part of the capsule unit 130.

As described above, in the first embodiment, the non-combustion type flavor extractor 100 has the outer wall 124 (outer casing) of the atomizing unit 120, and the outer wall 124 (outer casing) of the atomizing unit 120 has an air introduction hole. 125 (intake port) continues to the air flow path 122 of the suction port 141 (exhaust port). In the first embodiment, the air flow path 122 is constituted by the atomization unit 120, but the aspect of the air flow path 122 is not limited thereto. The air flow path 122 may also be formed by both the outer casing of the electric unit 110 and the outer casing of the atomizing unit 120.

As described above, in the first embodiment, the non-combustion type flavor extractor 100 is provided with the holder 60 for holding the gas gel source, and the holding body 60 is held by the suction operation for a plurality of times. A small amount of gas source.

(Control circuit)

Hereinafter, the control circuit of the first embodiment will be described. Fig. 4 is a block diagram showing the control circuit 50 of the first embodiment.

As shown in FIG. 4, the control circuit 50 includes a suction detecting unit 51, a light-emitting element control unit 52, and a heat source control unit 53.

The suction detecting unit 51 is connected to the sensor 20 that outputs a value that changes in accordance with the air sucked from the non-suction side toward the suction side. The suction detecting unit 51 detects the suction state based on the detection result of the sensor 20 (for example, the negative pressure in the non-combustion-type flavor absorber 100). In detail, suction The detecting unit 51 detects the suction state (suction section) of the sucked gas gel and the non-suction state (non-suction section) in which the gas gel is not sucked. Thereby, the suction detecting unit 51 can specify the number of times of suction operation of the suction gel. Further, the suction detecting unit 51 can also detect the time taken for each suction operation of the suction gel.

In the first embodiment, the suction detecting unit 51 detects the start or end of the suction section based on the slope of the response value of two or more derived from the output value output from the sensor 20. Here, the response value is the output value itself output from the sensor 20; the output value is a voltage value indicating the capacitance of the capacitor.

Specifically, the suction detecting unit 51 has a slope in which a slope composed of two or more output values output from the sensor 20 has a predetermined sign (here, negative) and has a predetermined sign (negative here). In the case where the absolute value is larger than the predetermined value, the start or end of the suction section is detected. In other words, the suction detecting unit 51 detects the start of the suction section in the case where the above condition is satisfied before the start of the suction section is detected. On the other hand, the suction detecting unit 51 detects the end of the suction section in the case where the above condition is satisfied after the start of the suction section is detected.

Here, the condition (predetermined value) for the start of the suction section may be the same as or different from the condition (predetermined value) for the end of the suction section. Further, the end of the suction section is preferably determined after the start of the suction section and after a predetermined period of time (for example, 200 msec to 500 msec). Thereby, it is possible to suppress a situation in which the end of the suction section is erroneously detected immediately after the start of the suction section.

In detail, as shown in Fig. 5, the suction detecting unit 51 monitors the output value output from the sensor 20 during the sampling period (Δt). It should be noted that in FIG. 5, the voltage value is exemplified as the output value output from the sensor 20. The sampling period (Δta) of monitoring the output value output from the sensor 20 before the start of the pumping section is detected is monitored for the output value output from the sensor 20 after being detected at the beginning of the pumping section. The sampling period (Δtb) is shorter. The sampling period (Δtc) of the output value output from the sensor 20 is monitored after the end of the pumping section is detected, and the output value output from the sensor 20 is monitored before the end of the pumping section is detected. The sampling period (Δtb) is shorter.

Further, the sampling period (Δta) for monitoring the output value output from the sensor 20 before the start of the suction section is detected is monitored and output from the sensor 20 after being detected at the end of the suction section. The sampling period (Δtc) of the output value is the same. Further, after the start of the suction section is detected, the sampling period (Δtb) of the output value output from the sensor 20 is monitored, and the output from the sensor 20 is monitored before the end of the suction section is detected. The sampling period (Δtb) of the output value is the same. In other words, the sampling period (Δta or Δtc) of monitoring the output value output from the sensor 20 outside the suction section is a sampling period in which the output value output from the sensor 20 is monitored in the suction section (Δ). Tb) is shorter. The sampling period (Δta or Δtc) for monitoring the output value output from the sensor 20 outside the suction section is, for example, 1 msec, and the sampling period of the output value output from the sensor 20 is monitored in the suction section (Δ) The tb) is, for example, 10 msec.

Hereinafter, each symbol indicates the following content. △t series The period in which the output value output from the sensor 20 is monitored is shown, D(n) represents the output value output from the sensor 20 at time t(n), and α(n) represents a positive integer, S(n) It represents the slope formed by the output value output from the sensor 20 at time t(n). In addition, n is the number of calculations of S(n). Further, α(n) may be a fixed value (for example, 3) or may be changed every time S(n) is calculated.

Under the premise of this, the suction detecting unit 51 can also calculate by S(n)={D(n)-D(n−α(n)×Δt)}/(α(n)×Δt). The slope formed by the output value output from the sensor 20. In addition, it should be noted that "D(n-α(n) × Δt)" indicates an output value that "α(n) × Δt" is monitored earlier than time t(n).

In this case, the suction detecting unit 51 satisfies all S(n) for S (n) consecutive m times (m is an integer of 2 or more) before the start of the suction section. In the case where the value of the predetermined symbol (here is negative) and the absolute value of all S(n) are larger than the first value to be described later, the start of the suction section is detected. Here, it should be noted that the sampling period (Δt) used at the beginning of detecting the suction section is Δta (or Δtc). On the other hand, after the suction detection unit 51 is detected at the beginning of the suction section, all of S(n) are satisfied as predetermined symbols (negative here) for the consecutive m times of S(n). In the case where the value is the condition that the absolute value of all S(n) is larger than the first value, the end of the suction section is detected. Here, it should be noted that the sampling period (Δt) used at the end of detecting the suction section is Δtb (> Δta or Δtc).

For example, when α(n)=3 and m=3, the case where the start of the suction section is detected with reference to FIG. 5 is described. Bright. In this case, all of S(p), S(p+1), and S(p+2) are negative values, and S(p), S(p+1), and S(p+2) Since all of the absolute values are larger than the first value, the start of the suction section is detected at time p+2. In addition, for the calculation method of S(n), when the time p is taken as an example, the S(p) system can be S(p)={D(p)-D(p-3)/3Δt}. Calculated.

In addition, the first value is a predetermined value determined in advance, and may be appropriately set by the type of the sensor 20 or the like. Further, the suction detector 51 calculates the period of S(n), which may be the same as the sampling period (Δt) or different from the sampling period (Δt). Further, the suction detector 51 calculates the period of S(n), preferably an integral multiple of the sampling period (Δt).

Further, the calculation cycle for the sampling periods (Δt) and S(n) can be appropriately set. Although the calculation periods of the sampling periods (Δt) and S(n) are preferably synchronized, they may not be synchronized. Further, the period in which the sensor 20 outputs the output value can be appropriately set. Furthermore, the sensor 20 can be turned on (on) or off (in) in synchronization with the calculation periods of the sampling periods (Δt) and S(n), or can be always turned on.

In the first embodiment, it is preferable that the sampling period (for example, 5 msec) of the output value referred to at the start or end of the suction section is longer than the predetermined time. Specifically, as shown in Fig. 5, the sampling period of the output value referred to at the start or end of the suction section is indicated by α(n) × Δt + (m - 1) × Δt. Preferably, the predetermined time is obtained by discretely obtaining an output value that varies in the pumping section on the time axis, and extracting a continuity approximation function from a discretely obtained plot of the output value, and comparing the approximation function The frequency wavelength of the derived waveform (λ shown in Figure 5) The average of 1/2 is longer. In this way, by setting the lower limit in the sampling period of the output value referred to at the beginning or the end of the suction section, it is possible to suppress the suction operation different from that of the user before the start of the suction section is detected. The phenomenon (for example, vibration of a human voice, etc.) occasionally satisfies the above conditions, and improves the accuracy of detecting the start of the suction section. Further, even after the start of the suction section is detected, it is possible to suppress the above condition from being erroneously satisfied before the user actually ends the suction operation, and to improve the accuracy of detecting the end of the suction section.

In the first embodiment, it is preferable that the suction detecting unit 51 satisfies S(n) of one of S (n) for m consecutive times, and satisfies the absolute value of S(n) more than the second value. In the case of a small condition, the beginning or the end of the suction section is detected. The second value is a value which is much larger than the first value, and is preferably an average value of slopes (absolute values) composed of output values of 2 or more which are varied in the suction section. In other words, the suction detecting unit 51 is for all of S(n) for m consecutive times, S(n) is a value of a predetermined symbol (here, negative), and the absolute value of S(n) is the second value. In the above case, the start or end of the suction section is not detected. On the other hand, the suction detecting unit 51 is for S (n) which is consecutive m times, as long as all the conditions in which S(n) is larger than the first value are satisfied, and the absolute of S(n) at least once is satisfied. When the value is smaller than the second value, the start or end of the suction section is detected. Thereby, even if the capacitance of the sensor 20 is rapidly changed due to a phenomenon different from the suction operation, erroneous detection of the start or end of the suction section can be suppressed. The phenomenon different from the suction operation is, for example, a phenomenon in which the capacitance of the sensor 20 changes due to the vibration of the table in the case where the non-combustion type flavor applicator 100 is placed on the table. Or the user blows air from the mouth of the non-combustion type flavor extractor 100 instead of sucking.

In the first embodiment, the sampling period of the output value referred to at the start or end of the suction section is α(n) × Δt + (m - 1) × Δt. In other words, the sampling period of the output value referred to by the calculation of S(n) which is two consecutive times in S(n) of m times is partially repeated, and α(n) is 2 or more. Thereby, the sampling period in which the sampling value of the output value referred to by the calculation of the continuous second S(n) is not repeated, that is, the sampling period of the output value referred to at the start or end of the determination of the suction section is In the case of α(n) × Δt × m, the sampling period of the output value referred to at the beginning or end of the suction section is determined (α(n) × Δt + (m - 1) × Δt) It is shorter, and it is possible to quickly detect the beginning of the suction section and improve the detection accuracy of the beginning of the suction section. Further, compared with the case where α(n) is 1, since the fluctuation of the fine output value is not detected as the start of the suction section, erroneous detection of the suction section can be suppressed.

The light-emitting element control unit 52 is connected to the light-emitting element 40 and the suction detecting unit 51, and controls the light-emitting element 40. Specifically, the light-emitting element control unit 52 controls the light-emitting element 40 in the first light-emitting state while sucking the suction gel. On the other hand, the light-emitting element control unit 52 controls the light-emitting element 40 in a second light-emitting state different from the first light-emitting state in a non-suction state in which the gas gel is not sucked.

Here, in the illuminating state, the light amount of the light-emitting element 40, the number of the light-emitting elements 40 in the lighting state, the color of the light-emitting element 40, the lighting of the light-emitting element 40, and the extinguishing of the light-emitting element 40 are performed. The cycle is defined by a combination of parameters. The so-called different illumination patterns mean that any of the above parameters have different illumination patterns.

In the first embodiment, the second illuminating state changes in accordance with the number of times of suction operation of the absorbing adhesive. The first illuminating state may be changed according to the number of times of suctioning of the absorbing gas, or may be fixed irrespective of the number of times of suctioning of the absorbing glue.

For example, the first illuminating state illuminates the red light-emitting element 40 in order to make it feel like a general cigarette which generates a gas gel accompanying combustion. The first illuminating aspect is preferably a state in which the illuminating element 40 is continuously lit. Alternatively, the first illuminating aspect may be a state in which the illuminating element 40 is turned on and the illuminating element 40 is turned off in the first cycle.

For example, the second illumination state is to illuminate the blue light-emitting element 40 in order to inform the user that the gas source is not heated. In the second light-emitting aspect, the light-emitting element 40 may be turned on and the light-emitting element 40 may be turned off in a second period longer than the first period.

As described above, the second illuminating state changes in accordance with the number of times the suction operation of the absorbing adhesive is performed.

For example, the second illuminating aspect may be an aspect in which the number of the light-emitting elements 40 to be controlled is increased as the number of times of the pumping operation increases. For example, the light-emitting element control unit 52 controls one light-emitting element 40 in the second light-emitting state in the first pumping operation, and controls the two light-emitting elements in the second light-emitting state in the second pumping operation. Element 40. Alternatively, the light-emitting element control unit 52 controls the n light-emitting elements 40 in the second light-emitting state during the first pumping operation, and the second light-emitting unit in the second pumping operation. The aspect controls the n-1 light emitting elements 40.

Alternatively, the second illuminating aspect may be an aspect in which the amount of light of the light-emitting element 40 is increased or decreased as the number of times of the pumping action increases. Alternatively, the second illuminating aspect may be an aspect in which the color of the light-emitting element 40 is changed in accordance with an increase in the number of times of the pumping operation.

Further, even in the case where the first illuminating state changes in accordance with the number of times of the pumping operation, the change in the first illuminating state is basically the same as the change in the second illuminating aspect.

In the first embodiment, the light-emitting element control unit 52 terminates the first light-emitting state and the second light-emitting state in the case where the number of times the suction operation of the suction gel has reached a predetermined number of times (for example, eight times). Control, and control the light-emitting element 40 in an end light-emitting state.

The end of the illumination pattern may be any one that is intended to notify the user of the timing at which the pumping operation is to be completed, and is preferably different from the first illumination pattern and the second illumination pattern. For example, the end light-emitting state is such that the amount of light of the light-emitting element 40 is smaller than that of the first light-emitting state and the second light-emitting state, and the amount of light of the light-emitting element 40 is gradually reduced.

The heat source control unit 53 is connected to the power source 10 and controls the power source output (hereinafter also referred to as the amount of supplied electric power) supplied from the power source 10 to the heat source 80 (atomization unit). In addition, the amount of supplied electric power refers to a result of multiplication of the time elapsed after the start of energization of the heat source 80 and the magnitude of the power supply output, and is a value controlled by the time and the magnitude of the power supply output.

In other words, the amount of supplied electric power can be expressed, for example, by E = {(D ₂ × V) ² / R} × D ₁ × t. E is the amount of supplied electric power, V is the output voltage value of the voltage applied from the power source 10 to the heat source 80, and R is the resistance value of the heat source 80. D ₁ is the energy ratio, and D ₂ is the correction coefficient of the output voltage value. T is the time elapsed after the heat source 80 is energized. Further, in the case where the energy rate control is not performed, D ₁ can be regarded as 1 and in the case where the output voltage value is not corrected, D ₂ can be regarded as 1. In the case where the output voltage value is not corrected, the heat source control unit 53 controls the voltage applied from the power source 10 to the heat source 80 by controlling a DC-DC converter or the like provided in the power source 10.

Here, the magnitude of the power supply output is controlled by the value of the voltage applied to the heat source 80 (the atomizing unit) in the case where the voltage is continuously applied to the heat source 80 (the atomizing unit). On the other hand, in the case of the case where the voltage of the power source is intermittently applied to the heat source 80 (the atomization unit) (pulse control), the value of the voltage applied to the heat source 80 (the atomization unit) and the energy ratio are used. control.

In other words, the power output of the heat source 80 may be, for example, the size of lines _{P = {(D 2 × V} ) 2 / R} × D 1 is represented. P is the size of the power output of the heat source 80. The meaning of the other tokens is as described above. Further, in the case where the energy rate control is not performed, D ₁ can be regarded as 1 and in the case where the output voltage value is not corrected, D ₂ can be regarded as 1 as described above.

First, the heat source control unit 53 gradually increases the power supply output to the heat source 80 from the reference power source output as the number of pumping operations of the suction gas is increased. Thereby, it is possible to emulate the feeling of use of a general cigarette which generates a gas gel accompanying combustion.

Here, in the case where the pumping operation is performed after the number of times of the pumping operation exceeds the predetermined number of times, the heat source control unit 53 may use the magnitude of the power source output smaller than the magnitude of the reference power source output as the heat source 80. The size of the power output should be. Thereby, even when the timing of the suction operation should be ended, the user can absorb a certain amount of the gas gel and increase the satisfaction of the user.

The heat source control unit 53 turns off the power of the non-combustion type flavor extractor 100 in the case where the number of times of the pumping operation exceeds the predetermined number of times and the predetermined time elapses. Thereby, the power waste of the non-combustion type flavor extractor 100 brought about by the power supply of the non-combustion type flavor extractor 100 is forgotten to be turned off.

Here, the heat source control unit 53 may combine the above-described operations, and after the number of times of the pumping operation exceeds the predetermined number of times, the size of the power source output smaller than the magnitude of the reference power source output is used as the supply to the heat source 80, and is drawn. In the case where the number of times of the suction operation exceeds the predetermined number of times and the predetermined time elapses, the power of the non-combustion type flavor extractor 100 is turned OFF.

The heat source control unit 53 preferably increases the gradient of the magnitude of the power supply output to the heat source 80 as the number of suction operations of the suction gel is increased. Here, the gradient of the magnitude of the power supply output is defined by the increase in the number of pumping operations that maintain the magnitude of the fixed power supply output and the increase in the magnitude of the power supply output. That is, as the number of pumping operations increases, the number of pumping operations that maintain a certain amount of power output is reduced. Or, as the number of times of the pumping action increases, the increase in the magnitude of the power output is increased. Alternatively, as the number of pumping operations increases, the number of pumping operations that maintain a certain power output is reduced, and the magnitude of increase in the magnitude of the power output is increased.

Further, the heat source control unit 53 may control the first mode to use the magnitude of the first reference power source output as the magnitude of the reference power source output, and the second mode to use the second reference that is larger than the magnitude of the first reference power source output. The size of the power output is used as the reference power output. The size of the reference power supply output of three or more stages can also be prepared as the size of the reference power supply output. In such an case, the switching of the magnitude of the reference power output can also be performed by the operation of the button 30. For example, the first mode can be applied by pressing the button 30 once, and the second mode can be applied by pressing twice. Also, the button 30 can be replaced by a touch sensor. The power supply of the non-combustion type flavor extractor 100 can also be activated by such operations. That is, the activation of the power source and the switching of the reference power supply output can be performed by one operation by the operation of the button 30. However, the operation of inputting the power by the operation of the button 30 may be different from the operation of switching the magnitude of the reference power output.

Secondly, the heat source control unit 53 controls the standard mode and the shortening mode, and the standard mode is a mode for the user to apply the time required for each suction operation of the suction gel to the standard required time interval. The shortening mode is a mode for a user who is applied to the suction operation of the suction gel for a short time than the standard required time interval. Here, the time interval required for the standard means a time interval in which the balance of the supply amount of the gas gel (TPM: Total Particulate Matter amount: the total amount of the particulate matter) is particularly excellent.

Specifically, the heat source control unit 53 uses the interval flag until the first time elapses in the pumping operation in the standard mode. The magnitude of the quasi-power output is the size of the power supply output to the heat source 80, and the size of the power output that is smaller than the standard power output after the first time period is used as the output of the power supply to the heat source 80. Further, the heat source control unit 53 can immediately set the magnitude of the power supply output to the heat source 80 to zero in the section after the lapse of the first time, and can gradually reduce the magnitude of the power supply output to the heat source 80.

Here, the first time is preferably the same as the end timing of the above-mentioned standard required time interval. However, the first time may be longer than the end timing of the standard required time interval within the range of the allowable supply of the gas glue (the amount of TPM).

On the other hand, the heat source control unit 53 uses the magnitude of the first power source output larger than the standard power source output in the interval of the second time period in the pumping operation for the shortening mode as the supply to the heat source. The size of the power output of the 80th, and the size of the second power supply output that is smaller than the size of the first power supply output in the third time period after the second time, and the interval after the third time is used. 2 The size of the power output whose power output is smaller is the size of the power supply output to the heat source 80. Further, the heat source control unit 53 can immediately set the magnitude of the power supply output to the heat source 80 to zero in the section after the lapse of the first time, and can gradually reduce the magnitude of the power supply output to the heat source 80.

Here, the second time is preferably shorter than the start timing of the time interval required by the above criteria. However, the second time can be included in the time interval required by the standard, or it can be more than the end time of the standard time interval. long. The third time is preferably the same as the end timing of the time interval required by the above criteria. However, the third time may be longer than the end timing of the standard required time interval within the range of the allowable supply of the gas glue (the amount of TPM). Further, the magnitude of the second power supply output smaller than the first power supply output may be the same as the size of the standard power supply output described above. However, the size of the second power output can be larger than the standard power output and smaller than the standard power output.

Further, as described above, the heat source control unit 53 gradually increases the power supply output to the heat source 80 from the reference power source output in accordance with the increase in the number of pumping operations. In other words, it should be noted that the standard power output per suction operation increases as the number of pumping operations increases.

The heat source control unit 53 can also set the standard mode or the shortened mode by learning the pumping action of the user. In detail, the heat source control unit 53 sets the standard mode when the time required for each of the stored pumping operations is in the standard required time interval. The heat source control unit 53 sets the shortening mode when the time required for each of the pumping operations memorized by learning is shorter than the standard required time interval.

In the first embodiment, the atomizing unit 120 can be attached and detached to the electric unit 110. Moreover, the capsule unit 130 can be attached and detached to the main unit including the electric unit 110. In other words, the electrical unit 110 can be reused throughout the plurality of pumping action series. The series of suction operations refers to a series of actions of repeatedly performing a suction operation a predetermined number of times. Therefore, it is also possible to learn every 1 time in the initial series of pumping actions. The time required for the pumping action is set, and the standard mode or the shortening mode is set in the pumping action series after the second time. Or, in each series of pumping action, by learning the time required for each pumping action in the first n times of pumping action, for the n+1th (or The suction mode is set to the standard mode or the shortened mode after n+2).

Alternatively, the heat source control unit 53 may set the standard mode or the shortened mode by the user's operation. In such an case, the switch for switching the standard mode and the shortening mode is provided to the non-combustion type flavor extractor 100. In addition, it is also possible to switch between the standard mode and the shortened mode in each series of pumping operations. Alternatively, the standard mode and the shortened mode may not be switched in each of the pumping action series, and the mode initially set by the application may be fixed.

(lighting aspect)

Hereinafter, an example of the light-emitting aspect of the first embodiment will be described. Fig. 6 and Fig. 7 are views showing an example of the illuminating aspect of the first embodiment. Fig. 6 and Fig. 7 show an example in which the user should end the series of suction operations in the case where the number of times of the suction operation has reached eight times (predetermined number of times).

First, the first example of the illuminating aspect will be described with reference to Fig. 6. As shown in Fig. 6, the first light-emitting pattern in the suction state is fixed irrespective of the number of times of the suction operation. On the other hand, the second light-emitting pattern in the non-suction state changes in accordance with the number of times of the pumping operation.

For example, as shown in Fig. 6, in the non-pumping state #1 to the non-pumping state #4, the illuminating state #2-1 can be employed as the second illuminating state. In the non-pumping state #5 to the non-pumping state #7, the illuminating state #2-2 can be employed as the second illuminating state. In the non-pumping state #8, the illuminating state #2-3 can be employed as the second illuminating state. Further, in the non-suction state of the ninth and subsequent times, the above-described end light-emitting state can be employed.

On the other hand, in the suction state #1 to the suction state #8, the light-emitting state #1 can be employed as the first light-emitting state. Even in the suction state after the ninth time, the illuminating state #1 can be used as the first illuminating state, and in order to display the suction for more than 8 times (predetermined number of times), it is also possible to adopt 1 different illumination patterns of the illuminating state and the second illuminating state.

The illuminating state #1, the illuminating state #2-1, the illuminating state #2-2, the illuminating state #2-3, and the ending illuminating state are mutually different illuminating aspects. As described above, the illuminating state is based on the amount of light of the light-emitting element 40, the number of the light-emitting elements 40 in the lighting state, the color of the light-emitting element 40, the lighting of the light-emitting element 40, and the period in which the light-emitting element 40 is turned off. Defined by a combination of parameters. The so-called different illumination patterns mean that the above-mentioned parameters have different illumination patterns.

For example, the illuminating aspect #1 is preferably designed to give a sense of use of a general cigarette which produces a gas gel accompanying combustion, and is reminiscent of a burning illuminating aspect. The illuminating aspect #2-1 is preferably reminiscent of the illuminating state of the initial stage of the pumping action series, and the illuminating aspect #2-2 is preferably reminiscent of the illuminating state of the middle stage of the pumping action series. Like, illuminating aspect #2-3 Preferably, it is reminiscent of the illuminating aspect of the final stage of the pumping action series. It is preferable that the end light-emitting state is an aspect in which the user is notified of the timing of ending the pumping operation.

Second, the first example of the illuminating aspect will be described with reference to Fig. 7. As shown in Fig. 7, both the first light-emitting pattern in the suction state and the second light-emitting pattern in the non-suction state change in accordance with the number of times of the pumping operation.

For example, as shown in Fig. 7, in the non-suction state, as in the case shown in Fig. 6, the illumination pattern #2-1, the illumination pattern #2-2, and the illumination pattern are used. 2-3, as the second illuminating aspect.

On the other hand, in the suction state #1 to the suction state #4, the light-emitting state #1-1 is employed as the first light-emitting state. In the suction state #5 to the suction state #7, the illuminating state #1-2 is employed as the first illuminating state. In the suction state #8, the illuminating state #1-3 is employed as the first illuminating state. Further, in the suction state after the ninth time, the illuminating state #1-4 was employed.

The illuminating aspect #1-1 is preferably an illuminating state which is reminiscent of the initial stage of the pumping action series, and the illuminating aspect #1-2 is preferably reminiscent of the illuminating state of the middle stage of the pumping action series. As such, the illuminating aspect #1-3 is preferably a luminescence that is reminiscent of the final stage of the pumping action series. Further, in the same manner as the end of the illuminating aspect, the illuminating aspect #1-4 is preferably an aspect in which the user is notified of the timing of ending the pumping operation.

As shown in Fig. 6 and Fig. 7, in the first embodiment, the non-pumping state #1 (i.e., the non-combustion type flavor applicator 100) is exemplified. An example in which the illuminating state in the non-pumping state after the power is turned on is the second illuminating state (the illuminating aspect #2-1). However, the embodiment is not limited to this. The illuminating state in the non-pumping state #1 may also be a starting illuminating state different from the second illuminating state. It is preferable to start the illuminating aspect in such a manner that the preparation for starting the pumping action is completed to notify the user.

(Power output in the pumping action series)

Hereinafter, an example of the power output in the pumping operation series of the first embodiment will be described. Fig. 8 and Fig. 9 are views showing an example of the power output in the pumping operation sequence of the first embodiment. In the eighth and ninth diagrams, in the case where the number of times of the suction operation has reached eight (predetermined number of times), in principle, the user should end the series of suction operations. Further, it should be noted that in the non-suction state, since the power source output is not supplied to the heat source 80, the behavior of the magnitude of the power source output during the non-suction operation is omitted in FIGS. 8 and 9.

Here, the case where the magnitude of the power supply output supplied to the heat source 80 is controlled by the voltage applied to the heat source 80 is exemplified. Therefore, in the first embodiment, the control of the magnitude of the power supply output can be considered synonymous with the control of the voltage. In addition, Fig. 8 shows a first mode (Low mode) in which a first voltage is used as a reference voltage, and Fig. 9 shows a second mode (High mode) in which a second voltage higher than the first voltage is used as a reference voltage. . However, although the reference voltage is different, in the first mode (Low mode) and the second mode (High mode), the action of the voltage applied to the heat source 80 is the same.

As shown in FIGS. 8 and 9, the heat source control unit 53 gradually increases the voltage applied to the heat source 80 from the reference voltage with an increase in the number of pumping operations of the suction gel. Specifically, in the suction state #1 to the suction state #4, the voltage applied to the heat source 80 is fixed, and the reference voltage is applied to the heat source 80. In the suction state #5 to the suction state #7, the voltage applied to the heat source 80 is fixed, and a voltage one step larger than the reference voltage is applied to the heat source 80. In the suction state #8, a voltage of two stages larger than the reference voltage is applied to the heat source 80. In the suction state after the ninth time, a voltage smaller than the reference voltage is applied to the heat source 80.

As described above, the heat source control unit 53 increases the gradient of the voltage applied to the heat source 80 as the number of suction operations of the suction gel is increased.

For example, as the number of times of the pumping operation increases, the number of times of the pumping operation for maintaining the fixed voltage is reduced. That is, the number of times of the pumping operation to which the reference voltage is applied is four, and the number of times of the pumping operation in which the voltage of one step larger than the reference voltage is applied is three times, and a voltage of two stages larger than the reference voltage is applied. The number of pumping actions is one. Alternatively, as the number of pumping operations increases, the number of pumping operations for maintaining a fixed voltage is reduced. Alternatively, the increase width Y of the second voltage is greater than the increase X of the voltage of the first stage.

Thereby, the gradients (θ 1 and θ 2 ) of the voltages defined by the number of times of the pumping operation for maintaining the fixed voltage and the increasing range of the voltage increase are increased as the number of pumping operations increases. In other words, the gradient θ 2 of the mid-stage of the pumping action series is more than the pumping action series. The gradient θ 1 in the initial stage is larger.

In FIGS. 8 and 9, the number of stages of increasing the voltage applied to the heat source 80 is two stages, but the embodiment is not limited thereto. The number of stages of increasing the voltage applied to the heat source 80 may be three or more stages. Alternatively, the number of stages of increasing the voltage applied to the heat source 80 may be one stage.

(Control of the magnitude of the power output in each pumping action)

Hereinafter, an example of control of the magnitude of the power supply output in each of the pumping operations in the first embodiment will be described. Fig. 10 and Fig. 11 are views showing an example of control of the magnitude of the power supply output per one suction operation in the first embodiment. In Figs. 10 and 11, it is exemplified that in the case where the number of times of the suction operation has reached eight (predetermined number of times), in principle, the user should end the series of suction operations.

Here, the case where the magnitude of the power supply output supplied to the heat source 80 is controlled by the voltage applied to the heat source 80 is exemplified. Therefore, in the first embodiment, the control of the magnitude of the power supply output can be considered synonymous with the control of the voltage. Further, Fig. 10 shows the behavior of the voltage applied to the heat source 80 in the standard mode, and Fig. 11 shows the behavior of the voltage applied to the heat source 80 in the shortening mode.

As shown in FIG. 10, in the standard mode, a standard voltage is applied to the heat source 80 in the section until the first time T1 elapses. A voltage smaller than the standard voltage is applied to the heat source 80 in the section after the first time T1 has elapsed.

Here, an example in which the first time T1 is the same as the end timing of the standard required time interval is exemplified. However, the first time T1 is not limited to the above as described above.

As shown in FIG. 11, in the shortening mode, the first voltage larger than the standard voltage is applied to the heat source 80 in the section until the second time T2 elapses. The second voltage smaller than the first voltage is applied to the heat source 80 in the section from the third time T3 after the second time T2. A voltage smaller than the second voltage is applied to the heat source 80 in the section after the third time T3 has elapsed.

Here, an example in which the second time is shorter than the start timing of the standard required time interval is exemplified. An example in which the third time is the same as the end timing of the standard required time interval is exemplified. An example in which the second voltage is smaller than the standard voltage is exemplified. However, the second time T2, the third time T3, and the second voltage are not limited thereto as described above.

Further, in the case where the standard mode or the shortened mode is set, it is also conceivable that the time required for each pumping operation changes. It should be noted that even in such an case, the contour of the voltage shown in Fig. 10 or Fig. 11 is traced, and the voltage is made zero at the end of the pumping action. In other words, it should be noted that since it is only necessary to control the magnitude of the power output supplied to the heat source 80 in accordance with a predetermined operation mode, it is not necessary to perform the air flow according to the air flow during the energization of the heat source 80. Continuous control of the complex control of the supply of such power outputs.

(function and efficacy)

In the first embodiment, the control circuit 50 (suction detecting unit 51) has a predetermined sign (for example, negative) having a slope composed of two or more output values output from the sensor 20, and has a predetermined symbol. In the case where the absolute value of the slope is larger than the predetermined value, the start or end of the suction section is detected. Therefore, it is possible to reduce the pressure of the pressure change or the vibration of the human voice, which is located at a high place, and the output of the sensor, which is unexpected at the beginning of the original suction section, is erroneously detected as the start of the suction section, and The tracking performance of the power supply supplied to the heat source 80 deteriorates, and the detection accuracy of the suction section can be improved. That is, it is possible to achieve both an improvement in the detection accuracy of the suction section and an improvement in the traceability of the power supply output.

In the first embodiment, the sensor 20 that outputs the capacitance of the capacitor that changes according to the user's pumping operation is used in the detection of the start or end of the suction section. As shown in Fig. 5, the point of view is that the pressure change in the outer casing constituting the air flow path at the initial stage and the end stage of the suction operation is specific, and the pumping can be performed by using a sensor capable of outputting such a pressure change. The reaction of the detection of the suction interval.

In the first embodiment, the sampling period (?ta or Δtc) of the output value output from the sensor 20 is monitored outside the suction section, and the output value output from the sensor 20 is monitored in the suction section. The sampling period (Δtb) is shorter. Thereby, the power required to monitor the output value output from the sensor 20 in the suction section can be reduced while maintaining the tracking of the power supply output to the heat source 80 while maintaining the accuracy of the start of the suction section. . In addition, it should be noted that even if the accuracy of the detection of the end of the suction section is lower than the accuracy of the detection of the beginning of the suction section, there is no problem.

In the first embodiment, the control circuit 50 (suction detecting unit 51) has performed S(n) for m consecutive times (m is an integer of 2 or more) before the start of the suction section. When the condition that all S(n) is a negative value and all the absolute values of S(n) are larger than the first value is satisfied, the start of the suction section is detected. On the other hand, the control circuit 50 (suction detecting unit 51) satisfies the value of S(n) for the consecutive m times of S(n) after the start of the suction section, and In the case where the absolute value of S(n) is larger than the first value, the end of the suction section is detected. Thus, in the case of detecting the beginning or the end of the suction section, the detection accuracy of the suction section can be improved by using successive m times of S(n).

In the first embodiment, the light-emitting element control unit 52 controls the light-emitting element 40 in a non-suction state in which the gas is not sucked, in a second light-emitting state different from the first light-emitting state. Thereby, even in the non-suction state, the user can grasp whether or not the non-combustion type flavor applicator 100 is in a usable state. Further, since the light-emitting state in the suction state is different from the light-emitting state in the non-suction state, it is possible to realize the feeling of use of a general cigarette which is similar to the gas gel produced by the combustion.

In the first embodiment, the second illuminating state changes in accordance with the number of times of suction operation of the absorbing adhesive. Thereby, in the non-suction state in which the light emission of the light-emitting element 40 is easily observed, the user can easily grasp the progress state of the suction in accordance with the change in the second illumination state.

In the first embodiment, the heat source control unit 53 gradually increases the magnitude of the output of the power source supplied to the heat source 80 from the reference power source in accordance with the increase in the number of pumping operations of the suction gas. Thereby, the supply amount of the gas gel can be made close to the general cigarette which generates the gas gel accompanying the combustion, and the feeling of use of the general cigarette can be realized.

In the first embodiment, the heat source control unit 53 arranges the cigarette source 131 closer to the suction side than the holder 60 (the gas gel source), and supplies the cigarette source 131 with the increase in the number of suction operations of the suction gel. The magnitude of the power supply output to the heat source 80 increases stepwise from the magnitude of the reference power supply output. Thereby, the supply of alkaloid can be maintained at a level close to the supply of alkaloids initially pumped.

Specifically, in the constitution in which the gas gel source of the existing electronic cigarette contains the alkaloid, the ratio of the alkaloid contained in the gas gel is fixed. Therefore, in order to use this configuration, the supply amount of the gas gel is made close to that of a general cigarette, and when the magnitude of the power supply output to the heat source 80 is stepwise increased from the reference power source output, it is proportional to the supply amount of the gas gel. Increase the supply of alkaloids.

On the other hand, in the first embodiment, the cigarette source 131 is disposed closer to the mouth side than the holder 60 (the gas gel source). The present inventors have found that the ratio of the alkaloid contained in the gas gel is reduced as the number of times of suction increases. Thereby, since the supply amount of the gas gel is close to that of a general cigarette, when the power supply output to the heat source 80 is stepwise increased from the reference power source output, the supply of the alkaloid can be maintained close to the initial pumping. The level of supply of alkaloids.

In the first embodiment, in the configuration in which the cigarette source 131 is disposed closer to the suction port than the holder 60 (the gas gel source), the heat source control unit 53 increases the number of suction operations associated with the suction gel. Big, but will supply The magnitude of the power supply output to the heat source 80 increases stepwise from the reference power supply output. Thereby, the supply amount of the alkaloid can be maintained at a level close to the supply amount of the alkaloid pumped at the initial stage while the supply amount of the gas gel is close to that of a general cigarette.

In the first embodiment, the heat source control unit 53 controls the first mode and the second mode. The first mode uses the magnitude of the first reference power output as the reference power output, and the second mode uses the first. The size of the second reference power supply output having a larger reference power supply output is used as the reference power supply output. Thereby, the user can select the amount of the gas glue corresponding to the preference of the user by using one non-combustion type flavor extractor 100.

In the first embodiment, by shortening the introduction of the mode, even if the time required for each pumping operation is shorter than the standard required time, the heat source can be used earlier than the standard mode. The temperature of 80 rises to increase the satisfaction of such users. Since it is not affected by the operation mode, the power supply to the heat source is reduced in the interval after the first time or the third time, so that the absorption of the decomposed substance can be suppressed, and the reduction in the smoking flavor can be suppressed.

In the first embodiment, it is only necessary to prepare an operation mode (standard mode and shorten mode) determined in advance, and to control the magnitude of the power supply output to the heat source in accordance with a predetermined operation mode. Thereby, during the energization of the heat source 80, it is not necessary to perform complicated control for continuously controlling the supply amount of such power source output in accordance with the Air flow. In other words, it is possible to achieve a reduction in smoking flavor and a user's fullness with a simple configuration. The increase in foot.

[Modification 1]

Hereinafter, a modification 1 of the first embodiment will be described. Hereinafter, the differences from the first embodiment will be mainly described.

Specifically, in the above-described first embodiment, the heat source control unit 53 controls the magnitude of the power supply output from the power source 10 to the heat source 80 by the control of the voltage applied from the power source 10 to the heat source 80. In detail, the heat source control unit 53 supplies the power source to the heat source 80 by gradually increasing the voltage supplied to the heat source 80 from the reference voltage with an increase in the number of pumping operations of the suction gel. The size of the output is increased stepwise from the magnitude of the reference power output (refer to Figures 8 and 9).

On the other hand, in the first modification, the heat source control unit 53 controls the voltage applied from the power source 10 to the heat source 80 by the energy rate control, and controls the slave power source 10 by controlling the energy ratio of the voltage applied to the heat source 80. The size of the power output supplied to the heat source 80. As shown in Fig. 12, one cycle is defined by the pulse width and the pulse interval, and the energy ratio is expressed by the pulse width / one cycle (here, one cycle = pulse width + pulse interval). Specifically, the heat source control unit 53 increases the energy ratio of the voltage applied to the heat source 80 as the number of suction operations of the suction gas source increases, (see FIG. 12).

Further, in Fig. 12, an example in which the magnitudes of the power supply outputs are increased between the suction state #4 and the suction state #5 is exemplified by emulating the examples shown in Figs. 8 and 9. In Fig. 12, although the suction is omitted State #4 and the suction state other than the suction state #5, but of course, the same effects as those of the examples shown in Figs. 8 and 9 can be obtained by controlling the energy ratio.

[Modification 2]

Hereinafter, a modification 2 of the first embodiment will be described. Hereinafter, the differences from the first embodiment will be mainly described.

Specifically, in the above-described first embodiment, the heat source control unit 53 controls the magnitude of the power supply output from the power source 10 to the heat source 80 by the control of the voltage applied from the power source 10 to the heat source 80. In detail, the heat source control unit 53 supplies the power source to the heat source 80 by gradually increasing the voltage supplied to the heat source 80 from the reference voltage with an increase in the number of pumping operations of the suction gel. The size of the output is increased stepwise from the magnitude of the reference power output (refer to Figures 8 and 9).

On the other hand, in the second modification, the heat source control unit 53 controls the power supply output (the amount of supplied electric power) supplied to the heat source 80 by the control of the maximum period (supply duration) in which the heat source 80 is continuously energized. In detail, the heat source control unit 53 is configured to extend the maximum period (supply duration) in which the heat source 80 is continuously energized from the reference time interval stepwisely as the number of times the suction operation of the suction gel is increased. Figure 13).

In the second modification, when the supply continuation period elapses after the heat source 80 starts to be energized, the energization of the heat source 80 is stopped. Further, even if the energization is stopped, the first light-emitting state of the calender element 40 is maintained while the user continues the suction operation. Thereby, since the power supply output (the amount of supplied electric power) supplied to the heat source 80 changes during each pumping operation, it can be changed. The same effects as the examples shown in Figs. 8 and 9 were obtained.

Further, when the standard mode and the shortening mode described in the first embodiment are introduced, the first time and the second time may be adjusted (extended) in accordance with an increase in the number of suction operations of the suction gel. The third time.

[Modification 3]

Hereinafter, a modification 3 of the first embodiment will be described. Hereinafter, the differences from the first embodiment will be mainly described.

Specifically, in the first embodiment described above, as described in detail in the first embodiment, the control circuit 50 (suction detecting unit 51) is detected before the start of the suction section. S(n) which is continuous m times (m is an integer of 2 or more), satisfies all negative values of S(n), and the absolute value of all S(n) is larger than the first value In the case, the beginning of the suction section is detected. Therefore, even in the case where the user blows air from the mouthpiece portion of the non-combustion type flavor absorbing device 100 toward the inside of the non-combustion type flavor absorbing device 100, it is possible to reduce the erroneous detection of such action as suction. The beginning of the interval.

On the other hand, in the third modification, the means for detecting the inhalation when the user performs the inhalation and notifying the user that the insufflation has been detected is provided.

Specifically, the control circuit 50 (suction detecting unit 51) satisfies all S(n) positive values for S (n) consecutive m times before the start of the suction section. And the absolute value of all S(n) In the case where the value is larger than the first value, the start of the blowing is detected. That is, in Modification 3, the sensor output pattern obtained in the case of performing the air blowing is opposite to the pattern obtained in the case of performing the pumping operation, and the use of this is the opposite. Perform a blow test.

When the air blow is detected in the suction detecting unit 51, the light-emitting element control unit 52 controls the light-emitting element 40 in a light-emitting manner different from the first light-emitting state and the second light-emitting state described above. That is, in the third modification, the light-emitting element 40 is controlled by the light-emitting elements different from the first light-emitting state and the second light-emitting state described above, thereby notifying the user that the blow has been detected.

Further, in the case where the air blowing is detected in the suction detecting unit 51, the heat source control unit 53 does not of course energize the heat source 80 from the power source 10 as in the first embodiment.

[Modification 4]

Hereinafter, a modification 4 of the first embodiment will be described. Hereinafter, the difference from the first embodiment will be mainly described.

In Modification 4, the control circuit 50 (heat source control unit 53) atomizes the heat source 80 (atomization unit) by one time of energization of the heat source 80 (atomization unit) in accordance with the absolute value of the slope. The power supply output to the heat source 80 (atomization unit) is controlled in such a manner that the amount of the gas gel falls within a desired range. In addition, it should be noted that the energization of the heat source 80 (atomization unit) once is the energization corresponding to the suction operation once. Further, the timing of the control method for determining the power output is preferably the detection described in the first embodiment. The timing of the beginning of the pumping interval is the same. Further, it should be noted that in the first embodiment, the sensor 20 that outputs the value of the capacitance of the display capacitor is used. However, the timing of the control method for determining the power output is not limited thereto, and the timing of the start of the suction section may be detected by another method.

Here, in the first embodiment, the output value output from the sensor 20 is a value (for example, a voltage value or a current value) indicating the capacitance of the capacitor. The response value derived from the output value is the output value itself output from the sensor 20. That is, the response value is a value (for example, a voltage value) indicating the capacitance of the capacitor.

On the other hand, in the fourth modification, the output value output from the sensor 20 is not limited to the value of the capacitance of the display capacitor, but may be air that is sucked from the non-suction side toward the suction side (ie, The value of the user's pumping action. In other words, the output value output from the sensor 20 may also be a value (for example, a voltage value or a current value) indicating an environment (for example, a pressure or a flow rate in the casing) that varies according to the user's pumping action. The output value outputted from the sensor 20 may be the value of the environment that changes according to the user's pumping action, or the value obtained by the predetermined conversion of the value. For example, the output value may also be a flow rate value obtained by conversion of the value detected by the sensor 20 (the value of the display pressure). Similarly, the response value derived from the output value may be either the output value itself output from the sensor 20 or a predetermined conversion value (for example, a flow rate value) by the output value output from the sensor 20. .

For example, in the case where the output value is a flow rate value obtained by converting the value of the display pressure, the sensor 20 is based on the time axis The flow rate value is obtained by plotting the amplitude or frequency of the waveform obtained by the value detected by the sensor 20 (the value of the display pressure). Thereby, the sensor 20 can output the flow rate value by a predetermined conversion of the value detected by the sensor 20. Further, in the case of using the condenser microphone sensor described in the first embodiment as the sensor 20, the control circuit 50 is based on the response value as the flow rate value obtained by the conversion of the value of the display pressure. The flow rate value is obtained by plotting the amplitude or frequency of the waveform obtained from the output value (the value of the display pressure) output from the sensor 20 on the time axis. Thereby, the response value (for example, the flow rate value) can be obtained by a predetermined conversion of the output value output from the sensor 20.

First, the control circuit 50 controls the magnitude of the power supply output to the heat source 80 (atomization unit) in such a manner that the amount of the gas gel falls within a desired range.

Further, the magnitude of the power supply output is controlled by the value of the voltage applied to the heat source 80 (the atomizing unit) in the case where the voltage is continuously applied to the heat source 80 (the atomizing unit). On the other hand, the magnitude of the power supply output is based on the value of the voltage applied to the heat source 80 (the atomization unit) and the energy ratio in the case where the voltage is intermittently applied to the heat source 80 (the atomization unit). To control.

In other words, the size of the power supply output to the heat source 80 can be expressed, for example, as P = {(D ₂ × V) ² / R} × D ₁ as described above.

In detail, the control circuit 50 preferably increases the magnitude of the power supply output to the heat source 80 (atomization unit) as the absolute value of the slope is larger. Therefore, under the premise of performing the suction operation with the same suction capacity, it is possible to suppress the inhalation by the user who performs the short and deep suction operation when compared with the user who performs the long and shallow suction operation. The total amount of gas glue is reduced state. In addition, the shallow suction operation refers to a suction operation in which the absolute value of the slope is relatively small, and the deep suction operation refers to a suction operation in which the absolute value of the slope is relatively large.

Alternatively, the control circuit 50 may use a predetermined size as the magnitude of the power supply output to the heat source 80 (atomization unit) when the absolute value of the slope is within a predetermined range of slope. In such an case, the control circuit 50 increases the magnitude of the power supply output to the heat source 80 (atomization unit) more than a predetermined magnitude when the absolute value of the slope is larger than a predetermined range. Thereby, it is possible to suppress a situation in which the total amount of the gas gel sucked by the user who performs the short and deep suction operation is reduced as compared with the user who performs the standard pumping operation. On the other hand, the control circuit 50 may also reduce the magnitude of the power supply output to the heat source 80 (atomization unit) to a predetermined size when the absolute value of the slope is smaller than the slope of the predetermined range. Thereby, it is possible to suppress a situation in which the total amount of the gas gel sucked by the user who performs the long and shallow suction operation is reduced as compared with the user who performs the standard pumping operation.

Second, the control circuit 50 stops in the heat source 80 (atomization unit) when the heat source 80 (atomization unit) is energized and the supply duration is passed, in a manner that the amount of the gas gel falls within a desired range. Power on. The duration of supply is preferably below the upper limit of the standard pumping interval derived from the statistics of the user's pumping interval.

For example, the supply duration is 1 second or longer and 3 seconds or shorter. When the supply duration is 1 second or longer, the energization time of the heat source 80 (atomization unit) does not become too short compared to the suction period, and the sense of discomfort given to the user can be alleviated. On the other hand, by setting the supply duration to 3 seconds or less, the energization time for the heat source 80 (atomization unit) can be fixed to the supply. The suction operation for the duration is set to be a fixed number or more.

Furthermore, the predetermined period may be 1.5 seconds or more and 2.5 seconds or less. Thereby, the sense of discomfort given to the user can be further alleviated, and the suction operation for fixing the energization time of the heat source 80 (atomization unit) to the supply duration can be increased.

In addition, the standard suction section means that it can be derived from the statistics of the user's suction section, and is the lower limit value in the suction section of the plurality of users and the upper part of the suction section of the plurality of users. The interval between the limits. The lower limit value and the upper limit value are based on the distribution of the user's suction interval data, and for example, the lower limit value and the upper limit value of the 95% reliability interval as the average value can be derived, and can be derived as m±n σ ( Here, m is an average value, σ is a standard deviation, and n is a positive real number). For example, as long as it is a suction section of the user, it can be regarded as an example of a normal distribution in which the average value m is 2.4 seconds and the standard deviation σ is 1 second, and the upper limit of the standard suction interval can be derived as described above. m+n σ, and is about 3 seconds to 4 seconds.

In detail, the control circuit 50 is preferably controlled to control the magnitude of the above-described power output, and it is preferable that the larger the absolute value of the slope, the shorter the supply duration. Thereby, it is possible to suppress a situation in which the total amount of the gas gel sucked by the user who performs the deep suction operation (especially, the long and deep suction operation) is excessively increased.

Alternatively, the control circuit 50 may use a predetermined duration as the supply duration when the absolute value of the slope is within a predetermined range in addition to the control for controlling the magnitude of the power output described above. In such an case, the control circuit 50 preferably has an absolute value of the slope greater than a predetermined range. The supply duration is shortened compared to the predetermined duration. Thereby, when compared with the user who performs the standard pumping operation, it is possible to suppress the excess amount of the gas gel sucked by the user who performs the deeper pumping action (especially the long and deep pumping action). The situation of increasing ground. On the other hand, the control circuit 50 preferably uses the predetermined duration as the supply duration when the absolute value of the slope is smaller than the predetermined range without shortening the supply duration.

For example, as shown in Fig. 14, the suction operation C and the suction operation D in which the response values (here, the flow rate values) are different are described as an example. The suction operation C is a short and deep suction operation compared to the suction operation D. Here, the suction operation C is an example of a short and deep suction operation compared to a standard suction operation, and the suction operation D is a long and shallow suction operation compared to a standard suction operation. An example. In other words, the absolute value of the slope corresponding to the pumping action C is larger than the predetermined range, and the absolute value of the slope corresponding to the pumping action D is smaller than the predetermined range.

Here, the capacity (absorption capacity) of the air sucked by the suction operation C is the same as the capacity (absorption capacity) of the air sucked by the suction operation D. However, it should be noted that when it is assumed that the magnitude of the power output for the heat source 80 (atomization portion) between the suction action C and the suction action D is fixed, the suction interval of the suction action C is higher than that of the suction. The suction section of the suction action D is shorter, so the total amount of the gas glue sucked by the suction action C is less than the total amount of the gas glue sucked by the suction action D.

In such an case, the control circuit 50 is such that the magnitude of the power supply output to the heat source 80 (atomizing portion) in the pumping action C becomes higher than the power source output of the heat source 80 (atomizing portion) in the pumping action D. Larger size In this manner, the magnitude of the power output for the heat source 80 (atomization unit) is controlled. Moreover, the control circuit 50 can also make the supply duration used in the pumping action C shorter than the supply duration used in the pumping action D, in addition to controlling the magnitude of the power output. Control the duration of supply.

Or, for the pumping action C, since the control circuit 50 is in the timing SP2, the absolute value of the slope is larger than the predetermined range, so that the magnitude of the power output supplied to the heat source 80 (atomizing unit) is larger than a predetermined size. Increase. Further, the control circuit 50 preferably shortens the supply duration from the predetermined duration in addition to the control for controlling the magnitude of the power output. On the other hand, with respect to the pumping operation D, since the control circuit 50 is at the timing SP2, the absolute value of the slope is smaller than the predetermined range, the supply duration is not shortened, but the predetermined duration is used as the supply duration. For the pumping action D, the control circuit 50 can also reduce the magnitude of the power output to the heat source 80 (atomizing portion) by a predetermined amount.

In the fourth modification, it should be noted that the control circuit 50 stops the heat source 80 (the atomization unit) even when the suction operation is continued after the supply of the heat source 80 (the atomization unit) is started. ) Power on. In such an example, the control circuit 50 preferably continues to control the light-emitting element 40 in the first light-emitting state even when the suction operation of the suction gas source is continued after the heat source 80 is stopped. Thereby, the uncomfortable feeling that the light-emitting pattern of the light-emitting element 40 is changed can be reduced regardless of whether or not the suction operation is performed.

Further, in the modification 4, attention is paid to the suction of one time. Work. However, the modification 4 is as shown in FIGS. 8 and 9 , and as the number of times of the pumping operation increases, it is also suitable for increasing the magnitude of the output of the power source supplied to the heat source 80 from the magnitude of the output of the reference power source. Big case. In such an case, it is also conceivable to set the desired range stepwise in accordance with the number of times of the pumping action. For example, in the examples shown in Figs. 8 and 9, the desired range of the suction state #5 may be larger than the desired range of the suction state #1.

(function and efficacy)

In Modification 4, the control circuit 50 controls the magnitude of the power supply output to the heat source 80 (atomization unit) in accordance with the absolute value of the slope so that the amount of the gas gel falls within a desired range. That is, according to the absolute value of the slope, the suction operation is estimated for each suction operation, whereby the total amount of the gas glue sucked by the user in each suction operation can be appropriately and quickly controlled. the amount.

In Modification 4, the larger the absolute value of the slope of the control circuit 50, the larger the magnitude of the power supply output supplied to the heat source 80 (atomization unit). Thereby, it is possible to suppress a situation in which the total amount of the gas gel sucked by the user who performs the short and deep suction operation is reduced as compared with the user who performs the long and shallow suction operation.

In Modification 4, the control circuit 50 increases the heat source 80 (the magnitude of the power supply output to the atomizing portion) more than a predetermined value when the absolute value of the slope is larger than the slope of the predetermined range. Thereby, in the case of comparison with the user who performs the standard pumping operation, it is possible to suppress the decrease in the total amount of the gas gel sucked by the user who performs the short and deep pumping operation. state.

In Modification 4, the larger the absolute value of the slope, the shorter the supply duration. Thereby, it is possible to suppress a situation in which the total amount of the gas gel sucked by the user who performs the deeper pumping operation (especially, the long and deep pumping operation) excessively increases.

In Modification 4, when the absolute value of the slope of the control circuit 50 is larger than the predetermined range, the supply duration is shortened more than the predetermined duration. Thereby, it is possible to suppress an excessive amount of the gas gel sucked by the user who performs the deeper pumping action (especially the long and deep pumping action) when compared with the user who performs the standard pumping action. The situation of increasing ground.

[Modification 5]

Hereinafter, a modification 5 of the first embodiment will be described. Hereinafter, the difference from the modification 4 will be mainly described.

In Modification 5, the relationship between the magnitude of the power supply output to the heat source 80 (atomization unit) and the supply duration will be described. Here, in order to clarify the description, the suction operation is classified into the first suction operation (Normal) and the second suction operation (Boost) based on the absolute value of the slope, and examples of the relative relationship between the suction operation are listed. Further, the size of the power supply output to the heat source 80 can be expressed by P = {(D ₂ × V) ² / R} × D ₁ . The first pumping operation has a pumping operation of the first slope absolute value, and the second pumping operation has a pumping operation of the second slope absolute value which is larger than the first slope absolute value.

In such an example, the control circuit 50 increases the magnitude of the power supply output to the heat source 80 and shortens the supply duration for the second pumping operation as compared with the first pumping operation. For example, the magnitude of the power output of the first pumping operation is represented by PX ₁ , the duration of the supply of the first pumping operation is represented by TX ₁ , and the magnitude of the power output of the second pumping operation is represented by PX ₂ . 2 The duration of supply of the pumping action is indicated by TX ₂ .

Fig. 15 is a view showing the relationship between the magnitude of the power supply output and the time for the first pumping operation and the second pumping operation, and Fig. 16 shows the amount of power supplied for the first pumping operation and the second pumping operation. A diagram of the relationship with time. As shown in Fig. 15 and Fig. 16, PX ₁ and TX ₁ of the first pumping operation are set such that the amount of supplied electric power (here, E ₁ = PX ₁ × TX ₁ ) satisfies the target electric power amount (E _Target ). . Similarly, PX operation of the second suction line ₂ and the TX ₂ is set so that the supply power _{(here, E 2 = PX 2 × TX} 2) satisfy the target power (E _Target). In other words, the relationship between PX ₁ × TX ₁ = PX ₂ × TX ₂ = E _Target is satisfied for the first pumping operation and the second pumping operation. However, PX ₁ and TX ₁ of the first pumping operation are used as reference values and are memorized in advance by the control circuit 50. Thus, when determining the operation of the second suction PX _2, according to the _{TX 2 = (PX 1 / PX} 2) × TX of Formula _1, to determine the operation of the second suction TX _2.

Here, the PX ₂ of the second pumping operation is determined based on the second slope absolute value. The PX _{2 of} the second pumping operation may be determined based on the function that the absolute value of the second slope is larger and the magnitude of the power output is increased. Alternatively, the PX _{2 of} the second pumping operation may correspond to the second slope absolute value. For example, when the absolute value of the slope does not reach the threshold A, and the magnitude of the power output is PX ₁ , when the absolute value of the slope is above the threshold A and the threshold B is not reached, the magnitude of the power output is PX _2-1 , and when the absolute value of the slope is above the threshold B, the power output can also be larger than the PX _2-1 PX _2-2 . Here, although the magnitudes of the two-stage power supply output (PX _2-1 and PX _2-2 ) are exemplified, the PX _{2 of} the second pumping operation may be classified into three or more stages depending on the absolute value of the slope.

Here, the value obtained by the increase rate (PX ₂ /PX ₁ ) of the magnitude of the power output of the first pumping operation with respect to the first pumping operation is preferably larger than 1 and equal to or less than 3. Further, the value obtained by the increase rate (PX ₂ /PX ₁ ) may be larger than 1 and 2 or less. On the other hand, the value obtained by the second pumping operation with respect to the shortening rate (TX ₂ /TX ₁ ) of the supply duration of the first pumping operation is preferably 1/3 or more and less than 1. Furthermore, the value obtained by the shortening rate (TX ₂ /TX ₁ ) is preferably 1/2 or more and is less than 1.

Further, even if PX ₂ can be changed to n (n is an integer of 3 or more) depending on the absolute value of the second slope, the value obtained by PX ₂ ({PX _2-1 , PX _2-2 , ‧‧‧ , PX _2-n }) is preferably larger than 1, and is 3 or less. On the other hand, even when the slope of the TX ₂ according to the second absolute value may be changed to n (n is an integer of 3 or more) of the above type, the obtained value of the TX _{2 ({TX 2-1, TX 2-2,} ‧ ‧‧, TX _2-n }) is preferably 1/3 or more and does not reach 1.

In Figure 15 and 16 in FIG supplied to the power output of the heat source 80 to the size of the system ^{_{{(D 2 × V) 2}} / R} × D 1 is represented. The size of the output power can be controlled by D _1, D ₂ can also be controlled by.

Further, in Modification 5, attention was paid to the suction operation once. However, the modified example 5 can be applied to the magnitude of the output of the power source of the heat source 80 from the reference power source as the number of times of the pumping operation increases as shown in Figs. 8 and 9. Increase the case. In so cases, it may also consider setting a target electric power (E _Target) increased stepwise according to the number of pumping action. For example, in the second case shown in FIG. 8 of FIG. 9, the suction state # 5 the target power (E _Target) than can suction the target power state # 1 (E _Target) greater.

[Modification 6]

Hereinafter, a modification 6 of the first embodiment will be described. Hereinafter, the difference from the modification 5 will be mainly described.

Specifically, in the fifth modification example, the case where the size PX ₂ of the power source output of the second pumping operation is fixed by one energization (suction operation) is fixed. On the other hand, in the sixth modification, the case where the size PX ₂ of the power supply output of the second pumping operation is variable in the first energization (suction operation) is exemplified.

In the sixth modification, the longer the elapsed time (in other words, the elapsed pumping time) elapsed after the control circuit 50 starts energizing the heat source 80 (the atomizing unit) in the energization (suction operation). The smaller the size of the power output of the heat source 80, PX _{2 , is} reduced.

As shown in FIG. 17, the suction power output with respect to the elapsed time of the size of the heat source 80 may also be based on stepwise PX ₂ (discontinuity) reduced. In the example shown in Fig. 17, the case where the size PX _{2 of the} power supply output is changed in two stages is exemplified, but the modification 6 is not limited thereto, and the size PX _{2 of the} power supply output can be performed in three stages or more. change. Further, the magnitude of the power output PX ₂ is set such that when the supply duration (here, TX ₁ ) is passed, the amount of supplied power is set to reach the target amount of power (E _Target ).

Alternatively, as shown in Fig. 18, the size PX ₂ of the power supply output to the heat source 80 may be continuously reduced in accordance with the elapsed pumping time. Further, the power output output size PX ₂ is set such that the supplied power amount reaches the target power amount (E _Target ) when the supply duration (here, TX ₁ ) elapses.

In this way, the amount of supplied power reaches the target power amount (E _Target ) due to the passage of TX ₁ longer than TX _{2, and the} longer the pumping time elapses, the smaller the size PX ₂ of the power supply output to the heat source 80 is reduced. This is compared with the modification 5 (Fig. 15 and Fig. 16) to obtain the effects shown below. Here, in the case where the user performs the second suction operation (Boost) in which the absolute value of the slope is the absolute value of the second slope, the case where the suction time of the user is longer than the TX ₂ can be considered.

In such an example, in the modification 5, when the suction time exceeds the TX ₂ , the energization of the heat source 80 is stopped. On the other hand, in the sixth modification, since the energization of the heat source 80 continues until the suction time reaches the TX ₁ longer than the TX ₂ , even the user who performs the deep suction operation occasionally performs the ratio TX. _When the suction operation is long, the energization time of the heat source 80 (atomization unit) is not too short compared to the suction section, and the discomfort to the user is alleviated.

Change in Example 6, although the second mentioned suction operation (the Boost) the size of the output power PX ₂ will be described as an example, but not limited to modification 6. The longer the suction time that the control circuit 50 passes, the smaller the size PX ₁ of the power supply output to the heat source 80 in the first suction operation (Normal) is reduced. Even in this case, of course, the size PX _{1 of the} power supply output can be controlled in such a manner that the amount of supplied electric power at the time of reaching the supply duration reaches the target electric power amount (E _Target ).

[Modification 7]

Hereinafter, a modification 7 of the first embodiment will be described. Hereinafter, the difference between the fifth modification will be mainly described.

Specifically, in Modification 7, the control circuit 50 determines the magnitude of the power supply output to the heat source 80 (atomization unit) based on the absolute value of the slope, and the learning result according to the required time of the user's pumping action. To determine the duration of supply.

For example, the control circuit 50 memorizes a plurality of required time samples according to the learning of the required time of the user's pumping action, and derives a representative value of the plurality of samples of the required time samples, and determines the supply continuity according to the representative value. period. In the case of representative values, the average, median or mode of sampling for a plurality of required times may be employed.

For example, the second pumping operation (Boost) described in the fifth modification will be described as an example. As described above, the second pumping operation is a pumping operation having a second slope absolute value larger than the absolute value of the first slope. Furthermore, it is assumed that the representative value sampled by the time required for learning is longer than the TX ₂ described above and is shorter than the TX ₁ described above.

In this case, as shown in Fig. 19, the supply duration is corrected to TX _L (TX ₂ <TX _L <TX ₁ ), and the power output output size PX _L is corrected to be the target power supply amount when TX _L passes. Power consumption (E _Target ).

For example, the magnitude of the power output can be corrected from PX ₂ to PX _L (PX ₁ <PX _L <PX ₂ ) (refer to the pumping action (Boost_L) in Fig. 19).

Alternatively, the control circuit 50 may determine the magnitude of the power output based on the absolute value of the slope. Specifically, the control circuit 50 can also determine the magnitude of the power output by increasing the absolute value of the slope and increasing the amount of power supplied earlier than the pumping operation (Boost_L) (refer to the pumping operation of FIG. 19). (Boost_L1 and Boost_L2)). In this kind of case, the power output of the system and the size of the change in the same manner in Example 6, a suction time can also be set to TX _L when supply of electric power through the electric power reaches the target (E _Target), and the longer the elapsed reduction . For example, the control circuit 50 applies the magnitude of the power output of the pumping action (Boost_L) when the absolute value of the slope does not reach the threshold value X. When the absolute value of the slope is above the threshold X and does not reach the threshold value Y, The magnitude of the power output of the pumping action (Boost_L1) is applied. When the absolute value of the slope is above the threshold Y, the magnitude of the power output of the pumping action (Boost_L2) is applied.

In the example shown in Fig. 19, the case where the magnitude (stage discontinuity) of the power output of the pumping operation (Boost_L1) and the pumping operation (Boost_L2) is reduced is illustrated, but the pumping operation (Boost_L1) and pumping are performed. The size of the power output of the suction action (Boost_L2) can also be continuously reduced.

Further, in Fig. 19, although the case where the representative value of the required time sampling is larger than the above-described TX ₂ is exemplified, the case where the representative value of the required time sampling is smaller than the above-described TX ₂ can be similarly controlled. .

[Other Embodiments]

The present invention has been described by way of example only, and is not to be construed as limiting the invention. Those having ordinary knowledge in the technical field to which the invention pertains can Various alternative embodiments, examples, and techniques of operation are apparent.

In the embodiment, the cigarette source 131 is exemplified as a flavor source. However, the embodiment is not limited to this. The source of flavor may also not contain cigarette material. Further, the non-combustion type flavor extractor 100 may not have a flavor source, but may impart a flavor taste component to the gas gel source.

In the embodiment, an example in which the non-combustion type flavor applicator 100 has the capsule unit 130 is exemplified. However, the embodiment is not limited to this. For example, the non-combustion type flavor extractor 100 may have a cartridge containing a flavor source.

In the embodiment, the following example is exemplified: the suction detecting unit 51 has a negative sign formed by the response value of two or more outputs output from the sensor 20, and has an absolute slope of a negative sign. In the case where the value is larger than the predetermined value, the start or end of the suction section is detected. However, the embodiment is not limited to this. Specifically, the suction detecting unit 51 may have a positive sign on the slope formed by the response value of 2 or more outputted from the sensor 20, and the absolute value of the slope having the positive sign is larger than the predetermined value. At the beginning, the beginning or end of the suction section is detected. In this case, the expression "negative" of the embodiment may be replaced by "positive". It should be noted that which of "positive" and "negative" should be utilized depends on the type of sensor 20, etc., that is, the output pattern of the sensor 20 corresponding to the user's pumping action.

Although not specifically mentioned in the embodiment, the button 30 constitutes a switching member for starting and stopping the supply of electric power to the control circuit 50 and the sensor 20 from the power source 10. Stopped by pressing button 30 Since the power supply to the sensor 20 is stopped, the power consumption can be reduced.

Although not specifically described in the embodiment, an example in which the output value monitored in the sampling period Δta does not change over a predetermined period (for example, 200 msec to 500 msec) before the start of the suction section can be detected. In the middle, the sensor 20 is set to be off. Thereby, power saving can be achieved. Moreover, in such an example, it is preferable to turn on the sensor 20 when a predetermined time (for example, 50 msec) elapses after the sensor 20 is turned off. Thereby, it is possible to ensure the traceability of the magnitude of the power supply output to the heat source 80 while achieving power saving. In addition, it should be noted that the sensor 20 is continuously turned on when the response value monitored by the sampling period Δta changes. Further, the sensor 20 may be turned on/off in synchronization with the calculation periods of the sampling periods (Δt) and S(n) as a behavior different from the on/off of the sensor 20.

Although not specifically described in the embodiment, since the cigarette source 131 is held in the capsule unit 130, it is also possible to add 10 times the weight of the cigarette material contained in the cigarette source 131 to each capsule unit 130. The pH of the aqueous solution. In this case, the gradient of the magnitude of the power supply output to the heat source 80 may be changed in accordance with the type of the capsule unit 130 as the number of pumping operations increases.

Although not specifically described in the embodiment, the number of times of the pumping operation may be corrected in accordance with a value (amount of gas gel production) defined by the magnitude of the power source output of the heat source 80 in each pumping operation. . Specifically, in the case where the amount of gas gel generated in each of the pumping operations is less than a predetermined value, the addition coefficient α (α<1) may be multiplied by 1 The resulting value is used to accumulate the number of pumping actions. On the other hand, in the case where the amount of the gas gel generated in each of the pumping operations is larger than the predetermined value, the value obtained by multiplying the predetermined coefficient β (β>1) by one time may be added. The number of cumulative pumping actions. That is, the number of pumping actions may not necessarily be an integer.

Although not specifically described in the embodiment, in the control of the magnitude of the power output of the pumping operation series, the timing of increasing the magnitude of the power supply output to the heat source 80 is preferably changed from the second illumination state. Timing synchronization. For example, as shown in FIGS. 8 to 9, when the magnitude of the power supply output (voltage) for the heat source 80 is increased between the suction state #4 and the suction state #5, it is preferably in the suction state # The second illumination pattern is changed between 4 and the suction state #5.

Although not particularly mentioned in the embodiment, it is preferable that as shown in FIGS. 10 and 11 , a voltage smaller than the standard voltage is applied in the interval after the first time T1 or the third time T3 has elapsed. At the heat source 80, even in such a range, the first illuminating state can be continued.

In the embodiment, the first mode and the second mode are used. The first mode uses the magnitude of the first reference power output as the reference power output (the Low mode shown in FIG. 8), and the second mode. The magnitude of the second reference power supply output larger than the magnitude of the first reference power supply output is used as the magnitude of the reference power supply output (High mode shown in FIG. 9). In such an case, the illuminating aspect of the first mode may be different from the illuminating aspect of the second mode. In other words, the first illuminating state, the second illuminating state, and the ending illuminating state in the first mode may be the first in the second mode. The illuminating state, the second illuminating state, and the ending illuminating state are different.

Although not specifically described in the embodiment, a program for causing a computer to execute each process performed by the non-combustion type flavor extractor 100 may be provided. Also, the program can be recorded on a computer readable medium. As long as you use the computer-readable media, you can install the program on your computer. Here, the computer-readable media on which the program is recorded may also be a non-transitory recording medium. Although the non-transitory recording medium is not particularly limited, it may be, for example, a recording medium such as a CD-ROM or a DVD-ROM.

Alternatively, a chip composed of a memory and a processor that memorizes a memory for executing a program of each processing performed by the non-combustion type flavor extractor 100 may be provided. The processor executes a program that is stored in the memory.

In addition, the entire contents of Japanese Patent Application No. 2014-095164 (filed on May 2, 2014) are incorporated herein by reference.

[Industrial availability]

According to the embodiment, it is possible to provide a non-combustion type flavor extractor capable of appropriately and promptly controlling the total amount of the gas gel sucked by the user during each suction operation.

10‧‧‧Power supply

20‧‧‧ sensor

30‧‧‧ button

40‧‧‧Lighting elements

50‧‧‧Control circuit

100‧‧‧Non-burning fragrance applicator

110‧‧‧Electrical unit

111‧‧‧Female connector

120‧‧‧Atomization unit

121‧‧‧ Male connector

A‧‧‧Predetermined direction

Claims (12)

A non-combustion type flavor extracting device comprising: an outer casing having an air flow path continuously from the air inlet to the exhaust port; and an atomizing unit for atomizing the gas glue source without accompanying combustion; the sensor, Outputting a value that varies according to a user's pumping action; and a control unit that causes the gas gel to fall according to an absolute value of a slope formed by a response value of two or more derived from a value output from the sensor The power output to the atomizing unit is controlled in a desired range, wherein the amount of the gas gel is the amount of the gas gel atomized by the atomizing unit in one energization of the atomizing unit. The non-combustion type flavor absorbing device according to claim 1, wherein the control unit controls the foregoing in a manner that the gas gel amount falls within the desired range in accordance with an absolute value of the slope The size of the power output of the atomizing section. The non-combustion type flavor applicator according to claim 2, wherein the control unit increases the magnitude of the power output of the atomizing unit as the absolute value of the slope is larger. The non-combustion type flavor absorbing device according to claim 2, wherein the control unit uses a predetermined size as a power output for the atomizing unit when the absolute value of the slope is within a predetermined range. The size of the control unit is such that when the absolute value of the slope is larger than the predetermined range, the magnitude of the power output to the atomizing unit is larger than the foregoing The predetermined size is increased. The non-combustion type flavor absorber according to claim 3, wherein the increase rate of the power output of the atomizing unit is greater than 1 and not more than 3. The non-combustion type flavor absorbing device according to any one of the preceding claims, wherein the control unit is configured to cause the amount of the gas gel to fall within the desired range. When the supply period continues after the atomization unit is energized, the energization of the atomization unit is stopped, and the supply duration is below the upper limit of the standard suction period derived from the statistics of the suction period of the user. . The non-combustion type flavor absorbing device according to the sixth aspect of the invention, wherein the control unit is configured to shorten the supply duration while the absolute value of the slope is larger. The non-combustion type flavor absorber according to claim 6, wherein the control unit uses the predetermined duration as the supply duration when the absolute value of the slope is within the predetermined range; the control unit When the absolute value of the aforementioned slope is larger than the predetermined range, the supply duration is shortened to be shorter than the predetermined duration. The non-combustion type flavor extractor according to Item 7 or Item 8, wherein the shortening rate of the supply duration is 1/3 or more and less than 1. The non-combustion type flavor aspirator according to any one of the sixth aspect, wherein the absolute value of the slope is the first suction operation of the first slope absolute value, The magnitude of the power output of the atomizing unit is represented by PX ₁ , and the supply duration is represented by TX ₁ , and the second pumping operation is performed when the absolute value of the slope is greater than the absolute value of the second slope. The magnitude of the power output of the atomizing unit is represented by PX ₂ , the supply duration is represented by TX ₂ , and the TX ₂ is calculated based on the formula of TX ₂ = (PX ₁ / PX ₂ ) × TX ₁ . . The non-combustion-type flavor absorbing device according to any one of the preceding claims, wherein the control unit starts the atomization unit when the atomization unit is energized once. The longer the elapsed time after the energization is performed, the smaller the size of the power supply output to the atomizing unit is. The non-combustion type flavor absorber according to any one of the preceding claims, wherein the control unit is configured to cause the amount of the gas gel to fall within the desired range. When the supply period continues after the atomization unit is energized, the energization of the atomization unit is stopped, and the control unit determines the supply duration based on the learning result of the required time of the user's pumping operation.