RU2797153C1 - Inhalation device, information processing performed by an inhalation device, and information carrier - Google Patents

Abstract

FIELD: medical devices.

SUBSTANCE: group of inventions relates to an inhalation device, a method of information processing performed by an inhalation device, and an information carrier. An inhalation device for generating, by heating a substrate, an aerosol for inhalation by a user, wherein the inhalation device comprises a heater inserted inside the substrate placed in an internal volume formed in the inhalation device and heating the substrate. The inhalation device also includes a compressor that compresses the area of the substrate heated by the heater in the direction from the peripheral region of the substrate to the heater, and a controller that triggers the heating performed by the heater or the compression performed by the compressor based on triggering another of these operations.

EFFECT: improving the quality of aspiration for the user.

18 cl, 13 dwg, 4 tbl

Description

The field of technology to which the invention belongs

[0001] The present invention relates to an inhalation device, an information processing method, and a program.

State of the art

[0002] Inhalation devices such as electronic cigarettes and nebulizers that produce a substance intended to be inhaled by the user have become widespread. For example, an inhalation device generates a flavor aerosol using a substrate containing an aerosol source for generating the aerosol, a flavoring agent for incorporating flavor components into the generated aerosol, and the like. The user can experience the taste by inhaling the flavored aerosol produced by the inhalation device.

[0003] In order to improve the quality of inhalation, various designs of inhalation devices have been studied. For example, Patent Literature 1 below describes an inhalation device that produces an aerosol by heating a stick-shaped substrate inserted into the inhalation device through an inlet provided in the device, the inhalation device being designed to compress the substrate stick by narrowing of the inlet.

References Patent Literature

[0004] Patent Literature 1: International Publication No. 2019/081602

The essence of the invention

Technical problem

[0005] However, the technologies described in Patent Literature 1 are designed to optimize the position of a substrate stick inserted into the interior of an inhalation device through an inlet, so it is difficult to judge whether these technologies directly result in improved inhalation quality.

[0006] The present invention addresses the above problem and provides a mechanism capable of improving the quality of inhalation.

Solution

[0007] In order to solve the above problem, in accordance with one aspect of the present invention, an inhalation device is provided that produces an aerosol for inhalation by a user by heating a substrate. The inhalation device contains a heater that is inserted inside the substrate placed in the internal volume formed in the inhalation device and heats the substrate, a compressor that compresses the area of the substrate heated by the heater in the direction from the peripheral region of the substrate to the heater, and a controller that initiates heating, performed by the heater, or compression performed by the decompressor based on the initiation of another of these operations.

[0008] The controller may synchronize or substantially synchronize the start time of the heating performed by the heater and the start time of the compression performed by the compressor.

[0009] The compressor can compress the substrate by moving towards the heater.

[0010] The cross section of the end surface of the compressor in the direction of the heater may be convex.

[0011] The cross section of the end surface of the compressor in the direction of the heater may be in the form of a convex arc.

[0012] The cross section of the end surface of the compressor in the direction of the heater may be in the form of a convex arc with a radius of 1 mm and a width of 2 mm.

[0013] The cross section of the end surface of the compressor in the direction of the heater may be concave.

[0014] The cross section of the end surface of the compressor in the direction of the heater may be in the form of a concave arc.

[0015] The cross section of the end surface of the compressor in the direction of the heater may be in the form of a concave arc with a radius of 3 mm and a width of 5 mm.

[0016] The cross section of the end surface of the compressor in the direction of the heater may be in the form of a concave arc with a radius of 2.5 mm and a width of 5 mm.

[0017] The outer diameter of the substrate may be 7.1 mm, and the distance that the end surface of the depressurizer advances after contact with the peripheral region of the substrate during compression by the depressurizer may be 1 mm or less.

[0018] The inhalation device may include three compressors that can compress the substrate from three different directions.

[0019] The compressor may be made from a heat resistant material.

[0020] The controller may set the time from the start to the end of the compression performed by the compressor to 70 seconds or less.

[0021] The controller may set the time from start to stop of the compression performed by the decompressor to 10 seconds or less.

[0022] Depending on the number of breaths of the aerosol by the user, the controller may adjust the time when the compression performed by the depressurizer stops.

[0023] In addition, in order to solve the above problem, another aspect of the present invention provides an information processing method carried out by an inhalation device that, by heating a substrate, produces an aerosol for inhalation by a user, and includes a heater that is inserted inside the substrate placed in an internal volume formed in the inhalation device and which heats the substrate, as well as a compressor which compresses the area of the substrate heated by the heater in the direction from the peripheral area of the substrate to the heater. The information processing method includes initiating heating performed by a heater or compressing performed by a compressor based on the initiation of another of these operations.

[0024] In addition, in order to solve the above problem, another aspect of the present invention provides a program for a computer that controls an inhalation device that, by heating a substrate, produces an aerosol for inhalation by a user and includes a heater that is inserted inside the substrate placed in an internal volume formed in the inhalation device and which heats the substrate, as well as a compressor which compresses the area of the substrate heated by the heater in the direction from the peripheral area of the substrate to the heater. This program allows the computer to function as a controller that initiates the heating performed by the heater or the compression performed by the decompressor based on the initiation of the other of these operations.

Benefits of the Invention

[0025] As described above, the present invention proposes a mechanism to improve the quality of inhalation.

Brief description of the drawings

[0026]

In FIG. 1 is a diagram illustrating an example configuration of an inhalation device.

In FIG. 2 is an exploded perspective view of an inhalation device according to an embodiment.

In FIG. 3 shows an example of a cross section of an inhalation device along the insertion/removal direction according to an embodiment.

In FIG. 4 shows an example of a cross section of an inhalation device in a released state perpendicular to the insertion/removal direction according to an embodiment.

In FIG. 5 shows an example of a cross section of an inhalation device in a state of compression perpendicular to the insertion/removal direction according to an embodiment.

In FIG. 6 shows an example of a cross section of one of the depressors perpendicular to the insertion/removal direction according to an embodiment.

In FIG. 7 shows another example of a cross section of one of the depressors perpendicular to the insertion/removal direction according to an embodiment.

In FIG. 8 is a graph illustrating the results of experiments with an inhalation device according to an embodiment.

In FIG. 9 is a graph illustrating the results of experiments with an inhalation device according to an embodiment.

In FIG. 10 is a graph illustrating the results of experiments with an inhalation device according to an embodiment.

In FIG. 11 is a graph illustrating the results of experiments with an inhalation device according to an embodiment.

In FIG. 12 is a chart showing the results of Table 4 in graphical form.

In FIG. 13 is an example flowchart of a process performed by an inhalation device according to an embodiment.

Description of embodiments of the invention

[0027] The preferred embodiment of the invention will now be described in detail with reference to the accompanying drawings. Elements of construction, the functional configurations of which are essentially the same, are denoted in this document and in the accompanying drawings by the same reference numbers and are not described again.

[0028] In addition, elements having essentially the same functional configurations can be distinguished from each other by different letter designations added to the same reference numbers in this document and in the accompanying drawings. For example, a plurality of elements having substantially the same functional configurations differ from each other as needed, such as compressors 160A and 160B. If a plurality of elements having substantially the same functional configurations need not be distinguished from each other, then only the same reference numbers are given. If, for example, in a particular case it is not necessary to distinguish between depressors 160A and 160B, these structural elements will simply be referred to as depressors 160.

[0029] 1. Inhalation device configuration example

An inhalation device according to an embodiment produces a substance to be inhaled by a user by heating the contents contained in the substrate. Specifically, the inhalation device according to the embodiment generates an aerosol by heating a substrate containing an aerosol source inside. An aerosol is an example of a substance intended to be inhaled by a user. The aerosol source is an example of the content contained in the substrate. Alternatively, the substance produced by the inhalation device may be a gas. The inhalation by the user of the substance produced by the inhalation device will hereinafter be simply referred to as "inhalation" or "puff". Next, all configuration examples of the inhalation device will be described. A configuration example of the inhalation device according to the embodiment will be described below with reference to FIG. 1.

[0030] FIG. 1 is a block diagram illustrating an example configuration of an inhalation device. As shown in FIG. 1, the inhalation device 100 according to the present configuration example includes a power supply 111, a sensor 112, an alarm 113, a memory 114, a communication module 115, a controller 116, a heater 121, depressors 160, and a holder 140. The user inhales in a state where the substrate stick 150 is held. holder 140. Next, the respective structural elements will be described in turn.

[0031] The power supply 111 stores electrical energy. The power supply 111 then supplies power to the respective structural elements of the inhalation device 100. The power supply 111 may be, for example, a rechargeable battery, such as a secondary lithium ion battery. The power supply 111 can be charged by connecting to an external power source using a USB (Universal Serial Bus) cable or the like. Alternatively, the power supply 111 may be charged using wireless power transmission technology in a state where the power supply 111 is not physically connected to the power transmission device. In addition, the power supply 111 may be configured to be the only component that can be detached from the inhalation device 100 in order to be replaced by a new power supply 111.

[0032] The sensor 112 detects various kinds of information related to the inhalation device 100. The sensor 112 then transmits the detected information to the controller 116. In particular, the sensor 112 may be a pressure sensor, such as a condenser microphone. Then, if the sensor 112 detects the negative pressure that occurs when the user inhales, the sensor 112 provides information to the controller 116 that the user has taken a breath. Alternatively, sensor 112 may be an input device that receives input from a user, such as with a button or switch. In particular, the sensor 112 may include a button that commands the start/stop of aerosol production. The sensor 112 then transmits the input detected information to the controller 116. In yet another example, the sensor 112 is a temperature sensor that senses the temperature of the heater 121. The temperature sensor determines the temperature of the heater 121 based on, for example, the electrical resistance of the conductive circuit of the heater 121. Instead, the sensor 112 may determine the temperature of the substrate stick 150 held by the holder 140 based on the temperature of the heater 121.

[0033] Annunciator 113 informs the user. In particular, the annunciator 113 may be a light-emitting device, such as an LED (LED, light-emitting diode). In this case, the annunciator 113 emits various combinations of light signals depending on the specific situation, for example, when the power supply 111 needs to be charged, when the power supply 111 is being charged, or when the inhalation device 100 is malfunctioning. In this case, the combination of light signals refers to a combination of color, on time of the light emitting device, off time of the light emitting device, and other characteristics. In addition to or instead of the light emitting device, the sirens 113 may include a display for displaying an image, an audio output for outputting sound, a vibration device for transmitting vibration, and the like. Alternatively, the annunciator 113 may indicate that the user is capable of inhaling. Information about whether the user can inhale is received at the moment when the temperature of the substrate stick 150 heated by the heater 121 reaches a certain value.

[0034] The memory 114 stores various kinds of information for the operation of the inhalation device 100. The memory 114 may be, for example, a non-volatile storage medium such as a flash memory. An example of information stored in the memory 114 may be information about the OS (operating system) of the inhalation device 100, for example, information about the control functions performed by the controller 116 in relation to the relevant structural elements. Another example of information stored in memory 114 may be information about the user's breaths, such as the number of breaths, the time of breaths, and the cumulative duration of breaths.

[0035] The communication module 115 provides a communication interface for exchanging information between the inhalation device 100 and another device. The communication module 115 communicates in accordance with some wired or wireless communication standard. As such a communication standard, for example, wireless local area network (LAN, local area network), wired LAN, Wi-Fi wireless network (registered trademark), Bluetooth wireless network (registered trademark), or other similar standards can be used. For example, the communication module 115 may transmit the user's inhalation information to the smartphone so that the smartphone can display the information. In another example, communication module 115 may receive new OS information from a server to update OS information stored in memory 114.

[0036] The controller 116 performs the functions of an arithmetic processing unit and a control device, and controls all operations within the inhalation device 100 in accordance with various programs. The controller 116 is implemented in the form of an electronic circuit, for example, in the form of a central processing unit (CPU, Central Processing Unit) or a microprocessor. In addition, the controller 116 may include a read only memory (ROM) that stores the program being used, arithmetic parameters, and other data, and a random access memory (RAM) that temporarily stores parameters or other data that may change. Under the control of the controller 116, the inhalation device 100 performs various processes. Examples of processes under the control of the controller 116 are the supply of power from the power source 111 to other structural elements, the charging of the power source 111, the detection of information by the sensor 112, the transmission of information by the siren 113, the storage/reading of information by the memory 114, and the transmission/reception of information by the communication module. 115. Examples of processes controlled by controller 116 also include compressing and releasing (stopping compressing) the depressurizers 160. Controller 116 also controls other processes performed by inhalation device 100, such as inputting information to appropriate structural elements and processes based on information received from the corresponding structural elements.

[0037] The holder 140 has an internal volume 141 and holds the substrate stick 150 in a state in which a portion of the substrate stick 150 is in the internal volume 141. The holder 140 has an opening 142 through which the internal volume 141 communicates with the outside. The holder 140 holds a stick of substrate 150 which is inserted into the inner volume 141 through the opening 142. For example, the holder 140 may have a tubular body, the bases of which are the opening 142 and the bottom 143. Such a tubular body defines the inner volume 141 having a columnar shape. The holder 140 also functions as a conduit for the airflow through the substrate stick 150. For example, bottom 143 is provided with an inlet through which air enters such a conduit. In this case, the opening 142 serves as an outlet through which air exits such an air duct.

[0038] Substrate stick 150 is a rod element. The outer surface of the substrate stick 150 is formed by a sheet member wound around the substrate. Roll paper is an example of such a sheet element. The substrate stick 150 consists of a substrate portion 151 and a mouthpiece 152.

[0039] The substrate portion 151 contains an aerosol source. The source of the aerosol is heated to produce an aerosol. The aerosol source is a liquid, such as a polyhydric alcohol or water. Examples of polyhydric alcohols are glycerol, propylene glycol and the like. The aerosol source may also contain tobacco or tobacco extract which, when heated, releases aromatic components. If the inhalation device 100 is categorized as a medical inhaler, then the aerosol source may be a drug intended to be inhaled by a patient. The aerosol source can be either liquid or solid. In the state where the substrate stick 150 is held by the holder 140, at least some of the substrate portion 151 is accommodated in the inner volume 141 of the holder 140.

[0040] In particular, the aerosol source is contained in an object of any shape, such as granules or sheet, and the substrate portion 151 is filled with the aerosol source. Objects containing an aerosol source will also be referred to as substrate elements in the following. The substrate portion 151 is filled with substrate elements so that there are gaps between them that allow air flow to pass through.

[0041] During inhalation, the user holds the mouthpiece 152 in the mouth. In the state that the substrate stick 150 is held by the holder 140, at least some of the mouthpiece 152 protrudes from the hole 142. When the user inhales while holding the mouthpiece 152 protruding from the hole 142 in his mouth, air enters the interior of the holder 140 through the intake hole air (not shown). The air flow passes through the internal volume 141 of the holder 140 and enters the user's mouth along with the aerosol produced by the substrate part 151.

[0042] The heater 121 heats the aerosol source to atomize it and generate the aerosol. The heater 121 is made of any material such as metal or polyimide. The heater 121 may be of any shape, in particular, a blade-like or columnar shape (for example, the shape of a needle), and is located so that the heater 121 protrudes from the bottom 143 of the holder 140 towards the internal volume 141 of the holder 140. Thus, when the substrate stick 150 is inserted into the holder 140, the heater 121 is stuck into the substrate stick 150 so that the heater 121 is fixed in the substrate portion 151 of the substrate stick 150. Then, when the heater 121 produces heat, the aerosol source contained in the substrate stick 150 is heated and sprayed out of the stick substrate 150, thereby generating an aerosol. The heater 121 produces heat when the power supply 111 supplies power to it. For example, power supply and aerosol generation may occur if sensor 112 detects predetermined user input. The user may inhale when the temperature of the substrate stick 150 heated by the heater 121 reaches a predetermined value. Then, the power supply may be terminated if the sensor 112 detects predetermined information from the user, or after a certain period of time. In another example, power supply and aerosol generation may occur while sensor 112 detects that the user is inhaling.

[0043] Heating until the temperature of the substrate stick 150 reaches a certain value is also called preheating. In addition, such a certain temperature is also called the inhalation temperature. The time required to reach the inhalation temperature will also be referred to hereinafter as the preheat time. Heating to maintain the temperature can be performed even after the temperature of the substrate stick 150 reaches the inhalation temperature as a result of preheating.

[0044] Compressors 160 compress substrate stick 150 held by holder 140. In particular, compressors 160 compress substrate stick 150 held by holder 140 in a heated zone that is heated by heater 121 in directions 190 from a peripheral region of substrate rod 150 to heater 121. The substrate portion 151 is a heated zone. Hereinafter, these directions will also be referred to as compression directions 190. The state in which the depressors 160 compress the substrate stick 150 will also be referred to as the compression state. The state in which the depressors 160 are not compressing the substrate stick 150 will also be referred to as the release state. The following is a detailed description of the configuration of the compressors 160.

[0045] 2. Compression mechanism configuration

(1) General configuration

An example of a mechanism in which the depressors 160 compress the substrate stick 150 will be described with reference to FIG. 2-5.

[0046] FIG. 2 is an exploded perspective view of an inhalation device 100 according to an embodiment. In FIG. 3 shows an example of a cross section of the inhalation device 100 along the insertion/removal direction 191 according to the embodiment. In FIG. 4 is a cross-sectional view of the inhalation device 100 in the released state perpendicular to the insertion/removal direction 191 according to the embodiment. In FIG. 5 is a cross-sectional view of the inhalation device 100 in a compressed state perpendicular to the insertion/removal direction 191 according to the embodiment.

[0047] As shown in FIG. 2-5, the inhalation device 100 includes depressors 160 (160A-160C), a heater 121, an edge portion 171, an inner wall 172, a first pivot assembly 174, a second pivot assembly 175, a first bottom 177, and a second bottom 178. In these figures, structural elements relating to holder 140, heater 121, and compressors 160 are shown, other structural elements are omitted.

[0048] Compression directions 190 are defined for a plurality of depressurizers 160 (160A-160C) that are included in inhalation device 100. For example, compression direction 190A corresponds to the direction from compressor 160A to heater 121. Compression direction 190B corresponds to the direction from compressor 160B to heater 121 The direction of compression 190C corresponds to the direction from the compressor 160C to the heater 121.

[0049] The insertion/removal direction 191 corresponds to the direction in which the substrate stick 150 is inserted into or removed from the inhalation device 100. The insertion/removal direction 191 or the direction in which the substrate stick 150 is inserted is also referred to as the insertion direction. The insertion/removal direction 191 or the direction in which the substrate stick 150 is removed is also referred to as the extraction direction. The insertion/removal direction 191 is perpendicular to the plurality of compression directions 190A-190C. The substrate stick 150 is inserted into the inhalation device 100 so that its longitudinal axis coincides with the insertion/removal direction 191.

[0050] The direction of rotation about the axis of rotation coinciding with the direction of insertion/extraction 191 is also referred to as the direction of rotation 192. The direction of rotation 192 clockwise facing the direction of insertion 191A is also referred to as the right direction of rotation 192A. The direction of rotation 192 counterclockwise facing the direction of the insert 191A is also referred to as the left direction of rotation 192A.

[0051] The characteristics of the compressors 160 are described in detail below in the context of a sequential description of the structural elements depicted in FIG. 2-5. However, when describing the structural elements, the characteristics of the compressor 160A can be considered as typical examples. Clearly, compressors 160B and 160C have the same characteristics as compressor 160A.

[0052] The edge portion 171 is an element that covers the edge of the hole 142 of the holder 140. The edge portion 171 has a cylindrical shape. The edge portion 171 is located on the edge of the inner wall 172 and the second rotary assembly 175 in the extraction direction 191B.

[0053] The inner wall 172 is an element that forms the inner wall of the inner volume 141 of the holder 140. The inner wall 172 has a cylindrical shape. First holes 173 (173A-173C) are provided in the inner wall 172. The first holes 173 are large enough to allow the teeth 161 of the respective depressors 160 to pass through. Specifically, the inner wall 172 is configured such that the positions of the first holes 173 and the second holes 176 provided in the top portion 175B of the second pivot assembly 175 match. The space inside the inner wall 172 corresponds to the inner volume 141 of the holder 140.

[0054] The first rotary assembly 174 is an element rotating in the direction of rotation 192. The first rotary assembly 174 has a cylindrical shape. The first pivot assembly 174 is positioned to enclose the peripheral region of the upper portion 175B of the second pivot assembly 175. The inner wall surfaces 179 of the first pivot assembly 174 are formed such that their height in the compression directions 190 varies along the direction of rotation 192.

[0055] The second pivot assembly 175 is an element rotating in the direction of rotation 192. The second pivot assembly 175 includes an upper portion 175B that is located in the extraction direction 191B and a lower portion 175A that is located in the insertion direction 191A. The upper part 175B and the lower part 175A are cylindrical in shape. The outer cross-sectional diameter of the upper portion 175B is smaller than the outer diameter of the lower portion 175A. In particular, the outer diameter of the cross section of the upper part 175B is smaller than the outer diameter of the cross section of the first pivot assembly 174. The second pivot assembly 175 is configured such that the upper portion 175B is inside the first pivot assembly 174. On the other hand, the outer diameter of the cross section of the lower portion 175A generally matches or substantially matches the outer diameter of the cross section of the first pivot assembly 174. As a result, the step at the boundary between the peripheral region of the lower part 175A and the peripheral region of the first pivot assembly 174 is minimized. Second openings 176 (176A-176C) are provided at the top 175B. The second holes 176 are large enough to allow the teeth 161 of the respective depressors 160 to pass through.

[0056] The first rotary assembly 174 and the second rotary assembly 175 rotate in opposite directions. As the first pivot assembly 174 and the second pivot assembly 175 rotate, the depressors 160 compress or decompress the substrate stick 150. The description below assumes that the position of the second pivot assembly 175 is fixed and the first pivot assembly 174 rotates in the right rotation direction 192A or the left rotation direction 192B. . The first pivot assembly 174 and the second pivot assembly 175 can also be rotated by the user. Alternatively, the first pivot assembly 174 and the second pivot assembly 175 may be rotated automatically by a mechanism not shown in the drawing, such as a motor.

[0057] The first bottom 177 and the second bottom 178 are elements that form the edge of the inhalation device 100 in the direction of the insert 191A. The first bottom 177 and the second bottom 178 are interconnected so that the end of the heater 121 protrudes from the first bottom 177, while the heater 121 is located in the gap between the first bottom 177 and the second bottom 178. In addition, the first bottom 177 and the second bottom 178 are installed in the lower part 175A of the second rotary assembly 175, and the end of the heater 121 protruding from the first bottom 177 is in the inner volume of the inner wall 172 present in the upper portion 175B of the second rotary assembly 175.

[0058] The heater 121 is positioned such that its end protrudes into the inner volume of the inner wall 172. When the substrate stick 150 is inserted into the inner volume of the inner wall 172, the end of the heater 121 sticks into the substrate portion 151 of the substrate stick 150 and is inserted into the substrate stick 150. The heater 121 can heat the aerosol source located in the substrate elements located around it, generating heat.

[0059] The inhalation device 100 according to the presented configuration includes three depressors 160, namely depressors 160A-160C. All three depressors 160 compress the substrate stick 150 from three different directions. With this configuration, all of the depressors 160 can compress the substrate stick 150 regardless of its position and orientation within the interior volume 141 of the holder 140.

[0060] Compressors 160 are composed of teeth 161 and bases 162. Teeth 161 are planar elements extended in the insertion/retraction direction 191 and in the compression direction 190. Bases 162 are bar elements extended in the insertion/retraction direction 191. Compressors 160 arranged so that the bases 162 are in contact with the surfaces of the inner wall 179 of the first rotary assembly 174, and the positions of the teeth 161, the first holes 173 and the second holes 176 respectively match. Between the compressors 160 and the second rotary assembly 175 there is a mechanism, such as springs, to make the compressors 160 resilient in directions opposite to the directions of compression 190.

[0061] The depressors 160 compress the substrate stick 150 by moving in the compression directions 190. In particular, as the first pivot assembly 174 rotates, the bases 162 slide over the surfaces of the inner wall 179 of the first pivot assembly 174. As a result, the positions of the depressors 160 in the compression directions 190 change into in accordance with the change in the height of the surfaces of the inner walls 179 in the directions of compression 190.

[0062] Here, the height of the surfaces of the inner wall 179 of the first rotary assembly 174 in the compression directions 190 increases in the right rotation direction 192A and decreases in the left rotation direction 192B for each of the plurality of depressors 160. Thus, for example, the height of the inner wall 179A with which the base contacts 162A of the compressor 160A, in the compression directions 190 increases in the right direction of rotation 192A and decreases in the left direction of rotation 192B.

[0063] Therefore, when the first pivot assembly 174 rotates in the left direction of rotation 192B, the height of the surfaces of the inner wall 179 at the points where the bases 162 contact the surfaces of the inner wall 179 gradually increase, and the depressors 160 move in the compression directions 190. For example, when the first pivot assembly 174 rotates in the left direction of rotation 192B, the height of the inner wall 179A at the point where the base 162A of the compressor 160A contacts the inner wall 179A gradually increases, and the compressor 160A moves in the compression direction 190A. As a result, as shown in FIG. 5, the teeth 161 pass through the first holes 173 and the second holes 176 and compress the substrate stick 150. For example, the tooth 161A of the depressor 160A passes through the first hole 173A and the second hole 176A and compresses the substrate stick 150.

[0064] On the other hand, when the first pivot assembly 174 rotates in the right rotation direction 192A, the height of the surfaces of the inner wall 179 at the points where the bases 162 contact the surfaces of the inner wall 179 gradually decreases. As a result, the depressors 160 move in directions opposite to the directions of compression 190 due to the elastic force generated by the mechanism, such as springs, installed between the depressors 160 and the second rotary assembly 175. For example, when the first rotary assembly 174 rotates in the right direction of rotation 192A, the height of the inner wall 179A at the point where the base 162A of the compressor 160A contacts the inner wall 179A gradually decreases, and the compressor 160A moves in the direction opposite to the compression direction 190A. As a result, as shown in FIG. 4, teeth 161 extend through first holes 173 and second holes 176 and separate from substrate stick 150. For example, tooth 161A of depressor 160A extends through first hole 173A and second hole 176A and separates from substrate stick 150.

[0065] (2) Compressor end shape 160

In FIG. 6 shows an example of a cross section of one of the depressors 160 perpendicular to the insertion/removal direction 191 according to an embodiment. As shown in FIG. 6, the cross section of the end surface of the compressor 160 (more specifically, the tooth 161) in the compression direction 190 may be convex. In particular, the cross section of the end surface of the compressor 160 (more precisely, the tooth 161) in the compression direction 190 may be in the form of a convex arc. The arc width of the tooth end surface 161, the radius of the tooth end surface arc 161, the compression length, and the outer diameter of the substrate portion 151 are designated W _C , _RC , L _C , and D _S , respectively, and may be of any size. The compression length L _C refers to the distance that the end surface of the compressor 160 (more precisely, the tooth 161) moves after contact with the peripheral region of the substrate portion 151 during compression performed by the compressor 160. For example, dimensions can be set in accordance with the following table 1.

[0067] FIG. 7 shows another example of a cross section of one of the depressors 160 perpendicular to the insertion/removal direction 191 according to an embodiment. As shown in FIG. 7, the cross section of the end surface of the compressor 160 (more specifically, the tooth 161) in the compression direction 190 may be concave. In particular, the cross section of the end surface of the compressor 160 (more precisely, the tooth 161) in the compression direction 190 may be in the form of a concave arc. The arc width of the tooth end surface 161, the radius of the tooth end surface arc 161, the compression length, and the outer diameter of the substrate portion 151 are designated W _C , R _C , L _C , and D _S , respectively, and may be of any size. The two ends of the concave arc of the end surface of the tooth 161 may be in the form of convex arcs. The arc radii at both ends of the tooth end surface arc 161 are designated R _H and may be of any size. For example, the dimensions can be given according to the following table 2.

[0069] (3) Compression and heating timings

In the inhalation device 100 according to an embodiment, the heating performed by the heater 121 or the compression performed by the depressurizers 160 is triggered based on the triggering of the other of these operations. In one example, the inhalation device 100 starts the compression performed by the depressors 160 based on the start of the heating performed by the heater 121. In this case, the compression performed by the depressors 160 occurs automatically. In another example, the inhalation device 100 starts preheating performed by the heater 121 based on the start of compression performed by the depressors 160. In this case, the compression performed by the depressors 160 may be manual or automatic.

[0070] If there are gaps between the heater 121 and the substrate elements, heat transfer from the heater 121 to the substrate portion 151 as a whole is reduced, making it difficult to efficiently generate an aerosol. However, if compression is performed at the same time as heating, the contact surface between the heater 121 and the substrate members is enlarged, thereby enhancing the heat transfer.

[0071] If there are gaps between the substrate elements in the substrate portion 151, heat transfer from the heater 121 to the substrate portion 151 as a whole is reduced, making it difficult to efficiently generate an aerosol. However, if compression is performed at the same time as heating, it is possible to increase the density of the substrate elements in the substrate portion 151, whereby the heat transfer is enhanced.

[0072] By improving the heat transfer, the effect of increasing the temperature of the substrate portion 151 is enhanced, thereby shortening the preheating time. In this way, the quality of inhalation can be improved.

[0073] In addition, after a certain period of time elapses from the start of the compression performed by the depressors 160, the inhalation device 100 stops the compression performed by the depressors 160. In other words, the inhalation device 100 limits the duration of compression to a certain period of time. Under the duration of compression refers to the time interval from the beginning of the compression performed by the compressors 160, to its termination. In the configuration detailed below with reference to the experimental results, it is possible to improve the effect of increasing the temperature of the substrate portion 151, increase the amount of aerosol in the inhaled gas composition, and reduce sticking and shedding of substrate elements. In this way, the quality of inhalation can be improved.

[0074] 3. Preferred Configuration Based on Experimental Results

The inventors conducted various experiments with the compression performed by the compressors 160 and determined the preferred configuration of the inhalation device 100. The conditions common to all experiments are described below first. The results of the experiments and the preferred configuration of the inhalation device 100 are then described.

[0075] The dimensions of the compressors 160 include the dimensions C1-C4 described above. It is assumed that the effective force of the compressors 160 is 25 N and the pressure is 0.4 MPa. Compressors 160 are made of stainless steel (SUS) or polyetheretherketone (PEEK).

[0076] Heater 121 is a columnar ceramic heater 2.5 mm in diameter. The temperature of the heater 121 during heating is 350°C. The temperature of the heater 121 rises from about 25°C to 350°C. If the substrate stick 150 is not inserted into the inhalation device 100, then the temperature of the heater 121 rises to 350° C. instantly. If the substrate stick 150 is inserted into the inhalation device 100, it takes about 10 seconds to raise the temperature of the heater 121 to 350°C. The temperature of the substrate portion 151 is detected by a temperature sensor inserted into the substrate portion 151.

[0077] The apparatus simulates a puff with a flow rate of 55 ^cc for 2 seconds. Puffing is done every 30 seconds. The source of the aerosol is glycerin. The amount of aerosol in the composition of the inhaled gas is analyzed by gas chromatography.

[0078] All experimental results described below are the average of the results of three experiments conducted under the same conditions using the same technique.

[0079] - Bursting experiments

The inventors conducted experiments to study the formation of a gap when the compressors 160 perform compression. A tear refers to a tear in the wrapping paper of the Substrate Stick 150.

[0080] The procedure and conditions for conducting the experiment are described below. The inventors investigated how rupture occurs in an inhalation device 100 using one of the sizes shown in Tables 1 and 2 above under conditions where the depressors 160 are compressed for 15 seconds and then decompressed. The tests were carried out at 22°C and 50% humidity. The results of the experiment are presented in table 3.

[0082] The dimension D _S ' in Table 3 indicates the outer diameter of the substrate portion 151 after compression.

[0083] According to Table 3, in the cases of sizes C1 and C3, the substrate stick 150 showed signs of compression, but it was not broken. On the other hand, when using sizes C2 and C4, the substrate stick 150 was broken. The tear occurred at the point where the stiffness of the substrate stick 150 changed in the longitudinal direction. The change in stiffness is due to different filling.

[0084] As the results of experiments show, when the outer diameter of the substrate stick is 150 7.1 mm, the compression length L _C should be less than or equal to 1 mm. This is explained by the fact that when the compression length L _C exceeds 1 mm, a break occurs. In addition, as follows from the experimental results, it is desirable that the compression length L _C be less than or equal to 0.5 mm. This is because if the compression length L _C is less than or equal to 0.5 mm, no tear occurs. The compression length L _C may vary as needed depending on the outer diameter D _S of the substrate stick 150.

[0085] - Material experiments

The inventors conducted experiments to investigate the relationship between the material of the compressors 160 and the effect of increasing temperature.

[0086] The procedure and conditions for conducting the experiment are described below. The inventors tested the temporal changes in the temperature of the substrate portion 151 after the start of preheating by the heater 121 for different materials of the compressors 160 with or without compression. The tests were carried out at 22°C and 60% humidity.

[0087] FIG. 8 is a graph illustrating the results of experiments with the inhalation device 8 according to the embodiment. The horizontal axis of graph 200 represents the preheating time. The preheating time corresponds to the time elapsed since the start of preheating. The vertical axis of graph 200 plots the temperature of the outer layer (ie, wrapping paper) of the heated zone of substrate portion 151. Graph 200 has lines 201-203. Line 201 reflects the results of the experiments at the time when the compressors 160, made of stainless steel (SUS), did not perform compression. Line 202 reflects the results of experiments under compression conditions with compressors 160 made of stainless steel (SUS). Line 203 reflects the results of experiments under compression conditions with compressors 160 made from PEEK.

[0088] When comparing lines 201 and 202, it can be seen that in the time interval 204 from 0 to about 18 seconds after the start of preheating at the same time, the temperature of the substrate portion 151 is higher for line 202 than for line 201. That is, in the range 204, an increase in the temperature of the substrate portion 151 can be achieved by compressing with stainless steel (SUS) compressors 160.

[0089] From a comparison of lines 201 and 203, it can be seen that in the time interval 205 from 0 to about 70 seconds after the start of preheating at the same time, the temperature of the substrate portion 151 is higher for line 203 than for line 201. That is, in the range 205, an increase in the temperature of the substrate portion 151 can be achieved by compressing with compressors 160 made of PEEK.

[0090] As follows from the experimental results described above, it is preferable to make the compressors 160 from a heat-resistant material. An example of a heat resistant material is a metal such as stainless steel (SUS). Another example of a heat resistant material is a non-metallic material such as PEEK. With this configuration, an increase in the temperature of the substrate portion 151 can be achieved.

[0091] A comparison of lines 202 and 203 shows that at the same time the temperature of the substrate portion 151 is significantly higher for line 203 than for line 202. may be greater than when stainless steel (SUS) is used as the material of the compressors 160. This difference is presumably due to thermal conductivity. The thermal conductivity of stainless steel (SUS) is 236 W/m⋅°C. The thermal conductivity of PEEK is 0.25 W/m⋅°C.

[0092] - Experiments to evaluate the effect of compression on temperature increase

The inventors conducted experiments to investigate the relationship between compression time and temperature increase.

[0093] The procedure and conditions for conducting the experiment are described below. The inventors tested the time variations in the temperature of the substrate portion 151 after the start of preheating by the heater 121 under the conditions of the presence or absence of compression performed by the compressors 160, and also depending on the duration of compression, the start time of compression and the shape of the ends of the compressors 160. The tests were carried out at a temperature of 22° C and humidity 60%. Compressors 160 were made of stainless steel (SUS).

[0094] FIG. 9 is a graph illustrating the results of experiments with the inhalation device 8 according to the embodiment. The horizontal axis of graph 210 represents the time that has elapsed since the start of preheating. The vertical axis of graph 210 plots the temperature of the outer layer (ie, roll paper) of the heated portion of the substrate portion 151. Graph 210 shows lines 211-217. Line 211 reflects the results of experiments under conditions where the compressors 160 are not compressing. Line 212 reflects the results of experiments under constant compression with convex end compressors 160. Line 213 reflects the results of experiments under compression conditions with convex end compressors 160 for 5 seconds from the start of preheating. Line 214 reflects the results of experiments under compression conditions with convex end compressors 160 for 10 seconds from the start of preheating. Line 215 reflects the results of experiments under compression conditions with bulbous end compressors 160 for 20 seconds from the start of preheating. Line 216 reflects the results of experiments under compression conditions with concave end compressors 160 for 5 seconds from the start of preheating. Line 217 reflects the results of experiments under compression conditions with convex end compressors 160 for 5 seconds prior to the start of preheating.

[0095] From a comparison of lines 211 and 217, it can be seen that at the same time the temperature of the substrate portion 151 is significantly higher for line 211 than for line 217. On the other hand, from a comparison of line 211 and lines 212-216, it can be seen that at the same time, the temperature of the substrate portion 151 is significantly higher for lines 212-216 than for line 211. Thus, an increase in the temperature of the substrate portion 151 can be achieved by performing compression with the compressors 160 after the start of preheating, and not before (e.g. simultaneously with the start of preheating).

[0096] According to the above experimental results, it is desirable that the compressors 160 perform compression during preheating. Therefore, the inhalation device 100 synchronizes the start time of the heating performed by the heater 121 with the start time of the compression performed by the depressors 160. That is, the inhalation device 100 starts the preheating performed by the heater 121 and the compression performed by the depressors 160 at the same time. temperature increase effect. Needless to say, the inhalation device 100 does not need to precisely synchronize the start time of the heating performed by the heater 121 with the start time of the compression performed by the decompressors 160; it is only required that the heating start time and the compression start time be substantially the same. By "substantially identical" is meant here the situation where the start time of heating and the start time of compression differ by no more than 1 second. With this configuration it is also possible to achieve the desired temperature increase.

[0097] A comparison of line 211 and lines 212-216 shows that at the same time the temperature of the substrate portion 151 is significantly higher for lines 212-216 than for line 211. The temperature difference is relatively small in the time interval immediately after the start of pre-treatment. heating (for example, in the interval 218 up to 22 seconds after the start of preheating). In the interval 219, which is 40 seconds or more after the start of preheating, the temperature difference is relatively large. Thus, an increase in temperature can be achieved not only during compression, but also for a long period of time after release.

[0098] At the same time, from a comparison of lines 211 and 212, it can be seen that at the same time the temperature of the substrate portion 151 is higher for line 212 than for line 211 up to 70 seconds after the start of preheating, but higher for line 211 than for line 212 after 70 seconds from the start of preheating. That is, with constant compression, it is difficult to achieve an increase in temperature 70 seconds or more after the start of preheating.

[0099] Further, when comparing line 212 and lines 213-216, it can be seen that at the same time the temperature of the substrate portion 151 is significantly higher for lines 213-216 than for line 212. That is, a higher temperature can be achieved by releasing at the appropriate time after compression, rather than by constant compression.

[0100] Thus, after a certain period of time has elapsed after the start of the compression performed by the depressurizers 160, the inhalation device 100 stops the compression. In one example, since the highest temperature of the substrate portion 151 among the lines 213-215 at the same time is observed for the line 214, it is recommended that the compression time be about 10 seconds when using the convex end depressors 160. In another example, when concave-ended compressors 160 are used, the recommended compression time is approximately 5 seconds. With this configuration, an increase in the temperature of the substrate portion 151 can be achieved.

[0101] - Experiments with the amount of aerosol in the composition of the inhaled gas at the initial puff

The inventors conducted experiments to investigate the relationship between the duration of compression and the amount of aerosol in the composition of the inhaled gas during the initial puff. Initial puff refers to the first puff.

[0102] The procedure and conditions for conducting the experiment are described below. The inventors tested the amount of aerosol in the composition of the inhaled gas at the initial puff in terms of the presence or absence of compression performed by the compressors 160, as well as depending on the duration of compression and the shape of the ends of the compressors 160. The tests were carried out at a temperature of 22°C and a humidity of 60%.

[0103] In FIG. 10 is a graph illustrating the results of experiments with the inhalation device 100 according to the embodiment. The horizontal axis of graph 220 represents the preheat time. The vertical axis of graph 220 shows the amount of aerosol in the composition of the inhaled gas at the initial puff. Chart 220 has lines 221-224. Line 221 reflects the results of experiments under conditions where the compressors 160 are not compressing. Line 222 reflects the results of experiments under compression conditions with convex end compressors 160 for 5 seconds from the start of preheating. Line 223 reflects the results of experiments under compression conditions with convex end compressors 160 for 10 seconds from the start of preheating. Line (dot) 224 reflects the results of experiments under compression conditions with concave end compressors 160 for 5 seconds from the start of preheating.

[0104] From a comparison of lines 221 and 223, it can be seen that when preheating for 20 seconds or longer, the amount of aerosol in the composition of inhaled gas in line 223 is greater than line 221. If preheating is performed for 20 seconds or longer, the amount of aerosol in the composition of the inhaled gas can be increased by compressing within 10 seconds from the start of preheating using the 160 convex end compressors.

[0105] From a comparison of lines 221 and 224, it can be seen that when preheating for 15 seconds, the amount of aerosol in the composition of inhaled gas for line 224 is greater than for line 221. Thus, if preheating is performed for 15 seconds or longer, the amount aerosol in the composition of the inhaled gas can be increased by compressing within 5 seconds from the start of preheating using the concave end compressors 160.

[0106] - Experiments with respect to changing the amount of aerosol in the composition of the inhaled gas

The inventors conducted experiments to investigate the relationship between the duration of compression and the change in the amount of aerosol in the composition of the inhaled gas. Changes in the amount of aerosol in the composition of the inhaled gas refers to changes in the amount of aerosol in the composition of the inhaled gas over many puffs.

[0107] The procedure and conditions for conducting the experiment are described below. The inventors tested the change in the amount of aerosol in the composition of the inhaled gas with each puff in terms of the presence or absence of compression performed by the compressors 160, as well as depending on the duration of compression, the shape of the ends of the compressors 160 and the start time of the puff. The tests were carried out at 22°C and 60% humidity.

[0108] In FIG. 11 is a graph illustrating the results of experiments with the inhalation device 100 according to the embodiment. The horizontal axis of the graph 230 represents the number of puffs. The vertical axis of graph 230 plots the amount of aerosol in the composition of the inhaled gas with each puff. Chart 230 has lines 231-224. Line 231 reflects the results of experiments under conditions where compression by the compressors 160 is not performed, and the tightening begins 15 seconds after the start of preheating. Line 232 reflects the results of experiments under conditions where compression by the compressors 160 is not performed, and the tightening begins 20 seconds after the start of preheating. Line 233 reflects the results of experiments under compression conditions with convex end compressors 160 for 10 seconds from the start of preheat, with the tightening starting 20 seconds from the start of preheat (i.e., 10 seconds after compression stops). Line 234 shows the results of experiments under compression conditions with concave end compressors 160 for 5 seconds from the start of preheating, with puffing starting 15 seconds from the start of preheating (i.e. 10 seconds after cessation of compression).

[0109] From a comparison of lines 231, 232 and 233, it can be seen that the amount of aerosol in the composition of the inhaled gas for the same number of puffs, as a rule, is greater for line 233 than for lines 231 or 232. Thus, performing compression with compressors 160 s convex ends, you can increase the amount of aerosol in the composition of the inhaled gas with many puffs.

[0110] From a comparison of lines 231, 232 and 234, it can be seen that the amount of aerosol in the composition of the inhaled gas for the same number of puffs, as a rule, is greater for line 234 than for lines 231 or 232. Thus, performing compression with compressors 160 s concave ends, you can increase the amount of aerosol in the composition of the inhaled gas with many puffs.

[0111] - Stick and Drop Experiments

The inventors conducted experiments to study sticking and dropping under compression conditions with compressors 160.

[0112] Dropout refers to a situation where the substrate elements fall out of the substrate stick 150 when it is removed from the inhalation device 100. In the event of a fallout, the substrate elements fall out of the substrate stick 150 after use and crumble. Therefore, it is desirable to reduce the probability of falling out.

[0113] Sticking refers to the situation where the substrate elements stick to the heater 121. When sticking occurs, the user has to clean the inhalation device 100 to remove adhered substrate elements from it. In addition, when sticking occurs, the amount of aerosol in the composition of the inhaled gas decreases. In addition, when sticking, a burning smell is formed. In connection with these circumstances, it is desirable to reduce the degree of sticking.

[0114] The procedure and conditions for conducting the experiment are described below. The inventors checked the condition of the substrate stick 150 after use by changing the duration of compression by the depressors 160 and the shape of the ends of the depressors 160. The inventors started the compression performed by the depressors 160 at the same time as the preheating performed by the heater 121, stopped heating 15 seconds after the compression ceased and the transition to release condition, the substrate stick 150 was removed from the inhalation device 100 and the condition of the substrate stick 150 was checked. Compressors 160 made of PEEK were used. Compressors 160 with sizes C1 or C3 were used. The tests were carried out at 22°C and 50% humidity. The results of the experiment are presented in table 4.

[0116] The dropout rate is an index value reflecting the dropout rate. A drop level of "1" means that there is no drop. A drop level of "2" means that a minor drop has occurred. A drop level of "3" means that a significant drop has occurred.

[0117] The sticking level is an index value reflecting the degree of sticking. Adhesion level "1" means that there is no adhesion. A sticking level of "2" means that slight sticking has occurred. A sticking level of "3" means that significant sticking has occurred.

[0118] In FIG. 12 is a chart showing the results of Table 4 in graphical form. The horizontal axis of graph 240 represents the duration of the compression. The vertical axis of graph 240 represents the sticking level and the dropout level. On the graph 240 there are lines 241 and 242. Line 241 reflects the results of experiments under compression conditions 160 with convex ends. Thus, line 241 was obtained by plotting the results of experiments according to Table 4 under conditions where ends of size C1 (convex) were used. Line 242 reflects the results of experiments under compression conditions with concave-ended compressors 160. Thus, line 242 was obtained by plotting the results of experiments according to Table 4 under conditions where C3 size (concave) ends were used.

[0119] As shown in line 241, if the duration of compression by the convex compressors 160 is 70 seconds or more, a high level of sticking and dropout is observed. Therefore, it is desirable that the duration of compression does not exceed 70 seconds. With this configuration, excessive sticking and shedding can be prevented.

[0120] As shown in line 241, if the duration of compression by the convex depressors 160 is 60 seconds or less, sticking and dropping do not occur. Therefore, it is desirable that the duration of compression does not exceed 60 seconds. With this configuration, sticking and falling off can be prevented.

[0121] As shown in line 242, if the duration of compression by the concave end compressors 160 is 15 seconds or more, a high level of sticking and dropout is observed. Therefore, it is desirable that the duration of compression does not exceed 15 seconds. With this configuration, excessive sticking and shedding can be prevented.

[0122] As shown in line 242, if the duration of compression by the concave end compressors 160 is 10 seconds or less, there is a low level of sticking and dropout. Therefore, it is desirable that the duration of compression does not exceed 10 seconds. Thanks to this configuration, it is possible, if not to completely prevent, then to reduce the level of sticking and shedding.

[0123] When comparing lines 241 and 242, it can be seen that for the same duration of compression, the degree of dropout and sticking is lower if the ends of the depressors 160 are convex than if the ends of the depressors 160 are concave. Therefore, it is desirable to use constrictors 160 with convex ends. Thanks to this configuration, it is possible, if not completely prevented, then to reduce the level of sticking and shedding.

[0124] 4. Flowchart of the process

In FIG. 13 is an example flowchart of a process performed by the inhalation device 100 according to the embodiment.

[0125] As shown in FIG. 13, first, the inhalation device 100 determines whether a user operation requesting the start of preheating has been detected (step S102). If the operation of the user requesting to start preheating is not detected (step S102: NO), the process again returns to step S102. If a user operation requesting to start preheating is detected (step S102: YES), then the inhalation device 100 simultaneously starts preheating performed by the heater 121 and compression performed by the depressors 160 (step S104).

[0126] Next, the inhalation device 100 determines whether the first determined time interval has elapsed since the start of preheating and compression (step S106). If the first determined time period has not elapsed (S106: NO), then the process returns to S106 again. If the first determined time interval has elapsed (step S106: YES), then the inhalation device 100 stops the compression performed by the depressurizers 160 (step S108). The first determined time interval may be set based on the results of the compression duration experiment.

[0127] Then, the inhalation device 100 determines whether the second predetermined time interval has elapsed since the start of preheating and compression (step S110). If the second determined time period has not elapsed (S110: NO), then the process returns to S110 again. If the second predetermined time interval has elapsed (step S110: YES), then the inhalation device 100 stops heating performed by the heater 121 (step S112). The second defined time interval may be set equal to or greater than the first defined interval, for example.

[0128] 5. Additions

Although the preferred embodiment of the present invention has been described in detail above with reference to the accompanying drawings, the present invention is not limited to this example. Obviously, various modifications and changes can be made by those skilled in the art within the scope of the technical ideas described in the claims, and such modifications and changes are to be considered included within the scope of the present invention.

[0129] Although convex arch and concave arch were given as examples of the shape of the ends of the teeth 161 in the above-described embodiment, the present invention is not limited to these examples. For example, the ends of the teeth 161 may be flat or spherical. In addition, the dimensions of the teeth 161 are not limited to the examples shown in Tables 1 and 2. The dimensions shown in Tables 1 and 2 can, for example, be increased or decreased in proportion.

[0130] Although the above experimental results were obtained under conditions where the temperature of the heater 121 during the heating process was 350°C, the temperature of the heater 121 during the heating process is not limited to this value. For example, the temperature of the heater 121 during heating may be 310°C. Needless to say, the temperature of the heater 121 during heating may be 300°C, 320°C, or any other value, or may vary depending on the time elapsed since the start of heating.

[0131] Although the above embodiment describes an example in which the inhalation device 100 stops the compression performed by the depressurizers 160 after a certain period of time has elapsed from the start of compression, the present invention is not limited to this example. For example, the inhalation device 100 can control when the compression performed by the depressurizer 160 stops depending on the number of breaths of the aerosol by the user. In particular, the inhalation device 100 may continue compressing the depressors 160 until the number of puffs reaches a certain number, and then stop compressing the depressors 160 and release the substrate stick when the number of puffs reaches a certain number. As stated above in connection with the experimental results, a greater increase in temperature can be achieved when the substrate stick 150 is expanded at the appropriate time after compression than when the substrate stick 150 is constantly compressed. One of the reasons for this is the fact that when the substrate stick 150 is released, the heat transfer towards the teeth 161 decreases and the temperature of the substrate stick 150 increases. It should also be taken into account that as the number of puffs increases, the source of aerosol contained in the substrate stick 150 is consumed and depleted, and the amount of aerosol produced is reduced. However, with this configuration, a decrease in aerosol output due to an increase in the number of puffs can be offset by an increase in aerosol output due to an increase in temperature caused by the release of the substrate stick 150, and therefore a decrease in the volume of aerosol in the inhaled gas composition can be prevented. In this way, the taste can be prevented from decaying over time after the start of heating, and the quality of inhalation can be improved.

[0132] The sequence of operations performed by the devices described here may be carried out using software, hardware, or a combination thereof. The programs included in the software are pre-recorded on storage media located inside or outside the devices. When executed by a computer, each of these programs is loaded into RAM and executed by a processor, such as a central processing unit. As storage media, in particular, magnetic disks, optical disks, magneto-optical disks, flash memory and the like can be used. Computer programs can be distributed without resorting to the use of storage media, such as over a network.

[0133] The process described herein using a flowchart or sequence diagram does not have to be performed in that order. Some of the steps in the process may run concurrently. Additional processing steps may also be provided, and some process steps may be omitted.

List of conventions

[0134]

100 inhalation device

111 power supply

112 sensor

113 siren

114 memory

115 communication module

116 controller 121 heater

140 holder

141 internal volume

142 hole

143 bottom

150 sticks of substrate

151 substrate parts

152 mouthpiece

160 compressors

161 teeth

162 bases

171 edge part

172 inner wall

173 first holes

174 first pivot point

175 second swivel assembly

176 second holes

177 first bottom

178 second bottom

179 inner wall surface

190 compression directions

191 insertion/extraction direction

191A insertion direction

191In pull out direction

192 direction of rotation

192A right direction of rotation

192V left direction of rotation

Claims (36)

1. An inhalation device for generating, by heating a substrate, an aerosol for inhalation by the user, while the inhalation device contains: a heater that is inserted inside the substrate placed in the inner volume formed in the inhalation device and that heats the substrate; a compressor that compresses the area of the substrate heated by the heater in a direction from the peripheral area of the substrate towards the heater; And a controller that triggers heating performed by the heater or compression performed by the decompressor based on triggering the other of these operations. 2. The inhalation device of claim. 1, wherein the controller synchronizes the start time of the heating performed by the heater and the start time of the compression performed by the depressurizer. 3. An inhalation device according to claim 1 or 2, wherein the compressor compresses the substrate by moving the compressor in the direction of the heater. 4. The inhalation device according to claim 3, wherein the cross section of the end surface of the compressor in the direction of the heater is convex. 5. The inhalation device according to claim 4, wherein the cross section of the end surface of the compressor in the direction of the heater is in the form of a convex arc. 6. The inhalation device according to claim 5, in which the cross section of the end surface of the compressor in the direction of the heater has the shape of a convex arc with a radius of 1 mm and a width of 2 mm. 7. The inhalation device according to claim 3, wherein the cross section of the end surface of the compressor in the direction of the heater is concave. 8. The inhalation device according to claim 7, wherein the cross section of the end surface of the compressor in the direction of the heater is in the form of a concave arc. 9. The inhalation device according to claim 8, wherein the cross section of the end surface of the compressor in the direction of the heater is in the form of a concave arc with a radius of 3 mm and a width of 5 mm. 10. The inhalation device of claim. 8, wherein the cross section of the end surface of the compressor in the direction of the heater has the shape of a concave arc with a radius of 2.5 mm and a width of 5 mm. 11. Inhalation device according to any one of paragraphs. 3-10, in which the outer diameter of the substrate is 7.1 mm and the distance that the end surface of the compressor advances after contact with the peripheral region of the substrate during the compression process performed by the compressor is 1 mm or less. 12. Inhalation device according to any one of paragraphs. 3-11, in which the inhalation device contains three depressurizers and three compressors compress the core substrate from three different directions. 13. Inhalation device according to any one of paragraphs. 1-12, in which the compressor is made of a heat-resistant material. 14. Inhalation device according to any one of paragraphs. 1-13, in which the controller sets the time from the start to the end of the compression performed by the compressor to 70 seconds or less. 15. Inhalation device according to any one of paragraphs. 1-13, in which the controller sets the time from the start to the end of the compression performed by the compressor to 10 seconds or less. 16. Inhalation device according to any one of paragraphs. 1-15, in which the controller adjusts the timing of the end of the compression performed by the depressor depending on the number of breaths of the aerosol by the user. 17. An information processing method carried out by an inhalation device designed to produce, by heating a substrate, an aerosol for inhalation by the user and containing a heater which is inserted inside the substrate placed in the internal volume formed in the inhalation device and which heats the substrate, and a compressor that compresses the area of the substrate heated by the heater in the direction from the peripheral area of the substrate towards the heater, while the method of information processing includes: - detection by the sensor of information related to the inhalation device, - transfer of detected information to the controller, - processing of detected information and management of operations inside the inhalation device by the controller, including - triggering the heating performed by the heater or the compression performed by the compressor based on the triggering of the other of these operations. 18. A storage medium that stores a program that causes a computer that controls an inhalation device designed to produce an aerosol for inhalation by the user and containing a heater that is inserted inside the substrate placed in the internal volume formed in the inhalation device and heats the substrate, and a compressor that compresses the area of the substrate heated by the heater in the direction from the peripheral area of the substrate towards the heater, function like: a controller that triggers heating performed by the heater or compression performed by the decompressor based on triggering the other of these operations.

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