JP2021531762A - Power Modules for Modular Aerosol Generation Devices and Modules for Modular Aerosol Generation Devices - Google Patents

Abstract

A power module for a modular aerosol generation device for producing an inhalable aerosol is described. The power module is configured so that the user can configure the aerosol generation device by selectively connecting a single module, which is a module of the first module type or a module of the second module type, to the power module. Has been done. The first module type module is for accommodating non-e-liquid material and comprises a heater that can be operated to heat the non-e-liquid material to produce an inhalable aerosol. .. The second module type module is for accommodating an e-liquid for producing an inhalable aerosol. [Selection diagram] Fig. 1

Description

The present invention relates to a power module for a modular aerosol generation device, a module for a modular aerosol generation device, and a modular aerosol generation device.

background

Smoking products, such as cigarettes and cigars, burn tobacco during use to produce tobacco smoke.

Attempts have been made to provide alternatives to these products that burn tobacco by producing products that release compounds without burning.

An example of such a product is a heating device that heats the material but releases the compound by not burning it. The material can be, for example, tobacco with or without nicotine, or other non-tobacco products.

As another example, there is a so-called e-cigarette device. These devices typically contain a liquid called an e-liquid that is heated to vaporize the liquid to produce an inhalable vapor or aerosol. The liquid can contain nicotine and / or fragrances and / or aerosol-producing substances such as glycerol. e-cigarette devices typically do not contain and do not use tobacco.

Yet another example is the so-called hybrid device. These hybrid devices typically contain e-liquids and tobacco or other perfume materials separately. The liquid is heated to vaporize the liquid to produce an inhalable vapor or aerosol through a tobacco or other perfume material such that the perfume is provided to the vapor or aerosol.

Overview

According to the first aspect of the present invention, the power module for a modular aerosol generation device for producing an inhalable aerosol, wherein the power module is a module of the first module type or a second module by the user. An aerosol generation device can be configured by selectively connecting a single module, which is one of the module type modules, to the power module. A second module type module is intended to contain the non-e-liquid material and is equipped with a heater that can be operated to heat the non-e-liquid material to produce an inhalable aerosol. A power module is provided, which is for accommodating an e-liquid for producing an inhalable aerosol.

The power module may include a control circuit, which is a first control suitable for controlling the first module type module when the first module type module is connected to the power module. To apply the scheme, and to apply the second control scheme suitable for controlling the module of the second module type when the module of the second module type is connected to the power module. It is composed.

The control circuit may be configured to identify which of the first type module and the second type module is connected to the power module.

The control circuit has a first control scheme and a second control scheme in response to identifying which of the first type module and the second type module is connected to the control module. It is configured to choose which of these applies.

According to a second aspect of the present invention, the first module type module for use with the power module of the first aspect, wherein the first module type module accommodates a non-e-liquid material. Housing, a heater that can be actuated to heat non-e-liquid materials to produce inhalable aerosols, and a first module type connection interface for connecting modules to power modules. A first module type module is provided.

According to a third aspect of the present invention, a second module type module for use with the power module of the third aspect, wherein the second module type module is a housing for accommodating an e-liquid. A second module comprising an aerosol generation component that can be actuated to generate an inhalable aerosol from the e-liquid and a second module type connection interface for connecting the module to the power module. A type of module is provided.

According to a fourth aspect of the present invention, the modular aerosol generation device for producing an inhalable aerosol, wherein the device is a power module of the first aspect, a first module type of the second aspect. A modular aerosol generation device comprising a module or a module of the second module type of the third aspect is provided.
Further features and advantages of the invention will become apparent from the following description of preferred embodiments of the invention given merely as an example, described with reference to the accompanying drawings. Similar features appearing in different drawings of the drawings are accompanied by the same reference numerals in different drawings.

It is a schematic diagram of a modular aerosol providing device. It is a schematic diagram of the module of the first module type. It is a schematic diagram of the module of the second module type. It is a schematic diagram of a power module. It is a schematic diagram of a mouthpiece.

Detailed explanation

Referring to FIG. 1, a schematic diagram of an example of a modular aerosol providing device 100 is shown. The aerosol providing device 100 is an inhalation device (ie, the user uses the aerosol providing device 100 to inhale the aerosol produced by the device 100), and the device 100 is a handheld device.

Roughly speaking, when the user inhales the device 100, the device 100 produces a vapor or aerosol from the device 100 that passes through the user's mouth.

In this regard, first, in general, it can be mentioned that the vapor is a substance in the gas phase at a temperature below the critical temperature of the substance, which increases the pressure of the vapor, for example, without lowering the temperature. This means that the vapor can be condensed into a liquid. On the other hand, aerosols are generally colloids of fine solid particles or droplets in air or another gas. Colloids are substances in which microscopically dispersed insoluble particles are suspended throughout another substance. For convenience reasons, as used herein, the term aerosol shall be construed to mean aerosol, vapor, or a combination of aerosol and vapor.

Returning to FIG. 1, the device 100 includes a power module 200, a module 300 for accommodating a substance for producing an aerosol, and a mouthpiece 600 in this example. As described in more detail below, it is useful for the user to be able to configure the device 100 by selecting the type of module 300 for connecting to the power module 200. In this example, the module 300 is a first module type module or a second module type module. The first module type module is for accommodating non-e-liquid material and comprises a heater that can be actuated to heat the non-e-liquid material to produce an inhalable aerosol. The second module type module is for accommodating an e-liquid for producing an inhalable aerosol.

Here, referring to FIG. 2, an example of the module 300a of the first module type is shown. The first module type module 300a comprises a housing 402 with a cylindrical path 403 extending through the housing 402. The cylindrical path portion 403 has an outlet 406 at one end 407, which is the proximal end of the module 300a, and is closed at the other end 409, which is the distal end of the module 300a. The module 300a is for accommodating the material 408, which is a non-e-liquid material, in the path portion 403. In some examples, the material 408 is a loosely bonded material housed within the pathway section 403. In those examples, the housing 402 may include an outlet screen 412 to prevent material from passing out of the outlet 406. The exit screen 412 may be removable to allow the user to refill the material 408 into the path portion 403. The outlet screen 412 is porous to allow the aerosol to pass through.

In some examples, the material 408 may be held in a container (not shown) of the material 408 itself, such as a tube with an open end, which itself is in the path section 403. The tube can be made of a suitable material, such as cellulose acetate wrapping or plastic.

The module 300a of the first module type further comprises a heating component 414 for heating the material 408. The heating construct 414 can be of any suitable type, including resistance heating constructs, induction heating constructs, and radiant heating constructs.
Material 408 typically comprises tobacco, but some other botanical or flavoring agent may be used.

In some examples, the material 408 is in the form of particles such as powders, microparticles, particles, fibers, etc. so as to increase the effective surface area of the material in order to maximize the amount of perfume provided by the material 408. It is powdered or treated differently so that it can be taken.
The module 300a of the first module type further comprises a first connection interface 418 of the first module type at the end 409 and a second connection interface 420 of the first module type at the outlet 406.

The first connection interface 418 detachably connects the first module type module 300a to the power module 200. The first connection interface 418 mechanically and electrically connects the first module type module 300a to the power module 200.

The first connection interface 418 comprises, for example, a threaded connection for connecting to a complementary threaded connection of the power module 200 to provide a simple standardized mechanical connection between the two. You may be.

The second connection interface 420 is for detachably connecting the module 300a of the first module type to the mouthpiece 600.

The housing 400 further comprises an air inlet 422 to allow air to flow into the path 403.

Here, with reference to FIG. 3, an example of the module 300b of the second module type is schematically shown. The module 300b of the second module type includes a housing 502 containing a liquid container 506 for containing the e-cigarette liquid 508.

In this example, the liquid container 506 is provided largely in the center of the second module type module 300b, but other configurations are possible. The liquid container 506 has a cylindrical shape, but may have a different shape such as a cone shape or a cylindrical shape. The liquid container 506 is annular and defines a cylindrical path portion 507 extending through the liquid container 506. The cylindrical path portion 507 has an outlet 512 at one end 513 of the module and is closed at the other end 515 of the module. The liquid container 506 can be made of a rigid watertight and airtight material such as metal, suitable plastic and the like.

In this example, the second module type module 300b comprises a heater 514 and a wick 516 that is in thermal contact with the heater 514. In this example, the heater 514 and wick 516 are provided as a single unit, also known as an "atomizer". In this case where the module 300b of the second module type includes an atomizer, such a module is often referred to as a "cartomizer".

The wick 516 is in fluid contact with the liquid 508. The wick 516 is generally absorbent and functions to draw liquid 508 from the liquid container 506 by capillarity. The wick 516 is preferably a non-woven fabric, and may be, for example, a cotton or wool material, or a synthetic material including, for example, polyester, nylon, viscose, polypropylene, or a ceramic material. During use, the heater 514 heats the liquid in the wick 516 to produce an aerosol.

In an alternative example, the module 300b of the second module type does not include a heater for heating the liquid to produce an aerosol, but includes an alternative aerosol-generating construct, such as a piezoelectric construct. As is known, in such a structure, the mesh directly or indirectly onto a piezoelectric structure that causes the mesh to oscillate in response to a control current / voltage applied during use. It may be attached. The liquid is located below the mesh and when the mesh vibrates, the liquid is pushed through the mesh to form an aerosol.

The module 300b of the second module type further comprises a first connection interface 518 of the second module type at the end 515 and a second connection interface 520 of the second module at the outlet 512.

The first connection interface 518 is for detachably connecting the module 300b of the second module type to the power module 200. The first connection interface 518 both mechanically connects and electrically connects the second module type module 300b to the power module 200.

The first connection interface 518, for example, for connecting to the complementary threaded connection of the power module 200 (a module of the first module type) to provide a simple standardized mechanical connection between the two. It may be provided with a threaded connection (which can be identical to that of).

The second connection interface 520 is for detachably connecting the module 300b of the second module type to the mouthpiece 600.

The housing 502 further comprises an air inlet 522 to allow air to flow into the path portion 507.

Here, referring to FIG. 4, a schematic diagram of the power module 200 is shown.

The power module 200 includes a power source 202, such as a battery, for supplying power to various components of the aerosol providing device 100. The battery 202 may be a rechargeable battery or a disposable battery. In this example, the control circuit 204 is further provided to control the operation of various components of the device 100.

For example, the control circuit 204 may be the first (eg, in terms of the wattage, temperature, heating time, or combination thereof) of the heater 414 when the module 300a of the first module type is connected to the power module 200. To apply a first control scheme suitable for controlling modules of module type 300a, and when a second module type module 300b is connected to a power module 200 (eg, of heater 514). It may be configured to apply a second control scheme suitable for controlling the module of the second module type 300b (in terms of wattage, temperature, heating time, or a combination thereof).

The control circuit 204 may be configured to identify which of the first type module 300b and the second type module 300b is connected to the power module, and the first type module. Which of the first and second control schemes applies in response to identifying which of the 300a and the second type of module 300b is connected to the power module. It may be configured to be selected.

In one example, control circuit 204 makes electrical measurements to identify the type of module connected to control circuit 204. For example, a module of the first module type can have a first electrical resistance (1.2 ohms to 1.3 ohms, which is merely an example) associated with the module of the first module type. The module of the two module types can have a second different electrical resistance (1.7 ohms to 1.8 ohms, which is merely an example) associated with the module of the second module type. The first type of module may have a resistance value between 1 ohm and 3 ohms, whereas the second type module may have a resistance value between 0.5 ohms and 4 ohms. .. The first type module and the second type module may have a resistance value different from the above-mentioned resistance value. The control circuit 204 may make one or more resistance measurements to identify which module is connected to the control circuit 204. This is especially true when the resistance of the first module type and the resistance of the second module type are sufficiently different (ie, the difference can be reliably detected by the control circuit 204). You may.

In a further example, each module type may be provided with a transmitter, eg, an RF transmitter (eg, an RFID tag) that transmits an identification signal that identifies the module. The control circuit 204 may include a receiver for receiving the identification signal.

The power module 200 further includes a power module connection interface 206 for detachably connecting the power module 200 to the first module type module 300a or the second module type module 300b.

The connection interface 206 is the first connection interface 418 of the first module type module 300a or the first module of the second module type 300b, depending on which module type is connected to the power module 200. The mechanical connection with the connection interface 518 of the above is realized.

The connection interface 206 may include a threaded connection for connecting to the complementary threaded connection of the first type of module or the second type of module.

Further, the connection interface 206 is a first module of the first module type module 300a in order to supply power from the power supply 202 to the first module type module 300a or the second module type module 300b, as the case may be. It realizes an electrical connection with the connection interface 418 or the first connection interface 518 of the module of the second module type 300b.

Here, referring to FIG. 5, the mouthpiece 600 is shown. The mouthpiece 600 includes a body 602 to be received in the user's mouth. The body 602 includes a path portion 604 extending along the length direction of the mouthpiece 600 from the mouthpiece inlet 606 to the mouthpiece outlet 608.

The inlet end portion 606 of the mouthpiece 600 is for connecting to the outlet end portion of the module 300a of the first module type or the outlet end portion of the module 300b of the second module type.

Referring to FIG. 1 again, when the device 100 is configured as a THP device, the module 300 is the first module type module 300a.

The first module type module 300a is to allow the heater configuration 414 in the first module type module 300a to be powered according to a control scheme suitable for the first module type module 300a. , Is electrically connected to the power supply 202 in the power module 200 via the control circuit 204.

When the heater configuration 414 is powered (powering is, for example, as is well known, by the user operating a button (not shown) on the power module 200, or the entire device 100. A material 408, which may contain tobacco, is heated (rather than burned) by a heater 414 to produce an aerosol (which may be caused by a puff detector (not shown)).

When the user sucks the mouthpiece 600, air is drawn from the outside of the housing 402 through the air inlet 422 into the path portion 403, and the material 408 volatilized or vaporized by the heater configuration 415 airflows. To produce an aerosol flow. The aerosol flow is drawn through the pathway section 403 and through the pathway section 604 in the mouthpiece 600 for inhalation by the user.

Referring to FIG. 1 again, when the device 100 is configured as an e-cigarette device, the module 300 is a module 300b of the second module type.

In order to allow the heater 514 in the module 300b of the second module type to be fed according to the control scheme suitable for the module 300b of the second module type, the module 300b of the second module type is supplied with the control circuit 204. It is electrically connected to the power supply 202 in the power module 200 via.

When the heater 514 is powered (powering is also, for example, as is well known, by the user operating a button (not shown) on the power module 200, or by the device 100. The liquid 508 drawn from the liquid container 506 by the entire puff detector (which may not be shown), the wick 516, is heated by the heater 514 to produce an aerosol.

During use, the liquid 508 can be heated to temperatures above about 70-300 ° C, especially between about 150 ° C and 250 ° C. The liquid 508 may or may not contain nicotine.

When the user sucks the mouthpiece 500, air is drawn from the outside of the housing 502 through the air inlet 522 into the path 507, and the liquid 508 volatilized or vaporized by the heater 514 mixes with the air stream. To generate an aerosol flow. The aerosol stream is drawn through the pathway section 507 and through the pathway section 604 in the mouthpiece 600 for inhalation by the user.

Therefore, the user can very easily switch between configuring the device 100 as a THP device or configuring the device 100 as an e-cigarette device by switching the type of module connected to the power module 200. Is understood. This is very convenient and means that if the user wants to use both types of THP and e-cigarette devices, the user does not have to wear and carry a separate THP and e-cigarette device. means.

In the above example with reference to FIGS. 1-5, the appropriate control scheme for the first module type module 300a or the second type module 300b is applied, depending on which is connected to the power module 200. The control circuit 204 for this is provided as part of the power module 200 itself. In an alternative example, rather than being provided in the power module 200, a suitable control circuit is provided in each of the first module type module 300a and the second type module 300b. In these examples, when the first module type module 300a or the second type module 300b is connected to the power module 200, the control circuit in the connected module is electrically connected to the power supply 202 in the power module 200. Apply the appropriate control scheme for the connected and connected modules. In these examples, the first module type module 300a or the second type module 300b is configured not only to have a custom control circuit but also to be mechanically and electrically connectable to the module. It may be used with any suitable power module 200.

In the above example, the mouthpiece 600 is independent of the first module type module 300a and the second type module 300b, and is released into the first module type module 300a and the second type module 300b. It can be installed as possible. In an alternative example, the mouthpiece 600 may be part of a first module type module 300a and / or part of a second type module 300b.

As used herein, the terms "fragrance" and "flavor" are used to produce the desired taste or aroma in a product for an adult consumer, where local regulations permit. May refer to materials that can be used. They are extracts (eg, mint, hydrangea, honeybee leaves, chamomile, phenuglique, cloves, menthol, Japanese mint, aniseed, cinnamon, herbs, winter green, cherry, berry, peach, apple, drumbui, bourbon, scotch, etc. Whiskey, spearmint, peppermint, lavender, cardamon, celery, cascarilla, nutmeg, byakudan, bergamot, geranium, honey essence, rose oil, vanilla, lemon oil, orange oil, cassia, caraway, cognac, jasmine, ylang ylang, sage, Peppermint, peppermint, ginger, anise, coriander, coffee, or peppermint oil from any species of the genus Peppermint), flavor enhancers, bitter taste receptor site blockers, sensory receptor site activators or stimulants, sugars, And / or alternative sugars (eg, sucralose, acesulfam potassium, aspartame, saccharin, cyclamate, lactose, sucrose, glucose, fructose, sorbitol, or mannitol), and other additives such as charcoal, mint, minerals, vegetable substances. , Or a breath refreshing agent can be included. Fragrances and flavors can be counterfeit, synthetic, or natural ingredients, or blends thereof. Fragrances and flavors can be in any suitable form, for example oils, liquids, solids, or powders. For example, liquids, oils, or other such fluid flavorings may be impregnated into the porous solid material in order to impart the fragrance and / or other characteristics to the porous solid material. .. Therefore, the liquid or oil is a component of the material through which the liquid or oil is impregnated.

The embodiments described above are understood as examples for the purposes of the present invention. Any feature described in connection with any one embodiment may be used alone or in combination with other features described, and is any of the embodiments. It is understood that it may be used in combination with one or more features of any combination of other embodiments, or any other embodiment of the embodiment. Further, equivalents and variations not described so far may be used without departing from the scope of the invention as defined in the appended claims.

Claims (13)

A power module for a modular aerosol generation device for producing inhalable aerosols, wherein the user is either a first module type module or a second module type module. The modular aerosol generation device is configured by selectively connecting a single module to the power module, wherein the module of the first module type is non-e-liquid. The second module type said, comprising a heater for accommodating the material and capable of being actuated to heat the non-e-liquid material to produce an inhalable aerosol. A power module, wherein the module is for accommodating an e-liquid for producing the inhalable aerosol. The power module comprises a control circuit, which is suitable for controlling the first module type module when the first module type module is connected to the power module. A second control scheme suitable for applying the control scheme of and controlling the second module type module when the second module type module is connected to the power module. The power module according to claim 1, wherein the power module is configured to apply. 2. The control circuit is configured to identify which of the module of the first module type and the module of the second module type is connected to the power module. The power module described. The first control in response to the control circuit identifying which of the module of the first module type and the module of the second module type is connected to the control module. The power module according to claim 3, wherein the power module is configured to select which of the scheme and the second control scheme is applied. One of claims 1 to 4, wherein the power module comprises a connection interface capable of connecting the power module to either the module of the first module type or the module of the second module type. The power module described in item 1. The power module of claim 5, wherein the connection interface comprises a threaded connection for connecting to a complementary threaded connection of the module of the first module type or of the module of the second module type. .. A module of the first module type for use with the power module according to any one of claims 1 to 6, wherein the module of the first module type houses a non-e-liquid material. A first module type for connecting the module to the power module, and a heater that can be actuated to heat the non-e-liquid material to produce an inhalable aerosol. A first module type module with a connection interface. The module according to claim 7, wherein the module further comprises a module control circuit for controlling the heater during use. A module of the second module type for use with the power module according to any one of claims 1 to 6, wherein the module of the second module type accommodates an e-liquid. It comprises a housing, an aerosol generation component that can be actuated to generate an inhalable aerosol from the e-liquid, and a second module type connection interface for connecting the module to the power module. The second module type module. The module according to claim 9, wherein the aerosol-generating component comprises one of a heater and a piezoelectric component. 10. The module of claim 10, wherein the module further comprises a module control circuit for controlling the heater or the piezoelectric component during use. A modular aerosol-generating device for producing inhalable aerosols, wherein the modular aerosol-generating device is:
The power module according to any one of claims 1 to 6.
The module of the first module type according to claim 7 or 8, or
The module of the second module type according to any one of claims 9 to 11.
A modular aerosol generation device. A kit of components for the modular aerosol generation device of claim 12, wherein the kit comprises the power module, the module of the first module type, and the module of the second module type. A kit that includes.

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