RU2803240C2 - Aerosol generating system, method for its application, aerosol generating device, and cartridge for use in aerosol generating device - Google Patents

Abstract

FIELD: aerosol generation.

SUBSTANCE: system includes a cartridge containing a storage compartment configured to accommodate a liquid composition containing an aerosol-forming substrate, an aerosol generating device configured to accommodate the cartridge and containing a power supply unit and control electronics functionally connected to the power supply unit. The light source is functionally connected to the control electronics and positioned to emit light into the cartridge storage compartment. Light emitted by the light source is absorbed by the liquid composition. The detector is functionally coupled to the control electronics and positioned to detect light emitted by the light source. The light source and the detector are located adjacent to the same side of the storage compartment. The surface of the storage compartment opposite the light source is configured to absorb light emitted by the light source into the storage compartment.

EFFECT: ability to determine the level of liquid filling of the cartridge in order to replace or update the cartridge and overcome the negative consequences of using the device in the absence of liquid or its insufficient amount.

19 cl, 10 dwg

Description

The present invention relates to electronic aerosol generating systems that operate by heating an aerosol generating substrate. In particular, the present invention relates to systems and devices using consumables filled with a liquid composition containing an aerosol-forming substrate and the consumable itself. More specifically, this invention relates to determining the level of filling of a liquid composition in a consumable material.

The liquid composition containing the aerosol-forming substrate may be referred to as e-liquid. In many aerosol generating systems that employ e-liquid, the e-liquid is stored in a cartridge housed in the aerosol generating device to heat the e-liquid to produce an aerosol for inhalation by the user. When the cartridge is housed in an aerosol generating device, the e-liquid is generally not visible to the user. Since the user cannot see the e-liquid level, the user may not know when the e-liquid is almost used up. In fact, e-liquid may be used up when the user does not have a supply of e-liquid available at any time to refill the e-liquid cartridge or does not have a replacement cartridge available. Accordingly, the user may unexpectedly be prevented from using the aerosol generating system. Additionally, when the cartridge is used up or nearly used up, excessive heating of the remaining e-liquid may occur and this may result in the generation of unwanted compounds. For at least these reasons, it may be desirable for the user to know the filling status of the e-liquid inside the cartridge.

Monitoring the full status of a cartridge housed in an aerosol generating device is difficult. For example, the cartridge is separate from the aerosol generating device and often does not have an electrical power source. Additionally, the position of the cartridge and the aerosol generating device may change, causing the liquid in the cartridge to move. Such movement can complicate static measurements and can interfere with measurements taken in preferred orientations. In addition, the volume of liquid in the cartridge is often quite small and may require precise sensors. Additionally, bringing the sensors into contact with e-liquid may result in undesirable interaction between the e-liquid and the sensors. For example, e-liquid may become contaminated by materials in the sensor, the sensor may be degraded by the e-liquid, and the sensor may require sealing and complications may arise due to that sealing. Such factors can cause increased costs for consumables.

EP 3 357 360 A2 describes an atomizer that is assembled with a battery assembly to form an electronic cigarette, comprising a liquid storage unit for storing tobacco liquid, a liquid guiding unit connected to the liquid storage unit and designed to direct tobacco liquid, and a heating unit. a unit electrically coupled to the battery unit for atomizing tobacco liquid, the atomizing device further comprising a signal transmitter and a receiver, the signal transmitter being configured to transmit a detection signal having a first intensity, and the signal receiver being configured to receive a detection signal having a second intensity; and wherein the electronic cigarette is configured to determine an amount of tobacco liquid in the detection signal transmission path in accordance with the difference between the first intensity and the second intensity, and control the ON/OFF of the electrical connection between the heating unit and the battery unit in accordance with the determined amount of tobacco liquid; wherein the signal transmitter is an infrared signal transmitter, and the signal receiver is an infrared signal receiver; or the signal transmitter is an ultrasonic signal transmitter, and the signal receiver is an ultrasonic signal receiver.

It would be desirable to provide an aerosol generating system using e-liquid that is capable of detecting the fill level of e-liquid in a cartridge.

The aerosol generating system may include a cartridge, an aerosol generating device configured to receive the cartridge, a light source, and a detector. The cartridge may include a storage compartment configured to receive a liquid composition containing an aerosol-forming substrate. The aerosol generating device may include a power supply and control electronics operatively coupled to the power supply. The light source may be operably coupled to the control electronics and positioned and oriented to emit light into the cartridge storage compartment. The light emitted by the light source may be absorbed by the liquid composition. The detector may be operably coupled to the control electronics and positioned and oriented to detect light emitted by the light source.

In some aspects, the present invention includes an aerosol generating system comprising a cartridge, an aerosol generating device configured to receive the cartridge, a light source, and a detector. The cartridge includes a storage compartment configured to accommodate a liquid composition containing an aerosol-forming substrate. The aerosol generating device contains a power supply and control electronics functionally connected to the power supply. The light source is operatively coupled to the control electronics and is positioned and oriented to emit light into the cartridge storage compartment. The light emitted by the light source is absorbed by the liquid composition. The detector is operatively coupled to the control electronics and is located and oriented to detect light emitted by the light source. Both the light source and the detector are configured to be adjacent to the same side of the storage compartment, and a surface of the storage compartment located opposite the light source is configured to absorb light emitted by the light source into the storage compartment.

The control electronics may be configured to determine the level of liquid composition in the storage compartment of the cartridge or may be configured to communicate a signal detected by the detector to another device for determining the level of liquid composition in the storage compartment.

In some aspects, the present invention may include an aerosol generating device, which may include a power supply, control electronics operably coupled to the power supply, and a reservoir configured to receive a cartridge having a storage compartment containing a liquid composition that contains a substrate that forms aerosol. The device may also include a light source and a detector. The light source may be operably coupled to the control electronics and positioned and oriented to emit light into the container storage compartment. The detector may be operatively coupled to the control electronics and positioned and oriented to detect light emitted by the light source after the light reaches the storage compartment.

In some aspects, the present invention includes an aerosol generating device that includes a power supply, control electronics operably coupled to the power supply, and a reservoir configured to receive a cartridge having a storage compartment containing a liquid composition that contains an aerosol-generating substrate. The device also contains a light source and a detector. The light source is operatively coupled to the control electronics and is located and oriented to emit light into the container (or cartridge) storage compartment. The detector is operatively coupled to the control electronics and is positioned and oriented to detect light emitted by the light source after the light reaches the storage compartment. Both the light source and the detector are configured to be adjacent to the same side of the cartridge storage compartment when the cartridge is placed inside the reservoir, and a surface of the storage compartment located opposite the light source is configured to absorb light emitted by the light source in storage compartment.

The present invention may include a cartridge for use in an aerosol generating device. The cartridge may include a storage compartment configured to receive a liquid composition, which may include an aerosol-forming substrate, a light source, a first contact, a detector, and a second contact. The light source may be positioned and oriented to emit light into the storage compartment. The first contact may be operably connected to a light source. The first contact may be located and oriented for electrical connection with a corresponding first contact of the aerosol generating device when the cartridge is disposed in the aerosol generating device. The detector may be positioned and oriented to detect light emitted by the light source. The second contact may be operatively connected to the detector. The second contact may be located and oriented for electrical connection with a corresponding second contact of the aerosol generating device when the cartridge is disposed in the aerosol generating device.

In some aspects, the present invention includes a cartridge for use in an aerosol generating device. The cartridge includes a storage compartment designed to accommodate a liquid composition that contains an aerosol-forming substrate, a light source, a first contact, a detector and a second contact. The light source is positioned and oriented to emit light into the storage compartment. The first contact is functionally connected to the light source. The first contact is positioned and oriented for electrical connection with a corresponding first contact of the aerosol generating device when the cartridge is disposed in the aerosol generating device. The detector is positioned and oriented to detect light emitted by the light source. The second contact is functionally connected to the detector. The second contact is located and oriented for electrical connection with a corresponding second contact of the aerosol generating device when the cartridge is disposed in the aerosol generating device. Both the light source and the detector are configured to be adjacent to the same side of the storage compartment, and a surface of the storage compartment located opposite the light source is configured to absorb light emitted by the light source into the storage compartment.

Various aspects or embodiments of the systems, devices, and cartridges containing liquid aerosol-generating substrates described herein may provide one or more advantages over currently available or previously described systems, devices, and cartridges for aerosol-generating devices. For example, the systems, devices and cartridges of the present invention allow the user to indicate the filling status of the liquid composition in the cartridge even if the liquid cannot be seen. This allows the user to anticipate the need to renew or replace the cartridge and allows the user to renew or replace the cartridge at an appropriate time when supplies of the liquid composition or replacement cartridge are on hand. Additionally, the system may alert the user that a cartridge is used up or nearly used up so that the user can stop using the system before a replacement cartridge is inserted or before the cartridge is refilled, which may serve to prevent the user from being affected. undesirable compounds that may be associated with excessive heating of the liquid composition. Additionally or alternatively, the system may be configured to reduce the temperature of the heater to prevent excessive heating that may occur due to the supply of liquid composition being used up. These and other advantages will be apparent to those skilled in the art upon reading the description herein.

The sensing apparatus and methods described herein can be used with any suitable aerosol generating system that generates an aerosol from a liquid composition containing an aerosol-forming substrate. The term "aerosol-generating" article, device or system refers to an article, device or system capable of releasing volatile compounds from an aerosol-forming substrate to produce an aerosol that can be inhaled by a user. The term "aerosol-forming substrate" means a substrate capable of releasing volatile compounds that can form an aerosol. Typically, the substrate is heated to cause the release of volatile compounds. An aerosol-forming liquid substrate is a substrate that is liquid at ambient temperature, for example from about 15°C to about 30°C. Liquid aerosol-forming substrates are considered to include liquid solutions, suspensions, dispersions, etc. Preferably, the liquid aerosol-forming substrate is a solution.

Preferably, the aerosol generating system is a hand-held system having a mouthpiece for insertion into the user's mouth. The aerosol generating system includes a cartridge comprising a storage compartment configured to receive a liquid composition containing an aerosol-forming substrate, and includes an aerosol generating device configured to receive the cartridge. The aerosol generating device or cartridge may include a mouthpiece. Preferably the cartridge includes a mouthpiece.

The aerosol generating device contains a power supply and control electronics functionally connected to the power supply. The power supply and control electronics are operatively coupled to an aerosol generating element which, when activated, is configured to generate an aerosol from a liquid composition containing an aerosol-forming substrate. Preferably, the aerosol generating element comprises a heating element. Preferably, the heating element comprises an electrically resistive heating element. Preferably, the heating element comprises a liquid-permeable heating element, such as a porous electrically resistive material. Preferably, the heating element comprises a grid of electrically resistive filaments. The mesh may be substantially planar or may comprise a substantially planar portion.

The cartridge or device may contain an aerosol generating element. If the cartridge contains an aerosol generating element, the aerosol generating element is electrically coupled to the power supply and control electronics when the cartridge is placed in the aerosol generating device. If the aerosol generating device includes an aerosol generating element, the aerosol generating element is electrically coupled to the power supply and control electronics and is positioned to cause an aerosol to be generated from the liquid composition when the cartridge is placed in the aerosol generating device and the aerosol generating element , is activated. The device is designed to accommodate an aerosol generating element where the aerosol generating element can be releasably attached to the aerosol generating device.

The aerosol generating system provides an air flow path that, when the aerosol generating element is activated, causes the user to capture an aerosol formed from the liquid composition into air that flows through the inhalation path when the user takes a puff at the mouth end , systems.

The cartridge may contain a retention material that is capable of absorbing, storing, or absorbing and storing a liquid composition containing an aerosol-forming substrate. The holding material is in contact with a liquid composition containing an aerosol-generating substrate and may be in contact with an aerosol-generating element, which may be part of a cartridge or aerosol-generating device.

The retaining material may comprise a capillary material characterized by a fibrous or porous structure that forms a plurality of small holes or microchannels. The liquid substrate forming the aerosol can be transported through the capillary material by capillary action. The retaining material may comprise a plurality of fibers, filaments or other tubes with narrow openings that form a bundle of capillaries. The fibers or filaments may be generally aligned to move a liquid composition containing an aerosol-forming substrate from one surface of the holding material to a generally opposing surface of the holding material. Alternatively, the retention material may comprise a sponge-like or foam-like material. The retaining material may comprise any suitable material or combination of materials. Examples of suitable materials include sponge or foam material, ceramic or graphite based materials in the form of fibers or sintered powders, foamed metal or plastic materials, fibrous materials (for example, spun or extruded fibers such as cellulose acetate, polyester, bonded polyolefin, polyethylene, polypropylene fibers, nylon fibers, ceramic fibers) and combinations thereof. In one illustrative embodiment, the retention material comprises high-density polyethylene (HDPE) or polyethylene terephthalate (PET).

The cartridge may contain a holding material and a transfer material. A transfer material is a material that actively transfers liquid from one end of the material to the other, for example through capillary action such as a wick. The holding material may be in contact with the liquid composition containing the aerosol-forming substrate and in contact with the transfer material. The transfer material may transfer the liquid composition from the holding material to the aerosol generating element.

The transfer material may have a first surface facing the high retention material and an opposing second surface facing the aerosol generating element. The shape of at least a portion of the surface of the transfer material may correspond to the shape of the surface of an aerosol generating element with which the second surface of the transfer element may come into contact.

The transfer material may have a fibrous or porous structure. The transfer material preferably comprises a bundle of capillaries. For example, the transfer material may comprise a plurality of fibers or filaments or other tubes with narrow openings. The transfer material may be configured to generally transfer liquid in an orthogonal direction or at right angles relative to the thickness direction of the transfer material. The transfer material may preferably comprise elongated fibers such that capillary action occurs in small spaces or microchannels between the fibers.

The transfer material may be made of a heat-resistant material that has a thermal decomposition temperature of at least 160°C or higher, such as approximately 250°C or higher. The transfer material may contain fibers or threads of cotton or treated cotton, such as acetylated cotton. Other suitable materials may be used, such as, for example, ceramic or graphite based fibrous materials or materials made from spun, drawn or extruded fibers such as fiberglass, cellulose acetate or any suitable heat resistant polymer. Each of the transfer material fibers may have a thickness of from 10 μm to 40 μm, and more particularly from 15 μm to 30 μm. The transfer material may have any suitable capillarity and porosity for its use with liquids having different physical properties. The transfer material can transport a liquid composition containing an aerosol-forming substrate by capillary action. The liquid composition containing the aerosol-forming substrate may have physical properties including viscosity, surface tension, density, thermal conductivity, boiling point, vapor pressure, etc., which are adapted to facilitate the transfer of the liquid composition containing the aerosol-forming substrate through material to be transferred by capillary action.

The holding material or holding material and transfer material, if present, may be located in the cartridge storage compartment or may be external to the storage compartment, provided that the holding material, if present, is positioned to contact the liquid composition containing the aerosol-forming substrate , located in the storage compartment. For example, the liquid-permeable wall or liquid-permeable wall portion may have an inner surface that defines at least a portion of the storage compartment and may have an outer surface with which the retention material is in contact.

The aerosol generating system includes a sensing apparatus for detecting the volume of the liquid composition in the storage compartment or for detecting the fill level of the liquid composition in the storage compartment. The sensor apparatus contains a light source and a light detector. The light source and detector are functionally connected to the control electronics and power supply of the aerosol generating device. The light source is positioned and oriented to emit light into the cartridge storage compartment. The detector is positioned and oriented to detect light emitted by the light source. The cartridge or aerosol generating device may contain a light source. The cartridge or aerosol generating device may contain a detector.

If the cartridge contains a light source, the light source is preferably operably coupled to the power supply and control electronics of the aerosol generating device when the cartridge is disposed in the device. For example, the cartridge may include an external electrical contact that is electrically coupled to the light source. The aerosol generating device may include a corresponding contact that is operatively connected to the control electronics and the power supply. When the cartridge is placed in the device, an external contact of the cartridge may be contacted with a corresponding contact of the device to operatively connect the light source to the control electronics and power supply of the device. The cartridge and the device may be provided with appropriate features to provide the required orientation to achieve contact between the electrical contacts when the cartridge is placed in the device.

If the cartridge contains a light source, the light source may be open to the interior of the storage compartment or may be closed to the interior of the storage compartment. For example, the cartridge may include a window of material through which light from the light source may be transmitted to the interior of the storage compartment.

If the device contains a light source, the cartridge includes a window of material through which light from the light source can be transmitted to the interior of the storage compartment when the cartridge is placed in the device. The cartridge and device may be provided with appropriate features to ensure proper alignment of the light source and window when the cartridge is placed in the device.

If the cartridge contains a detector, the detector is preferably operably coupled to the power supply and control electronics of the aerosol generating device when the cartridge is placed in the device. For example, the cartridge may include an external electrical contact that is electrically coupled to the detector. The aerosol generating device may include a corresponding contact that is operatively connected to the control electronics and the power supply. When the cartridge is placed in the device, an external contact of the cartridge may be contacted with a corresponding contact of the device to operatively connect the detector to the control electronics and power supply of the device. The cartridge and the device may be provided with appropriate features to provide the required orientation to achieve contact between the electrical contacts when the cartridge is placed in the device.

If the cartridge contains a detector, the detector may be open to the interior of the storage compartment or may be closed to the interior of the storage compartment. For example, the cartridge may include a window of material through which light from the storage compartment can be transmitted to a detector located external to the storage compartment and adjacent to the window.

If the device contains a detector, the cartridge contains a window of material through which light from the storage compartment can be transmitted to the detector when the cartridge is placed in the device. The cartridge and device may be provided with appropriate features to ensure proper alignment of the detector and window when the cartridge is placed in the device.

The light source may emit light of a wavelength that is absorbed by a liquid composition containing an aerosol-forming substrate. For example, the light source may emit light with a wavelength ranging from about 10 nm to about 1 mm. Preferably, the light source emits infrared light. For example, the light source may emit light with a wavelength ranging from about 100 nm to about 1 mm. For example, the light source may emit light with a wavelength of from about 200 nm to about 25 micrometers, or with a wavelength from about 500 nm to about 10 micrometers, or from about 700 nm to about 4 micrometers.

Any suitable light source can be used. For example, the light source may be relatively monochrome or may emit light with a wavelength within a range. Preferably, the wavelength range within which the light is emitted is narrow.

In some embodiments, a filter may be used to limit the wavelength of light that can pass through the filter. The filter may be, for example, an optical bandpass filter that allows light within a certain range of wavelengths to pass through and restricts the passage of light at wavelengths outside that range. The filter may be located between the light source and the inside of the storage compartment. When such a filter is used, the light source can emit a wide spectrum of light.

The light that passes from the light source through the liquid composition in the cartridge storage chamber may be omnidirectional, directional, or focused. The light can be focused in any suitable manner, such as by using lenses to focus the light on a specific point. The light can be made directional using a directional light source such as an LED, laser diode, or collimator. In some embodiments, the light may be focused and collimated or focused and directional. It should be understood that the use of omnidirectional, directional or focused light may depend on the detection scheme used. Some examples of detection schemes that may be used are discussed in more detail below.

The light source or filter may be selected based on the wavelengths of light that will be absorbed by the liquid composition containing the aerosol-forming substrate. Additionally or alternatively, a compound that absorbs light emitted by the light source may be added to the liquid composition to cause the liquid composition to absorb the emitted light.

Any suitable liquid composition containing an aerosol-forming substrate can be used with the systems described herein. Suitable aerosol-forming substrates may contain material of plant origin. For example, the aerosol-forming substrate may contain tobacco or tobacco-containing material containing tobacco volatile aromatic compounds that are released from the aerosol-forming substrate when heated. Additionally or alternatively, the aerosol-forming substrate may comprise a non-tobacco material. The aerosol-forming substrate may contain homogenized material of plant origin. The aerosol-forming substrate may contain at least one aerosol-forming substance. Examples of aerosol-forming agents include polyhydric alcohols such as triethylene glycol, 1,3-butanediol, propylene glycol and glycerin; polyhydric alcohol esters such as glycerol mono-, di- or triacetate; and aliphatic esters of mono-, di- or polycarboxylic acids, such as dimethyl dodecanedioate and dimethyl tetradecanedioate. The aerosol-forming substrate may contain other additives and ingredients such as flavoring agents. Preferably, the aerosol-forming substrate contains nicotine. Preferably, the aerosol-forming substrate is a liquid aerosol-forming substrate. In some embodiments, the aerosol-forming substrate contains glycerin, propylene glycol, water, nicotine, and optionally one or more flavorings.

Any suitable detector may be used. For example, the detector may be a photodetector such as a photodiode. The detector is configured to detect the wavelength of light emitted by the light source or passing through a filter, if one is used. Preferably, the light source emits infrared light and it passes through a filter, if present, and the detector absorbs the infrared light. For example, the detector can detect light with wavelengths ranging from about 100 nm to about 1 mm. For example, the detector may detect light with a wavelength from about 200 nm to about 25 micrometers, or a wavelength from about 500 nm to about 10 micrometers, or from about 700 nm to about 4 micrometers. In some embodiments, the detector is capable of detecting light over a wide range of wavelengths, but the wavelength of light that reaches the detector is limited by the light source and the filter, if present.

The cartridge may include a light guide for guiding light that has passed through the liquid composition to a detector. For example, the cartridge may contain a collimator, mirror or other reflective surface, lens, etc. to direct light to the detector. It should be understood that the use of the apparatus to direct light to the detector may depend on the detection circuit used. Some examples of detection schemes that may be used are discussed in more detail below.

Because the liquid composition absorbs light emitted by the light source, the amount of light that reaches the detector can be reduced relative to the amount of light that is transmitted by the light source. The reduction in light detected by the light source will be proportional to the volume of liquid composition in the cartridge storage compartment.

In the case of a liquid composition containing an aerosol-forming substrate that may be intended to contain known or relatively constant concentrations of compounds, light absorption by the liquid composition should be proportional to the light path length through the liquid composition in the storage tank. Accordingly, if there is more liquid composition in the storage compartment, more light must be absorbed and less must reach the detector.

The detector may be positioned and oriented relative to the light source to detect light that is reflected from the liquid-air interface within the cartridge storage compartment. In such orientations, light can travel from the light source through the liquid composition to the liquid-air interface and back through the liquid composition to the detector. This can increase the length of the path that light travels to reach the detector and thus can increase the sensitivity of the system. In some embodiments, the detector is positioned and oriented relative to the light source to detect light that passes through the liquid composition and through the liquid-air interface.

The detector may be positioned and oriented in any suitable manner relative to the light source so long as light emitted by the light source can reach the detector. The detector may be located adjacent the opposite side of the storage compartment relative to the light source, or may be located adjacent to the same side as the light source. If the reflected signal has been detected by the detector, the light source and the detector may be located adjacent to the same side. The detector may be located near or on the same side of the storage compartment as the light source. Both the light source and the detector may be located near or on the same side of the storage compartment. Both the light source and the detector may be located adjacent to the same side of the storage compartment.

The storage compartment has a length extending from the bottom of the storage compartment to the top of the storage compartment. The "bottom" of the storage compartment may be the surface of the storage compartment that is furthest from the mouth end of the system. The light source may be positioned adjacent the top or bottom of the storage compartment, and the detector may be positioned adjacent the top or bottom of the storage compartment. When the light source and the detector are located adjacent to the opposite upper and lower sides of the storage compartment, the cartridge preferably includes a light guide for directing light to the detector.

The storage compartment includes a peripheral side wall that extends from a lower portion to an upper portion of the storage compartment. When the light source and detector are positioned adjacent the opposite top and bottom sides of the storage compartment, the inner surface of the side wall preferably reflects light emitted by the light source or passing through a filter, if provided.

The light source and the detector may be adjacent to the side wall of the storage compartment between the upper portion and the lower portion of the storage compartment.

The system may include a plurality of light sources and a plurality of detectors, each of which is operably coupled when placed on a device, or may be operably coupled when placed on a cartridge, to the power supply and control electronics of the aerosol generating device. The position and orientation of the plurality of light sources and detectors may vary. In some embodiments, light sources are located and oriented adjacent to one surface, such as a top or bottom surface, and detectors are located and oriented adjacent to the same surface or an opposing surface. In some embodiments, light sources and detectors are located around the periphery of the storage chamber, such as along a side wall. The position of light sources and detectors around the periphery can be changed.

The interior surface of the cartridge storage compartment may reflect or absorb light emitted by the light source or passing through a filter, if equipped. The inner surface of the storage compartment preferably reflects light if complete light detection or substantially complete light detection is desired. When complete light detection or substantially complete light detection is desired, the light source or light sources may be multi-directional. When complete light detection or nearly complete light detection is required, the system may include multiple detectors. Additionally or alternatively, the system may include a light guide for directing light to the detector or detectors.

If the light source and the detector are located adjacent to the same side of the storage compartment and are configured to detect absorption of the liquid composition by reflection, then the surface of the storage compartment opposite the light source preferably absorbs light emitted by the light source or passing through the filter, when its availability. The signal received by the detector when the liquid composition fills the storage compartment may be relatively low, may increase as the liquid composition is consumed, and may be essentially zero when the storage compartment is empty because light may be absorbed by the opposing surface and thus may not be reflected back to the detector. The light source and detector may be located adjacent to the same side of the storage compartment when the cartridge is housed in the aerosol generating device.

It may be desirable for the device and the cartridge housed in the device to be in a particular orientation when the light source and detector are activated to determine the volume of the liquid composition in the storage chamber. To facilitate determination of the orientation of the device and the cartridge housed within the device, the device may include an inertial sensor operably coupled to the power supply and control electronics. Any suitable inertial sensor may be used. For example, the inertial sensor may be an accelerometer and a gyroscope, or an accelerometer and a gyroscope. Preferably, the inertial sensor is a uniaxial accelerometer whose axis extends along the longitudinal axis of the storage compartment. Such an accelerometer can be used as an inclinometer where it measures the value of acceleration due to gravity. When the accelerometer measures 1 g along its axis, the storage compartment should be oriented in a vertical position with the bottom facing down. Such orientations may be preferred when the light source and detector are located adjacent to the top or bottom surfaces of the storage tank.

The input signal from the inertial sensor can be used to determine the angle of inclination of the device, which can be used to determine the volume of liquid composition in the storage compartment based on the angle of inclination, can be used to determine which pair of light sources and detectors to activate, etc. .

The device may include a display or may be configured to transmit information to another device, such as a computer or mobile smartphone, for display. The display may prompt the user to orient the device in a particular orientation before determining the volume or fill level of the liquid composition in the storage compartment. For example, the display may instruct the user to position the device in a vertical orientation with the bottom facing down, or may instruct the user to position the device in a base configured to orient the device in a vertical orientation with the bottom facing down. If the device contains an inertial sensor, then the light source and detector can be activated once the device is correctly oriented. Additionally or alternatively, the device may include an input device operably coupled to the control electronics that allows the user to indicate that the device is correctly oriented and that volume or fill level measurement can begin.

In some preferred embodiments, the system includes one light source and one detector located adjacent the bottom of the storage compartment. The device or cartridge may include a light source and a detector. The device and the storage compartment housed in the device are preferably oriented in a vertical orientation with the bottom portion being downward when the light source and detector are activated to measure the volume or fill level of the liquid composition in the storage tank. Preferably, the light source, the detector and the liquid-air interface of the liquid composition in the storage compartment, which can reflect light from the light source to the detector, are oriented in a three-parameter relationship. The device preferably includes an inertial sensor or is capable of alerting the user to place the device in a vertical orientation with the bottom portion facing down. Once the vertical orientation with the bottom down is detected or fixed, the light source and detector can be activated. The amount of light received by the detector can be used by the control electronics to determine the volume of liquid in the storage compartment or the occupancy level of the storage compartment. The upper inner surface of the storage compartment preferably absorbs light emitted from the storage compartment. For example, the top inner surface may be black.

The signal received by the detector when the liquid composition fills the storage compartment may be relatively low due to light absorption by the liquid composition, may increase as the liquid composition is consumed, and may be essentially zero when the storage compartment is empty because light may be absorbed by the opposing surface and thus may not be reflected back to the detector.

In some cases, when a small amount of liquid composition remains in the storage compartment, the signal transmitted from the light source may not reach the detector because the reflection angle is too large. In such cases, the signal detected by the detector may be similar to that of an empty storage compartment. That is, the signal can essentially reach zero. The system may initiate a complementary process in such cases to check whether the storage compartment is empty or whether a small volume of liquid composition remains in the storage compartment. The complementary process involves instructing the user to reposition the device to a vertical orientation with the bottom at the top, which will result in any remaining liquid being located at the top of the storage compartment, which will be oriented at the bottom. The light source and detector can be activated. If a small volume of liquid composition is in the storage compartment, then some light will be reflected from the air-liquid interface and returned to the detector, which will receive the signal. If there is no liquid composition remaining in the storage compartment, then the light will be absorbed by the top of the storage compartment and as such the signal will not be picked up by detection. Thus, if a signal is detected by the complementary process, a determination can be made that a small amount of liquid composition remains in the storage compartment, and if the complementary process does not detect a signal, a determination can be made that no liquid composition remains in the storage compartment.

In some preferred embodiments, the system includes a plurality of light sources and detectors that are alternately arranged around the periphery of the storage compartment. For example, if the storage compartment is cylindrical, then the light sources and detectors may form a ring around the periphery of the storage compartment. Several rings of alternating light sources and detectors may be located around the periphery of the storage compartment. The detection scheme is preferably based on the reflection of light from the light source from the liquid-air interface to the detector. In some embodiments, the control electronics are configured to detect a light source and detector pair that are immersed in a liquid composition in a storage compartment. The light sources may be sequentially activated while the light received by the detectors is measured to identify the light source and at least one detector that are oriented such that the light passes through the liquid composition before reaching the detector. If light does not pass through the liquid composition, the amount of light reaching the detector will be greater than the amount of light that reaches the detector when the light passes through the liquid composition, due to the absorption of light by the liquid composition. The one or more detected signals indicating that light is passing through the liquid composition may be used to determine the volume of the liquid composition in the storage compartment or the fill level of the liquid composition in the storage compartment.

In some preferred embodiments, the system includes a light source located adjacent the bottom or top of the storage compartment, and a detector located adjacent to the bottom of the storage compartment, wherein the light source and detector are located adjacent to opposing surfaces. The device preferably includes an inertial sensor or is capable of alerting the user to place the device in a vertical orientation with the bottom portion facing down. Once the vertical orientation with the bottom down is detected or fixed, the light source and detector can be activated. The amount of light received by the detector can be used by the control electronics to determine the volume of liquid in the storage compartment or the occupancy level of the storage compartment. The aerosol generating element may be located along and externally to the side wall of the storage compartment in such configurations that the aerosol generating element does not interfere with the transmission of light through the storage compartment from the top to the bottom or from the bottom to the top. The aerosol generating element may form part of a side wall of the storage compartment. The aerosol generating element and the portion of the side wall along which the aerosol generating element is located are preferably permeable to the liquid composition in the storage compartment. For example, the aerosol generating element may be porous. Preferably, the aerosol generating element comprises a heating element. The cartridge may include a passage between the aerosol generating element and a wall of the cartridge, which may form part of an air flow path to deliver the aerosol to a user for inhalation.

In some preferred embodiments, the system includes a light source located adjacent the bottom or top of the storage compartment, and a detector located adjacent to the bottom of the storage compartment, wherein the light source and detector are located adjacent to opposing surfaces. The system may contain multiple light sources on one side and multiple detectors on the other side. Preferably, the inner surface of the storage compartment reflects light emitted by the light source or light sources. The cartridge may include a light guide for directing light to the detector or detectors. Additionally or alternatively, the light source or light sources may be multi-directional. The aerosol generating element may be located along and externally to the side wall of the storage compartment in such configurations that the aerosol generating element does not interfere with the transmission of light through the storage compartment from the top to the bottom or from the bottom to the top. The aerosol generating element may form part of a side wall of the storage compartment. The aerosol generating element and the portion of the side wall along which the aerosol generating element is located are preferably permeable to the liquid composition in the storage compartment. For example, the aerosol generating element may be porous. Preferably, the aerosol generating element comprises a heating element. The cartridge may include a passage between the aerosol generating element and a wall of the cartridge, which may form part of an air flow path to deliver the aerosol to a user for inhalation.

In some preferred embodiments, the system includes a light source and a detector located adjacent the bottom of the storage compartment. The device or cartridge may include a light source and a detector. The system may include a plurality of light sources and a plurality of detectors located adjacent the bottom of the storage compartment. The device may preferably include an inertial sensor or may be capable of alerting the user to position the device in a vertical orientation with the bottom portion facing down. Once the vertical orientation with the bottom down is detected or fixed, the light source and detector can be activated. The upper inner surface of the storage compartment preferably absorbs light emitted from the storage compartment. The control electronics may be configured to simultaneously activate all light sources and may be configured to simultaneously receive input from all detectors.

Regardless of how the light is emitted and detected, the signal detected by the detector can be estimated based on the laws of absorption, calibration, using known volumes of a liquid composition, having known components with a known concentration, or based on the laws of absorption and calibration, using known volumes of a liquid compositions having known components with known concentrations. The control electronics may include a memory device in which a lookup table relates the received signal to the level of the liquid composition. Additionally or alternatively, the control electronics may include a transmitter for providing information regarding the detected signal or signals to an external device, such as a computer or mobile smartphone, to determine the liquid fill level.

The control electronics of the aerosol generating device may be provided in any suitable form and may, for example, comprise a controller or a memory device and a controller. The controller may comprise one or more of the following: an application specific integrated circuit (ASIC) state machine, a digital signal processor, a gate array, a microprocessor, or an equivalent discrete or integrated logic circuit. The control electronics may include a memory device that stores instructions causing one or more circuit components to perform a function or aspect of the control electronics. The functions inherent in the control electronics in the present invention may be implemented as one or more of software, firmware, and hardware.

Reference will now be made to drawings which illustrate one or more aspects described in the present invention. However, it will be understood that other aspects not depicted in the drawings fall within the scope and spirit of the present invention. Like numbers used in the figures refer to like components, steps, etc. It will be understood, however, that the use of a number to designate a component in a given figure is not intended to limit a component in another figure designated by the same number. In addition, the use of different numbers to designate components in different figures is not intended to indicate that components designated by different numbers may not be the same or similar to components designated by different numbers. The figures are presented for purposes of illustration and not limitation. The schematic representations shown in the figures are not necessarily to scale.

Figure 1 is a schematic representation of an example of an aerosol generating system.

FIG. 2 is a schematic, enlarged view of the storage compartment and heating assembly of an embodiment of a cartridge for use in an aerosol generating system.

FIG. 3 is a schematic diagram of an example of a cartridge and a light source and detector of an aerosol generating device.

FIG. 4A is a schematic diagram of an example cartridge and an aerosol generating device configured to receive the cartridge.

FIG. 4B is a schematic view illustrating a cross-section of the cartridge and light sources and detectors of the aerosol generating device of FIG. 4A in a horizontal orientation.

FIG. 5 is a schematic diagram illustrating a section of parts of an aerosol generating device and a cartridge housed in the device.

FIG. 6 is a schematic diagram illustrating a section of parts of an aerosol generating device and a cartridge housed in the device.

FIG. 7 is a schematic view illustrating a portion of a cartridge containing light sources and detectors and a storage compartment.

FIG. 8 is a schematic view illustrating a portion of a cartridge containing a light source and a detector and a storage compartment.

FIG. 9 is a schematic diagram illustrating a portion of a cartridge containing light sources and detectors and a storage compartment.

FIG. 10 is a schematic view illustrating a portion of a cartridge containing a light source and detector and a storage compartment.

Referring now to FIG. 1, the aerosol generating system 1 includes two main components, a cartridge 100 and an aerosol generating device 300 . The cartridge 100 extends from the mouth end 101 to the connecting end 115 . The cartridge 100 is removably connected to a corresponding connecting end 315 of the aerosol generating device 300 . The aerosol generating device 300 includes a housing 305 that houses a power supply, such as a battery 310 , and control electronics 320 and any associated electronic circuitry (eg, electrical conductors and contacts passing through the housing). The aerosol generating system 1 may be portable and may be of a size comparable to a traditional smoking article such as a cigar or cigarette.

The cartridge 100 includes a housing 105 containing an aerosol generating element, which in this case contains a heater assembly 120 containing an electrically resistive heating element, and a storage compartment 103 containing a liquid composition containing an aerosol generating substrate 131 . When the cartridge 100 is placed in the aerosol generating device 300 , such as when the cartridge 100 is coupled to the aerosol generating device 300 as described in FIG . The heater may be activated to heat the liquid composition 131 . Heater assembly 120 may include a high retention material and a transfer material (not shown), where the high retention material is in contact with the liquid composition 131 and the transfer material is in contact with the high retention material and the heating element.

An air flow passage (not shown) extends through the cartridge 100 from an air inlet (not shown) formed on the side of the housing 105 , along the heater assembly 120 , and from the heater assembly 120 to the mouthpiece hole formed at the end 101 brought to the mouth, casing 105 .

The system is designed in such a way that the user is able to puff or draw in the mouth end 101 of the cartridge 100 to draw in the aerosol from the system 1 . When system 1 is activated, control electronics 320 controls the supply of electrical power from battery 310 to cartridge 100. Control electronics 320 may include an air flow sensor (not shown) and may provide electrical power to the heating element of heater assembly 120 when a user takes a puff on cartridge 100 . as determined by the air flow sensor. Alternatively, system 1 may be activated by pressing a button or the like. When the system 1 is activated, the heating element of the heater assembly 120 is activated, thereby heating the transfer material, which conducts the aerosol-forming liquid substrate 131 from the high retention material to the heater element. The heating element 120 heats the liquid substrate 131 to form an aerosol and generates steam, which is entrained in the air flow passing through the air flow passage. The vapor is cooled within the air flow in the passage to form an aerosol, which is then drawn into the user's mouth through an opening at the end 101 brought to the mouth.

The cartridge 100 includes a light source 160 and a light detector 165 extending into the storage compartment 103 adjacent the bottom of the storage compartment 103 . The light source 160 and the light detector 165 may be closed relative to the interior of the cartridge 100 . Light source 160 and light detector 165 are electrically coupled to control electronics 320 and power supply 310 when cartridge 100 is positioned in device 300 via contacts (not shown). Control electronics 320 is configured to activate a light source 160 that is oriented to emit light into the storage compartment 130 and is configured to receive a signal from a detector 165 that is positioned and configured to detect light emitted by the light source 160 that is reflected from the liquid-air interface 173 formed between the liquid composition 131 and the air 170 in the storage compartment 103 . The cartridge 100 includes light blocking elements 162 , 167 to prevent light emitted by the light source 160 from being transmitted directly to the detector 167 . The walls defining the storage compartment 130 or cartridge housing 150 are impermeable to light so that light from outside does not interfere with the light detection sensor system.

The storage compartment 103 is configured in such a way that an isosceles triangle is formed between the light source 160 , the liquid-air interface 173 , and the detector 165 when the device 300 is oriented such that the storage compartment 103 is in a vertical orientation with the bottom portion at the bottom. (as described in Fig. 1 ). In the embodiments depicted in FIGS. 1 , the inner surface of the storage compartment 103 preferably absorbs light emitted by the light source 160 . For example, the inner surface of the storage compartment 103 may be black. However, if the inner surface of the storage compartment 103 reflects the emitted light, the sensor system is expected to function properly.

In fig. 2 is an enlarged view of the cartridge storage compartment 103 . The storage compartment 103 has a longitudinal axis A , a lower inner surface 182 , an upper inner surface 184, and a side wall 186 extending from the lower portion 182 to the upper portion 184 . The liquid composition 131 containing the aerosol generating substrate is contained in the storage compartment 103 and is in communication with the heating unit 120 . Between the liquid composition 131 and the air 170, a liquid-air interface 173 is formed in the storage compartment 103 .

The light source 160 and the light detector 165 extend into the storage compartment 103 adjacent the bottom surface 182 . As illustrated, light emitted by the light source 160 may be reflected from the liquid-air interface 173 along the longitudinal axis A to be directed toward the detector 165 . The reflected light path forms an isosceles triangle with the light source 160 and the detector 165 as the base and two sides 11 , 12 of equal length. The path length that light travels must be proportional to the light absorbed by the liquid composition 131 and the signal detected by the detector 165 .

In fig. 3 depicts some components of the cartridge and device embodiment. The cartridge includes a housing 105 that defines a mouth-facing end 101 and includes a storage compartment 103 . A liquid composition 131 containing an aerosol-forming substrate is placed in a storage compartment 130 . Between the liquid composition 131 and the air 170, a liquid-air interface 173 is formed in the storage compartment 103 . The storage compartment 103 includes a first window 108 and a second window 109 adjacent the bottom. The first 108 and second 109 windows are transparent to the light emitted by the light source 165 . The light source 165 and detector 160 are part of the aerosol generating device. When the cartridge is placed in the device, the light source 165 is located and oriented to transmit light to the storage compartment 103 through the first window 108 , and the detector 165 is located and oriented to detect emitted light that passes through the second window 109 . A detector 165 is positioned to detect light that is reflected from the liquid-air interface 173 .

The heater assembly 120 is located below the bottom of the storage compartment 103 . However, the heater assembly may be located at any other suitable location.

Onfig. 4A illustrates a system that contains a cartridge100 and device300, generating an aerosol, configured to accommodate a cartridge100. Device300, aerosol generating, contains rings169alternating sources160 light and detectors165 so that when the cartridge100placed in the device300, rings169alternating sources160 light and detectors165 surround the periphery of the department103 for cartridge storage100. Cartridge100 turns on the heater assembled120, which is functionally connected to the power supply and control electronics of the device300when the cartridge100 placed in the device300. Cartridge100forms the end101, brought to the mouth, for insertion into the mouth of the user. Liquid composition131, containing a substrate that forms an aerosol, is placed in the compartment103 for storage. Between liquid composition131 and air170 surface formed173 liquid-air section in the compartment103 for storage. The side walls or parts thereof are transparent to the light emitted by the sources160 light, to ensure penetration of light from sources160 light to the department103 for storage and to allow emitted light to escape from the compartment103 for storage to reach detectors165. The light sources are preferably omnidirectional.

In FIG. 4B , the apparatus and cartridge are positioned horizontally such that the liquid-air interface 173 formed between the liquid composition 131 and the air 170 in the storage compartment 103 extends parallel to the longitudinal axis of the storage compartment 103 . In this configuration, some light sources 160 and detectors 165 are above the level of the liquid composition 131 , and some are below the liquid composition 131 . The light sources 160 may be sequentially activated while light is detected at the detectors 165 to identify at least one pair of light sources 160 and detector 165 that are below the level of the liquid composition 131 based on the signal received by the detector. One or more such pairs may be used to determine the fill level or volume of the liquid composition 131 in the storage compartment 103 . It should be understood that the fill level or volume of the liquid composition can also be detected when the device and cartridge are in different orientations using similar processes.

In fig. 5, the cartridge 100 is housed in an aerosol generating device 300 . The device 300 has a housing 305 that defines a cavity for receiving the cartridge 100 . The cartridge 100 includes a storage compartment 130 and a heater assembly 120 . The heater assembly 120 is located along the side wall of the storage compartment 103 so that the heater assembly 120 does not interfere with the transmission of light through the storage compartment 103 from the bottom to the top of the storage compartment 103 . The liquid composition 131 containing the aerosol-forming substrate is located in the storage compartment 103 , and a liquid-air interface 173 is formed between the liquid composition 131 and the air 170 in the storage compartment 103 .

A transition 400 is formed between the heating element 120 and the housing 305 of the aerosol generating device 300 . Transition 400 forms part of an air flow path to transport the aerosol to the user for inhalation.

The light source 160 and the detector 165 are located outside the storage compartment 103 . Accordingly, the storage compartment includes transparent portions at the top and bottom to allow light emitted by the light source 160 to pass through the storage compartment 130 to reach the detector 165 .

In fig. 6, aerosol generating device 300 and cartridge 100 are similar to those shown and are discussed in relation to FIG. 5 , with similar components designated by similar numbers. In fig. 6 , cartridge 100 contains light guides 460 and 465 . The light guide 460 at the bottom of the storage compartment 103 is configured to direct light emitted by the light source 160 onto the entire bottom surface of the cartridge in a direction generally parallel to the longitudinal axis of the storage compartment. The light guide 460 is generally parabolic and reflects light such that light from the light source 160 that impinges on the surface of the light guide 460 is reflected generally parallel to the length of the cartridge 100 . The light guide 465 at the top of the storage compartment 103 is configured to direct substantially all of the light transmitted to the detector 165 through the top of the storage compartment 103 . The light guide 465 is generally parabolic, and light that impinges on the surface of the light guide 465 is reflected toward the detector 165 . In some examples (not shown), the detector may be located at or near the inner center of a parabolic light guide that reflects light toward the detection center.

The aerosol generating device 300 may include an inertial orientation sensor to characterize the overall signal amplitude as a function of the fill level or volume ratio to more accurately determine the volume or fill level of the liquid composition 131 in the storage compartment 103 . In fig. 7, the cartridge contains a plurality of light sources 160 and detectors 165 positioned adjacent the bottom of the storage compartment 103 in an interleaved manner. Having the light sources 160 and detectors 165 on the same side of the cartridge provides a more practical design since it confines the electronic components to one side. Detectors 165 are located and oriented to detect light that is reflected from the liquid-air interface 173 formed between the liquid composition 131 containing the aerosol-forming substrate and the air 170 in the storage compartment 103 . For clarity, the light is shown as being emitted by only two light sources 160 , but can be emitted by any number of light sources. The signal received by all detectors 165 may be summed to determine the fill level or volume of the liquid composition 131 . As a sum, the signal detected by the detectors 165 provides a simple way to determine the volume of liquid if the orientation is known. However, the data received by the detectors 165 may be evaluated in a different manner to determine the volume of liquid.

In fig. 8, the cartridge includes a light source 160 and a detector 165 located adjacent to the bottom of the storage compartment 103 . A dividing wall 169 is located between the light source 160 and the detector 165 . The detector 165 is located and oriented to detect light that is reflected from the liquid-air interface 173 formed between the liquid composition 131 containing the aerosol-forming substrate and the air 170 in the storage compartment 103 . The interior surfaces of the storage compartment reflect the light emitted by the light source. The cartridge in Fig. 8 has the advantage of simplicity. Only one light source 160 has a wide beam angle and only one detector 165 . With a large beam angle, it is possible for detector 165 to receive signals in any orientation with only one light source 160 . In addition, the light source 160 and the detector 165 are on the same side of the device, which also simplifies the design.

In fig. 9, the cartridge includes a plurality of light sources 160 located adjacent to the bottom of the storage compartment 103 , and a plurality of detectors 165 located adjacent to the top of the storage compartment 103 . The detectors 165 are located and oriented to detect light emitted by the light sources 160 through the storage compartment 103 from the bottom to the top. For a known orientation, there is a relationship between the sum of all received signals and the volume of fluid filled. The cartridge in Fig. 9 is configured to measure a light signal transmitted through the liquid-air interface 173 , which may be acceptable if the device surrounds the top and bottom of the cartridge.

In fig. 10 , the cartridge includes a light source 160 located adjacent to the bottom of the storage compartment 103 , and includes a detector 165 located adjacent to the top of the storage compartment 103 . The detector 165 is positioned and oriented to detect light emitted by the light source 160 through the storage compartment 103 from the bottom to the top. The light source is omnidirectional. The inner surfaces of the storage compartment 103 reflect the light emitted by the light source 160 . For a known orientation, there is a relationship between the sum of all received signals and the volume of fluid filled. The cartridge in Fig. 10 is configured to measure a light signal transmitted through the liquid-air interface 173 , which may be acceptable if the device surrounds the top and bottom of the cartridge.

All scientific and technical terms used herein have the meanings commonly used in the art unless otherwise noted. The definitions provided in this document are intended to make it easier to understand certain terms that are frequently used in this document.

As used in this specification and the accompanying claims, the singular form includes embodiments containing plural entities unless otherwise expressly stated in the content.

As used in this specification and the accompanying claims, the term “or” is generally used to include “and/or” unless otherwise expressly stated in the content.

As used herein, the words “have,” “having,” “include,” “including,” “contain,” “comprising,” or the like are used in their broadest sense and generally mean “including but not limited to " It will be understood that the expressions “consisting essentially of”, “consisting of”, etc. fall within the category of “comprising”, etc.

The words “preferred” and “preferably” refer to embodiments of the present invention that may provide certain advantages under certain circumstances. However, other embodiments may also be preferred under the same or different circumstances. Moreover, the disclosure of one or more preferred embodiments does not imply that other embodiments are not useful and is not intended to exclude other embodiments from the scope of the present invention, including the claims.

Any direction mentioned herein, such as "up", "down", "left", "right", "top", "bottom", and other directions or orientations are described herein for clarity and brevity and are not intended to to limit the actual device or system. The devices and systems described in this document may be used in a variety of directions and orientations.

The exemplified embodiments above are not limiting. Other embodiments consistent with the above-described embodiments will be apparent to those skilled in the art.

Claims (44)

1. An aerosol generating system containing: a cartridge comprising a storage compartment configured to receive a liquid composition containing an aerosol-forming substrate; an aerosol generating device configured to accommodate a cartridge, the aerosol generating device comprising a power supply and control electronics operably connected to the power supply; a light source operably coupled to the control electronics and positioned and oriented to emit light into the cartridge storage compartment, wherein the light emitted by the light source is absorbed by the liquid composition; And a detector operably coupled to the control electronics and positioned and oriented to detect light emitted by the light source, wherein both the light source and the detector are located adjacent to the same side of the storage compartment, and wherein a surface of the storage compartment located opposite the light source is configured to absorb light emitted by the light source into the storage compartment. 2. The aerosol generating system according to claim 1, characterized in that the control electronics are configured to determine the level of filling of the liquid composition in the cartridge storage compartment or the control electronics are configured to transmit data regarding the signal detected by the detector to an external device for determining the level filled with liquid composition in the storage compartment. 3. An aerosol generating system according to claim 1 or 2, characterized in that the cartridge contains a light source and a detector, the aerosol generating device contains a light source and a detector; the cartridge contains a light source and the aerosol generating device contains a detector; or the cartridge contains a detector and the aerosol generating device contains a light source. 4. The aerosol generating system according to claim 3, characterized in that when the cartridge contains a light source, the cartridge further includes an external electrical contact operatively connected to the light source, and wherein the aerosol generating device includes a contact operatively connected to the control electronics, wherein the contact of the aerosol generating article, and the external electrical contact of the cartridge is configured to be electrically connected when the cartridge is placed in the aerosol generating device; And wherein when the cartridge comprises a detector, the cartridge further comprises an external electrical contact operatively coupled to the detector, and wherein the aerosol generating device comprises a contact operatively coupled to the control electronics, wherein the contact of the aerosol generating article and the external electrical contact of the cartridge configured to be electrically connected when the cartridge is placed in the aerosol generating device. 5. An aerosol generating system according to claim 3 or 4, characterized in that when the aerosol generating device contains a light source, the cartridge includes a window of material transparent to light, the material extending from the inner surface of the storage compartment to the outer surface of the cartridge, the light source being aligned with the window when the cartridge placed in a device that generates an aerosol; And wherein, when the aerosol generating device includes a detector, the cartridge includes a window of material transparent to light, the material extending from an interior surface of the storage compartment to an exterior surface of the cartridge, the detector being aligned with the window when the cartridge is placed in the device, generating aerosol. 6. The aerosol generating system as claimed in any one of the preceding claims, wherein the cartridge storage compartment has a length extending from the bottom of the storage compartment to the top of the storage compartment, the light source and the detector being located adjacent to the bottom of the compartment for storage. 7. The aerosol generating system according to any one of claims 1 to 5, characterized in that the cartridge storage compartment has a length extending from the bottom of the storage compartment to the top of the storage compartment, wherein one of the light source and the detector is adjacent located with the lower part of the storage compartment, and the other of the light source and the detector is located adjacent to the upper part of the storage compartment. 8. The aerosol generating system of claim 7, wherein the detector comprises a light guide configured to direct light within the storage compartment to a surface of the detector. 9. The aerosol generating system according to claim 7 or 8, wherein the storage compartment includes a side wall extending from the bottom to the top of the storage compartment, the inner surface of the side wall reflecting light emitted by the light source. 10. The aerosol generating system according to any one of claims 1 to 5, characterized in that the storage compartment has a side wall extending from the bottom of the storage compartment to the top of the storage compartment, the light source and the detector being located adjacent to the side wall between the top and bottom of the storage compartment. 11. The aerosol generating system of claim 10, wherein the light source is one of a plurality of light sources and the detector is one of a plurality of detectors, wherein each of the light sources and detectors is operably coupled to control electronics, wherein a plurality of light sources and detectors are located around the periphery of the storage compartment substantially transverse to the longitudinal axis of the storage compartment. 12. The aerosol generating system of claim 11, wherein the control electronics are configured to detect a light source and detector pair that are immersed in the liquid composition in the storage compartment. 13. The aerosol generating system according to any of the previous paragraphs, characterized in that it additionally contains a position sensor operatively connected to the control electronics. 14. The aerosol generating system according to claim 13, characterized in that the control electronics are configured to determine the level of filling of the liquid composition in the cartridge storage compartment based on data from the detector and from the position sensor. 15. The aerosol generating system of claim 13 or 14, wherein the control electronics are configured to activate the light source and detector when the position sensor indicates that the device is in a predetermined orientation. 16. A method of using an aerosol generating system as claimed in any one of the preceding claims, comprising the step of repositioning the aerosol generating device to a vertical orientation with the bottom portion at the top, thereby allowing the aerosol generating device to verify whether the compartment is suitable for empty or whether a small volume of liquid composition remains in the storage compartment. 17. The method according to claim 16, characterized in that it includes providing commands to the user to initiate the step of changing the position of the aerosol generating device. 18. An aerosol generating device that contains: power unit; control electronics functionally connected to the power supply; a reservoir configured to accommodate a cartridge having a storage compartment that contains a liquid composition containing an aerosol-forming substrate; a light source operably coupled to the control electronics and positioned and oriented to radiate light into the cartridge storage compartment; And a detector operatively coupled to the control electronics and positioned and oriented to detect light emitted by the light source after the light reaches the storage compartment; wherein both the light source and the detector are configured to be adjacent to the same side of the cartridge storage compartment when the cartridge is placed inside the reservoir, and wherein a surface of the storage compartment opposite the light source is configured to absorb light, emitted by the light source into the storage compartment. 19. A cartridge for use in an aerosol generating device, containing: a storage compartment for housing a liquid composition containing an aerosol-forming substrate; a light source located and oriented to radiate light into the storage compartment; a first contact operatively coupled to the light source, the first contact being located and oriented for electrical connection with a corresponding first contact of the aerosol generating device when the cartridge is disposed in the aerosol generating device; a detector positioned and oriented to detect light emitted by the light source; And a second contact operatively coupled to the detector, the second contact being located and oriented for electrical connection with a corresponding second contact of the aerosol generating device when the cartridge is disposed in the aerosol generating device; wherein both the light source and the detector are located adjacent to the same side of the storage compartment, and wherein a surface of the storage compartment located opposite the light source is configured to absorb light emitted by the light source into the storage compartment.

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