Patent Description:
One example of an aerosol generating device is an e-cigarette. Typically, in an e-cigarette a liquid aerosol-forming substrate is heated to generate a vapour to generate an aerosol. However, alternative designs have been proposed that use a vibrating transducer to generate droplets from a liquid aerosol-generating device, with the droplets forming an aerosol.

<CIT> discloses an electronic cigarette vaporiser system that includes a piezoelectric pump with multiple piezo-actuators, in which a microcontroller independently adjusts the phase or timing or power of each voltage pulse that triggers a piezo-actuator. The microcontroller continuously or regularly monitors the efficiency or performance of the entire pump and adjusts the phase, timing, or power delivered to each piezo-actuator until or so that the optimum pumping performance is achieved.

Vibrating transducers can also be used as the basis of small liquid pumps. Small liquid pumps can be used in aerosol-generating devices, such as e-cigarettes, to deliver liquid aerosol-forming substrate from a reservoir to an atomising elements, such as a heater or vibrating transducer.

It would be desirable to optimise as far as possible the efficiency of any vibrating transducers used in an aerosol-generating device, either for generating an aerosol or for moving liquid within the device. This is particularly important in handheld aerosol-generating devices, such as e-cigarettes, which are typically battery powered, and are desirably as small as possible, but which need to generate a significant volume of aerosol on demand by a user.

It would also be desirable to be able to be able to quickly and simply detect any changing operating conditions that affect the output and efficiency of the aerosol-generating device.

According to an aspect of the present invention, there is provided an aerosol generating device. The aerosol-generating device comprises a transducer. The transducer is a piezoelectric transducer. The aerosol generating device comprises drive circuitry connected to the transducer and configured to apply an oscillating current to the transducer. The aerosol-generating device comprises control circuitry connected to the drive circuitry and configured to monitor the resonant behaviour of the transducer, the control circuitry configured to control the operation of the drive circuitry based on the resonant behaviour of the transducer.

The piezoelectric transducer forms part of a transducer assembly in a liquid pump. The transducer assembly comprises a membrane or surface configured to contact a liquid aerosol-forming substrate, the transducer assembly configured to drive the membrane or surface into vibration, the vibration of the membrane or surface forcing the liquid through an adjacent liquid valve in the liquid pump.

As used herein "resonant behaviour" means any measurable aspect of the response of the piezoelectric transducer to oscillating input signals. For example, resonant behaviour may be a resonant frequency or resonant frequencies, or a change in resonant frequency or resonant frequencies, a maximum amplitude of response or a minimum amplitude of response, a maximum or minimum input impedance, a phase response or a change in phase response.

The resonant behaviour of the transducer may be represented by one or more measureable parameters, such as input impedance or one or more frequencies of maximum amplitude response.

The transducer assembly may be configured to interact with liquid aerosol-forming substrate within the device. The transducer assembly may be configured to generate an aerosol from the liquid aerosol-forming substrate. The transducer assembly may be configured to move the liquid aerosol-forming substrate.

In some embodiments, the transducer assembly comprises a perforated membrane or mesh. The transducer may be configured to drive the perforated membrane or mesh into vibration at one or more frequencies. The vibration of the perforated membrane or mesh may force liquid aerosol-forming substrate through the perforated membrane or mesh, which may result in the formation of an aerosol comprising droplets of the liquid aerosol-forming substrate.

The transducer assembly comprises a membrane or surface configured to contact a liquid aerosol-forming substrate. The transducer may be configured to drive the membrane or surface into vibration at one or more frequencies. The vibration of the membrane or surface may force the liquid through an adjacent mesh or perforated membrane, which may result in the formation of an aerosol comprising droplets of the liquid aerosol-forming substrate.

In some embodiments, the transducer assembly comprises an atomising surface configured to contact a liquid aerosol-forming substrate and electrodes on the transducer configured to generate surface acoustic waves (SAW) on the atomising surface. The SAW generate droplets of the liquid aerosol-forming substrate, which form an aerosol.

The transducer comprises a membrane or surface configured to contact a liquid aerosol-forming substrate. The transducer may be configured to drive the membrane or surface into vibration at one or more frequencies. The vibration of the membrane or surface may force the liquid through an adjacent liquid valve.

In all of these embodiments, it is beneficial to be able to control the operating frequency of the transducer or the operating power of the transducer (or both the operating frequency and the operating power of the transducer) in response to changes in the resonant behaviour of the transducer. Controlling the operating frequency in particular may be beneficial in order to improve the efficiency of the system. Controlling the operating frequency may allow generation of aerosol to be maximised.

The control circuitry may be configured to control the operation of the drive circuitry at the time that the device is first activated. The control circuitry may be configured to control the operation of the drive circuitry periodically or intermittently during operation of the device.

There are several reasons why the resonant behaviour of the piezoelectric transducer may change during operation of the device. One parameter that might affect the resonant behaviour of the transducer is temperature. The resonant frequency of the transducer assembly may change with temperature as materials of the transducer assembly expand or contract, resulting in changes in dimension and changes in residual stresses within the transducer assembly. Temperature changes of the transducer assembly may occur because of changes in ambient temperature. Temperature changes of the transducer assembly may occur because of warming of the transducer assembly as a result of energy dissipation within the device during operation. Typically the transducer assembly will warm up during operation of the device. Warming of the transducer assembly may result in a fall in the resonant frequencies of the transducer.

Other changes in ambient conditions may affect the resonant behaviour of the transducer. For example, changes in atmospheric pressure or humidity may affect the resonant behaviour of the transducer.

Changes in the material in contact with the transducer assembly may change the resonant behaviour of the transducer. In particular, changes in load on the transducer may change the resonant behaviour of the transducer. For example, changes in a volume of liquid aerosol-forming substrate in contact with the transducer assembly may change the load on the transducer. Change in the composition of the liquid aerosol-forming substrate in contact with the transducer assembly may change the load on the transducer.

The resonant behaviour of the transducer may change as a result of ageing of one or more components of the transducer assembly.

So it can be seen that changes in the resonant behaviour of the transducer assembly may be rapid or may comprise a longer term drift. It is beneficial for the device to be able to respond to both rapid changes and longer term drift.

The control circuitry may be configured to control the operation of the drive circuitry so that the oscillating current has a frequency equal to a resonant frequency of the piezoelectric transducer. Operating at a resonant frequency may allow for a maximum amount of power to be transferred to the transducer. Operating at a resonant frequency may result in a maximum amplitude of vibration and a maximum vibration velocity. This may be beneficial for generating an aerosol with desirable properties.

The control circuitry may be configured to control the operation of the drive circuitry so that the oscillating current has a frequency offset from a resonant frequency of the transducer. This may be advantageous in some circumstances. For example when the impedance of the transducer at its resonance frequency is not matched with the output impedance of the drive circuitry, then a small offset of frequency is useful to operate the system at the impedance matching point where the highest power is delivered to the transducer. This frequency may be somewhere between the resonance and anti-resonance frequencies. In this region impedance changes significantly with frequency, allowing for precise tuning.

The control circuitry may be configured to monitor the resonant behaviour of the transducer at a plurality of resonant frequencies of the transducer corresponding to different modes of vibration. The transducer may be driven at a plurality of different frequencies in order to generate aerosol droplets with different properties.

The control circuitry may be configured to monitor the resonant behaviour of the piezoelectric transducer by measuring a delivered power to the transducer or an input impedance of the transducer. At a resonant frequency, delivered power is maximised and input impedance is minimised.

The control circuitry may be configured to monitor the resonant behaviour of the piezoelectric transducer by determining zero crossing points of an output signal from the transducer or points of inflection of an output signal from the transducer. The zero crossing points or points of inflection may be used to determine a frequency of operation.

The control circuitry may comprise a phase locked loop (PLL). The phase locked loop may comprise a phase comparator and may determine a phase shift in a response from the transducer. Use of a phase locked loop may be advantageous as it does not require a microprocessor. It may be a low cost and high reliability solution.

In some embodiments, the drive and control circuitry is configured to:.

The drive circuitry may use a second frequency that is higher than the drive frequency in alternate time slots and may use a second frequency that is lower than the drive frequency in alternate time slots.

This process results in a device that automatically tracks the resonant frequency of the transducer.

The second frequency may be higher or lower than the drive frequency by a predetermined amount.

Other options for detecting changes in resonant frequency include the use of a dedicated MEMS sensor. For example, a MEMS cantilever with low inertia can be placed in contact with a vibrating element of the transducer assembly so that the cantilever synchronizes with the oscillation of the transducer assembly and provides a corresponding electric signal. Another option is the use of real-time impedance measurement by monitoring the voltage and current in the transducer. In this case, the series and parallel modes of the transducer can be addressed individually. The transducer behaviour can be described in terms of an electric equivalent circuit consisting of a capacitance C1, an inductance L1, and a resistance R1 in series for the mechanical part and another capacitance C0 and resistance R0 for the transducer electrical part in parallel. Depending on the frequency, this circuit can run in a state where the series branch (C1,L1,R1) resonates itself (series resonance mode) or where this LCR-series resonates with the parallel C0 (parallel resonance mode). The series resonance frequency is close to the resonant frequency of the transducer and the parallel resonance frequency is close to the anti-resonance frequency of the transducer. The series mode resonance provides low impedance and results in higher current and lower voltage for the same power. Mechanically this provides large displacement amplitudes. The parallel mode resonance provides high impedance and results in lower current and higher voltage for the same power. Mechanically the losses are lower. In this case, a tuning series inductance can be added and the electro-acoustic energy transfer efficiency can be higher at anti-resonance.

The device may comprise a means to tune the resonant frequency of the transducer. For example, a membrane coupled to the piezoelectric transducer may be pre-stressed by the application of a DC bias voltage, which will alter its resonant behaviour. As components of the device age it may be beneficial to tune the resonant response of the device to the match a particular desired frequency or frequencies associated with the aerosol-forming substrate.

The control circuitry may comprise a microprocessor. The control circuitry may comprise a field programmable gate array (FPGA). The drive circuitry and the control circuitry may be integrated into a single circuit.

The control circuitry may be configured to control a carrier frequency, duty cycle, power, modulation frequency or amplitude of the oscillating current from the drive circuitry.

As described, the resonant behaviour of the transducer may be affected by the amount of liquid in contact with portion of the transducer assembly. The control circuitry may be configured to detect a reduction in the amount of liquid in contact with transducer assembly based on changes in the resonant behaviour of the transducer. This may be based on sudden changes in resonant frequency greater than a threshold amount. The control circuitry may be configured to stop operation of the drive circuitry in response to detection of a significant reduction on liquid delivered to the transducer assembly. The control circuitry may be configured to stop or modify operation of the drive circuitry based on any malfunction of the device, determined based on the resonant behaviour of the transducer.

The piezoelectric transducer may comprise a monocrystalline material. The piezoelectric transducer may comprise quartz. The piezoelectric transducer may comprise a ceramic. The ceramic may comprise barium titanate (BaTiO3). The ceramic may comprise lead zirconate titanate (PZT). The ceramic may include doping materials such as Ni, Bi, La, Nd or Nb ions. The piezoelectric transducer may be polarised. The piezoelectric transducer may be unpolarised. The piezoelectric transducer may comprise both polarised and unpolarised piezoelectric materials.

The drive circuitry may be configured to apply an oscillating current having a frequency between about <NUM> and about <NUM>, or between about <NUM> and about <NUM>, or between about <NUM> and about <NUM>. This may provide a desired aerosol-output rate and a desired droplet size.

The aerosol-generating device may be configured to generate an aerosol for user inhalation. The aerosol-generating device may be an electrically operated smoking device.

The aerosol generating device may comprise a liquid reservoir containing a liquid aerosol-forming substrate. In use, the piezoelectric transducer may be in contact with liquid from the liquid reservoir.

The aerosol-generating device may comprise a liquid storage portion containing the liquid aerosol-forming substrate reservoir. The liquid storage portion may form part of a cartridge that is separable from the remainder of the device. The liquid storage portion of the aerosol-generating system may comprise a housing that is substantially cylindrical, wherein an opening is at one end of the cylinder. The housing of the liquid storage portion may have a substantially circular cross section. The housing may be a rigid housing. As used herein, the term 'rigid housing' is used to mean a housing that is self-supporting. The rigid housing of the liquid-storage portion may provide mechanical support to the heating means.

The liquid storage portion may further comprise a carrier material within the housing for holding the aerosol-forming substrate.

The liquid aerosol-forming substrate may be adsorbed or otherwise loaded onto a carrier or support. The carrier material may be made from any suitable absorbent plug or body, for example, a foamed metal or plastics material, polypropylene, terylene, nylon fibres or ceramic. The liquid aerosol-forming substrate may be retained in the carrier material prior to use of the aerosol-generating system. The liquid aerosol-forming substrate may be released into the carrier material during use. The liquid aerosol-forming substrate may be released into the carrier material immediately prior to use.

In one example, the liquid aerosol-forming substrate is held in capillary material. A capillary material is a material that actively conveys liquid from one end of the material to another. The capillary material may be advantageously oriented in the housing to convey liquid aerosol-forming substrate to the transducer assembly. The capillary material may have a fibrous structure. The capillary material may have a spongy structure. The capillary material may comprise a bundle of capillaries. The capillary material may comprise a plurality of fibres. The capillary material may comprise a plurality of threads. The capillary material may comprise fine bore tubes. The capillary material may comprise a combination of fibres, threads and fine-bore tubes. The fibres, threads and fine-bore tubes may be generally aligned to convey liquid to the vibratable element. The capillary material may comprise sponge-like material. The capillary material may comprise foam-like material. The structure of the capillary material may form a plurality of small bores or tubes, through which the liquid can be transported by capillary action.

The capillary material may comprise any suitable material or combination of materials. Examples of suitable materials are a sponge or foam material, ceramic- or graphite-based materials in the form of fibres or sintered powders, foamed metal or plastics materials, a fibrous material, for example made of spun or extruded fibres, such as cellulose acetate, polyester, or bonded polyolefin, polyethylene, terylene or polypropylene fibres, nylon fibres or ceramic. The capillary material may have any suitable capillarity and porosity so as to be used with different liquid physical properties. The liquid aerosol-forming substrate has physical properties, including but not limited to viscosity, surface tension, density, thermal conductivity, boiling point and atom pressure, which allow the liquid to be transported through the capillary material by capillary action. The capillary material may be configured to convey the aerosol-forming substrate to the transducer assembly.

The carrier material may abut the transducer assembly. The liquid aerosol-forming substrate may be transported by capillary action from the liquid storage portion to the transducer assembly.

Alternatively, or in addition, the device may comprise a pump. Liquid aerosol-forming substrate may be delivered to the transducer assembly from the reservoir by the pump.

The aerosol-generating device may comprise liquid aerosol-forming substrate in the housing of the liquid-storage portion. The liquid aerosol-forming substrate is a substrate capable of releasing volatile compounds that can form an aerosol. The volatile compounds may be released by moving the liquid aerosol-forming substrate through the passages of the vibratable element.

The liquid aerosol-forming substrate may comprise nicotine. The nicotine containing liquid aerosol-forming substrate may be a nicotine salt matrix. The liquid aerosol-forming substrate may comprise plant-based material. The liquid aerosol-forming substrate may comprise tobacco. The liquid aerosol-forming substrate may comprise a tobacco-containing material containing volatile tobacco flavour compounds, which are released from the aerosol-forming substrate upon heating. The liquid aerosol-forming substrate may comprise homogenised tobacco material. The liquid aerosol-forming substrate may comprise a non-tobacco-containing material. The liquid aerosol-forming substrate may comprise homogenised plant-based material.

The liquid aerosol-forming substrate may comprise at least one aerosol-former. An aerosol-former is any suitable known compound or mixture of compounds that, in use, facilitates formation of a dense and stable aerosol and that is substantially resistant to thermal degradation at the temperature of operation of the system. Suitable aerosol-formers are well known in the art and include, but are not limited to: polyhydric alcohols, such as triethylene glycol, <NUM>,<NUM>-butanediol and glycerine; esters of polyhydric alcohols, such as glycerol mono-, di- or triacetate; and aliphatic esters of mono-, di- or polycarboxylic acids, such as dimethyl dodecanedioate and dimethyl tetradecanedioate. Aerosol formers may be polyhydric alcohols or mixtures thereof, such as triethylene glycol, <NUM>,<NUM>-butanediol and glycerine. The liquid aerosol-forming substrate may comprise other additives and ingredients, such as flavourants.

The aerosol-forming substrate may comprise nicotine and at least one aerosol former. The aerosol former may be glycerine. The aerosol-former may be propylene glycol. The aerosol former may comprise both glycerine and propylene glycol. The aerosol-forming substrate may have a nicotine concentration of between about <NUM>% and about <NUM>%.

The aerosol-forming substrate may have a dynamic viscosity (µ) at a temperature of <NUM> of between about <NUM> mPa. S (<NUM> mPl, <NUM> cP) and about <NUM> mPa. S (<NUM> mPl, <NUM> cP), or between about <NUM> mPa. S and about <NUM> mPa. S, or about <NUM> mPa. S and about <NUM> mPa.

The aerosol-generating device may comprise a power supply. The power supply may be a battery. The battery may be a Lithium based battery, for example a Lithium-Cobalt, a Lithium-Iron-Phosphate, a Lithium Titanate or a Lithium-Polymer battery. The battery may be a Nickel-metal hydride battery or a Nickel cadmium battery. The power supply may be another form of charge storage device such as a capacitor. The power supply may require recharging and be configured for many cycles of charge and discharge. The power supply may have a capacity that allows for the storage of enough energy for one or more smoking experiences; for example, the power supply may have sufficient capacity to allow for the continuous generation of aerosol for a period of around six minutes, corresponding to the typical time taken to smoke a conventional cigarette, or for a period that is a multiple of six minutes. In another example, the power supply may have sufficient capacity to allow for a predetermined number of puffs or discrete activations of the heating means and actuator.

The aerosol-generating device may be portable. The aerosol-generating device may have a size comparable to a conventional cigar or cigarette. The aerosol-generating system may have a total length between about <NUM> and about <NUM>. The aerosol-generating device may have an external diameter between about <NUM> and about <NUM>.

The aerosol-generating device may comprise a housing. The housing may be elongate. The housing may comprise any suitable material or combination of materials. Examples of suitable materials include metals, alloys, plastics or composite materials containing one or more of those materials, or thermoplastics that are suitable for food or pharmaceutical applications, for example polypropylene, polyetheretherketone (PEEK) and polyethylene. The material may be light and non-brittle.

The housing may comprise a cavity for receiving the power supply. The housing may comprise a mouthpiece. The mouthpiece may comprise at least one air inlet and at least one air outlet. The mouthpiece may comprise more than one air inlet.

The action of the transducer assembly on the liquid aerosol-forming substrate may heat the aerosol-forming substrate. This may be desirable when it is desirable to deliver a warm aerosol to a user. Alternatively, or in addition, the device may include a heater. The heater may heat the liquid aerosol-forming substrate before it reaches the transducer assembly, at the transducer assembly or after it has formed an aerosol.

In another aspect of the invention, there is provided a method of operating an aerosol generating device. The device comprises a piezoelectric transducer. The device comprises drive circuitry connected to the piezoelectric transducer. The device comprises control circuitry configured to monitor a parameter of the piezoelectric transducer and connected to the drive circuitry. The method comprises applying an oscillating current to the transducer using the drive circuity. The method further comprises monitoring the resonant behaviour of the piezoelectric transducer using the control circuitry. The method further comprises controlling the operation of the drive circuitry based on the monitored resonant behaviour of the piezoelectric transducer.

The piezoelectric transducer is part of a transducer assembly. The transducer assembly is in a liquid pump. The transducer assembly comprises a membrane or surface configured to contact a liquid aerosol-forming substrate. The piezoelectric transducer is configured to drive the membrane or surface into vibration. The vibration of the membrane or surface forces the liquid through an adjacent liquid valve in the liquid pump.

The method may comprise stopping the operation of the drive circuitry based on the monitored resonant behaviour of the piezoelectric transducer. The method may comprise controlling a carrier frequency, duty cycle, power, modulation frequency or amplitude of the oscillating current from the drive circuitry.

The step of monitoring the resonant behaviour may comprise periodically applying an oscillating current with a different frequency and determining the resonant behaviour of the transducer at the different frequency. The method may comprise applying an oscillating current comprising a plurality of sinusoidal frequencies.

The invention may provide the advantage of efficient operation throughout operation, regardless of changing loads on the transducer and changing ambient conditions or device conditions. The invention may also provide a means for detecting malfunctions and abnormal operating conditions, such as a reduced supply of liquid aerosol-forming substrate.

<FIG> is a schematic illustration of a feedback control loop in accordance with the invention. The feedback loop comprises a transducer <NUM>, driver circuitry <NUM> and control circuitry <NUM>. The transducer in this example is a piezoelectric transducer. The transducer is coupled to and vibrates a membrane for generating an aerosol from a liquid supply. The transducer <NUM> is driven at a particular drive frequency by the drive circuitry <NUM>. The drive circuitry <NUM> supplies an oscillating current to the transducer, which causes it to expand and contract. This in turn causes the membrane to vibrate.

The transducer has one or more resonant frequencies. The resonant frequencies depend on several factors including the load on the transducer. The load on the transducer depends on the properties of the membrane and any load on the membrane. The resonant frequencies also depend on temperature, for example.

In order to ensure that the transducer is being driven at a resonant frequency by the drive circuitry, the control circuitry <NUM> completes a feedback loop. The control circuitry receives a feedback parameter from the transducer, for example a phase shift or a vibration amplitude. The value of the feedback parameter varies depending on how close the drive frequency is to the resonant frequency of the transducer. The drive circuitry <NUM> adjusts the drive frequency of the oscillating current applied to the transducer <NUM> and the effect of that change in drive frequency on the feedback parameter is monitored by the control circuitry. The control circuitry then sends a control signal to the drive circuitry and the drive circuitry adjusts the frequency of the applied oscillating current based on the control signal, in order to achieve particular effect. In many cases it is desirable to drive the transducer as close to a resonant frequency as possible. But in some circumstances it may be desirable to drive the transducer at a particular offset from a resonant frequency or at a frequency between resonant and anti-resonant frequencies. The control circuitry may comprise filters, a microcontroller or any analog or digital means to process the feedback parameter in order generate the control signal.

<FIG> is a schematic view of a first embodiment of an aerosol-generating device according to the invention, that incorporates the feedback control illustrated in <FIG>. <FIG> is schematic in nature. In particular, the components shown are not necessarily to scale either individually or relative to one another. The aerosol-generating device comprises a reusable device portion <NUM> in cooperation with a cartridge <NUM>, which is preferably disposable. In <FIG>, the device is an electrically operated smoking system.

The device portion <NUM> comprises a main body having a housing <NUM>. The housing <NUM> is substantially circularly cylindrical and has a longitudinal length of about <NUM> and an external diameter of about <NUM>, comparable to a conventional cigar. In the device, there is provided an electric power supply in the form of battery <NUM> and electric control circuitry <NUM>. The electric control circuitry <NUM> includes the drive circuitry and control circuitry for the transducer, as described with reference to <FIG>. The main body housing <NUM> also defines a cavity <NUM> into which the cartridge <NUM> is received.

The cartridge <NUM> (shown in schematic form in <FIG>) comprises a rigid housing defining a liquid storage portion <NUM>. The liquid storage portion <NUM> holds a liquid aerosol-forming substrate (not shown). The housing of the cartridge <NUM> is fluid impermeable but has an open end (not shown) that is coverable by a removable lid (not shown) when the cartridge is removed from the device <NUM>. The lid may be removed from the cartridge <NUM> before insertion of the cartridge into the device. The cartridge <NUM> includes keying features (not shown) to ensure the cartridge <NUM> cannot be inserted into the device upside-down.

The device portion <NUM> also includes a mouthpiece portion <NUM>. The mouthpiece portion <NUM> is connected to the main body housing <NUM> by a hinged connection in this example, but any kind of connection may be used, such as a snap fitting or a screw fitting. The mouthpiece portion <NUM> comprises a plurality of air inlets <NUM>, an air outlet <NUM> and an aerosol forming chamber <NUM>, and an atomiser <NUM> mounted therein (shown schematically in <FIG>). Air inlets <NUM> are defined between the mouthpiece portion <NUM> and the main body housing <NUM> of the device <NUM> when the mouthpiece portion is in a closed position, as shown in <FIG>. An air-flow route <NUM> is formed from the air inlets <NUM> to the air outlet <NUM> via the aerosol forming chamber <NUM> and the atomiser <NUM>, as shown in <FIG> by the arrows.

As shown in <FIG>, the atomiser <NUM> comprises a vibratable element <NUM> and transducer <NUM> housed inside an atomiser housing <NUM>. Atomiser housing <NUM> comprises a hollow cylindrical box, having an inlet opening <NUM> and an outlet opening <NUM> arranged in coaxial alignment at opposite sides of the housing <NUM>. The housing <NUM> is removably connected to the mouthpiece <NUM> of the device portion <NUM> by a screw thread connection (not shown). A male screw thread (not shown) is provided at an outer surface of the atomiser housing <NUM>, that is complimentary to a female screw thread (not shown) on an inner surface of the mouthpiece <NUM>. Atomiser <NUM> is removable from the mouthpiece portion <NUM> of the device portion for disposal or for cleaning.

Vibratable element <NUM> comprises a substantially circular aluminium disc, having a thickness of about <NUM> and a diameter of about <NUM>.

A plurality of passages <NUM> extends from an inlet side <NUM> to an opposing outlet side <NUM> of the vibratable element. The plurality of passages form an array having a substantially circular shape. The substantially circular array has a diameter of about <NUM>, and is arranged substantially centrally in the element <NUM>.

The passages (not shown) have a substantially circular cross-section and are tapered from the inlet side <NUM> to the outlet side <NUM> of the vibratable element <NUM>. The passages have a diameter at the inlet side of about <NUM> and a diameter at the outlet side of about <NUM>. The passages are typically formed by high-speed laser drilling. The plurality of passages is comprised of about <NUM> passages arranged with equal spacing across the array.

Transducer <NUM> comprises a piezoelectric transducer. The piezoelectric transducer is a substantially circular annular disc of piezoelectric material, typically zirconate titanate (PZT). The piezoelectric transducer has a thickness of about <NUM>, an outer diameter of about <NUM> and an inner diameter of about <NUM>.

As shown in <FIG>, the transducer <NUM> is in direct contact with the vibratable element <NUM>, at the outlet side <NUM> of the vibratable element. The inner diameter of the piezoelectric transducer <NUM> circumscribes the array of passages <NUM> of the vibratable element <NUM>, such that the open ends of the passages at the outlet side are not covered by the piezoelectric transducer <NUM>. In other embodiments (not shown) it is envisaged that the piezoelectric transducer <NUM> may be in direct contact with the vibratable element <NUM> at the inlet side <NUM>.

The vibratable element <NUM> and piezoelectric transducer <NUM> are supported within the atomiser housing <NUM> by a pair of elastomeric O-rings <NUM>, which allow the vibratable element <NUM> and the piezoelectric transducer <NUM> to vibrate within the housing <NUM>. The vibratable element <NUM> and piezoelectric transducer <NUM> are held together by pressure from the opposing O-rings <NUM>. However, in other embodiments (not shown) the vibratable element <NUM> and the piezoelectric transducer <NUM> may be bonded by any suitable means, such as an adhesive layer.

The vibratable element <NUM> and the piezoelectric transducer <NUM> are arranged within the atomiser housing <NUM> such that the array of passages <NUM> is in coaxial alignment with the inlet and outlet openings <NUM>, <NUM> of the housing <NUM>.

One or more spring pins <NUM> extend through an opening <NUM> in the atomiser housing <NUM> to provide electrical connection of the piezoelectric transducer <NUM> to the control circuitry <NUM> and the battery <NUM> of the device <NUM>. The one or more spring pins <NUM> are held in contact with the piezoelectric transducer <NUM> by pressure, rather than by a mechanical connection so that good electrical contact is maintained during vibration of the piezoelectric transducer <NUM>.

In use, when the atomiser <NUM> is removably connected to the mouthpiece portion <NUM> of the device portion <NUM> and the cartridge <NUM> is received in the cavity <NUM> of the device, an elongate capillary body (not shown in <FIG>) extends from the liquid storage portion <NUM> of the cartridge <NUM> to the atomiser <NUM> to fluidly connect the cartridge <NUM> to the atomiser <NUM>. As shown in <FIG>, the elongate capillary body <NUM> extends into the atomiser housing <NUM> and abuts the inlet side <NUM> of the vibratable element <NUM> at the array of passages <NUM>. Heating means is provided in the liquid storage portion in the form of a coil heater <NUM> surrounding the capillary body <NUM>. Note that the coil heater is only shown schematically in <FIG>. The coil heater <NUM> is connected to the electric circuitry <NUM> and battery <NUM> of the device <NUM> via connections (not shown), which may pass along the outside of the liquid storage portion <NUM>, although this is not shown in <FIG> or <FIG>.

In use, liquid aerosol-forming substrate (not shown) is conveyed by capillary action from the liquid storage portion <NUM> from the end of the capillary body <NUM> which extends into the liquid storage portion <NUM>, past the heater coil <NUM>, and to the other end of the capillary body <NUM>, which extends into the atomiser housing <NUM> and abuts the vibratable element <NUM> at the inlet side <NUM> at the array of passages <NUM>.

When a user draws on the air outlet <NUM> of the mouthpiece portion <NUM>, ambient air is drawn through air inlets <NUM>. In the embodiment of <FIG>, a puff detection device <NUM> in the form of a microphone, is also provided as part of the control electronics <NUM>. A small air flow is drawn through a sensor inlet <NUM> in the main body housing <NUM>, past the microphone <NUM> and up into the mouthpiece portion <NUM>. When a puff is detected by the electric circuitry <NUM>, the electric circuitry <NUM> activates the heater coil <NUM> and the piezoelectric transducer <NUM>. The battery <NUM> supplies electrical energy to the coil heater <NUM> to heat the capillary body <NUM> surrounded by the coil heater.

The battery <NUM> further supplies electrical energy to the piezoelectric transducer <NUM>, under the control of the drive and control circuitry, which vibrates, deforming in the thickness direction. The piezoelectric transducer <NUM> typically vibrates at around approximately <NUM>. The drive current supplied to the transducer has an initial frequency and wave shape based on parameters stored in memory. During manufacture of the device the frequency response of the transducer assembly, including the vibratable element <NUM>, can be characterised and an initial frequency and waveform set. The piezoelectric transducer <NUM> transmits the vibrations to the vibratable element <NUM>, which vibrates, also deforming in the thickness direction. An LED <NUM> is also activated to indicate that the device is activated. As will be described, during operation the feedback control loop is used to adjust the drive current supplied to the transducer in response to detected changes in resonant behaviour.

The coil heater <NUM> heats the liquid aerosol-forming substrate being conveyed along the capillary body, past the coil heater <NUM>, to a predetermined temperature of about <NUM>.

The vibrations in the vibratable element deform the plurality of passages <NUM>, which draws heated liquid aerosol-forming substrate from the capillary body <NUM>, through the plurality of passages <NUM> at the inlet side <NUM> of the vibratable element <NUM>, and ejects atomised droplets of liquid aerosol-forming substrate from the passages at the outlet side <NUM> of the vibratable element <NUM>, forming an aerosol. At the same time, the heated liquid being atomised is replaced by further liquid moving along the capillary body <NUM> by capillary action. (This is sometimes referred to as 'pumping action'). The aerosol droplets ejected from the vibratable element <NUM> mix with and are carried in the air flow <NUM> from the inlets <NUM> in the aerosol forming chamber <NUM>, and are carried towards the air outlet <NUM> of the mouthpiece <NUM> for inhalation by the user.

As previously described, during operation the resonant response of the transducer may change. <FIG> is a schematic plot of a sensed parameter from the transducer, showing a change in frequency over time. The distance in time between successive crossings of the signal through zero is a measure of frequency and may be used to synchronize the driving signal with the working frequency of the transducer, in this example its resonant frequency. The signal may be, for example, the current measured by a sense resistor in series with the transducer. In that case the amplitude may have a unit of Amperes for the current or the amplitude may be normalized, for example by its maximum value, in which case the unit of the amplitude is <NUM>. Time may have, for example, the unit of milliseconds or microseconds depending on the characteristic frequency working range covered by the transducer.

One specific example of a possible implementation of such a feedback loop is shown in <FIG>. The transducer <NUM>, which is connected to the vibratable perforated plate in the embodiment of <FIG>, is driven by a half-bridge <NUM>, consisting of two power MOSFETs <NUM>, <NUM>. An optional series inductor <NUM>, for example a <NUM> microhenrys inductor, may be used between the half-bridge and the transducer to tune impedance. The current sense resistor <NUM>, of for example <NUM> Ohm, may be placed at the low end of the transducer <NUM>. The voltage measured across the current sense resistor is proportional to the current through the transducer. This voltage signal may be filtered and amplified by filter and gain stage <NUM>. The filter and gain stage <NUM> may comprise, for example, a low pass filter, in order to cut off high frequency harmonics, and an FET amplifier, for example AD823, to amplify the signal. A comparator <NUM> creates the feedback signal, in this example a square wave signal as an appropriate input waveform for the gate driver <NUM>. The gate driver <NUM> may, for example, be an IC of type LT1162, and drives the half-bridge <NUM>. As the change in frequency is detected and sent back to the driver, the transducer <NUM> will be driven always at its working frequency, for example its resonant frequency. The drive and control circuitry shown in <FIG> can be incorporated into the control circuitry <NUM> shown in <FIG>.

<FIG> is an illustration of an aerosol-generating device according to another embodiment of the present invention. <FIG> is schematic in nature. In particular, the components shown are not necessarily to scale either individually or relative to one another. The device of <FIG> generates aerosol by heating a liquid aerosol-forming substrate using a heater. However the device includes a pump that uses a piezoelectric transducer to transport the liquid aerosol-forming substrate to the heater.

The device is a handheld, electrically operated smoking device <NUM> and comprises a housing <NUM>. Within the housing <NUM> there is an electric power supply in the form of battery <NUM> and control circuitry <NUM>. Also within the housing there is a liquid reservoir <NUM> containing a liquid aerosol-forming substrate that is vapourised in order to form an aerosol that is inhaled by a user. An atomiser assembly <NUM> is provided within the housing, coupled to the liquid reservoir <NUM>. The atomiser assembly comprises a vapouriser <NUM>, in this example an electrical heater, and a pump <NUM> positioned to pump liquid from the liquid reservoir <NUM> to the vapouriser <NUM>. Both the pump <NUM> and the electric heater <NUM> are provided with power from the battery <NUM> under the control of the control circuitry <NUM>, as will be described.

The housing <NUM> includes an air inlet <NUM> and an air outlet <NUM>. The air outlet <NUM> is provided at a mouthpiece end of the housing. In use, a user sucks on the mouthpiece end of the housing. This draws air through the air inlet <NUM> into the housing, past the vapouriser <NUM> and out through the outlet <NUM> into the user's mouth. The air drawn past the vapouriser entrains vapourised aerosol-forming substrate. The vapourised aerosol-forming substrate cools to form an aerosol as it moves through the device and into the user's mouth.

Activation of the heater may be controlled directly by a user pressing a button on the housing <NUM>. Alternatively, the system may comprise an airflow sensor, such as a microphone <NUM>, that detects airflow through the system and the heater may be activated based on signals from the airflow sensor. When a user draws air through the system, herein referred to as puffing, air flows past the air flow sensor <NUM>. If the airflow detected by the airflow sensor exceeds a threshold value, then the control circuitry may activate the heater by supplying power to the heater. The control circuitry may supply power to the heater for a predetermined time period or may supply power to the heater for as long as the detected airflow exceeds a threshold. The control circuitry may include temperature sensing means, such as a dedicated temperature sensor or by monitoring an electrical resistance of the heater. The control circuitry may then supply power to the heater to raise the temperature of the heater to within a desired temperature range. The temperature should be sufficient to vapourise the aerosol-forming substrate but not so high that there is a significant risk of combustion.

The liquid in this example comprises a mixture of water, glycerol, propylene glycol, nicotine and flavourings. The liquid is held within the liquid reservoir <NUM>. The liquid reservoir is provided as a cartridge that can be replaced when the liquid has been used up. In order to prevent leakage of the liquid, both before and during use, the liquid reservoir has a housing formed from a rigid plastics material, and is liquid tight. As used herein "rigid" means that the housing that is self-supporting. In this example, the reservoir is formed by 3D printing using an acrylic based photopolymer. The cartridge needs to be robust and able to withstand significant loads during shipping and storage. However, because the liquid reservoir housing is sealed and rigid, the liquid reservoir has a fixed internal volume. A reduction in the internal pressure inside the liquid reservoir as liquid is removed by the pump, could detrimentally affect the ability to pump liquid out of the reservoir. In order to prevent a significant drop in pressure, the liquid reservoir has an equalising air inlet valve <NUM>. The equalising valve <NUM> allows air into the liquid reservoir when the pressure difference between the inside the reservoir and outside of the reservoir exceeds a threshold pressure difference.

The pump may be activated in the same way as the heater. For example the control circuitry may supply power to the pump for the same time periods as power is supplied to the heater. Alternatively, the control circuitry may supply power to the pump in periods immediately following activation of the heater.

The control circuitry <NUM> includes a feedback loop as illustrated in <FIG> for control of the pump <NUM>. The pump <NUM> includes a piezoelectric transducer that drives a flexible diaphragm to vibrate. Vibration of the flexible diaphragm pushes liquid aerosol-forming substrate out of a pump chamber through an outlet valve as it reduces the chamber volume, and draws liquid aerosol-forming substrate into the pump chamber through an inlet valve as it increase chamber volume. In order maximise pumping efficiency, it is advantageous to operate the pump <NUM> at or close to a resonant frequency of the transducer. However, as previously described, the resonant frequency of the transducer may change for a number of reasons.

Changes in the resonant frequency of the transducer due to temperature changes, other environmental changes or aging can be monitored and the drive signal modified accordingly using one of the feedback mechanisms described above.

Claim 1:
An aerosol generating device comprising:
a piezoelectric transducer (<NUM>);
drive circuitry (<NUM>) connected to the piezoelectric transducer (<NUM>) and configured to apply an oscillating current to the transducer (<NUM>); and
control circuitry (<NUM>) connected to the drive circuitry (<NUM>) and configured to monitor the resonant behaviour of the piezoelectric transducer (<NUM>), the control circuitry (<NUM>) configured to control the operation of the drive circuitry based on the resonant behaviour of the piezoelectric transducer; wherein
the piezoelectric transducer (<NUM>) forms part of a transducer assembly in a liquid pump, and the transducer assembly comprises a membrane or surface configured to contact a liquid aerosol-forming substrate, the transducer assembly configured to drive the membrane or surface into vibration, the vibration of the membrane or surface forcing the liquid through an adjacent liquid valve in the liquid pump.