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    • 专利摘要:
    methods and apparatus for determining the temperature of a susceptor of an aerosol generating device are disclosed, the susceptor being for inductive heating by an rlc resonance circuit. the apparatus is arranged to: determine a peak frequency characteristic of a frequency response of the rlc resonance circuit; and determining, based on the frequency characteristic determined, the temperature of the susceptor. an aerosol generating device comprising the apparatus is also disclosed.
    公开号:BR112019020551A2
    申请号:R112019020551
    申请日:2018-03-27
    公开日:2020-04-28
    发明作者:Fallon Gary;Darryn White Julian;Daniel Horrod Martin;Abi Aoun Walid
    申请人:British American Tobacco Investments Ltd;
    IPC主号:
    专利说明:

    APPARATUS TO DETERMINE THE TEMPERATURE OF A SUSCEPTOR, AEROSOL GENERATING DEVICE, METHOD AND COMPUTER PROGRAM
    Technical Field [0001] The present invention relates to an apparatus and methods for determining the temperature of a susceptor of an aerosol generating device, more particularly of a susceptor to inductive heating by an RLC resonance circuit.
    Background [0002] Smoking articles, such as cigarettes, cigars and the like, smoke tobacco during use to create tobacco smoke. Attempts have been made to provide alternatives to these articles, creating products that release compounds without burning. Examples of such products are the so-called non-burning heat products or tobacco heating devices or products, which release compounds by heating, but without burning, the material. The material can be, for example, tobacco or other non-tobacco products, which may or may not contain nicotine.
    Summary [0003] According to a first aspect of the present invention, an apparatus is provided to determine the temperature of a susceptor of an aerosol generating device, the susceptor being for inductive heating by an RLC resonance circuit, the apparatus being arranged for : determine a characteristic frequency of a peak in a frequency response of the
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    2/42 RLC resonance circuit; and determining, based on the frequency characteristic determined, the temperature of the susceptor.
    [0004] The frequency characteristic can be a resonant frequency of the RLC resonance circuit.
    [0005] The frequency characteristic can be indicative of a peak bandwidth of the frequency response of the RLC circuit.
    [0006] The device can be arranged to: determine indicative temperature data according to the frequency characteristic; where the temperature is determined based on the determined data and the determined frequency characteristic.
    [0007] The data can comprise one or more parameters in a functional way that describe the temperature as a function of the frequency characteristic.
    [0008] The data can be a constant of proportionality between the temperature and the frequency characteristic.
    [0009] Data can comprise a series of data points
    of the temperature measured frequency. in occupation gives feature in [0010] The device can to be willing to determine, with based on feature in frequency determined, an
    resistance of the RLC circuit; where the temperature determination is based on the determined resistance of the RLC circuit.
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    3/42 [0011] The device can be arranged to: determine a temperature resistance constant for the susceptor; wherein the temperature determination is based on the determined resistance and the resistance constant at the determined temperature.
    [0012] The apparatus can be arranged to: determine a reference characteristic indicative of the frequency characteristic at a reference temperature; compare the determined frequency characteristic with the determined reference characteristic; where the temperature determination is based on the comparison of the determined frequency characteristic with the reference characteristic.
    [0013] The apparatus may be arranged to: measure the reference characteristic substantially at the start of the aerosol generating device and / or substantially at the installation of a new susceptor and / or replacement of the susceptor for the aerosol generating device and / or substantially at installation of a new inductor and / or replacement inductor in the aerosol generating device.
    [0014] The device can be arranged to: measure an electrical property of the RLC circuit as a function of an activation frequency at which the RLC circuit is activated; wherein the determination of the frequency characteristic is based on the measured electrical property of the RLC circuit as a function of a drive frequency at which the RLC circuit is driven.
    [0015] The electrical property can be a voltage measured through an RLC circuit inductor, the inductor being for transferring energy to the susceptor.
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    4/42 [0016] The measurement of electrical property can be a passive measure.
    [0017] The electrical property can be indicative of a current induced in a sensor coil by an inductor of the RLC circuit, the inductor being for transferring energy to the susceptor.
    [0018] The electrical property can be indicative of a current induced in a pick-up coil by a supply voltage element, the supply voltage element being to supply voltage to a drive element, the drive element being to drive the RLC circuit.
    [0019] According to a second aspect of the present invention, an aerosol generating device is provided comprising: a susceptor arranged to heat an aerosol generating material, to thereby generate an aerosol in use; an RLC resonance circuit arranged to inductively heat the susceptor in use; and the apparatus according to the first aspect.
    [0020] The susceptor may comprise nickel.
    [0021] The susceptor may comprise a body having a nickel coating.
    [0022] The nickel coating can be less than substantially 5 pm thick or substantially in the range 2 pm to 3 pm.
    [0023] The nickel coating can be galvanized on the body.
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    5/42 [0024] The susceptor may comprise one or more of steel, iron and cobalt.
    [0025] The susceptor may be a sheet of mild steel.
    [0026] The sheet of mild steel may have a thickness in the range of substantially 10 pm to substantially 50 pm, or it may have a thickness of substantially 25 pm.
    [0027] According to a third aspect of the present invention, a method is provided for determining the temperature of a susceptor of an aerosol generating device, the susceptor being for inductive heating by an RLC resonance circuit, the method comprising: determining a frequency characteristic of a peak of a frequency response of the RLC resonance circuit; and determining, based on the frequency characteristic determined, the temperature of the susceptor.
    [0028] According to a fourth aspect of the present invention, a computer program is provided which, when executed by a processing system, causes the processing system to execute the method according to the third aspect.
    [0029] Other features and advantages of the invention will become apparent from the following description of the preferred embodiments of the invention, given by way of example only, which are made with reference to the accompanying drawings.
    Brief Description of the Drawings [0030] Figure 1 schematically illustrates an aerosol generating device according to an example;
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    6/42 [0031] Figure 2 schematically illustrates an RLC resonance circuit according to a first example;
    [0032] Figure 2b schematically illustrates an RLC resonance circuit according to a second example;
    [0033] Figure 2c schematically illustrates an RLC resonance circuit according to a third example;
    [0034] Figure 3a schematically illustrates an example of the frequency response of an example of an RLC resonance circuit;
    [0035] Figure 3b schematically illustrates an example of frequency response of an example of RLC resonance circuit, at two different susceptor temperatures TI and T2, according to an example;
    [0036] Figure 3c schematically illustrates an example of frequency response of an example of RLC resonance circuit, at two different susceptor temperatures TI and T2, according to another example; and [0037] Figure 4 is a flow chart that schematically illustrates an example method.
    Detailed Description [0038] Induction heating is a process of heating an electrically conductive object (or susceptor) by electromagnetic induction. An induction heater may comprise an electromagnet and a device for passing a variable electrical current, such as alternating electrical current, through the
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    7/42 electromagnet. The variable electric current in the electromagnet produces a variable magnetic field. The variable magnetic field penetrates a susceptor positioned properly in relation to the electromagnet, generating eddy currents within the susceptor. The susceptor has electrical resistance to eddy currents and, therefore, the flow of eddy currents against this resistance causes the susceptor to be heated by Joule heating. In cases where the susceptor comprises ferromagnetic material, such as iron, nickel or cobalt, heat can also be generated by losses of magnetic hysteresis in the susceptor, that is, by the variable orientation of the magnetic dipoles in the magnetic material, as a result of its alignment with the variable magnetic field.
    [0039] In inductive heating, compared to heating by conduction, for example, heat is generated inside the susceptor, allowing rapid heating. In addition, no physical contact between the inductive heater and the susceptor is necessary, allowing greater freedom in construction and application.
    [0040] The electrical resonance occurs in an electrical circuit at a specific resonant frequency when the imaginary parts of impedances or admissions of elements of the circuit are canceled. An example of a circuit showing electrical resonance is an RLC circuit, which comprises a resistor (R) provided by a resistor, an inductance (L) provided by an inductor, and a capacitance (C) provided by a capacitor, connected in series. Resonance occurs in an RLC circuit because the collapsing magnetic field of the inductor generates an electrical current in its windings that charges the capacitor, while
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    8/42 that the discharge capacitor provides an electric current that builds the magnetic field in the inductor. When the circuit is activated at the resonant frequency, the series impedance of the inductor and capacitor is minimal and the circuit current is maximum. The resonance frequency and bandwidth of the RLC resonance circuit depends on the capacitance, inductance and resistance in the circuit.
    [0041] Figure 1 schematically illustrates an example of an aerosol generating device 150 comprising an RLC resonance circuit 100 for inductively heating an aerosol generating material 164 through a susceptor 116. In some examples, the susceptor 116 and the aerosol generation 164 form an integral unit that can be inserted and / or removed from the aerosol generating device 150 and can be disposable. The aerosol generating device 150 is portable. The aerosol generating device 150 is arranged to heat the aerosol generating material 164 to generate aerosol for inhalation by a user.
    [0042] It is noted that, as used herein, the term aerosol-generating material includes materials that provide volatilized components upon heating, typically in the form of steam or aerosol. The aerosol generating material can be a non-tobacco material or a tobacco-containing material. The aerosol-generating material can, for example, include one or more of the tobacco itself, tobacco derivatives, expanded tobacco, reconstituted tobacco, tobacco extract, homogenized tobacco or tobacco substitutes. The aerosol-generating material may be in the form of ground tobacco, cut rag tobacco, tobacco
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    9/42 extruded, reconstituted tobacco, reconstituted material, liquid, gel, gelled leaf, powder or agglomerates, or the like. The aerosol-generating material can also include other non-tobacco products which, depending on the product, may or may not contain nicotine. The aerosol-generating material may comprise one or more humectants, such as glycerol or propylene glycol.
    [0043] Returning to Figure 1, the aerosol generating device 150 comprises an external body 151 that houses the resonance circuit RLC 100, the susceptor 116, the aerosol generating material 164, a controller 114 and a battery 162. A battery is arranged to energize the resonance circuit RLC 100. Controller 114 is arranged to control the resonance circuit RLC 100, for example, to control the voltage supplied to the resonance circuit RLC 100 from battery 162, and the frequency f in the which the RLC 100 resonance circuit is triggered. The resonance circuit RLC 100 is arranged for inductive heating of the susceptor 116. The susceptor 116 is arranged to heat the aerosol generating material 364 to generate an aerosol in use. The outer body 151 comprises a nozzle 160 to allow the aerosol generated in use to exit the device 150.
    [0044] In use, a user can activate, for example, via a button (not shown) or a puff detector (not shown) which is known per se, controller 114 to make the RLC 100 resonance circuit be activated, for example, at the resonant frequency f r of the RLC 100 resonance circuit. The resonance circuit 100 thus heats up by induction
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    10/42 the susceptor 116, which in turn heats the aerosol generating material 164, and causes the aerosol generating material 164, in this way, to generate an aerosol. The aerosol is generated in the air sucked into the device 150 from an air inlet (not shown) and is thus transported to the nozzle 160, where the aerosol exits the device 150.
    The controller 114 and the device 150 as a whole can be arranged to heat the aerosol generating material to a temperature range to volatilize at least one component of the aerosol generating material without burning the aerosol generating material. For example, the temperature range can be from about 50 ° C to about 350 ° C, such as between about 50 ° C and about 250 ° C, between about 50 ° C and about 150 ° C, between about 50 ° C and about 120 ° C, between about 50 ° C and about 100 ° C, between about 50 ° C and about 80 ° C, or between about 60 ° C and about 70 ° C. In some examples, the temperature range is between about 170 ° C and about 220 ° C. In some examples, the temperature range may be different from that range and the upper limit of the temperature range may be greater than 300 ° C.
    [0046] It is desirable to determine the temperature of susceptor 116, for example, for the purpose of controlling the heating of aerosol generating material 164, for example, to ensure that it is not heated beyond a certain temperature, for example, so that it does not burn or carbonize, or so that it is heated to a certain temperature or according to a certain temperature profile, for example. For example, it may be desirable that the temperature of susceptor 116 does not exceed 400 ° C in order to ensure
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    11/42 that susceptor 116 does not cause aerosol generating material 164 to burn or carbonize. It should be noted that there may be a difference between the temperature of the susceptor 116 and the temperature of the aerosol generating material 164 as a whole, for example, during heating of the susceptor 116, for example, where the heating rate is large. Therefore, it should be noted that, in some instances, the temperature at which susceptor 116 is controlled or must not exceed may be greater than the temperature at which it is desired that the aerosol generating material 164 be heated or that it should not be heated. exceed, for example.
    [0047] According to examples of the present invention, an apparatus (for example, controller 114) is arranged to determine the temperature of susceptor 116. In a broad overview, and as described in more detail below, controller 114 is arranged to determine a peak frequency characteristic of a frequency response from the RLC 100 resonance circuit. The frequency characteristic varies with the variable temperature of susceptor 116. The frequency characteristic can be, for example, the resonant frequency or the width peak bandwidth. The controller is arranged to determine the temperature of susceptor 116 based on the determined frequency characteristic. Determining the temperature of susceptor 116 based on a peak frequency characteristic of a frequency response from the RLC 100 resonance circuit allows determining the temperature of susceptor 116 without requiring physical contact with susceptor 116 and therefore allows greater freedom design of the aerosol generating device 150, for example.
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    12/42 [0048] Referring now to Figure 2a, an example of an RLC resonance circuit 100 for inductive heating of the susceptor 116 is illustrated. The resonance circuit 100 comprises a resistor 104, a capacitor 106 and an inductor 108 connected in series . The resonance circuit 100 has a resistance R, an inductance L and a capacitance C.
    [0049] Inductance L of circuit 100 is provided by inductor 108 arranged for inductive heating of susceptor 116. Inductive heating of susceptor 116 is through an alternating magnetic field generated by inductor 108, which, as mentioned above, induces heating Joule and / or losses of magnetic hysteresis at susceptor 116. A portion of inductance L of circuit 100 may be due to the magnetic permeability of susceptor 116. The alternating magnetic field generated by inductor 108 is generated by an alternating current flowing through inductor 108 The alternating current flowing through inductor 108 is an alternating current flowing through the RLC 100 resonance circuit. Inductor 108 may, for example, be in the form of a coiled wire, for example, a copper coil. Inductor 108 may comprise, for example, a Litz wire, for example, a wire comprising a number of individually insulated wires twisted together. Litz wires can be particularly useful when drive frequencies f in the MHz band are used, as this can reduce energy loss due to the effect of the skin, as it is known per se. At these relatively high frequencies, lower inductance values are required. As another example, inductor 108 can be a spiral strip on a printed circuit board. The use of a spiral strip on a printed circuit board can be
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    13/42 useful, as it provides a rigid and self-supporting strip, with a cross section that avoids any requirement for Litz yarn (which can be expensive), which can be mass produced with high reproducibility at low cost. Although an inductor 108 is shown, it will readily be realized that there may be more than one inductor arranged for inductive heating of one or more susceptors 116.
    [0050] Capacitance C of circuit 100 is provided by capacitor 106. Capacitor 106 can be, for example, a Class 1 ceramic capacitor, for example, a COG capacitor. Capacitance C can also comprise the lost capacitance of circuit 100; however, this is or may be negligible compared to capacitance C provided by capacitor 106.
    [0051] Resistance R of circuit 100 is provided by resistor 104, resistance of the strip or wire connecting the components of resonance circuit 100, resistance of inductor 108, and resistance to current flowing in the supplied resonance circuit 100 by susceptor 116 arranged for energy transfer with inductor 108. It should be noted that circuit 100 does not necessarily need to comprise resistor 104 and that resistance R in circuit 100 can be provided by the resistance of the connecting strip or wire, inductor 108 and susceptor 116.
    [0052] Circuit 100 is driven by the H 102 bridge actuator. The H 102 Bridge actuator is a trigger element to supply alternating current in the resonance circuit 100. The H 102 bridge actuator is connected to a DC voltage source.
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    14/42
    Vsupp 110, and a GND 112 electrical ground. The DC Vsupp 110 voltage source can be, for example, from battery 162. The H 102 bridge can be an integrated circuit, or can comprise discrete switching components (not shown) ), which can be solid state or mechanical. The H 102 bridge actuator can be, for example, a High Efficiency Bridge Rectifier. As is known per se, the H 102 bridge driver can supply alternating current in circuit 100 from the DC Vsupp 110 voltage source by reversing (and then restoring) the voltage across the circuit via switching components (not shown). This can be useful as it allows the RLC resonance circuit to be powered by a DC battery and allows the frequency of the alternating current to be controlled.
    [0053] The Bridge actuator H 104 is connected to a controller 114. Controller 114 controls Bridge H 102 or its components (not shown) to supply an alternating current I in the resonance circuit RLC 100 at a given drive frequency f . For example, the drive frequency f can be in the range of MHz, for example, 0.5 MHz to 4 MHz, for example, in the range of 2 MHz to 3 MHz. It should be noted that other frequencies f or frequency ranges can be used, for example, depending on the particular resonance circuit 100 (and / or its components), controller 114, susceptor 116 and / or driver element 102 used. For example, it should be noted that the resonant frequency f r of circuit RLC 100 is dependent on inductance L and capacitance C of circuit 100, which in turn is dependent on inductor 108, capacitor 106 and susceptor 116. The frequency ranges switching frequency f may be around the resonant frequency f r
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    15/42 of the particular RLC circuit 100 and / or susceptor 116 used, for example. It should also be noted that the resonance circuit 100 and / or the drive frequency or the drive frequency range f used can be selected based on other factors for a given susceptor 116. For example, to improve the energy transfer of the inductor 108 for susceptor 116, it may be useful to predict that the depth of the skin (i.e. the depth of the surface of susceptor 116 within which the alternating magnetic field of inductor 108 is absorbed) is less, for example, a factor of two three times less than the thickness of the susceptor material 116. The depth of the skin differs for different materials and construction of susceptors 116 and decreases with increasing frequency of activation f. In some instances, therefore, it may be beneficial to use relatively high drive frequencies f. On the other hand, for example, to reduce the proportion of energy supplied to the resonance circuit 100 and / or actuator element 102 that is lost as heat within the electronics, it may be beneficial to use lower drive frequencies. In some instances, a compromise between these factors can therefore be chosen as appropriate and / or desired.
    [0054] As mentioned above, controller 114 is arranged to determine the temperature of susceptor 116 by determining a peak frequency characteristic of the frequency response of the RLC 100 resonance circuit and determining the temperature of susceptor 116 based on the characteristic determined.
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    16/42 [0055] Figure 3a schematically illustrates a frequency response 300 of resonance circuit 100. In the example of Figure 3a, frequency response 300 of resonance circuit 100 is illustrated by a schematic graph of current I flowing in the circuit 100 as a function of the drive frequency f in which the circuit is driven by the H bridge controller 104.
    [0056] The resonance circuit 100 of Figure 2a has a resonant frequency f r at which the Z series impedance of inductor 108 and capacitor 106 is minimal and therefore circuit current I is maximum. Therefore, as illustrated in Figure 2a, when the bridge actuator H 104 drives circuit 100 at resonant frequency f r , the alternating current I in circuit 100 and, therefore, in inductor 108 will be maximum Imax. The oscillating magnetic field generated by inductor 106 will therefore be maximum and, therefore, the inductive heating of susceptor 116 by inductor 106 will be maximum. When the bridge actuator H 104 drives circuit 100 at a frequency f, which is out of resonance, that is, above or below the resonant frequency f r , the alternating current I in circuit 100, and therefore inductor 108, will be less than the maximum, and therefore the oscillating magnetic field generated by inductor 106 will be less than the maximum, and therefore the inductive heating of susceptor 116 by inductor 106 will be less than the maximum. As can be seen in Figure 3a, therefore, the frequency response 300 of the resonance circuit 100 has a peak, centered on the resonant frequency f r , and decreasing on the frequencies above and below the resonant frequency f r .
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    17/42 [0057] As mentioned above, controller 114 is arranged to determine a peak frequency characteristic of the frequency response 300 of the RLC resonance circuit 100. The characteristic of the frequency response peak 300 of the resonance circuit 100 can be the resonant frequency f r on which the peak is centered, for example. As another example, the peak characteristic of the frequency response 300 of the resonant circuit 100 may be a peak width. The peak width can be characterized by the peak bandwidth B, which in the example shown in Figure 2a is the total peak width in Αμχ / λ / Σ.
    [0058] In some examples, to determine the peak frequency characteristic, controller 114 is willing to measure a frequency response 300 from the RLC 100 resonance circuit. For example, the controller may be willing to measure an electrical property of the circuit RLC 100 as a function of the activation frequency f at which the RLC circuit must be activated. Controller 114 may comprise a clock generator (not shown) to determine the absolute frequency at which the RLC circuit 100 is to be driven. Controller 114 may be arranged to control bridge H 104 to sweep across a range of drive frequencies f over a period of time. The electrical property of the RLC circuit 100 can be measured during the scanning of drive frequencies and therefore the frequency response 300 of the RLC circuit 100 as a function of the drive frequency f can be determined.
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    18/42 [0059] The measurement of electrical property can be a passive measurement, that is, a measurement that does not involve any direct electrical contact with the resonance circuit 100.
    [0060] For example, with reference again to the example shown in Figure 2a, the electrical property may be indicative of a current induced in a sensor coil 120a by inductor 108 of the RLC circuit 100. As illustrated in Figure 2a, the sensor coil 120a is positioned for transferring energy from inductor 108 and is arranged to detect current I flowing in circuit 100. Sensor coil 120a can be, for example, a wire coil or a strip on a printed circuit board. For example, if inductor 108 is a strip on a printed circuit board, the sensor coil 120a can be a strip on a printed circuit board and positioned above or below inductor 108, for example, in a plane parallel to the plane of inductor 108. As another example, in the example where there is more than one inductor 108, the sensing coil 120a can be placed between inductors 108, for energy transfer from both inductors. For example, if inductors 108 are strips on a printed circuit board and located in a plane parallel to each other, the sensor coil 120a can be a strip on a printed circuit board between the two inductors and on a parallel plane. to inductors 108.
    [0061] In any case, the alternating current I flowing in circuit 100 and, therefore, in inductor 108, causes inductor 108 to generate an alternating magnetic field. The alternating magnetic field induces a current in the sensing coil 120a. The current induced in the sensor coil 120a produces a voltage Vind through the
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    19/42 sensor coil 120a. The voltage Vind through the sensor coil 120a can be measured and is proportional to the current I flowing in the RLC circuit 100. The voltage Vind through the sensor coil 120a can be recorded as a function of the drive frequency f at which the bridge actuator H 104 is driving resonance circuit 100 and therefore a frequency response 300 of circuit 100 is determined. For example, controller 114 can record a measurement of voltage Vind through sensor coil 120a as a function of the frequency f at which it is controlling the bridge actuator H 104 to drive alternating current in resonance circuit 100. The controller can then analyze the frequency response 300 to determine a frequency characteristic of a peak of frequency response 300, for example, the resonant frequency f r at which the peak is centered, or the peak bandwidth B.
    [0062] Figure 2b illustrates another example of passive measurement of an electrical property of the RLC 100 circuit. Figure 2b is the same as Figure 2a, except that the sensor coil 120a of Figure 2a is replaced by a pickup coil 120b . As illustrated in Figure 2b, the pickup coil 120b is placed so as to intercept a portion of a magnetic field produced by the DC supply voltage wire or range 110 when the current flowing through it changes due to changes in the demands of the RLC circuit 100. The magnetic field produced by changes in the current flowing in the DC supply voltage wire or in the range 110 induces a current in the pickup coil 120b, which produces a voltage Vind through the pickup coil 120b. For example, although, in an ideal case, the current flowing in the wire or DC 110 voltage supply range is only current
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    In practice, the current flowing in the wire or DC supply voltage range can be modulated to some extent by the bridge actuator H 104, for example, due to imperfections in the switching in the bridge actuator H 104. These Current modulations induce a current in the pick-up coil, which is detected through the voltage Vind through the pick-up coil 120b.
    [0063] The voltage Vind through the pickup coil 120b can be measured and recorded as a function of the drive frequency f in which the bridge actuator H 104 is driving the resonance circuit 100 and therefore a frequency response 300 of the circuit 100 is determined. For example, controller 114 can record a measurement of voltage Vind through pickup coil 120a as a function of the frequency f at which it is controlling the bridge actuator H 104 to drive alternating current in resonance circuit 100. The controller can then analyze the frequency response 300 to determine a frequency characteristic of a peak of the frequency response 300, for example, the resonant frequency f r at which the peak is centered, or the bandwidth B of the peak.
    [0064] It should be noted that, in some examples, it may be desirable to reduce or remove the modulated component of the current in the wire or DC 110 voltage supply range that can be caused by imperfections in the H 104 bridge actuator. This can be achieved , for example, implementing a bypass capacitor (not shown) through the bridge actuator H 104. It should be noted that in this case, the electrical property of the RLC circuit 100 used to determine the frequency response 300 of the
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    21/42 circuit 100 can be measured by means other than the pickup coil 120b.
    [0065] Figure 2c illustrates an example of an active measurement of an electrical property of the RLC circuit. Figure 2c is the same as Figure 2a, except that the sensor coil 120a of Figure 2a is replaced by an element 120c, for example, a passive differential circuit 120c, arranged to measure voltage Vl through inductor 108. As the current I in the resonance circuit 100 changes, the voltage V1 through inductor 108 changes. The voltage V1 through inductor 108 can be measured and recorded as a function of the drive frequency f at which the bridge actuator H 104 drives the resonance circuit 100 and, therefore, a frequency response 300 of circuit 100 is determined. For example, controller 114 can record a voltage measurement Vl through inductor 108 as a function of the frequency f at which it is controlling the bridge actuator H 104 to drive alternating current in resonance circuit 100. Controller 114 can then analyze the frequency response 300 to determine a frequency characteristic of a peak of frequency response 300, for example, the resonant frequency f r at which the peak is centered, or the peak bandwidth B.
    [0066] In each of the examples illustrated in Figures 2a to 2c, or otherwise, controller 114 can analyze frequency response 300 to determine a frequency characteristic of a peak frequency response 300, for example, the frequency resonant f r over which the peak is centered or the peak bandwidth B. For example, controller 114
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    22/42 can use known data analysis techniques to determine the peak frequency characteristics. For example, the controller can infer the resonant frequency fr and / or the bandwidth B directly from the frequency response data. For example, for the resonant frequency fr, controller 114 can determine the frequency f at which the highest response was recorded as the resonant frequency fr, or it can determine the frequencies f for which the two largest responses were recorded and average these. two frequencies f as the resonant frequency fr. For bandwidth B, controller 114 can determine the frequencies f at which the response was 1 / V2 of the highest response and determine the difference between those two frequencies such as bandwidth B, for example. As another example, controller 114 can adjust a function that describes current I (or another response) as a function of frequency f for an RLC circuit to the frequency response data and infer or calculate from the adjusted function the resonant frequency fr and / or the peak bandwidth B of the frequency response data.
    [0067] As mentioned above, controller 114 is arranged to determine the temperature of susceptor 116 based on the determined frequency characteristic of the peak frequency response 300 of resonance circuit 100.
    [0068] In one example, the peak characteristic of the frequency response 300 of resonant circuit 100 is the resonant frequency fr on which the peak is centered, for example, measured in Hz. The resonant frequency fr of circuit 100 depends on capacitance C and inductance L of circuit 100 and is given by:
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    23/42 f r y / LC (1) [0069] The inductance L of inductor 108 and, therefore, of resonance circuit 100 is dependent on the magnetic permeability μ of susceptor 116. Magnetic permeability μ is a measure of the capacity of a material to support the formation of a magnetic field within itself, and expresses the degree of magnetization that a material obtains in response to an applied magnetic field. The greater the magnetic permeability μ of susceptor 116, the greater the inductance L. The magnetic permeability μ of a material from which susceptor 116 is composed can change with temperature.
    [0070] For example, for ferromagnetic and ferrimagnetic materials such as iron, nickel, cobalt and their alloys, the saturation magnetization (ie the maximum magnetization obtained for an applied magnetic field) decreases as the material temperature approaches of its Curie T c temperature, temperature at which the material's permanent magnetic properties are lost. For example, the nickel Curie T c temperature is 358 ° C, and the relative change in saturation magnetization for nickel at 250 ° C, compared to 358 ° C, is greater than 50%. Therefore, in this case, as the temperature of the susceptor 116 increases when approaching the Curie T c temperature, the magnetic permeability μ of the susceptor 116 will decrease and, therefore, the inductance L in the resonance circuit 100 will decrease, and, therefore, through equation (1), the resonant frequency fr on which the peak is centered will increase.
    [0071] Figure 3b schematically illustrates a 360, 370 frequency response of resonance circuit 100 for which
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    24/42 susceptor 116 is at two different temperatures TI (solid curve 360) and T2 (dashed curve 370), where T2 is greater than Tl. In the example of Figure 3b, the frequency response 360, 370 of resonance circuit 100 is illustrated by a schematic graph of current I flowing in circuit 100 as a function of the drive frequency f at which circuit 100 is driven. As mentioned above, when susceptor 116 is at the lowest temperature T1, the inductance L of circuit 100 is LI and the resonant frequency f r is fri. However, when susceptor 116 is at the highest temperature T2 (which is below, but approaching the temperature of Curie T c of the material from which susceptor 116 is composed), the inductance L of circuit 100 decreases to L2, and, therefore, the resonant frequency f r of circuit 100 increases to f r 2.
    [0072] Therefore, by determining the resonant frequency f r of circuit 100, controller 114 can determine, for example, to infer or calculate (as described in more detail below), the temperature of susceptor 116.
    [0073] Using the resonant frequency f r of circuit 100 to determine the temperature of susceptor 116 can be useful in cases, for example, where the working temperature range of susceptor 116 (i.e., the temperature range at which the susceptor 116 must be heated in the aerosol generating device 150) is lower than the Curie temperature T c of the susceptor 116 (or a material that comprises the susceptor 116). This can avoid a given resonant frequency f r corresponding to more than one temperature of susceptor 116 and, therefore, allow a more accurate temperature measurement. In addition, using the
    Petition 870190097791, of 09/30/2019, p. 36/68
    25/42 resonance frequency f r of circuit 100 to determine the temperature of susceptor 116 can be useful in cases, for example, where the operating temperature range of susceptor 116 is in the region of, that is, approaching, the temperature Curie T and susceptor 116 (or a material that the susceptor comprises 116). This is because the saturation magnetization of ferromagnetic or ferromagnetic materials changes more rapidly as a function of the temperature in the region of, that is, approaching, the temperature of Curie T c of the material, compared to temperatures distant from the temperature of Curie T c of material. Therefore, in the region of, that is, approaching the Curie Temperature T c of the material, a given temperature change will result in a greater change in the saturation magnetization of susceptor 166, and, consequently, change the resonant frequency f r of the resonance circuit 100, and, consequently, will allow a more sensitive measurement of the temperature of susceptor 116.
    [0074] As a specific example, susceptor 116 may comprise nickel. For example, susceptor 116 may comprise a body or substrate having a thin nickel coating. For example, the body may be a sheet of mild steel with a thickness of about 25 pm. In other examples, the sheet may be made of a different material, such as aluminum or plastic or stainless steel or other non-magnetic materials and / or may have a different thickness, such as between 10 pm and 50 pm. The body can be coated or galvanized with nickel. Nickel can, for example, be less than 5 pm thick, such as between 2 pm and 3 pm. The coating or galvanizing may be of another material. Supply susceptor 116 with only
    Petition 870190097791, of 09/30/2019, p. 37/68
    26/42 a relatively small thickness can help to reduce the time required to heat susceptor 116 in use. A sheet shape of the susceptor 116 can allow a high degree of efficiency of thermal coupling of the susceptor 116 to the aerosol generating material 164. The susceptor 116 can be integrated into a consumable comprising the aerosol generating material 164. A thin sheet of the material of the susceptor 116 can be particularly useful for this purpose. The susceptor 116 may be disposable. Such a susceptor 116 can be cost-effective.
    [0075] Nickel is ferromagnetic. The nickel Curie T c temperature is 358 ° C. In one example, the nickel-coated or galvanized susceptor 116 can be heated to temperatures in the range of about 200 ° C to about 300 ° C, which can be working range of the 350 aerosol generating device. The change in nickel saturation magnetization at 250 ° C is 50% over the room temperature value. Therefore, in this case, measuring the resonance frequency f r of the resonance circuit 100 will allow an accurate and sensitive determination of the temperature of the susceptor 116.
    [0076] However, other materials that susceptor 116 can comprise or be made of, such as iron or cobalt or mild steel, may have a higher Curie temperature T c that may be relatively distant from the working temperature range of susceptor 116 in a given aerosol generating device 350. For example, a mild steel susceptor 116 may have a Curie T c temperature around 770 ° C. In that case, the change in saturation magnetization of the material such as steel at 250 ° C can be relatively small, for example, less than 10% in
    Petition 870190097791, of 09/30/2019, p. 38/68
    27/42 relative to the value at room temperature and, therefore, the resulting change in inductance L and, therefore, in the resonant frequency f r of circuit 100 at different temperatures in the working range of the example can be relatively small.
    [0077] It may be beneficial to use a material for susceptor 116 for which the Curie T c temperature is distant and above the working temperature range of the device, as this can help to avoid the reduction in inductive heating efficiency that may occur with a reduction in saturation magnetization of the material near the Curie temperature T c.
    [0078] Another characteristic of the peak frequency response 300 of resonant circuit 100 is a peak width. The peak width can be characterized by the peak bandwidth B. The peak bandwidth B is the total peak width in Hz at Imax / y / 2. The peak bandwidth B depends on the inductance L and the resistance R of the series 100 resonance circuit and is given by:
    n B = T (1) [0079] As mentioned above, the resistance R of circuit 100 is provided, at least in part, by the resistance of susceptor 116 to eddy currents induced in it by inductor 108, which, in turn, increases the resistance of inductor 108 arranged for inductive heating of susceptor 116. Resistance R of susceptor 116 (and therefore of inductor 108 and therefore of circuit 100) can vary with the temperature of susceptor 116.
    [0080]
    For example, for susceptors 116 comprising conductors, such as iron, cobalt or steel, resistance R increases
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    28/42 with increasing temperature, for example, increases linearly or almost linearly, or at least monotonically, with increasing temperature of susceptor 116. Therefore, as the temperature of susceptor 116 increases, the resistance of susceptor 116 increases , which in turn increases the resistance of inductor 108, which in turn increases the resistance R of the resonance RLC circuit 100, which in turn, through equation (2), increases the bandwidth B of the peak response of the resonance circuit 100.
    [0081] Figure 3c schematically illustrates a frequency response 380, 390 of resonance circuit 100 for which susceptor 116 is at two different temperatures TI (solid curve 380) and T2 (dashed curve 390), where T2 is greater that Tl. In the example of Figure 3c, the frequency response of resonance circuit 100 is illustrated by a schematic graph of current I flowing in circuit 100 as a function of the drive frequency f at which circuit 100 is driven. When susceptor 116 is at the lowest temperature T1, resistance R of circuit 100 is RI and the peak bandwidth B is Bl. However, as mentioned above, when susceptor 116 is at the highest temperature T2, resistance R of circuit 100 increases to R2 and therefore the bandwidth B of the peak response of resonance circuit 100 increases to B2.
    Therefore, when determining the peak bandwidth B of the response 380, 390 of circuit 100, controller 114 can determine, for example, to infer or calculate (as described in more detail below), the temperature of susceptor 116.
    Petition 870190097791, of 09/30/2019, p. 40/68
    29/42 [0083] Using the peak bandwidth B of response 380, 390 of circuit 100 to determine the temperature of susceptor 116 may be useful in cases, for example, where the operating temperature range of susceptor 116 (ie is the temperature range a in which the susceptor 116 must be heated in the device aerosol generator 350) is spaced from, i.e. not close, the Curie temperature T c of the susceptor 116 (or a material from which the susceptor 116 is done). In these cases, the inductance L of the circuit 100 can remain relatively constant at different temperatures and, therefore, the resistance R of the circuit 100 and, therefore, the temperature of the susceptor 116, can be determined directly from the determined bandwidth B. This allows for simple determination of the temperature of susceptor 116.
    [0084] As a specific example, susceptor 116 may be or comprise steel. The susceptor 116 can be a sheet of mild steel with a thickness between about 10 pm and about 50 pm, for example, a thickness of about 25 pm. Providing the susceptor 116 with only a relatively small thickness can help reduce the time required to heat the susceptor in use. The susceptor 116 can be integrated with the apparatus 105, for example, instead of being integrated with the aerosol generating material 164, which material can be disposable. However, susceptor 116 may be removable from apparatus 115, for example, to allow replacement of susceptor 116 after use, for example, after degradation due to thermal stress and oxidation by use. The susceptor 116 can therefore be semi-permanent, in that it must be replaced infrequently. Mild steel sheets or sheets or sheets or sheets of
    Petition 870190097791, of 09/30/2019, p. 41/68
    Nickel-coated steel 30/42 as susceptors 116 may be particularly suitable for this purpose, as they are durable and thus, for example, can withstand damage from multiple uses and / or multiple contact with aerosol generating material 164, for example . A sheet shape can allow a high degree of efficiency of the thermal coupling of the susceptor 116 to the aerosol generating material 164.
    [0085] The temperature of Curie T c for iron is 770 ° C. The temperature of Curie T c for mild steel can be around 770 ° C. The temperature of Curie T c for cobalt is 1127 ° C. In one example, the mild steel susceptor 116 can be heated to temperatures in the range of about 200 ° C to about 300 ° C, which can be the working range of the aerosol generating device 150. The change in the magnetization of the mild steel saturation at 250 ° C is less than 10% in relation to the value at room temperature. Therefore, the change in inductance L between temperatures in the working temperature range is relatively small and can be assumed to be constant for steel susceptor 116. Therefore, the change in bandwidth B of the peak response of circuit 100 can be directly related to the resistance R of circuit 100 (via equation (2)) and, therefore, to the temperature of steel susceptor 116. Therefore, in this case, measuring the peak bandwidth B will allow a simple and accurate determination of the temperature of susceptor 116 .
    [0086] In some examples, controller 114 may be arranged to determine only one of the resonant frequency f r or the bandwidth B to determine the temperature of the susceptor. In some examples, controller 114 may be arranged to
    Petition 870190097791, of 09/30/2019, p. 42/68
    31/42 determine either the resonance frequency f r or the bandwidth B to determine the temperature of susceptor 116, depending on the type of susceptor 116 used and / or the working temperature range of device 350. In some examples, the resonant frequency f r or the bandwidth B of controller 114 to be used to determine the temperature of susceptor 116 is predefined or predetermined in controller 114 and / or the global device 150. In some examples, controller 114 can be arranged to determine both the resonant frequency f r and the bandwidth B, and use both to determine the temperature of the susceptor 116. For example, the controller can be arranged to take an average of the temperature as determined using the resonant frequency f r and bandwidth B and determine this as the temperature of susceptor 116.
    [0087] As mentioned above, controller 114 is arranged to determine the temperature of susceptor 116 based on the determined frequency characteristic, for example, the resonant frequency f r of circuit 100, or the bandwidth B of the peak response. frequency 300 of circuit 100. There are several ways in which this can be achieved.
    [0088] In one example, controller 114 is arranged to determine data indicative of temperature as a function of the frequency characteristic; and determining the temperature based on the determined data and the determined frequency characteristic.
    [0089] For example, the data may comprise a series of temperature data points measured as a function of the first
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    32/42 characteristic. For example, controller 114 can store in a memory (not shown) the calibration data that maps the frequency characteristic to the temperature of susceptor 116. For example, the temperature as a function of the first characteristic can be monotonic. For example, calibration data can be determined during the manufacture of device 350 or controller 114 by measuring the frequency characteristic of the circuit as a function of the temperature of susceptor 116 as determined using a thermometer, such as a thermocouple, for example. This calibration data can then be stored on device 350 or controller 114, for example, as a look-up table in a memory (not shown) of device 350 or controller 114. In use, controller 114 can determine the characteristic of peak frequency of the frequency response 300 of the resonance circuit 100 and use the determined frequency characteristic to search for the corresponding temperature of susceptor 116 from the calibration data. This can be useful in cases where the relationship between the frequency characteristic and the temperature is complicated and therefore can provide an accurate determination of the temperature.
    [0090] As another example, controller 114 or device 350 can store data comprising one or more parameters in a functional way that describe temperature as a function of the frequency characteristic. For example, it can be assumed that the frequency characteristic varies linearly with the temperature of susceptor 116. In this case, a functional form that describes the temperature T of susceptor 116 as a function of frequency characteristic F can be T = aF + b where a and b
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    33/42 are constant parameterizing the functional form. These parameters can be determined during the manufacturing process of controller 114 or device 350, and stored in the memory (not shown) of the controller or device 350. In use, the controller can determine the peak frequency characteristic of the frequency response 300 of the resonance circuit 100 and use parameters a and b stored in memory to calculate the temperature of susceptor 116. It should be noted that other functional forms can be used as needed, for example, non-linear functional forms, by parameterized exemplary polynomial functions as appropriate. This can be useful, as the storage of parameters uses less storage space compared to, for example, the storage of a series of data of characteristics and frequency temperatures.
    [0091] In some examples, the data may simply be a constant of proportionality between the temperature and the frequency characteristic. This constant can be stored in a memory (not shown) and used by the controller to calculate the temperature of susceptor 116 directly from the frequency characteristic. This can be useful as it is computationally simple and involves storing a parameter that can reduce the required storage capacity.
    [0092] In cases where the frequency characteristic is the bandwidth B of the peak frequency response 300 of the resonance circuit 100, the controller 114 may be arranged to determine the resistance R of the resonance circuit
    Petition 870190097791, of 09/30/2019, p. 45/68
    34/42
    100, using equation (2) with a known value, for example, predetermined inductance L. The temperature of susceptor 116 can then be determined from the determined resistance R. For example, the contribution to resistance R, in addition to the contribution of susceptor 116, can be known or predetermined and assumed to remain constant. The resistance of susceptor 116 can then be determined as the difference between the determined resistance R and the contribution to resistance R, in addition to the contribution of susceptor 116. As another example, the contribution to resistance R, in addition to the contribution of susceptor 116 can be assumed to be negligible, and therefore the determined resistance R equated with the resistance of the susceptor. The temperature of susceptor 116 can then be determined by multiplying the resistance of the susceptor by a constant, for example, a temperature resistance constant of susceptor 116, which can be stored in the memory (not shown) of controller 114 or device 150. Different materials have resistance constants at different temperatures. Therefore, controller 114 can store a plurality of temperature resistance constants for different materials and determine the appropriate temperature resistance constant to be used in determining the temperature of susceptor 116 according to the material that the susceptor comprises 116. For example , the material that susceptor 116 comprises can be known to controller 114 through user input or another input through which susceptor 116 can be identified to controller 114. This can be useful as it provides a
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    35/42 precise temperature determination while allowing flexibility in the used 116 susceptors.
    [0093] In some examples, controller 114 may be arranged to determine a reference characteristic indicative of the characteristic frequency at a reference temperature; compare the determined frequency characteristic with the determined reference characteristic; and determining the temperature of susceptor 116 based on a comparison of the determined frequency characteristic with the reference characteristic.
    [0094] For example, controller 114 can be arranged to determine the frequency characteristic when it is known or it can be assumed that susceptor 116 is at a certain temperature. For example, controller 114 may be arranged to determine the frequency characteristic at an initiation of device 150 (for example, using the methods described above), when it can be assumed that the temperature of susceptor 116 is room temperature, for example, The controller 114 can then store this frequency characteristic determined as a reference frequency characteristic for the reference temperature of 20 ° C. In a later stage, for example, when the susceptor 116 is being inductively heated, the controller 114 can determine the frequency characteristic again. Controller 114 can then compare this determined frequency characteristic with the reference frequency characteristic. For example, controller 114 can calculate the difference between the determined frequency characteristic and the frequency characteristic of
    Petition 870190097791, of 09/30/2019, p. 47/68
    36/42 reference. Controller 114 can then determine the temperature of susceptor 116 based on that difference. For example, the difference can be mapped to a temperature of susceptor 116 in ways similar to those described above, for example, through pre-stored calibration data, or a calibration function, or a proportionality constant.
    [0095] Determining the temperature of susceptor 116 based on a comparison of the determined frequency characteristic with a reference characteristic determined at a reference temperature removes the need for an assumption of the frequency characteristic of the resonance circuit at a given temperature and therefore, it provides a more accurate temperature determination. In addition, temperature determination is more robust to changes in susceptor 116, or resonance circuit 100, or the device as a whole 350. For example, susceptor 116 can be replaceable. For example, susceptor 116 may be disposable and, for example, integrated with aerosol generating material 164 which is arranged to heat. The determination of the reference frequency characteristic can therefore take into account differences between different susceptors 116 and / or differences in the placement of susceptor 116 in relation to inductor 108, such as when susceptor 116 is replaced. In addition, inductor 108, or even any component of the resonance circuit 100, can be replaceable, for example, after a certain use or after damage. Similarly, the determination of the reference frequency characteristic can therefore take into account differences between different inductors 108, and / or differences in the placement of inductor 108 in
    Petition 870190097791, of 09/30/2019, p. 48/68
    37/42 with respect to susceptor 116, how and when inductor 108 is replaced.
    [0096] Therefore, controller 114 may be arranged to measure the reference characteristic substantially at the initiation of the aerosol generating device 150 and / or substantially at the installation of a new susceptor and / or replacement susceptor 116 for the aerosol generating device 150 and / or substantially in the installation of a new and / or replacement inductor 108 in the aerosol generating device 150.
    [0097] Figure 4 is a flow diagram that schematically illustrates a method 400 for determining a temperature of a susceptor 116 of an aerosol generating device 105, the susceptor 116 for inductive heating by an RLC 100 resonance circuit. step 402, the method 400 comprises determining a frequency characteristic of a peak of a frequency response 300 of the RLC resonant circuit 100. As mentioned above, the frequency characteristic can be a resonant frequency f r of the resonance circuit 100 or may be the bandwidth B of the peak frequency response 300 of circuit 100. The frequency characteristic can be obtained, for example, using the techniques described above. In step 404, method 400 comprises determining, based on the determined frequency characteristic, the temperature of the susceptor 116. The temperature of the susceptor can be obtained from the determined frequency characteristic, for example, using the techniques described above.
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    38/42 [0098] Controller 114 may comprise a processor and a memory (not shown). The memory can store instructions executable by the processor. For example, memory can store instructions that, when executed on the processor, can cause the processor to execute method 400 described above. Instructions can be stored in any suitable storage medium, for example, in a non-transitory storage medium.
    [0099] Although some of the above examples refer to the frequency response 300 of the RLC 100 resonance circuit in terms of a current I flowing in the RLC 100 resonance circuit as a function of the frequency f at which the circuit is driven, it should be noted that this need not necessarily be the case and, in other examples, the frequency response 300 of the RLC circuit 100 can be any measure related to the current I flowing in the RLC resonance circuit as a function of the frequency f at which the circuit is triggered . For example, frequency response 300 may be a response of a circuit impedance to frequency f, or, as described above, it may be a voltage measured through the inductor or a voltage or current resulting from current induction in a pick-up coil. by a change in current flowing in a line or range of supply voltage to the resonance circuit, or a voltage or current resulting from current induction in a sensor coil by inductor 108 of the RLC resonance circuit or a signal from a non-inductive pickup coil or non-inductive field sensor such as a Hall effect device, as a function of the frequency f at which the circuit is triggered. On each
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    39/42 case, a frequency characteristic of a peak frequency response 300 can be determined.
    [0100] Although in some of the examples above the frequency characteristic is a B bandwidth of a peak frequency response 300, it should be noted that this need not necessarily be the case, and the frequency characteristic may be indicative of peak bandwidth. For example, the full width or half width of the peak at an arbitrary predetermined response span, or fraction of a maximum response span, can be used. This characteristic indicative of the peak bandwidth can be used in place of the bandwidth, when necessary, with the appropriate scaling factors applied. It should also be noted that in other examples, the so-called Q factor or Quality or value of resonance circuit 100, which may be related to bandwidth B and resonant frequency f r of resonance circuit 100 via Q = f r / B , can be determined and / or measured and used as a frequency characteristic instead of bandwidth B and / or resonant frequency f r , in a manner similar to that described in the examples above, with suitable factors applied. Therefore, it should be noted that in some instances the Q factor of circuit 100 can be measured or determined, and the resonant frequency f r of circuit 100, bandwidth B of circuit 100 and / or temperature of susceptor 116 can be determined based on on the Q factor determined in this way.
    [0101] Although the above examples refer to a peak as associated with a maximum, it should be readily noted that this need not necessarily be the case and that, depending on the response
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    40/42 frequency 300 determined and in the way it is measured, the peak can be associated to a minimum. For example, at resonance, the impedance of the RLC circuit 100 is minimal and therefore in cases where the impedance as a function of the drive frequency f is used as a frequency response 300, for example, the peak frequency response 300 of the RLC circuit will be associated with a minimum.
    [0102] Although in some of the examples above it is described that, to determine the peak frequency characteristic of the frequency response 300 of the RLC resonance circuit, controller 114 is willing to measure a frequency response 300 of the RLC resonance circuit 100 , it should be noted that this need not necessarily be the case, and in other instances controller 114 can determine the frequency characteristic by analyzing frequency response data communicated to it by a separate measurement or control system (not shown) or can determine the characteristic frequency directly communicating the frequency characteristic through a separate control or measurement system, for example. Controller 114 can then determine the temperature of susceptor 116 based on the frequency characteristic determined, for example, by the techniques described above.
    [0103] Although in some of the examples above it is described that controller 114 is arranged to determine the temperature of susceptor 116, it should be noted that this need not necessarily be the case and, in other examples, an apparatus that does not necessarily need to be or understand controller 114 and can be arranged to determine the characteristic of
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    41/42 frequency and determining the temperature of the susceptor based on the determined frequency characteristic, for example, by measuring the frequency response itself 300 or by communicating frequency response data or the frequency characteristic as described above, for example. The apparatus can be arranged to determine the temperature from the frequency characteristic determined, for example, by the methods described above. It should be noted that this apparatus or controller 114 need not necessarily be an integral part of the aerosol generating device 150 and may, for example, be a separate apparatus or controller 114 for use with the aerosol generating device 150.
    [0104] Although in the examples described above it is described that the apparatus or controller 114 is for determining a temperature of a susceptor of an aerosol generating device, this need not necessarily be the case and in other examples the apparatus or controller 114 may be for determining a temperature of a susceptor of any device where the susceptor is for inductive heating by an RLC resonance circuit, for example, any inductive heating device.
    [0105] Although in the examples described above it is described that the RLC resonance circuit is driven by the bridge actuator H 102, this need not necessarily be the case, and in other examples the RLC 100 resonance circuit can be driven by any element of drive suitable for supplying an alternating current in the resonance circuit 100, such as an oscillator or the like.
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    42/42 [0106] The above examples are to be understood as illustrative examples of the invention. It is to be understood that any feature described in relation to any example can be used alone or in combination with other features described and can also be used in combination with one or more features of any other example or any combination of any other of the other examples. In addition, equivalents and modifications not described above can also be employed without departing from the scope of the invention, which is defined in the appended claims.
    权利要求:
    Claims (26)
    [1]
    1. Apparatus for determining the temperature of a susceptor of an aerosol generating device, the susceptor being for inductive heating by an RLC resonance circuit, the apparatus characterized by the fact that it is arranged for:
    determining a peak frequency characteristic of a frequency response from the RLC resonance circuit; and determining, based on the frequency characteristic determined, the temperature of the susceptor.
    [2]
    2. Apparatus according to claim 1, characterized by the fact that the frequency characteristic is a resonant frequency of the RLC resonance circuit.
    [3]
    Apparatus according to claim 1, characterized by the fact that the frequency characteristic is indicative of a peak bandwidth of the frequency response of the RLC circuit.
    [4]
    4. Apparatus according to any one of claims 1 to 3, characterized by the fact that the apparatus is arranged to:
    determine indicative temperature data according to the frequency characteristic; and where the temperature is determined based on the determined data and the determined frequency characteristic.
    [5]
    5. Apparatus, according to claim 4, characterized by the fact that the data comprise one or more parameters of
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    2/6 a functional form that describe the temperature as a function of the frequency characteristic.
    [6]
    6. Apparatus, according to claim 4 or claim 5, characterized by the fact that the data is a constant of proportionality between the temperature and the frequency characteristic.
    [7]
    7. Apparatus according to claim 4, characterized by the fact that the data comprises a series of temperature data points measured as a function of the frequency characteristic.
    [8]
    8. Apparatus, according to claim 3, characterized by the fact that the apparatus is arranged for:
    determine, based on the determined frequency characteristic, a resistance of the RLC circuit; and where the temperature determination is based on the determined resistance of the RLC circuit.
    [9]
    9. Apparatus, according to claim 8, characterized by the fact that the apparatus is arranged for:
    determine a temperature resistance constant for the susceptor; and where the temperature determination is based on the determined resistance and the resistance constant at the determined temperature.
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    3/6
    [10]
    10. Apparatus according to any one of claims 1 to 9, characterized by the fact that the apparatus is arranged to:
    determining a reference characteristic indicative of the frequency characteristic at a reference temperature;
    compare the determined frequency characteristic with the determined reference characteristic; and where the temperature determination is based on a comparison of the determined frequency characteristic with the reference characteristic.
    [11]
    11. Apparatus, according to claim 10, characterized by the fact that the apparatus is arranged for:
    measure the reference characteristic substantially at the initiation of the aerosol generating device and / or substantially in the installation of a new and / or replacement susceptor in the aerosol generating device and / or substantially in the installation of a new and / or replacement inductor in the device aerosol generator.
    [12]
    Apparatus according to any one of claims 1 to 11, characterized in that the apparatus is arranged to:
    measure an electrical property of the RLC circuit as a function of a drive frequency at which the RLC circuit is driven; and
    Petition 870190097791, of 09/30/2019, p. 57/68
    4/6 where the determination of the frequency characteristic is based on the measured electrical property of the RLC circuit as a function of a drive frequency at which the RLC circuit is driven.
    [13]
    13. Apparatus according to claim 12, characterized by the fact that the electrical property is a voltage measured through an RLC circuit inductor, the inductor being for transferring energy to the susceptor.
    [14]
    14. Apparatus according to claim 12, characterized by the fact that the measurement of electrical property is a passive measurement.
    [15]
    15. Apparatus according to claim 14, characterized by the fact that the electrical property is indicative of a current induced in a sensor coil by an inductor of the RLC circuit, the inductor being for transferring energy to the susceptor.
    [16]
    16. Apparatus according to claim 14, characterized by the fact that the electrical property is indicative of a current induced in a pick-up coil by a supply voltage element, the supply voltage element being to supply voltage to a drive element, the drive element being for driving the RLC circuit.
    [17]
    17. Aerosol generating device characterized by the fact that it comprises:
    a susceptor arranged to heat an aerosol-generating material, thereby to generate an aerosol in use;
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    5/6 an RLC resonance circuit arranged to inductively heat the susceptor in use; and the apparatus as defined in any one of claims 1 to 16.
    [18]
    An aerosol generating device according to claim 17, characterized in that it comprises the apparatus as defined in claim 2, wherein the susceptor comprises nickel.
    [19]
    19. Aerosol generating device according to claim 18, characterized in that the susceptor comprises a body with a nickel coating.
    [20]
    An aerosol generating device according to claim 19, characterized in that the nickel coating has a thickness less than substantially 5 pm or substantially in the range of 2 pm to 3 pm.
    [21]
    21. Aerosol generating device according to claim 19 or claim 20, characterized by the fact that the nickel coating is galvanized in the body.
    [22]
    22. Aerosol generating device according to claim 17, characterized in that it comprises the apparatus as defined in claim 3, wherein the susceptor comprises one or more of steel, iron and cobalt.
    [23]
    23. An aerosol generating device according to claim 22, characterized in that the susceptor is a sheet of mild steel.
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    6/6
    [24]
    24. An aerosol generating device according to claim 23, characterized in that the mild steel sheet has a thickness in the range of substantially 10 pm to substantially 50 pm, or has a thickness of substantially 25 pm.
    [25]
    25. Method for determining the temperature of a susceptor of an aerosol generating device, the susceptor being for inductive heating by an RLC resonance circuit, the method characterized by the fact that it comprises:
    determining a peak frequency characteristic of a frequency response from the RLC resonance circuit; and determining, based on the frequency characteristic determined, the temperature of the susceptor.
    [26]
    26. Computer program characterized by the fact that, when executed by a processing system, it causes the processing system to execute the method as defined in claim 25.
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    同族专利:
    公开号 | 公开日
    GB201705208D0|2017-05-17|
    US20200022412A1|2020-01-23|
    RU2759608C2|2021-11-16|
    CA3057903A1|2018-10-04|
    CL2019002766A1|2020-03-06|
    MX2019011800A|2019-11-07|
    CN110476477A|2019-11-19|
    RU2019134684A|2021-04-30|
    RU2019134684A3|2021-04-30|
    AU2020294182A1|2021-01-28|
    JP2020516014A|2020-05-28|
    JP2021192374A|2021-12-16|
    PH12019502135A1|2020-06-15|
    KR102344986B1|2021-12-28|
    WO2018178113A2|2018-10-04|
    WO2018178113A3|2018-12-13|
    RU2021131848A|2021-11-19|
    AU2018241907B2|2020-09-24|
    KR20190130021A|2019-11-20|
    AU2018241907A1|2019-10-03|
    KR20210158889A|2021-12-31|
    EP3603332A2|2020-02-05|
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    法律状态:
    2021-08-10| B25A| Requested transfer of rights approved|Owner name: NICOVENTURES TRADING LIMITED (GB) |
    2021-10-19| B350| Update of information on the portal [chapter 15.35 patent gazette]|
    优先权:
    申请号 | 申请日 | 专利标题
    GBGB1705208.5A|GB201705208D0|2017-03-31|2017-03-31|Temperature determination|
    PCT/EP2018/057834|WO2018178113A2|2017-03-31|2018-03-27|Temperature determination|
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