CN115998001A - Power supply control method and system for aerosol generator - Google Patents

Abstract

The invention provides a power supply control method and a power supply control system for an aerosol generator, wherein the method comprises the following steps: if a preset first instruction is received, selecting a power supply as a target power supply; detecting a current target power supply, and if the detection result shows that the current target power supply meets the preset heating power, controlling the current target power supply to drive the aerosol generator to perform heating operation; if the current target power supply does not meet the preset heating power, selecting another power supply as the target power supply, and executing the operation of detecting the current target power supply until the current target power supply meets the preset heating power or all the power supplies are detected. The method provided by the invention keeps the heating output efficiency and power of the aerosol generator in a relatively constant interval, ensures the heating speed of the circuit during preheating, can delay the aging speed of the power supply, ensures that the suction taste of a user is not influenced by the power supply, and meets the requirement of consistency.

Description

Power supply control method and system for aerosol generator

Technical Field

The invention belongs to the technical field of aerosol generators, and particularly relates to a power supply control method and a power supply control system for an aerosol generator.

Background

Aerosol-generating systems typically comprise an aerosol generator and an aerosol-generating article that is heated by the aerosol generator to generate an aerosol for inhalation by a user. In practice, the aerosol generator typically needs to be preheated prior to use, and a rechargeable battery is typically provided within the aerosol generator to power the various modules or devices within the aerosol generator. And along with the use of a user, the electric quantity of the battery gradually decreases, when the electric quantity of the battery decreases to a certain extent, the battery voltage is lower than the nominal voltage of the battery because of the material characteristic of the battery, so that the power supply is reduced, the heating speed is reduced in the process of preheating an aerosol generating product by the heating device of the aerosol generator, the heating time reaching the required temperature is prolonged, and when the required preheating temperature cannot be reached within the set preheating time, the suction taste of the aerosol generated by heating is deteriorated.

Disclosure of Invention

In order to overcome the defects in the prior art, the invention provides a power supply control method and a power supply control system for an aerosol generator, wherein the aerosol generator is provided with a plurality of power supplies, and the problems of inconsistent preheating speed and inconsistent sucking taste can be solved on a larger possibility compared with the prior art through cooperative control among the plurality of power supplies, so that the consistency of the sucking taste of heated aerosol is ensured.

Specifically, the present invention proposes the following specific embodiments:

the embodiment of the invention provides a power supply control method of an aerosol generator, wherein the aerosol generator comprises a plurality of power supplies; the method comprises the following steps:

if a first preset instruction is received, selecting one power supply as a target power supply;

detecting the current target power supply, and if the detection result shows that the current target power supply meets the preset heating power, controlling the current target power supply to supply power to the aerosol generator so as to enable the aerosol generator to perform heating operation;

and if the current target power supply does not meet the preset heating power, selecting another power supply as the target power supply, and executing the operation of detecting the current target power supply until the current target power supply meets the preset heating power or all the power supplies are detected.

Further, the method further comprises:

after the preset time of the heating operation is completed, if the power supply for driving the aerosol generator to perform the heating operation still meets the preset heating power, the prompt of sufficient electric quantity is performed.

Further, the method further comprises:

and after the preset time of the heating operation is finished, if the power supply for driving the aerosol generator to perform the heating operation does not meet the preset heating power, selecting one or more other power supplies with residual electric quantity except the target power supply to perform the charging operation on the power supply for driving the heating.

Further, the method further comprises:

after the preset time of the heating operation is completed, if the power supply for driving the aerosol generator to perform the heating operation does not meet the preset heating power and no electric quantity remains in other power supplies except the power supply for driving the heating, the prompt of needing to be charged is performed.

Further, the method further comprises:

if a second preset instruction is received, selecting one power supply as an object power supply;

detecting the current object power supply, and if the detection result shows that the current object power supply meets the preset heating power, prompting that the electric quantity is sufficient;

and if the current object power supply does not meet the preset heating power, selecting another power supply as the object power supply, and executing the operation of detecting the current object power supply until the current object power supply meets the preset heating power or all the power supplies are detected.

Further, the method further comprises:

and if all the power supplies do not meet the preset heating power, prompting that the power supplies need to be charged.

Further, rated power of different power supplies is different;

the method further comprises the steps of:

sequencing the power supplies according to the rated power from large to small;

the selection is based on the ordering.

Further, the method further comprises: for each power supply, a corresponding table of the power supply is established; the corresponding table comprises a corresponding relation between voltage and output power;

whether the power supply meets preset heating power is judged by the following steps of;

detecting the voltage of the power supply and determining a corresponding table of the detected power supply;

searching the output power corresponding to the detected voltage in the determined corresponding table;

if the found output power is greater than or equal to the preset heating power, confirming that the power supply meets the preset heating power;

if the found output power is smaller than the preset heating power, the power supply is confirmed to not meet the preset heating power.

Further, the power source includes a rechargeable battery.

The embodiment of the invention also discloses an aerosol generator system which comprises a processing unit, wherein the processing unit is used for executing the power supply control method of the aerosol generator.

The invention has at least the following beneficial effects:

according to the scheme provided by the invention, the multiple power supplies are arranged for supplying power alternately, and the power supply is coordinated among the multiple power supplies, so that the preheating power of the aerosol generator is easier to keep in a more constant interval compared with a single power supply, the heating speed of the aerosol generator when the aerosol generator heats a device to be heated is ensured, the preheating time required by the cigarette can not be prolonged when the aerosol generating device heats the cigarette, the heating speed when the cigarette is preheated is ensured, the taste of a user smoking the cigarette is not influenced by insufficient electric quantity of the power supply, and the consistency requirement of the smoking taste of the aerosol generated by heating is met. In addition, the capacity of the plurality of power sources is maximized, and power supply can be coordinated among the plurality of power sources, so that the working strength of a single power source is reduced, and the aging time of the power source is effectively delayed;

drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are needed in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a flow chart of a power supply control method of an aerosol generator provided in embodiment 1;

fig. 2 is a schematic block diagram of an aerosol generator according to embodiment 2;

FIG. 3 is a schematic diagram of the circuit configuration of the power supply portion of the aerosol generator;

fig. 4 is a schematic circuit diagram of a power connection part of the aerosol generator.

Reference numerals:

20-generating means; 21-a control circuit; 22-an activation switch; a 23-output circuit; 24-a first battery; 25-a second cell; 26-a charging interface; 27-a first charging circuit; 28-a second charging circuit; 29-indicator light.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Hereinafter, various embodiments of the present invention will be described more fully. The invention is capable of various embodiments and of modifications and variations therein. However, it should be understood that: there is no intention to limit the various embodiments of the invention to the specific embodiments disclosed herein, but rather the invention is to be understood to cover all modifications, equivalents, and/or alternatives falling within the spirit and scope of the various embodiments of the invention.

The terminology used in the various embodiments of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the various embodiments of the invention. As used herein, the singular is intended to include the plural as well, unless the context clearly indicates otherwise. Unless otherwise defined, all terms (including technical and scientific terms) used herein have the same meaning as commonly understood by one of ordinary skill in the art to which various embodiments of the invention belong. The terms (such as those defined in commonly used dictionaries) will be interpreted as having a meaning that is the same as the context of the relevant art and will not be interpreted in an idealized or overly formal sense unless expressly so defined herein in connection with the various embodiments of the invention.

Example 1

The embodiment provides a power supply control method of an aerosol generator, wherein the aerosol generator comprises a plurality of power supplies; referring to fig. 1, the method includes:

s101, if a preset first instruction is received, selecting one power supply as a target power supply;

in a specific embodiment, the multiple power sources are exemplified by 2 batteries (refer to fig. 2), and similar control methods of other power sources are omitted herein, and the starting switch in fig. 2 generates a preset first instruction (the preset first instruction may be sent by the user to control the starting switch to the control circuit), and the specific preset first instruction may be triggered by the user when the user needs to use the electronic cigarette, for example, the specific preset first instruction may be a starting signal.

Specifically, referring to fig. 2, the aerosol generator includes a control circuit 21, a start switch 22, a first battery 24, a second battery 25, and an output circuit 23, where the first power supply is connected to the output circuit through a first switch Q1, and the second battery 25 is connected to the output circuit through a second switch Q2. The first battery 24 and the second battery 25 each include at least one rechargeable battery.

The start switch 22 is used for sending a signal to the control circuit 21, and the control circuit 21 is connected with the first switch Q1 and the second switch Q2 to control the first battery 24 or the second battery 25 to supply power to the output circuit, so that the output circuit heats the generating device 20 to be heated.

Further, the aerosol generator further comprises a charging interface 26, a first charging circuit 27 and a second charging circuit 28, wherein the charging interface 26 is respectively connected with the first battery 24 and the second battery 25 through the first charging circuit 27, so that an external power supply charges the first battery 24 and the second battery 25 through the first charging circuit 27; the aerosol generator may further comprise an indicator lamp 29, where the indicator lamp 29 is configured to send out different signals to prompt a user when the power of the heating circuit meets a preset heating power, when the power of the heating circuit needs to be charged, when the power of the heating circuit is charged, and when the charging of the power of the heating circuit is completed.

After receiving the first preset command, selecting one power supply as the target power supply, wherein the specific selection can be random selection, or can be performed according to the order of the rated power (also called as the rated capacity or the maximum capacity) from large to small, for example, 2 power supplies are provided, and the rated capacity is selected to be larger.

S102, detecting the current target power supply.

S103, if the detection result shows that the current target power supply meets the preset heating power, controlling the current target power supply to supply power to the aerosol generator so as to enable the aerosol generator to perform heating operation;

in this case, if the power source 1 is currently selected as the target power source, the power source 1 is detected, and if the power source 1 satisfies the preset heating power, the aerosol generator is driven by the power source 1 to perform the heating operation.

And S104, if the current target power supply does not meet the preset heating power, selecting another power supply as the target power supply, and executing the operation of detecting the current target power supply until the current target power supply meets the preset heating power or all the power supplies are detected.

Still referring to the above example, if the power supply 1 does not satisfy the preset heating power, the power supply 2 is selected as the target power supply, and it is detected whether the power supply 2 satisfies the preset heating power, and if the power supply 2 satisfies the preset heating power, the power supply 2 is selected to drive the aerosol generator to perform the heating operation.

Specifically, taking 2 power sources as an example, the power sources may be batteries, referring to fig. 3, the battery 1 (corresponding to VBAT1 in fig. 3) and the battery 2 (corresponding to VBAT2 in fig. 3) are connected to vcc_dcdc (connected to an output circuit to supply power to the output circuit to drive the aerosol generator for heating operation), when Q1 is turned on and Q2 is turned off, the battery 1 is powered, and when Q1 is turned off and Q2 is turned on, the battery 2 is powered. The voltage of the battery 1 is detected through the port VBAT-DET1 in fig. 3 by dividing the voltage by the dividing resistor R1 and the dividing resistor R2, and the voltage of the battery 2 is detected through the port VBAT-DET2 in fig. 3 by dividing the voltage by the dividing resistor R3 and the dividing resistor R4. The output circuit is powered by VCC_DCDC, and outputs control signals (including DRIVE1 and DRIVE2, wherein the DRIVE1 control signals are used for controlling the switch of Q1, and the DRIVE2 is used for controlling the switch of Q2), and the control circuit can be powered by the battery 1 and is in a dormant state to wait for a user to wake up and start.

Further, the method further comprises: after the preset time of the heating operation is completed, if the power supply for driving the aerosol generator to perform the heating operation still meets the preset heating power, the prompt of sufficient electric quantity is performed. Specifically, 2 power sources are still used as examples for illustration, and the following two cases can be distinguished in conjunction with fig. 2 and 3:

case 1, heating operation completed by battery 1; specifically, when the start switch sends a start signal to the control circuit, the control circuit is awakened and starts a start process, at this moment, the Q1 and the Q2 are in a closed state, the voltage U1 of the battery 1 is collected first, whether the residual electric quantity of the battery 1 meets the preheating power is judged, if yes, the Q1 is opened, the battery 1 is connected with VCC_DCDC, at this moment, the output circuit is powered by the battery 1, the controller enters a normal start process, and heating is started. When the heating process is finished, the control circuit recognizes the voltage U1 of the battery 1 again after a certain time delay, judges whether the residual electric quantity of the battery 1 meets the preheating power or not, and if yes, the indicator light sends out a signal capable of meeting the next pumping. Waiting for the next start.

In case 2, the heating operation of the battery 2 is completed, specifically, the start switch sends a start signal to the control circuit, the control circuit is awakened and starts the start process, at this time, Q1 and Q2 are in a closed state, the voltage U1 of the battery 1 is collected first, when the electric quantity of the battery 1 does not meet the preheating power, the control circuit collects the voltage U2 of the battery 2, if the residual electric quantity of the battery 2 meets the preheating power, the Q2 is turned on, so that the battery 2 is connected with vcc_dcdc, and at this time, the output circuit is powered by the battery 2. The controller enters a normal starting flow and starts heating. When the heating process is finished, the control circuit recognizes the voltage U2 of the battery 2 again after a certain time delay, judges whether the preheating power started next time is met or not, and if so, the indicator light sends out a signal capable of meeting the next pumping. Waiting for the next start.

By means of the method for prompting the sufficient electric quantity, the user can be intuitively informed of whether charging is needed and whether suction can be performed next time.

In a specific embodiment, the method further comprises: and after the preset time of the heating operation is finished, if the power supply for driving the aerosol generator to perform the heating operation does not meet the preset heating power, selecting one or more other power supplies with residual electric quantity except the target power supply to perform the charging operation on the power supply for driving the heating.

Specifically, after the battery 2 completes the operation of driving and heating, if the electric quantity of the battery 2 is insufficient, other batteries may be allocated to charge the battery 2, specifically, if there are only 2 batteries and the battery 1 has electric quantity remaining, the battery 1 is selected to charge the battery 2, and if there are 3 batteries, for example, the battery 1, the battery 2 and the battery 3, respectively, and the battery 1 and the battery 3 have electric quantity remaining, the battery 1 and/or the battery 3 may be selected to charge the battery 2.

Specifically, still taking 2 batteries as an example, referring to fig. 2 and fig. 4, when the start switch sends a start signal to the control circuit, the control circuit is awakened and starts the start process, at this time, Q1 and Q2 are in a closed state, the voltage U1 of "battery 1" is collected first, when the electric quantity of battery 1 does not meet the preheating power, the control circuit collects the voltage U2 of "battery 2", if the residual electric quantity of battery 2 meets the preheating power, Q2 is turned on, so that battery 2 is connected to vcc_dcdc, and at this time, the output circuit is powered by battery 2. The controller enters a normal starting flow and starts heating. When the heating process is finished, the control circuit recognizes the voltage U2 of the battery 2 again after a certain time delay, judges whether the preheating power started next time is met or not, if not, the control circuit collects the voltage U1 of the battery 1, if the battery 1 has residual electric quantity, the controller opens Q3, the battery 1 passes through the charging circuit 2 (corresponding to C2 in FIG. 4, specifically when the driving circuit generates a DRIVE3 signal and sends the DRIVE3 signal to the switch Q3, the switch Q3 is communicated, and then the battery 1 charges the battery 2) and charges the battery 2. Meanwhile, the indicator light sends out a signal which is being charged, the user is reminded to be reminded, and after the charging is finished, the indicator light reminds the user of the completion of the charging again. Waiting for the next start.

By the mode, the electric quantity of the batteries can be synthesized, the electric quantity can be utilized to the greatest extent, the aerosol generator is driven to perform heating operation, and the service time of a user is prolonged.

In a specific embodiment, the method further comprises: after the preset time of the heating operation is completed, if the power supply for driving the aerosol generator to perform the heating operation does not meet the preset heating power and no electric quantity remains in other power supplies except the power supply for driving the heating, the prompt of needing to be charged is performed.

Specifically, taking 2 batteries as an example to illustrate, if the battery 2 is driven to perform heating operation, and the battery 2 after the battery 2 is driven to perform heating operation does not meet preset heating power, and the battery 1 also has no residual electric quantity, a charging prompt is needed, a specific start switch sends a start signal to give a control circuit, the control circuit is awakened and starts a start process, at this moment, Q1 and Q2 are in a closed state, the control circuit collects the voltage U1 of the battery 1 first, when the electric quantity of the battery 1 does not meet the preheating power, the control circuit collects the voltage U2 of the battery 2, if the residual electric quantity of the battery 2 meets the preheating power, the Q2 is turned on, so that the battery 2 is connected with vcc_dcdc, and at this moment, the output circuit is powered by the battery 2. The controller enters a normal starting flow and starts heating. When the heating process is finished, the control circuit recognizes the voltage U2 of the battery 2 again after a certain time delay, judges whether the preheating power started next time is met or not, if not, the control circuit collects the voltage U1 of the battery 1, and if no electric quantity of the battery 1 remains, the indicator light sends a low electric signal to remind a user to recharge.

Specifically, 2 power sources are taken as an example to illustrate, if the power source 2 drives the heating operation and the power source 1 has no residual electric quantity, the whole of the power source is unable to satisfy the next heating operation, so as to remind the user of timely charging and avoid the defect caused by the unable to normally drive the heating operation during use.

In a specific embodiment, the method further comprises: if a second preset instruction is received, selecting one power supply as an object power supply; detecting the current object power supply, and if the detection result shows that the current object power supply meets the preset heating power, prompting that the electric quantity is sufficient; and if the current object power supply does not meet the preset heating power, selecting another power supply as the object power supply, and executing the operation of detecting the current object power supply until the current object power supply meets the preset heating power or all the power supplies are detected.

The preset second instruction may also be generated by a start switch with reference to the preset first instruction, and the specific preset second instruction may be, for example, a wake-up signal, which is used for enabling a user to know whether the normal heating operation can be driven currently, so that the defect that the normal driving cannot be performed due to direct start can be avoided. Specifically, when the starting switch sends a wake-up signal to the control circuit, the control circuit is waken up but does not start the starting process, the battery 1 voltage U1 is collected first, when the electric quantity of the battery 1 does not meet the preheating power, the control circuit collects the battery 2 voltage U2, and if the residual electric quantity of the battery 2 meets the preheating power, the indicating lamp sends a signal capable of meeting the next pumping. Waiting for the next start.

Further, the method further comprises: and if all the power supplies do not meet the preset heating power, prompting that the power supplies need to be charged. Specifically, when the starting switch sends a wake-up signal to the control circuit, the control circuit is awakened but does not start the starting process, the battery 1 voltage U1 is collected first, when the electric quantity of the battery 1 does not meet the preheating power, the control circuit collects the battery 2 voltage U2, and if the residual electric quantity of the battery 2 does not meet the preheating power, the indicator light sends a low electric signal to remind a user to recharge.

Through the mode, the user can be effectively reminded of charging.

In a specific embodiment, the rated power of different power supplies is different; the method further comprises the steps of: sequencing the power supplies according to the rated power from large to small; the selection is based on the ordering.

Specifically, for example, there are 3 batteries, and the rated power of the batteries is sequentially from large to small, namely, battery 1, battery 2 and battery 3, and whether the first instruction is received or the second instruction is received, the detection is selected according to the sequence of battery 1, battery 2 and battery 3.

For example, there are 2 batteries, and the rated power of the batteries is sequentially from large to small, namely a battery 1 and a battery 2; whether the first instruction is received or the second instruction is received, selecting to detect according to the sequence of the battery 1 and the battery 2; and based on the battery setting of a plurality of different rated powers, the characteristics of small rated capacity, higher charging speed and reduced occupied space can be utilized, and the battery setting can be alternately used with the battery with large rated capacity, so that the aging is slowed down.

Further, the method further comprises: for each power supply, a corresponding table of the power supply is established; the corresponding table comprises a corresponding relation between voltage and output power; whether the power supply meets preset heating power is judged by the following steps of; detecting the voltage of the power supply and determining a corresponding table of the detected power supply; searching the output power corresponding to the detected voltage in the determined corresponding table; if the found output power is greater than or equal to the preset heating power, confirming that the power supply meets the preset heating power; if the found output power is smaller than the preset heating power, the power supply is confirmed to not meet the preset heating power.

In particular, the power source comprises a rechargeable battery. Taking a power supply as an example of a battery, the corresponding relation between the output powers which can be achieved under different voltages can be obtained by testing all the batteries, so that a corresponding table is formed, the output power can be obtained by detecting the power supply voltage and inquiring the corresponding table corresponding to the battery when the power supply is detected later, and compared with the preset heating power, when the output power is larger than or equal to the preset heating power, the indication can be met, and otherwise, the indication cannot be met.

Example 2

The present embodiment proposes an aerosol generator system comprising a processing unit for performing the method of controlling the power supply of an aerosol generator as described in embodiment 1. .

In summary, the invention provides a power supply control method and a system for an aerosol generator, which can keep the heating output efficiency and power of the aerosol generator in a relatively constant interval, ensure the heating speed of a circuit during preheating, delay the aging speed of a power supply, prevent the taste of smoking a user from being influenced by the power supply, and meet the requirement of consistency of the smoking taste of aerosol generated by heating.

The foregoing description of the preferred embodiments of the invention is not intended to limit the invention to the precise form disclosed, and any such modifications, equivalents, and alternatives falling within the spirit and scope of the invention are intended to be included within the scope of the invention.

Claims (10)

1. A method of controlling the power supply of an aerosol generator, the aerosol generator comprising a plurality of power sources; the method comprises the following steps:

if a first preset instruction is received, selecting one power supply as a target power supply;

detecting the current target power supply, and if the detection result shows that the current target power supply meets the preset heating power, controlling the current target power supply to supply power to the aerosol generator so as to enable the aerosol generator to perform heating operation;

and if the current target power supply does not meet the preset heating power, selecting another power supply as the target power supply, and executing the operation of detecting the current target power supply until the current target power supply meets the preset heating power or all the power supplies are detected.

2. The method of controlling the power supply to an aerosol generator as set forth in claim 1, further comprising:

after the preset time of the heating operation is completed, if the power supply for driving the aerosol generator to perform the heating operation still meets the preset heating power, the prompt of sufficient electric quantity is performed.

3. The method of controlling the power supply to an aerosol generator as set forth in claim 1, further comprising:

and after the preset time of the heating operation is finished, if the power supply for driving the aerosol generator to perform the heating operation does not meet the preset heating power, selecting one or more other power supplies with residual electric quantity except the target power supply to perform the charging operation on the power supply for driving the heating.

4. The method of controlling the power supply to an aerosol generator as set forth in claim 1, further comprising:

after the preset time of the heating operation is completed, if the power supply for driving the aerosol generator to perform the heating operation does not meet the preset heating power and no electric quantity remains in other power supplies except the power supply for driving the heating, the prompt of needing to be charged is performed.

5. The method of controlling the power supply to an aerosol generator as set forth in claim 1, further comprising:

if a second preset instruction is received, selecting one power supply as an object power supply;

detecting the current object power supply, and if the detection result shows that the current object power supply meets the preset heating power, prompting that the electric quantity is sufficient;

and if the current object power supply does not meet the preset heating power, selecting another power supply as the object power supply, and executing the operation of detecting the current object power supply until the current object power supply meets the preset heating power or all the power supplies are detected.

6. The method of controlling the power supply to an aerosol generator as set forth in claim 5, further comprising:

and if all the power supplies do not meet the preset heating power, prompting that the power supplies need to be charged.

7. A method of controlling the power supply to an aerosol generator as set forth in any one of claims 1 to 6, wherein the rated power of different ones of said power sources is different;

the method further comprises the steps of:

sequencing the power supplies according to the rated power from large to small;

the selection is based on the ordering.

8. A method of controlling the power supply to an aerosol generator as set forth in any one of claims 1 to 6, further comprising: for each power supply, a corresponding table of the power supply is established; the corresponding table comprises a corresponding relation between voltage and output power;

whether the power supply meets preset heating power is judged by the following steps of;

detecting the voltage of the power supply and determining a corresponding table of the detected power supply;

searching the output power corresponding to the detected voltage in the determined corresponding table;

if the found output power is greater than or equal to the preset heating power, confirming that the power supply meets the preset heating power;

if the found output power is smaller than the preset heating power, the power supply is confirmed to not meet the preset heating power.

9. The method of controlling the power supply to an aerosol generator as set forth in claim 1, wherein the power source comprises a rechargeable battery.

10. An aerosol generator system, characterized in that it comprises a processing unit for performing the method of controlling the power supply of an aerosol generator according to any of claims 1-9.

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