WO2019179238A1

WO2019179238A1 - Electronic cigarette control device and method, electronic cigarette and computer storage medium

Info

Publication number: WO2019179238A1
Application number: PCT/CN2019/073135
Authority: WO
Inventors: 邱伟华; 刘魁
Original assignee: 常州市派腾电子技术服务有限公司
Priority date: 2018-03-20
Filing date: 2019-01-25
Publication date: 2019-09-26
Also published as: CN108451036B; CN108451036A

Abstract

An electronic cigarette control device and method, an electronic cigarette and a computer storage medium, the device comprising: an electrostatic friction film assembly (110) disposed in an airflow passage of the electronic cigarette so as to generate, when an airflow in the airflow passage changes, a corresponding electrostatic current (210); and a controller (120), which is connected respectively with the electrostatic friction film assembly (110) and the operating circuit of a heating piece of the electronic cigarette, and is used for detecting the electrostatic current generated by the electrostatic friction film assembly and controlling, when the value of the electrostatic current is greater than a first threshold, the heating piece to start operation (220). The electronic cigarette control device is capable of saving internal space of the electronic cigarette and implementing control for the heating piece.

Description

Electronic cigarette control device, method, electronic cigarette and computer storage medium

Technical field

The invention relates to the field of electronic cigarette technology, in particular to an electronic cigarette control device, a method, an electronic cigarette and a computer storage medium.

Background technique

For the current electronic cigarettes on the market, an air flow sensor is disposed in the electronic cigarette, the airflow sensor is used to detect the magnitude of the user's suction force, and the heat-generating component of the electronic cigarette is controlled to work. However, the airflow sensor takes up a lot of space and requires a special mount to mount the microphone, which undoubtedly increases the volume of the electronic cigarette.

Summary of the invention

In view of this, the technical problem to be solved by the present invention is to provide an electronic cigarette control device, method, electronic cigarette and computer storage medium, which can save the internal space of the electronic cigarette and realize the control of the heat generating component.

The invention provides an electronic cigarette control device, comprising:

An electrostatic friction film assembly disposed in an air flow passage of the electronic cigarette to generate a corresponding electrostatic current when the air flow in the air flow passage changes;

a controller electrically connected to the working circuit of the electrostatic friction film assembly and the heat generating component of the electronic cigarette, respectively, for detecting an electrostatic current generated by the electrostatic friction film assembly, and the value of the electrostatic current is greater than The heat generating member starts to work at a threshold.

The controller is further configured to control an output power and/or an output temperature of the heat generating component according to a value of the static current after the heat generating component starts to work.

Wherein, the controlling the output power and/or the output temperature of the heat generating component according to the value of the electrostatic current comprises:

Controlling an output power and/or an output temperature of the heat generating component according to a preset relationship between an interval in which the value of the electrostatic current is located and an output power and/or an output temperature of the heat generating component; or

An output power and/or an output temperature of the heat generating member is controlled according to a predetermined linear relationship between a value of the electrostatic current and an output power and/or an output temperature of the heat generating member.

The controlling the output power and/or the output temperature of the heat generating component according to the value of the electrostatic current includes:

Controlling the heat generating component according to a preset relationship between a maximum value of the electrostatic current and an output power and/or an output temperature of the heat generating component before the value of the electrostatic current decreases from the maximum value to the first threshold value The operation is performed at an output power and/or an output temperature corresponding to the maximum value.

Wherein, the controller is further configured to adjust the liquid intake amount of the smoke liquid according to the value of the electrostatic current.

The controller is further configured to accumulate the number of times of suction in the set period when the value of the static current is detected to fall back to the first threshold after being greater than the first threshold.

The application also provides an electronic cigarette control method, including:

Detecting an electrostatic current generated when a flow of the electrostatic friction film assembly disposed in the air flow passage of the electronic cigarette changes in the air flow passage;

When the value of the electrostatic current is greater than the first threshold, the heat generating member that controls the electronic cigarette starts to operate.

The method further includes:

After the heat generating member starts operating, the output power and/or the output temperature of the heat generating member is controlled according to the value of the electrostatic current.

The step of controlling the output power and/or the output temperature of the heat generating component according to the value of the electrostatic current includes:

The output power and/or the output temperature of the heat generating member is controlled in accordance with a predetermined linear positive correlation between the value of the electrostatic current and the output power and/or the output temperature of the heat generating member.

The method further includes:

The amount of liquid introduced into the liquid is adjusted according to the value of the electrostatic current.

The method further includes:

When it is detected that the value of the electrostatic current falls back to the first threshold value after being greater than the first threshold value, the number of times of suction in the set period is accumulated.

The present invention also provides an electronic cigarette comprising the electronic cigarette control device as described above.

The present invention also provides an electronic cigarette comprising a memory and a processor, the memory storing at least one program instruction; the processor implementing the electronic cigarette control method as described above by loading and executing the at least one program instruction.

The present invention also provides a computer storage medium having stored thereon computer program instructions; the computer program instructions being executed by a processor to implement the electronic cigarette control method as described above.

The electronic cigarette control device, method, electronic cigarette and computer storage medium of the invention are provided with an electrostatic friction film assembly in an air flow passage of the electronic cigarette, and the electrostatic friction film assembly generates a corresponding electrostatic current when the air flow in the air flow passage changes. The electrostatic current generated by the electrostatic friction film assembly is detected by the controller, and when the value of the electrostatic current is greater than the first threshold, the heating element is controlled to start working, thereby saving the internal space of the electronic cigarette and realizing the control of the heating element.

DRAWINGS

FIG. 1 is a schematic structural diagram of an electronic cigarette control device according to an exemplary embodiment of the present invention.

FIG. 2 is a schematic flow chart of an electronic cigarette control method according to an exemplary embodiment of the present invention.

FIG. 3 is a schematic structural diagram of an electronic cigarette according to an exemplary embodiment of the present invention.

detailed description

The specific embodiments, structures, features and functions of the present invention are described in detail below with reference to the accompanying drawings and embodiments.

FIG. 1 is a schematic structural diagram of an electronic cigarette control device according to an exemplary embodiment of the present invention. As shown in FIG. 1, the electronic cigarette control device of the present embodiment includes an electrostatic friction film assembly 110 and a controller 120.

The electrostatic friction film assembly 110 is disposed in the air flow passage of the electronic cigarette to generate a corresponding electrostatic current when the air flow in the air flow passage changes, and the electrostatic current is the current generated by the electrostatic friction, and the controller 120 and the electrostatic friction film assembly 110 and the electron respectively The working circuit of the heat generating component of the smoke is electrically connected to detect the electrostatic current generated by the electrostatic friction film assembly 110, and controls the heat generating component to start working when the value of the electrostatic current is greater than the first threshold.

Specifically, the electrostatic friction film assembly 110 includes at least two layers of the electrostatic friction film and electrodes disposed on the back side of the friction surface of the electrostatic friction film, and the electronegativity between the adjacent electrostatic friction films is different. Preferably, the number of the electrostatic friction films is two layers and are stacked in opposite directions, and the opposite faces of the electrostatic friction film are friction surfaces, and the friction surface is preferably a rough surface on which granular protrusions or irregular lines are formed. Thereby increasing the friction area between the electrostatic friction films and improving the ability to generate a stable electric charge, the electrostatic friction film may be comb-like or planar, and the edges of the electrostatic friction film are fixed together by pressing or fitting. The intermediate portion of the electrostatic friction film is relatively movable to produce a relative displacement when the air flow in the air flow passage changes to frictionally generate electricity. In one embodiment, the electrode is an electrode wire electrically connected to the back side of the friction surface of the electrostatic friction film, or a transparent conductive film formed by depositing indium tin oxide on the back side of the friction surface of the electrostatic friction film to improve charge collection. The effect is to increase the bonding force between the electrode and the electrostatic friction film, and the controller 120 is electrically connected to the electrode on the electrostatic friction film assembly 110 through a wire or a metal wire connected to the pin of the controller 120, so that the electrostatic friction film is The electrostatic current generated during the friction can be fed back to the controller 120, and the controller 120 detects the magnitude of the electrostatic current and the electrostatic current value of the electrostatic friction film.

In one embodiment, the electrostatic friction film may be made of polyvinyl alcohol, polyethylene, polypropylene, polyvinyl chloride, polytetrafluoroethylene, etc., and only the electronegativity between adjacent electrostatic friction films may be different. It is only necessary to generate an induced charge when rubbing against each other. In addition, the thickness of the electrostatic friction film and/or the total thickness of the electrostatic friction film and the transparent conductive film should be controlled to be 1 to 100 μm to make the electrostatic friction film assembly 110 have a long time while ensuring normal operation of the electrostatic friction film assembly 110. Service life.

In an embodiment, the air flow passage of the electronic cigarette is disposed in the electronic cigarette housing and communicates with the cigarette holder. When the user smokes the electronic cigarette through the cigarette holder, the air is sucked from the outside of the electronic cigarette through the air inlet of the airflow passage, and then It is discharged from the air outlet through the air flow passage, so that air flow changes occur in the air flow passage. The electrostatic friction film assembly 110 is disposed on a side wall of the housing corresponding to the air flow passage, and is preferably disposed close to the air inlet to accurately sense a change of the air flow. When the air flow changes in the air flow passage, the electrostatic friction film will be disturbed by the air flow. Vibration occurs and frictional discharge with each other. As the user's pumping force increases and decreases, the air flow rate and flow rate through the air flow passage will increase and decrease accordingly, and the relative friction between the electrostatic friction films will also increase. The increase and decrease are such that the magnitude of the electrostatic current generated by the friction reflects the magnitude of the suction force.

The heat generating component is, for example, a heating wire disposed in the atomizer of the electronic cigarette, and the smoke liquid entering the atomizer is heated by the heating wire to generate atomized smoke, and the working circuit of the heat generating component is electrically connected with the controller 120, and is controlled. The device 120 controls the heat generating component to start working when detecting that the value of the static current is greater than the first threshold, for example, controlling conduction between the heat generating component and the power source device, so that the electronic cigarette emits smoke when the user smokes. In actual implementation, the first threshold may be determined experimentally, for example, determining a corresponding electrostatic current value according to different pumping strengths, and selecting a minimum electrostatic current value as the first threshold, so that only when the user normally smokes the electronic cigarette The electrostatic current of the first threshold can trigger the heat generating component to work, thereby preventing the electrostatic friction film from rubbing against each other under the condition that the electronic cigarette is vibrated or slammed, and the electrostatic current is generated, thereby causing the heat generating component to be falsely triggered to ensure the electronic cigarette. Safe to use and have a better user experience.

Further, the controller 120 is further configured to control the output power and/or the output temperature of the heat generating component according to the value of the static current after the heat generating component starts to work. Specifically, the heat generating member can be controlled to operate with the same or the same varying output power and/or output temperature at each pumping, or the heat generating member can be controlled according to the change of the value of the electrostatic current at each pumping. Output power and/or output temperature, wherein the magnitude of the electrostatic current generated by the friction of the electrostatic friction film reflects the magnitude of the suction force, and thus the output power of the heat generating member is controlled according to the change in the value of the electrostatic current at each pumping And / or output temperature, so that users can get different smoke output from time to time, the user experience is better.

In an embodiment, controlling the output power and/or the output temperature of the heat generating component according to the value of the electrostatic current includes: a preset relationship between the interval in which the value of the electrostatic current is located and the output power and/or the output temperature of the heat generating component , controlling the output power and/or output temperature of the heat generating component.

Specifically, the magnitude of the electrostatic current generated by the friction of the electrostatic friction film reflects the magnitude of the suction force, and the maximum and minimum values of the electrostatic current of the frictional discharge of the electrostatic friction film caused by the suction can be determined by experiments, and the electrostatic current is preliminarily determined. The magnitude of the value sets a plurality of electrostatic current intervals, each interval corresponding to a different output power and/or output temperature, the output power and/or output temperature being the optimum output power and/or output temperature at the pumping force. For example, the amount of smoke generated and the atomization effect are optimal, thereby forming a preset relationship between the interval in which the value of the electrostatic current is located and the output power and/or output temperature of the heat generating member. In actual implementation, since the value of the electrostatic current obtained by the controller 120 generally increases gradually to a maximum value and then gradually decreases during each pumping process, it may be in the process of changing the electrostatic current value, according to The current interval in which the electrostatic current value is currently determined determines the corresponding output power and/or output temperature in real time to control the operation of the heat generating component.

In another embodiment, controlling the output power and/or the output temperature of the heat generating component according to the value of the electrostatic current includes: a predetermined linear relationship between the value of the electrostatic current and the output power and/or the output temperature of the heat generating component, Control the output power and/or output temperature of the heat generating component.

Specifically, when the electrostatic current generated by the friction of the electrostatic friction film is the first threshold, it corresponds to the lowest output power and/or output temperature of the heat generating component, that is, when the heat generating component operates at the lowest output power and/or output temperature, the smoke liquid It will be atomized into smoke. When the value of the electrostatic current is greater than the first threshold, the output power and/or output temperature of the heating element increases with the value of the electrostatic current. When the value of the electrostatic current reaches the maximum value. The output power and/or output temperature of the heat generating component also reaches a maximum value, and the maximum value of the output power and/or the output temperature is limited to avoid excessive increase in output power and/or output temperature, resulting in burnout of the heat generating component, the specific value It can be obtained experimentally that after the value of the electrostatic current reaches a maximum value, the output power and/or output temperature of the heat-generating component can be lowered as the value of the electrostatic current decreases, and the output power of the heat-generating component is linearly positively correlated and/ Or output temperature for real-time adjustment. In actual implementation, the maximum and minimum values of the electrostatic current of the electrostatic friction film friction discharge can be determined through experiments, and the output power and/or output corresponding to each electrostatic current value is determined according to the change of the electrostatic current between the maximum value and the minimum value. The temperature, thereby forming a predetermined linear relationship between the value of the electrostatic current and the output power and/or output temperature of the heat generating member.

In still another embodiment, controlling the output power and/or the output temperature of the heat generating component according to the value of the electrostatic current includes: before the value of the electrostatic current drops from the maximum value to the first threshold, according to the maximum value of the electrostatic current and the heat generating component The preset relationship of the output power and/or the output temperature controls the heat generating component to operate at an output power and/or an output temperature corresponding to the maximum value.

Specifically, since the flow rate and the flow velocity of the airflow gradually increase at the beginning of the pumping behavior, and gradually decrease after reaching the peak value, the electrostatic current of the frictional discharge of the electrostatic friction film falls below the first threshold again after reaching the maximum value, therefore, The output of the heat generating component may be continuously outputted with the output power corresponding to the maximum value of the electrostatic current and/or the output temperature before the value of the electrostatic current drops from the maximum value to the first threshold. The maximum value of the electrostatic current here is the time of each pumping. The measured peak value of the electrostatic current makes the working process simpler and ensures a proper amount of smoke. In actual implementation, the maximum and minimum values of the electrostatic current of the electrostatic friction film friction discharge can be determined through experiments. The maximum value measured by the experiment can be the maximum theoretical current value of the friction energy released by the electrostatic friction film. A plurality of electrostatic current value intervals are set between the minimum values to correspond to the maximum electrostatic current values achievable by different pumping forces, and each electrostatic current interval corresponds to a different output power and/or output temperature, thereby forming each pumping time. The preset relationship between the maximum value of the generated electrostatic current and the output power and/or output temperature of the heat generating member.

It is worth mentioning that, in the process of the user sucking the electronic cigarette each time, before the electrostatic current value reaches the maximum value and after falling back from the maximum value, one or a combination of the above embodiments may be adopted according to the value of the electrostatic current. The output power and/or output temperature of the heat generating component are controlled to achieve different control effects.

Further, the controller 120 is further configured to adjust the liquid intake amount of the smoke liquid according to the value of the electrostatic current.

Specifically, when the output power and/or the output temperature of the heat generating component are controlled according to the value of the electrostatic current, the amount of the smoke liquid required for the heat generating component to operate at different output powers and/or output temperatures may vary, usually The larger the value of the electrostatic current, the higher the output power and/or the output temperature, and the higher the amount of smoke liquid required. By adjusting the amount of liquid in the liquid according to the value of the electrostatic current, the amount of liquid can be made-output. And / or output temperature - the amount of intake air to achieve the best match, improve the user's pumping experience. In actual implementation, the amount of the liquid input corresponding to the interval of the electrostatic current value is preset, or the preset linear relationship between the value of the electrostatic current and the amount of the liquid, or the maximum value of the electrostatic current and the amount of the liquid. The preset relationship is such that the controller 120 can adjust the size or the opening amount of the liquid inlet according to the value of the electrostatic current to adjust the liquid intake amount, wherein when the value of the electrostatic current is not greater than the first threshold, the liquid inlet is closed, and the electrostatic current is After the value is greater than the first threshold, the change trend of the liquid intake amount is mainly that the larger the value of the electrostatic current is, the larger the liquid intake amount is, the larger the liquid inlet opening is or the more the opening is, when the value of the electrostatic current is greater than When the second threshold is reached, the liquid intake amount reaches the maximum, and the liquid inlet port is opened to the maximum or all of the opening. The specific liquid inlet amount is set according to the output power and/or the output temperature corresponding to the value of the electrostatic current, and may also be directly related to the static electricity. The value of the current value is associated with the setting. The second threshold can be determined experimentally, typically a value less than the maximum value of the electrostatic current. It should be understood that, in another embodiment, when the output power and/or the output temperature of the heat generating component is controlled according to the value of the electrostatic current, the liquid amount of the liquid smoke may also be adjusted according to the current output power and/or the output temperature of the heat generating component. The current required amount of liquid input can be determined by the preset output power and/or the corresponding relationship between the output temperature and the liquid intake amount, and the liquid inlet can be controlled to open when the output power and/or the output temperature is greater than the third threshold. To the maximum or all of the opening to obtain the maximum amount of liquid, the specific adjustment process is similar to the aforementioned adjustment process, and will not be described herein.

Further, the controller 120 is further configured to accumulate the number of times of suction in the set period when the value of the static current is detected to fall back to the first threshold again after being greater than the first threshold.

Specifically, when the controller 120 detects that the value of the electrostatic current rises to the first threshold and then drops to the first threshold, it can be regarded as a single pumping behavior of the user, and the user is counted by accumulating the number of times of pumping. The number of puffs in a given period, such as the number of puffs in a day, the number of puffs in a week, and the like. The counted number of puffs can be displayed on the display screen of the e-cigarette in real time or when the set number of puffs is accumulated, the display screen and the sound device on the e-cigarette are used to remind, or the counted number of puffs is set in the electronic cigarette. The wireless communication module is sent to an external device such as a mobile phone or a tablet computer for display or prompting. When the number of puffs is greater than the predetermined number of puffs, the controller 120 will no longer respond to the electrostatic current generated by the electrostatic tribo module 110, the user cannot smoke again, and the predetermined number of puffs can be set by the user.

The electronic cigarette control device of the present invention is provided with an electrostatic friction film assembly in the air flow passage of the electronic cigarette, and generates a corresponding electrostatic current when the air flow in the air flow passage is changed by the electrostatic friction film assembly, and the electrostatic friction film assembly is detected by the controller. The electrostatic current is controlled, and when the value of the electrostatic current is greater than the first threshold, the heating element is controlled to start working, thereby saving the internal space of the electronic cigarette and realizing the control of the heating element.

FIG. 2 is a schematic flow chart of an electronic cigarette control method according to an exemplary embodiment of the present invention. As shown in FIG. 2, the electronic cigarette control method of this embodiment includes but is not limited to the following steps:

Step 210, detecting an electrostatic current generated when the airflow in the airflow passage is changed by the electrostatic friction film assembly disposed in the airflow passage of the electronic cigarette;

Step 220: When the value of the electrostatic current is greater than the first threshold, the heat generating component that controls the electronic cigarette starts to work.

In an embodiment, the electronic cigarette control method of the embodiment further includes:

After the heat generating member starts working, the output power and/or the output temperature of the heat generating member is controlled according to the value of the electrostatic current.

In an embodiment, the step of controlling the output power and/or the output temperature of the heat generating component according to the value of the electrostatic current comprises:

Controlling the output power and/or the output temperature of the heat generating component according to a preset relationship between the interval in which the value of the electrostatic current is located and the output power and/or the output temperature of the heat generating component; or

Controlling the output power and/or the output temperature of the heat generating component according to a preset linear positive correlation between the value of the electrostatic current and the output power and/or the output temperature of the heat generating component; or

Before the value of the electrostatic current drops from the maximum value to the first threshold, the output of the heat generating component corresponding to the maximum value is controlled according to a preset relationship between the maximum value of the electrostatic current and the output power and/or the output temperature of the heat generating component. Or output temperature to work.

When the output power and/or the output temperature of the heat generating member is controlled according to the value of the electrostatic current, the liquid amount of the liquid smoke is adjusted according to the value of the electrostatic current.

When it is detected that the value of the electrostatic current falls back to the first threshold again after being greater than the first threshold, the number of times of suction in the set period is accumulated.

For the specific steps of the electronic cigarette control method in this embodiment, refer to the description of the embodiment shown in FIG. 1 , and details are not described herein again.

In the electronic cigarette control method of the present invention, the electrostatic current is generated by the electrostatic friction film assembly disposed in the air flow passage of the electronic cigarette when the air flow in the air flow passage changes, and the value of the electrostatic current is greater than the first At the threshold value, the heat generating member that controls the electronic cigarette starts to work, thereby saving the internal space of the electronic cigarette and realizing the control of the heat generating member.

FIG. 3 is a schematic structural diagram of an electronic cigarette according to an exemplary embodiment of the present invention. As shown in FIG. 3, the present invention further provides an electronic cigarette comprising a memory 310 and a processor 320, wherein the memory 310 stores at least one program instruction. The processor 320 implements the electronic cigarette control method as described above by loading and executing at least one program instruction.

For the specific steps of the implementation of the processor 320 in this embodiment, refer to the description of the embodiment shown in FIG. 1 to FIG. 2, and details are not described herein again.

The present invention also provides a computer storage medium having stored thereon computer program instructions; the computer program instructions being executed by the processor to implement the electronic cigarette control method as described above.

The foregoing storage medium includes: a USB flash drive, a mobile hard disk, a read-only memory (ROM), a random access memory (RAM), a magnetic disk, an optical disk, or a cloud, and the like, which can store program codes. medium.

For the specific steps that are implemented when the computer program instructions of the computer storage medium of the embodiment are executed by the processor, refer to the description of the embodiment shown in FIG. 1 to FIG. 2, and details are not described herein again.

The above is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention. The present invention has been described above by way of a preferred embodiment, but is not intended to limit the invention, and any person skilled in the art, The equivalents of the technical solutions disclosed above may be modified or modified to equivalent variations without departing from the technical scope of the present invention, without departing from the technical scope of the present invention. Any simple modifications, equivalent changes and modifications made by the above embodiments are still within the scope of the technical solutions of the present invention.

Claims

An electronic cigarette control device, comprising:

An electrostatic friction film assembly disposed in an air flow passage of the electronic cigarette to generate a corresponding electrostatic current when the air flow in the air flow passage changes;

a controller electrically connected to the working circuit of the electrostatic friction film assembly and the heat generating component of the electronic cigarette, respectively, for detecting an electrostatic current generated by the electrostatic friction film assembly, and the value of the electrostatic current is greater than The heat generating member starts to work at a threshold.
The electronic cigarette control device according to claim 1, wherein the controller is further configured to control an output power of the heat generating component according to a value of the electrostatic current after the heat generating component starts operating. Or output temperature.
The electronic cigarette control device according to claim 2, wherein the controlling the output power and/or the output temperature of the heat generating component according to the value of the electrostatic current comprises:

Controlling the heat generating component according to a preset relationship between a maximum value of the electrostatic current and an output power and/or an output temperature of the heat generating component before the value of the electrostatic current decreases from the maximum value to the first threshold value The operation is performed at an output power and/or an output temperature corresponding to the maximum value.
The electronic cigarette control device according to claim 1 or 2, wherein the controller is further configured to adjust the liquid intake amount of the smoke liquid according to the value of the electrostatic current.
The electronic cigarette control device according to claim 1 or 2, wherein the controller is further configured to fall back to the first after detecting that the value of the electrostatic current is greater than the first threshold At the threshold, the number of puffs in the set period is accumulated.
An electronic cigarette control method, comprising:

Detecting an electrostatic current generated when a flow of the electrostatic friction film assembly disposed in the air flow passage of the electronic cigarette changes in the air flow passage;

When the value of the electrostatic current is greater than the first threshold, the heat generating member that controls the electronic cigarette starts to operate.
The electronic cigarette control method according to claim 6, wherein the method further comprises:

After the heat generating member starts operating, the output power and/or the output temperature of the heat generating member is controlled according to the value of the electrostatic current.
The electronic cigarette control method according to claim 7, wherein the step of controlling the output power and/or the output temperature of the heat generating component according to the value of the electrostatic current comprises:

Controlling an output power and/or an output temperature of the heat generating component according to a preset relationship between an interval in which the value of the electrostatic current is located and an output power and/or an output temperature of the heat generating component; or

The output power and/or the output temperature of the heat generating member is controlled according to a predetermined linear positive correlation between the value of the electrostatic current and the output power and/or the output temperature of the heat generating member.
The electronic cigarette control method according to claim 7 or 8, wherein the step of controlling the output power and/or the output temperature of the heat generating component according to the value of the electrostatic current comprises:

Controlling the heat generating component according to a preset relationship between a maximum value of the electrostatic current and an output power and/or an output temperature of the heat generating component before the value of the electrostatic current decreases from the maximum value to the first threshold value The operation is performed at an output power and/or an output temperature corresponding to the maximum value.
The electronic cigarette control method according to claim 6 or 7, wherein the method further comprises:

The amount of liquid introduced into the liquid is adjusted according to the value of the electrostatic current.
The electronic cigarette control method according to claim 6 or 7, wherein the method further comprises:

When it is detected that the value of the electrostatic current falls back to the first threshold value after being greater than the first threshold value, the number of times of suction in the set period is accumulated.
An electronic cigarette comprising the electronic cigarette control device according to any one of claims 1 to 6.
An electronic cigarette, comprising: a memory and a processor, the memory storing at least one program instruction; the processor implementing the at least one program instruction by loading and executing the at least one program instruction to implement any one of claims 7 to 12 The electronic cigarette control method described in the item.
A computer storage medium, wherein the computer storage medium is stored with computer program instructions; and the computer program instructions are executed by a processor to implement the electronic cigarette control method according to any one of claims 6 to .