CN113841939B - Electronic atomizer control method, device, storage medium and induction system - Google Patents

Abstract

The application relates to the field of atomizers, in particular to a control method and device of an electronic atomizer, a storage medium and an induction system; the induction system of the electronic atomizer comprises an air pressure acquisition module, a mode information module and a signal output module; before absorbing mist, a user selects an absorbing mode which is needed to be used; the method comprises the steps that air pressure at an absorption channel of the electronic atomizer is obtained through an air pressure obtaining module, and an absorption mode selected by a user is obtained through a mode information module, so that the amount of fog needing to be output by the electronic atomizer is obtained; the information output module outputs a signal for adjusting the output quantity of the fog value; the application has the effect of automatically adjusting the mist output according to the practical requirement of a user.

Description

Electronic atomizer control method, device, storage medium and induction system

Technical Field

The present disclosure relates to the field of atomizers, and in particular, to a method and apparatus for controlling an electronic atomizer, a storage medium, and an induction system.

Background

The atomizer is a device for converting liquid into mist, and in life, the atomizer can convert chemical liquid reagents into mist for people to absorb, so that the use requirements of people are met.

An electronic atomizer is one type of atomizer, and the electronic atomizer generally evaporates liquid into mist for people to absorb in a heating manner; however, in the related art, the electronic atomizer can only keep constant power to generate heat, so that the situations of too little mist generated by too little power or too much mist generated by too much power can occur, and the actual use requirements of people can not be met.

Disclosure of Invention

In order to improve the practical degree of the electronic atomizer, the application provides an electronic atomizer control method, an electronic atomizer control device, a storage medium and an induction system.

In a first aspect, the present application provides a control method of an electronic atomizer, which adopts the following technical scheme:

an electronic atomizer control method, comprising:

and acquiring the air pressure value of the air suction channel of the electronic atomizer in real time, and obtaining the air flow speed value of the air suction channel of the electronic atomizer according to the air pressure value.

And acquiring mode information selected by a user in real time, and determining a mode of fog adjustment.

And outputting a signal for adjusting the output quantity of the fog value according to the fog adjusting mode and the airflow speed value at the air suction channel of the electronic atomizer.

By adopting the technical scheme, when a user makes actions of absorbing mist, the air flow speed value at the air suction channel of the electronic atomizer changes, and then the air pressure value at the air suction channel of the electronic atomizer changes; obtaining an air flow speed value by detecting air pressure, and deducing the suction force of a user by utilizing the change value of the air flow speed value; and based on the regulation mode selected by the user and the suction force of the user, the device outputs a signal for regulating the output quantity of the mist value, and regulates the heating power of the electronic atomizer, thereby playing the role of changing the heating power according to the suction condition of the user, and achieving the effect of improving the practical degree of the electronic atomizer.

Optionally, the step of obtaining, in real time, the air pressure value at the air suction channel of the electronic atomizer, and obtaining the air flow velocity value at the air suction channel of the electronic atomizer according to the air pressure value includes:

and when the air pressure value at the air suction channel of the electronic atomizer changes and the maintaining time of the changed air pressure value is more than or equal to a set time threshold, acquiring the air pressure value at the air suction channel of the electronic atomizer in real time.

And calculating the air flow speed value at the air suction channel of the electronic atomizer based on the air pressure value obtained in real time.

By adopting the technical scheme, as people usually can make a sucking action lasting for a certain period of time when sucking mist by using the electronic atomizer, the time threshold is set, so that the electronic atomizer is more close to the use habit of people, and the occurrence of false triggering caused by blowing external wind into an airflow channel of the electronic atomizer is also reduced.

Optionally, the step of calculating the airflow velocity value at the air suction channel of the electronic atomizer based on the air pressure value obtained in real time includes:

and acquiring the current air pressure value in real time, and calculating the difference value between the current air pressure value and the atmospheric pressure value.

And calculating the air flow speed value at the air suction channel of the electronic atomizer based on the difference value between the current air pressure value and the atmospheric pressure value.

By adopting the technical scheme, when the air flow speed value at the air suction channel of the electronic atomizer is obtained, the current air pressure value and the atmospheric pressure value are required to be compared, and after the difference value between the current air pressure value and the atmospheric pressure value is obtained, the change value of the air flow speed value is obtained.

Optionally, the step of acquiring the mode information selected by the user in real time and determining the mode of mist adjustment includes:

and acquiring a plurality of calculation modes in real time, wherein the calculation modes relate to mist value output quantity, the mist value output quantity is regulated according to the change of the airflow speed value, and each calculation mode corresponds to one mist regulation mode.

Information of a mist regulating mode selected by a user is obtained in real time, and a calculation mode of regulating the output quantity of the mist value according to the change of the airflow speed value is determined.

By adopting the technical scheme, each calculation mode for adjusting the output quantity of the fog value corresponds to one fog adjusting mode, and a user selects the corresponding fog adjusting mode according to own requirements before absorbing fog, so that the electronic atomizer can meet the current requirements of the user; the effect of satisfying multiple different demands is played in setting up multiple fog regulation mode.

Optionally, the step of outputting a signal for adjusting the output quantity of the mist value according to the mist adjusting mode and the airflow speed value at the air suction channel of the electronic atomizer includes:

and obtaining information of the force of absorbing mist by a user according to the air flow speed value at the air suction channel of the electronic atomizer.

And outputting a signal for adjusting the output quantity of the fog value based on the fog adjusting mode and information of the fog sucking force of a user.

Through adopting above-mentioned technical scheme, when the user absorbs fog, the action of absorbing of user makes the air current velocity value of electronic atomizer suction channel department change, obtains the information of the dynamics of user's absorption fog through the change of air current velocity value, adjusts the fog volume that electronic atomizer released according to the mode of user's selection and the information of the dynamics of user's absorption fog.

Optionally, the step of obtaining, in real time, the air pressure value at the air suction channel of the electronic atomizer, and obtaining the air flow velocity value at the air suction channel of the electronic atomizer according to the air pressure value, further includes:

and outputting a signal for keeping the original action of the electronic atomizer when the air pressure value at the air suction channel of the electronic atomizer changes and the duration is smaller than a set time threshold.

Through adopting above-mentioned technical scheme, when the user absorbs fog, can keep the action of absorbing of certain time generally, if the duration does not reach the threshold value, then not trigger the change action of electronic atomizer, electronic atomizer keeps original output atomization volume, has reduced the influence of external air current to electronic atomizer.

In a second aspect, the present application provides an electronic atomizer control device, which adopts the following technical scheme:

an electronic atomizer control apparatus, comprising:

the air pressure acquisition module is as follows: the method is used for acquiring the air pressure value at the air suction channel of the electronic atomizer in real time.

Mode information module: the method is used for acquiring the mode information selected by the user in real time.

The signal output module: and the device is used for outputting a signal for adjusting the output quantity of the fog value.

In a third aspect, the present application provides a readable storage medium, which adopts the following technical scheme:

a readable storage medium storing a computer program which, when executed by an electronic nebulizer control apparatus, implements the steps of the electronic nebulizer control method according to any one of the aspects described above.

In a fourth aspect, the present application provides an electronic atomizer controller, which adopts the following technical scheme:

an electronic nebulizer controller comprising a memory, a processor and a computer program stored in the memory and executable on the processor, the processor implementing the steps of the electronic nebulizer control method according to any one of the preceding aspects when the computer program is executed by the processor.

In a fifth aspect, the present application provides an electronic atomizer sensing system, which adopts the following technical scheme:

an electronic atomizer sensing system, comprising:

air pressure acquisition device: the air pressure measuring device is used for collecting the air pressure value at the air suction channel of the electronic atomizer in real time.

Mode collection device: the method is used for collecting the mode information selected by the user in real time.

And the electronic atomizer controller according to the scheme, wherein the air pressure acquisition device and the mode acquisition device are connected with the electronic atomizer controller.

In summary, the present application includes at least one of the following beneficial technical effects:

1. when a user makes actions of absorbing mist, the air flow speed value at the air suction channel of the electronic atomizer changes, and then the air pressure value at the air suction channel of the electronic atomizer changes; obtaining an air flow speed value by detecting air pressure, and deducing the suction force of a user by utilizing the change value of the air flow speed value; based on the adjusting mode selected by the user and the sucking force of the user, a signal for adjusting the output quantity of the fog value is output, and the heating power of the electronic atomizer is adjusted, so that the effect of changing the heating power according to the sucking condition of the user is achieved, and the effect of improving the practical degree of the electronic atomizer is achieved;

2. each calculation mode for adjusting the output quantity of the fog value corresponds to a fog adjusting mode, and before absorbing fog, a user selects the corresponding fog adjusting mode according to own requirements, so that the electronic atomizer can meet the current requirements of the user; the multiple mist adjusting modes are set, so that the effect of meeting multiple different requirements is achieved;

3. when a user sucks fog, the sucking action is usually kept for a certain time, if the duration does not reach the threshold value, the changing action of the electronic atomizer is not triggered, the electronic atomizer keeps the original output atomization amount, and the influence of external airflow on the electronic atomizer is reduced.

Drawings

Fig. 1 is a flowchart of a method of controlling an electronic atomizer according to an embodiment of the present application.

Fig. 2 is a specific flowchart of step S1 in the embodiment of the present application.

Fig. 3 is a specific flowchart of step S13 in the embodiment of the present application.

Fig. 4 is a specific flowchart of step S2 in the embodiment of the present application.

Fig. 5 is a specific flowchart of step S3 in the embodiment of the present application.

Fig. 6 is a connection diagram of the electronic atomizer control apparatus in the embodiment of the present application.

Reference numerals illustrate:

1. an air pressure acquisition module; 2. a mode information module; 3. a signal output module; 4. an air pressure acquisition device; 5. and the mode acquisition device.

Detailed Description

The present application is described in further detail below in conjunction with figures 1-6.

Referring to fig. 1, an embodiment of the application discloses a control method of an electronic atomizer, which includes the following steps:

s1, acquiring an air pressure value at an air suction channel of the electronic atomizer in real time, and obtaining an air flow speed value at the air suction channel of the electronic atomizer according to the air pressure value.

As one of the implementation cases, when the user of the electronic atomizer is a human, the user usually uses the mouth to suck the mist generated by the electronic atomizer. Because the sucking requirement of the user needs to be obtained, the force of sucking the gas by the mouth of the user needs to be obtained. The force of sucking gas at the mouth of the user is reflected by the air flow speed value at the air suction channel of the electronic atomizer, and when the force of sucking gas at the mouth of the user is small, the air flow speed value at the air suction channel of the electronic atomizer is small; when the force of sucking the gas by the mouth of the user is large, the value of the air flow speed at the air suction channel of the electronic atomizer is also increased. When the air flow speed value at the air suction channel of the electronic atomizer changes, the air pressure value at the air suction channel of the electronic atomizer also changes, so that the air flow speed value at the air suction channel of the electronic atomizer can be obtained by detecting the air pressure value at the air suction channel of the electronic atomizer.

Referring to fig. 2, specifically, step S1 includes the sub-steps of:

and S11, when the air pressure value at the air suction channel of the electronic atomizer changes and the maintaining time of the changed air pressure value is more than or equal to a set time threshold value, acquiring the air pressure value at the air suction channel of the electronic atomizer in real time.

In this embodiment, since the rhythm of the mist sucking by the person using the electronic atomizer is similar to the rhythm of the breath, there is a continuous gas sucking action when the user sucks the mist. If the heating power of the electronic atomizer is changed immediately when the air pressure value at the air suction channel of the electronic atomizer is changed, the situation that the heating power of the electronic atomizer is changed mistakenly can occur. The time threshold is set, so that the electronic atomizer is more close to the use habit of people, and the occurrence of false triggering caused by external wind blowing into an airflow channel of the electronic atomizer is reduced.

For example: as one of the embodiments, assuming that the time threshold is set to 1s, when the air pressure value at the air suction channel of the electronic atomizer changes, the detection signal is triggered and the changed air pressure value is acquired when the duration of the changed air pressure value is 2 s.

When the air pressure value at the air suction channel of the electronic atomizer changes, the duration of the changed air pressure value is 0.5s, and the detection signal is not triggered.

S12: when the air pressure value at the air suction channel of the electronic atomizer changes and the duration is smaller than the set time threshold, outputting a signal for keeping the original action of the electronic atomizer.

Because the air suction channel of the electronic atomizer is communicated with the outside, the air from the outside is inevitably blown into the air suction channel of the electronic atomizer; if the electronic atomizer is triggered by external gas, the situation that a user generates mist when not sucking the mist, and then chemical liquid reagent is wasted is avoided. The external air is blown into the air suction channel of the electronic atomizer, which is not always continuous, but happens accidentally, and the time threshold is set, so that the electronic atomizer is triggered by mistake.

For example: assuming that the set time threshold is 0.5s, when the electronic cigarette is in a closed state, the air pressure value at the air suction channel of the electronic atomizer changes, and the duration after the air pressure value changes is 0.1s. And outputting a signal for keeping the original action of the electronic atomizer as the duration time after the air pressure value is changed is smaller than the set time threshold value, wherein the electronic atomizer is still in a closed state.

And S13, calculating the air flow speed value at the air suction channel of the electronic atomizer based on the air pressure value obtained in real time.

Specifically, the acquired air pressure value is converted into an air flow velocity value based on the bernoulli equation.

Referring to fig. 3, further, step S13 includes the sub-steps of:

s131: and acquiring the current air pressure value in real time, and calculating the difference value between the current air pressure value and the atmospheric pressure value.

S132: and calculating the air flow speed value at the air suction channel of the electronic atomizer based on the difference value between the current air pressure value and the atmospheric pressure value.

In this embodiment, when the air flow velocity value at the air suction channel of the electronic atomizer is obtained, the current air pressure value and the atmospheric pressure value need to be compared, and after the difference between the current air pressure value and the atmospheric pressure value is obtained, the change value of the air flow velocity value is obtained.

Let the atmospheric pressure beThe gas density is ρ, the gas flow speed value is v, and the current gas pressure value is +.>The gravity acceleration is g, the height of the electronic atomizer is h, and C is a constant, and the calculation mode is as follows:

bernoulli's equation is p ++/>= C；

The reference airflow velocity value when the current air pressure value is equal to the atmospheric pressure value corresponds to the airflow velocity value of 0 when the current air pressure value is equal to the atmospheric pressure value.

The formula can be derived:

since the gas density ρ is constant, the current gas flow velocity value can be obtained by detecting the current gas pressure value.

S2, acquiring mode information selected by a user in real time, and determining a mode of fog adjustment.

The mode of adjusting the fog of multiple different sets up, makes the user can select the suction mode that is fit for self condition, plays the effect that improves electronic atomizer's suitability.

Referring to fig. 4, specifically, step S2 includes the sub-steps of:

s21, acquiring a plurality of calculation modes in real time, wherein the calculation modes are related to a mist value output quantity, the mist value output quantity is regulated according to the change of the airflow speed value, and each calculation mode corresponds to one mist regulation mode.

Specifically, each mode is further calculated based on the calculated airflow speed value, so that under the condition that the airflow speed value is unchanged, each calculation mode can obtain different mist adjustment modes, and further different mist adjustment modes are obtained.

S22, acquiring information of a mist regulating mode selected by a user in real time, and determining a calculation mode for regulating the output quantity of the mist value according to the change of the airflow speed value.

As one of the embodiments, the mist adjustment mode includes an auto-adaptive mode. When the user needs to change the amount of the fog according to the suction force, that is, the larger the suction force of the user is, the more fog is released by the electronic atomizer, and then the automatic adaptation mode is selected. In the calculation mode of the automatic adaptation mode, the mist value output quantity of the electronic atomizer increases with the increase of the airflow speed value, and the mist value output quantity of the electronic atomizer decreases with the decrease of the airflow speed value.

As another embodiment, the mist adjustment mode further includes a constant mode. When a user needs to ingest a constant amount of mist per unit time, a constant mode is selected.

In particular, in order to provide a constant amount of mist to a user per unit time, the power of the electronic atomizer needs to be adjusted depending on the air flow velocity value. The larger the airflow speed value is, the heating power of the electronic atomizer is correspondingly adjusted and reduced; the smaller the airflow speed value is, the heating power of the electronic atomizer is correspondingly adjusted to be increased.

When the suction force of a user is increased, the airflow speed value at the airflow channel of the electronic atomizer is increased, the gas sucked by the user is increased, and in order to keep the quantity of mist sucked by the user constant, the content of the mist in the gas needs to be reduced, and the heating power of the electronic atomizer needs to be reduced; after the heating power of the electronic atomizer is reduced, the release amount of fog is reduced, and the content of fog in gas is reduced; the amount of mist sucked by the user remains constant due to the increased gas sucked.

When the suction force of a user is reduced, the air flow speed value at the air flow channel of the electronic atomizer is reduced, the air sucked by the user is reduced, and in order to keep the amount of mist sucked by the user constant, the content of the mist in the air needs to be increased, and the heating power of the electronic atomizer needs to be increased; after the heating power of the electronic atomizer is improved, the release amount of fog is increased, and the content of the fog in the gas is increased; the amount of mist sucked by the user remains constant due to the reduction of the sucked gas.

The relationship between the constant mode, the adaptive mode and the total amount of mist at the air flow rate value of 4m/s is shown in Table 1.

The relationship between the airflow velocity values of 2m/s, 4m/s and the total amount of mist in the constant mode is shown in Table 1.

In the adaptive mode, the relationship between the airflow velocity values of 2m/s and 4m/s and the total amount of mist is shown in Table 1.

In this embodiment, each calculation mode for adjusting the output quantity of the mist value corresponds to one mist adjustment mode, and before absorbing the mist, a user selects the corresponding mist adjustment mode according to own needs, so that the electronic atomizer can meet the current needs of the user; the effect of satisfying multiple different demands is played in setting up multiple fog regulation mode.

And S3, outputting a signal for adjusting the output quantity of the fog value according to the fog adjusting mode and the airflow speed value at the air suction channel of the electronic atomizer.

Referring to fig. 5, specifically, step S3 includes the sub-steps of:

s31: and obtaining information of the force of a user to suck the mist according to the air flow speed value at the air suction channel of the electronic atomizer.

S32: and outputting a signal for adjusting the output quantity of the fog value based on the fog adjusting mode and information of the fog sucking force of a user.

When a user sucks fog, the sucking action of the user enables the airflow speed value at the air suction channel of the electronic atomizer to change, the information of the fog sucking force of the user is obtained through the change of the airflow speed value, and the fog amount released by the electronic atomizer is adjusted according to the selected mode of the user and the information of the fog sucking force of the user.

When a user makes actions of absorbing mist, the air flow speed value at the air suction channel of the electronic atomizer changes, and then the air pressure value at the air suction channel of the electronic atomizer changes; obtaining an air flow speed value by detecting air pressure, and deducing the suction force of a user by utilizing the change value of the air flow speed value; and based on the regulation mode selected by the user and the suction force of the user, the device outputs a signal for regulating the output quantity of the mist value, and regulates the heating power of the electronic atomizer, thereby playing the role of changing the heating power according to the suction condition of the user, and achieving the effect of improving the practical degree of the electronic atomizer.

The specific implementation manner of the embodiment of the application is as follows: when a user sucks fog, the sucking action is usually kept for a certain time, if the duration does not reach the threshold value, the changing action of the electronic atomizer is not triggered, the electronic atomizer keeps the original output atomization amount, and the influence of external airflow on the electronic atomizer is reduced.

The embodiment of the application also discloses an electronic atomizer controller, which comprises a memory, a processor and a computer program stored in the memory and capable of running on the processor, wherein the processor realizes the following steps when executing the computer program:

s1, acquiring an air pressure value at an air suction channel of the electronic atomizer in real time, and obtaining an air flow speed value at the air suction channel of the electronic atomizer according to the air pressure value.

S2, acquiring mode information selected by a user in real time, and determining a mode of fog adjustment.

And S3, outputting a signal for adjusting the output quantity of the fog value according to the fog adjusting mode and the airflow speed value at the air suction channel of the electronic atomizer.

The processor, when executing the computer program, is also capable of executing the steps of the method for controlling an electronic nebulizer in any of the embodiments described above.

The electronic atomizer controller is a server and comprises a processor, a memory, a network interface and a database which are connected through a system bus. Wherein the processor of the electronic nebulizer controller is configured to provide computing and control capabilities. The memory of the electronic atomizer controller comprises a nonvolatile storage medium and an internal memory. The non-volatile storage medium stores an operating system, computer programs, and a database. The internal memory provides an environment for the operation of the operating system and computer programs in the non-volatile storage media. The database of the electronic nebulizer controller is used for information. The network interface of the electronic atomizer controller is used for communicating with an external terminal through network connection. The computer program is executed by a processor to implement an electronic nebulizer control method.

Referring to fig. 6, an embodiment of the present application discloses an electronic atomizer control device, which corresponds to the electronic atomizer control method in the above embodiment one by one. The electronic atomizer control device comprises an air pressure acquisition module 1, a mode information module 2 and a signal output module 3.

Air pressure acquisition module 1: the method is used for acquiring the air pressure value at the air suction channel of the electronic atomizer in real time.

Mode information module 2: the method is used for acquiring the mode information selected by the user in real time.

Signal output module 3: and the device is used for outputting a signal for adjusting the output quantity of the fog value.

The air pressure value at the air suction channel of the electronic atomizer is acquired in real time through the air pressure acquisition module 1, and the signal output module 3 is utilized to output a signal for adjusting the output quantity of the mist value in combination with the mode information selected by the user and acquired by the mode information module 2, so that the heating power of the electronic atomizer is changed, and the effect of controlling the output quantity of the mist of the electronic atomizer is further achieved.

For specific limitations of the electronic nebulizer control apparatus, reference may be made to the above limitations of the electronic nebulizer control method, and no further description is given here. The above-described respective modules in the electronic atomizer control apparatus may be implemented in whole or in part by software, hardware, and a combination thereof.

The application also discloses a readable storage medium having stored thereon a computer program which, when run by an electronic nebulizer control device, is implemented to:

s1, acquiring an air pressure value at an air suction channel of the electronic atomizer in real time, and obtaining an air flow speed value at the air suction channel of the electronic atomizer according to the air pressure value.

S2, acquiring mode information selected by a user in real time, and determining a mode of fog adjustment.

And S3, outputting a signal for adjusting the output quantity of the fog value according to the fog adjusting mode and the airflow speed value at the air suction channel of the electronic atomizer.

The readable storage medium stores a computer program which, when executed by a processor, implements the steps of all of the electronic nebulizer control methods described above. .

Those skilled in the art will appreciate that implementing all or part of the above-described methods may be accomplished by way of a computer program, which may be stored on a non-transitory computer readable storage medium, that when executed may comprise the steps of the embodiments of the methods described above. Any reference to memory, storage, database, or other medium used in the various embodiments provided herein may include non-volatile and/or volatile memory. The nonvolatile memory can include Read Only Memory (ROM), programmable ROM (PROM), electrically Programmable ROM (EPROM), electrically Erasable Programmable ROM (EEPROM), or flash memory; volatile memory can include Random Access Memory (RAM) or external cache memory; by way of illustration and not limitation, RAM is available in a variety of forms such as Static RAM (SRAM), dynamic RAM (DRAM), synchronous DRAM (SDRAM), double Data Rate SDRAM (DDRSDRAM), enhanced SDRAM (ESDRAM), synchronous Link DRAM (SLDRAM), memory bus direct RAM (RD RAM), direct memory bus dynamic RAM (DRDRAM), and memory bus dynamic RAM (RDRAM), among others.

The embodiment of the application also discloses an induction system of the electronic atomizer.

An electronic atomizer sensing system, comprising:

air pressure acquisition device 4: the air pressure measuring device is used for collecting the air pressure value at the air suction channel of the electronic atomizer in real time.

Mode acquisition device 5: the method is used for collecting the mode information selected by the user in real time.

And the electronic atomizer controller in the embodiment is connected with the air pressure acquisition device 4 and the mode acquisition device 5.

The air pressure acquisition device 4 acquires the air pressure value at the air suction channel of the electronic atomizer in real time and outputs air pressure value information to the electronic atomizer controller; the mode acquisition device 5 acquires the mode selected by the user in real time and outputs the mode information to the electronic atomizer controller; and the electronic atomizer controller controls the output fog amount of the electronic atomizer according to the received air pressure value information and the mode information.

Specifically, the air pressure acquisition device 4 includes, but is not limited to, an air pressure sensor; the mode acquisition device 5 includes, but is not limited to, a touch control panel.

It will be apparent to those skilled in the art that, for convenience and brevity of description, only the above-described division of the functional units and modules is illustrated, and in practical application, the above-described functional distribution may be performed by different functional units and modules according to needs, i.e. the internal structure of the apparatus is divided into different functional units or modules to perform all or part of the above-described functions.

The above embodiments are only for illustrating the technical solution of the present application, and are not limiting thereof: although the present application has been described in detail with reference to the foregoing embodiments, it should be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments may be modified, or some technical features thereof may be replaced by equivalents: such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present application, and are intended to be included in the scope of the present application.

Claims (8)

1. An electronic atomizer control method, characterized by comprising:

acquiring an air pressure value at an air suction channel of the electronic atomizer in real time, and obtaining an air flow speed value at the air suction channel of the electronic atomizer according to the air pressure value;

acquiring mode information selected by a user in real time, and determining a mode of fog adjustment;

outputting a signal for adjusting the output quantity of the fog value according to the fog adjusting mode and the airflow speed value at the air suction channel of the electronic atomizer;

the step of obtaining the air pressure value at the air suction channel of the electronic atomizer in real time and obtaining the air flow speed value at the air suction channel of the electronic atomizer according to the air pressure value comprises the following steps:

when the air pressure value at the air suction channel of the electronic atomizer changes and the maintaining time of the changed air pressure value is more than or equal to a set time threshold value, acquiring the air pressure value at the air suction channel of the electronic atomizer in real time;

based on the air pressure value obtained in real time, calculating an air flow speed value at the air suction channel of the electronic atomizer;

the step of calculating the air flow speed value at the air suction channel of the electronic atomizer based on the air pressure value obtained in real time comprises the following steps:

acquiring a current air pressure value in real time, and calculating a difference value between the current air pressure value and an atmospheric pressure value;

and calculating the air flow speed value at the air suction channel of the electronic atomizer based on the difference value between the current air pressure value and the atmospheric pressure value.

2. The method according to claim 1, wherein the step of acquiring the mode information selected by the user in real time and determining the mode of mist adjustment comprises:

acquiring a plurality of calculation modes in real time, wherein the calculation modes relate to a mist value output quantity, the mist value output quantity is regulated according to the change of an airflow speed value, and each calculation mode corresponds to a mist regulation mode;

information of a mist regulating mode selected by a user is obtained in real time, and a calculation mode of regulating the output quantity of the mist value according to the change of the airflow speed value is determined.

3. The method according to claim 2, wherein the step of outputting a signal for adjusting the output amount of the mist value according to the mist adjustment mode and the air flow speed value at the air suction passage of the electronic atomizer comprises:

according to the air flow speed value at the air suction channel of the electronic atomizer, information of the force of absorbing mist by a user is obtained;

and outputting a signal for adjusting the output quantity of the fog value based on the fog adjusting mode and information of the fog sucking force of a user.

4. The method according to claim 1, wherein the step of acquiring the air pressure value at the air suction channel of the electronic atomizer in real time, and deriving the air flow velocity value at the air suction channel of the electronic atomizer based on the air pressure value, further comprises:

and outputting a signal for keeping the original action of the electronic atomizer when the air pressure value at the air suction channel of the electronic atomizer changes and the duration is smaller than a set time threshold.

5. An electronic nebulizer control apparatus, characterized in that it is implemented based on the electronic nebulizer control method according to any one of claims 1 to 4, comprising:

air pressure acquisition module (1): the method comprises the steps of acquiring an air pressure value at an air suction channel of an electronic atomizer in real time, and obtaining an air flow speed value at the air suction channel of the electronic atomizer according to the air pressure value;

mode information module (2): the method comprises the steps of acquiring mode information selected by a user in real time and determining a mode of fog adjustment;

signal output module (3): and the device is used for outputting a signal for adjusting the output quantity of the fog value according to the fog adjusting mode and the airflow speed value at the air suction channel of the electronic atomizer.

6. A readable storage medium, characterized in that the readable storage medium stores a computer program which, when executed by an electronic nebulizer control apparatus, implements the steps of the electronic nebulizer control method according to any one of claims 1 to 4.

7. An electronic atomizer controller, characterized in that: comprising a memory, a processor and a computer program stored in the memory and executable on the processor, the processor implementing the steps of the electronic nebulizer control method according to any one of claims 1 to 4 when the computer program is executed.

8. An electronic atomizer sensing system, comprising:

air pressure acquisition device (4): the air pressure measuring device is used for collecting air pressure values at an air suction channel of the electronic atomizer in real time;

mode acquisition device (5): the method is used for collecting mode information selected by a user in real time;

and the electronic atomizer controller according to claim 7, wherein the air pressure acquisition device (4) and the mode acquisition device (5) are connected with the electronic atomizer controller.