CN113951577A - Over-suction protection method, device and system for electronic atomizer - Google Patents

Abstract

The application relates to the field of atomizers, in particular to an over-suction protection method, device and system for an electronic atomizer, wherein the method comprises the steps of responding to a starting request and outputting a detection instruction for obtaining ambient air pressure; acquiring an ambient air pressure index based on a result detected by the detection device in response to the detection instruction; comparing the environmental air pressure index with an air pressure threshold value to obtain an air pressure comparison result; and when the current ambient air pressure is determined to be in the first air pressure state based on the air pressure comparison result, determining to send a timing instruction for reducing the atomization time length. The application has the advantage of improving the safety in utilization of electronic atomizer.

Description

Over-suction protection method, device and system for electronic atomizer

Technical Field

The application relates to the field of atomizers, in particular to an over-suction protection method, device and system for an electronic atomizer.

Background

Atomization refers to the operation of dispersing a liquid into tiny droplets through a nozzle or with a high velocity gas stream. The atomized plurality of discrete droplets may trap particulate matter in the gas. The liquid atomization method includes pressure atomization, rotary disc atomization, gas atomization, sound wave atomization and the like, so that the liquid is converted into small droplets through a special device and sprayed out in a mist shape. The atomization technology can be applied to various fields such as an atomizing medical device, an electronic atomizer, and the like, wherein the electronic atomizer has been popular among many people as a recently emerging product.

In the related art, an electronic atomizer is a product that is powered by a rechargeable lithium polymer battery to drive the atomizer, oil in an oil tank is heated to change the oil into steam, and then aerosol with specific smell is generated through heating and atomization, so that a user can suck the aerosol.

With respect to the above-described related art, the inventors consider that the following problems exist: when the existing electronic atomizer is used by users in plateau areas or areas with higher altitude, the pressure of the plateau areas or areas with higher altitude is lower, the air is thinner, and after part of users absorb the electronic atomizer for too long time, adverse symptoms such as oxygen deficiency are generated due to insufficient oxygen supply, so that the physical conditions of the users are influenced.

Disclosure of Invention

In order to improve the use safety of the electronic atomizer, the application provides an electronic atomizer over-suction protection method, device and system.

In a first aspect, the present application provides a method for protecting over-suction of an electronic atomizer, comprising:

responding to a starting request based on user input and outputting a detection control instruction;

acquiring an ambient air pressure index based on detection operation which is executed by the detection device in response to the detection instruction;

if the environmental air pressure index falls into the preset air pressure threshold range, determining that the current environmental air pressure is in a first air pressure state;

and if the conditions are met, sending a heating time control instruction for controlling the heating time of the heating atomization device.

By adopting the technical scheme, the electronic atomizer control device responds to the starting request and outputs a detection control instruction for acquiring the ambient air pressure, the detection device responds to the detection control instruction and then detects the ambient air pressure and outputs a result, based on the result detected by the detection device responding to the detection control instruction, the electronic atomizer control device acquires the ambient air pressure index and compares the ambient air pressure index with the air pressure threshold range to acquire an air pressure comparison result, after judgment, if the ambient air pressure index falls within the preset air pressure threshold range, the current ambient air pressure is determined to be in a first air pressure state, when the current ambient air pressure is determined to be in the first air pressure state, a timing control instruction for reducing the atomization duration is sent to the heating atomization device, when a user inhales the electronic atomizer, the heating atomization device appropriately reduces the atomization duration after receiving the timing instruction, and furthermore, the time for a user to suck the electronic atomizer once is reduced, adverse symptoms such as oxygen deficiency caused by insufficient oxygen supply after the user possibly absorbs the electronic atomizer for too long time are reduced, the physical condition of the user is influenced, and the use safety of the electronic atomizer is indirectly improved.

Optionally, the preset air pressure threshold range includes a first endpoint value and a second endpoint value, and the first endpoint value is smaller than the second endpoint value;

based on the detection operation executed by the detection device in response to the detection control instruction, the method also comprises the following steps after the environmental air pressure index is obtained:

if the ambient air pressure index is smaller than the first endpoint value, determining that the current ambient air pressure is in a second air pressure state;

and if the conditions are met, sending a closing control instruction for stopping the heating atomization device and sending an oxygen supply starting instruction for starting the oxygen supply device.

By adopting the technical scheme, when the environmental air pressure index detected by the detection device is smaller than the first endpoint value, the electronic atomizer control device determines that the current environmental air pressure is in a second air pressure state, then sends a closing control instruction for forbidding atomization work to the heating atomization device, and the heating atomization device is closed after responding to the closing instruction; meanwhile, the electronic atomizer control device also sends an oxygen supply starting instruction for supplying oxygen to the user to the oxygen supply device, and the oxygen supply device responds to the oxygen supply starting instruction and supplies oxygen to the user; when the user is prohibited to suck the electronic atomizer in the environment of the second air pressure state, oxygen can be supplied to the user who probably has oxygen deficiency for sucking, the occurrence of adverse symptoms such as oxygen deficiency of the user is reduced, and the safety of the user is further guaranteed.

Optionally, the specific step of responding to the start request based on the user input includes:

acquiring a pressure index output based on the detection device sensing the holding operation of the user according to the holding operation of the user;

and if the pressure index is larger than a preset pressure threshold value, taking the pressure index as a starting request input by a user, and responding to the starting request.

By adopting the technical scheme, when a user needs to suck the electronic atomizer, the user holds the electronic atomizer firstly, the detection device receives the information of the operation that the user holds the electronic atomizer and responds, at the moment, the pressure index is larger than the preset pressure threshold value, and therefore the electronic atomizer control device responds to the starting request input by the user and carries out the operation of obtaining the ambient air pressure in the next step. In the operation, a period of time is required from holding the electronic atomizer by a user to sucking, so that working time can be reserved for the detection device and the electronic atomizer control device, and the ambient air pressure can be detected before the user sucks the electronic atomizer; meanwhile, the detection device is powered on to work when a user needs to suck, and the effect of saving power is achieved.

Optionally, after the response is based on the start request input by the user, the method further includes the following steps:

and sending a prompt control command for controlling a prompt device to perform prompt action.

By adopting the technical scheme, after the electronic atomizer control device determines to output the starting request, the electronic atomizer control device sends a prompt control instruction for prompting a user to the prompt device, and the prompt device responds to the prompt control instruction and makes a prompt operation for the user so as to prompt the user that the electronic atomizer is in a starting state currently.

Optionally, the atomizer over-suction protection method further includes the following steps:

acquiring an air flow duration parameter based on the air flow timing operation which is induced by the flow metering device and executed by the air flow metering device;

when the gas flow time length parameter is larger than a preset time length threshold value, determining that the current gas flow is influenced by human factors;

and when the conditions are met, outputting a starting control instruction for starting the heating atomization device to act.

By adopting the technical scheme, based on the gas flow timing operation which is sensed by the flow metering device and executed by the gas flow metering device, the electronic atomizer control device acquires the gas flow time length parameter, compares the gas flow time length parameter with the preset time length threshold value, determines that the current gas flow is influenced by human factors when the gas flow time length parameter is greater than the preset time length threshold value, and outputs a starting control instruction when the current gas flow is confirmed to be influenced by the human factors, so that the heating atomization device can be started to work; and then reduced the atomizing device that generates heat and frequently taken place the mistake because of the air current interference of short time and started, lead to the atomizing device that generates heat to frequently open and close and impaired condition takes place, indirectly improved the life of electronic atomizer.

Optionally, after determining that the current airflow is influenced by human factors, the method further includes the following steps:

sending a speed measurement control instruction;

acquiring a flow velocity value of the sucked gas based on the speed measurement operation executed by the speed measurement device in response to the speed measurement control instruction;

when the flow rate value of the sucked gas is larger than a preset flow rate threshold value, determining that the sucking rate of the current user is too high;

and when the conditions are met, sending a power control command for improving the power of the heating atomization device.

Through adopting above-mentioned technical scheme, electronic atomizer controlling means has confirmed when current user inhales the speed too fast based on the velocity of flow comparison result, in time to the atomizer that generates heat sends the power control instruction that improves atomization rate, the atomizer that generates heat responds to this power control instruction and improves atomization speed, in order to reduce the partial oil in the atomizer that generates heat and can not in time form the fog because of the atomizing device's that generates heat efficiency is not enough, and is inhaled by the user, the condition that influences user's taste takes place.

Optionally, when the value of the flow rate of the inspired gas is greater than the preset flow rate threshold, after determining that the current user inspired rate is too fast, the method further includes the following steps:

and sending an alarm control instruction for controlling the alarm device to perform alarm action.

By adopting the technical scheme, when the sucking speed of the user is too high, the electronic atomizer control device sends an alarm control instruction to the alarm device, and the alarm device responds to the alarm control instruction and gives an alarm prompt to the user so as to remind the user that the sucking speed is too high at present.

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

an electronic atomizer control device comprising:

the memory is used for storing the acquired environmental air pressure index, flow rate value of the sucked gas and an over-suction protection program;

and the processor executes the steps of any one of the electronic atomizer over-suction protection methods when the over-suction protection program is run.

In a third aspect, the present application provides an electronic atomizer device, comprising,

an electronic atomizer apparatus comprising:

the detection device is used for executing detection operation to obtain an ambient air pressure index;

the heating atomization device is used for responding to the heating time length control instruction and carrying out heating atomization according to the specified time length;

the oxygen supply device is used for responding to the oxygen supply starting instruction to start oxygen supply;

the detection device is used for sensing the holding operation of a user to obtain a pressure index;

the prompting device is used for responding to the prompting control instruction to perform a prompting action;

a flow metering device for sensing gas flow and performing gas flow timing operations;

the speed measuring device is used for executing speed measuring operation to obtain a flow velocity value of the sucked gas;

the alarm device is used for responding to the alarm control command to perform alarm action;

the input end of the electronic atomizer control device is respectively connected with the detection device, the flow metering device and the speed measuring device, and the output end of the electronic atomizer control device is respectively connected with the detection device, the heating atomization device, the oxygen supply device, the prompt device, the speed measuring device and the alarm device.

In a fourth aspect, the present application provides an over-suction protection system for an electronic atomizer, which adopts the following technical scheme:

an electronic atomizer over-suction protection system comprising:

the detection control module is used for responding to a starting request input by a user and outputting a detection control instruction;

the environment air pressure index acquisition module is used for acquiring an environment air pressure index based on detection operation which is executed by the detection device in response to the detection instruction;

the environment air pressure determining module is used for determining that the current environment air pressure is in a first air pressure state if the environment air pressure index falls into a preset air pressure threshold range;

and the judging module is used for sending a heating time control instruction for controlling the heating time of the heating atomization device if the conditions are met.

Through adopting above-mentioned technical scheme, the user is when sucking electronic atomizer, and detection control module responds the start-up request of user's input, and the output acquires the detection control instruction of environment atmospheric pressure, and the environment atmospheric pressure index is based on the detection device response detection operation that detection instruction and execution acquire the environment atmospheric pressure index, and current environment atmospheric pressure state is confirmed to environment atmospheric pressure confirming module, and when environment atmospheric pressure index fell into the atmospheric pressure threshold value within range of predetermineeing, it is first atmospheric pressure state to confirm current environment atmospheric pressure, and the judging module is used for judging the atmospheric pressure comparison result, and when above-mentioned condition satisfied, send the long control command of length of generating heat that is used for controlling the atomizing device that generates heat and generate heat.

To sum up, the application comprises the following beneficial technical effects:

the electronic atomizer can reduce the time for a user to suck the electronic atomizer once, reduce adverse symptoms such as oxygen deficiency caused by insufficient oxygen supply after the user possibly absorbs the electronic atomizer for too long time, influence the physical condition of the user, and indirectly improve the use safety of the electronic atomizer;

the electronic atomizer can be prohibited from being sucked by a user in the environment of the second air pressure state, and meanwhile, oxygen can be provided for the user possibly suffering from oxygen deficiency, so that the safety of the user is further ensured;

this application can reduce the atomizing device that generates heat and frequently take place the mistake because of the air current interference of short time and touch, leads to the atomizing device that generates heat to frequently open and close and impaired condition takes place, has indirectly improved electronic atomizer's life.

Drawings

Fig. 1 is a flowchart of an over-suction protection method for an electronic atomizer according to an embodiment of the present application.

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

Fig. 3 is a flowchart of the sub-step of step S2 in the embodiment of the present application.

Fig. 4 is a block diagram of an electronic atomizer apparatus according to an embodiment of the present application.

Fig. 5 is a block diagram of an over-suction protection system of an electronic atomizer according to an embodiment of the present application.

Reference numerals: 1. a memory; 2. a processor; 3. a detection device; 4. a heat generating atomizer; 5. an oxygen supply device; 6. a detection device; 7. a prompting device; 8. a flow metering device; 9. a speed measuring device; 10. an alarm device; 11. a detection control module; 12. an ambient air pressure index acquisition module; 13. an ambient air pressure determination module; 14. a judgment module; 15. a gas flow duration parameter acquisition module; 16. a time length comparison module; 17. starting a control module; 18. a speed measurement control module; 19. a suction gas flow rate value acquisition module; 20. a flow rate comparison module; 21. a power control module; 22. and an alarm control module.

Detailed Description

The present application is described in further detail below with reference to figures 1-5.

The embodiment of the application discloses an over-suction protection method, device and system for an electronic atomizer, which can improve the use safety of the electronic atomizer.

Referring to fig. 1 and 2, the method specifically includes the following steps:

s1: and responding to a starting request based on user input and outputting a detection control instruction.

Referring to fig. 3, for step S1, the step of responding to the start request based on the user input further includes the sub-steps of:

s11: according to the holding operation of the user, the pressure index output based on the sensing of the holding operation of the user by the detection device 6 is acquired.

S12: and if the pressure index is larger than the preset pressure threshold, taking the pressure index as a starting request input by a user, and responding to the starting request.

For step S12, the step of responding to the start request further includes the following sub-steps:

s121: a presentation control command for controlling the presentation device 7 to perform a presentation operation is issued.

After the electronic atomizer control device determines to output the start request, the electronic atomizer control device sends a prompt control instruction for prompting a user to the prompt device 7, and the prompt device 7 responds and makes a prompt operation for the user.

The following are illustrative:

when a user is in a plateau zone or a first air pressure state zone, wherein the first air pressure state refers to a low-pressure environment state, the user needs to suck the electronic atomizer, the electronic atomizer needs to be held by a hand, and the electronic atomizer is generally kept in a pocket of the user or hung in the chest of the user by an auxiliary tool such as a tie when the electronic atomizer is not used, so that the user needs a certain time when holding the electronic atomizer and moving a sucking area of the electronic atomizer to the mouth of the user; when a user holds the electronic atomizer, the detection device 6 starts to work, the detection device 6 can be understood as a pressure sensor or various devices equivalent to the pressure sensor, the detection device 6 detects the pressure held by the user and outputs a result to the electronic atomizer control device, namely, the electronic atomizer control device obtains a pressure index, the electronic atomizer control device compares and judges the pressure index with a preset pressure threshold, and when the pressure index is greater than the pressure threshold, the electronic atomizer control device determines to respond to a starting request input by the user and controls the heating atomizer 4 to perform the next action. The operation can reserve working time for the detection device 3 and the electronic atomizer control device, and the environmental air pressure can be detected before a user sucks the electronic atomizer; meanwhile, the detection device 3 is powered on to work when the user needs to suck, and the effect of saving power is achieved.

S2: the ambient air pressure index is acquired based on the detection operation that the detection device 3 responds to the detection instruction and executes.

S3: and if the ambient air pressure index falls within the preset air pressure threshold range, determining that the current ambient air pressure is in a first air pressure state.

Referring to fig. 1 and 3, for the step S2, the following sub-steps are included after acquiring the ambient air pressure index based on the detection operation performed by the detection device 3 in response to the detection control command:

it should be noted that the preset air pressure threshold range includes a first endpoint value and a second endpoint value, and the first endpoint value is smaller than the second endpoint value.

And S21, if the environmental air pressure index is smaller than the first endpoint value, determining that the current environmental air pressure is in a second air pressure state.

S22: and if the ambient air pressure index is lower than the minimum endpoint value of the air pressure threshold range, determining that the current ambient air pressure is in a second air pressure state, and sending a closing instruction for forbidding atomization work and an opening instruction for supplying oxygen to a user.

When the environmental air pressure index detected by the detection device 3 is lower than the minimum endpoint value of the preset air pressure threshold range in the electronic atomizer control device, the electronic atomizer control device determines that the current environmental air pressure is in a second air pressure state, the environmental air pressure at the moment is considered to be an ultra-low pressure state, the second air pressure state is worse than the first air pressure state, the air around the environment where the user is located is thinner, and the possibility of oxygen deficiency of the user is also improved, at the moment, when the user sucks the electronic atomizer, the electronic atomizer control device sends a closing control instruction for forbidding atomization work to the heat-generating atomization device 4, and the heat-generating atomization device 4 is closed after responding to the closing instruction so as to forbid the user in the environment of the second air pressure state from sucking the electronic atomizer; simultaneously, electronic nebulizer controlling means still sends the control command of opening to user's oxygen suppliment to oxygen suppliment device 5, and oxygen suppliment device 5 responds this opening command and carries out the oxygen suppliment to the user, and the user can adjust the state of oneself through inhaling oxygen to reduce the condition emergence of bad symptoms such as oxygen deficiency appear in the user, further guaranteed user's safety.

In addition, when the ambient air pressure index detected by the detection device 3 is higher than the second endpoint value of the air pressure threshold range, the electronic atomizer control device determines that the current ambient air pressure is in a normal air pressure state, the heat-generating atomizing device 4 works normally, and the working time of the electronic atomizer is the conventional time.

Continuing back to fig. 1 and 2;

further, when the following certain condition is satisfied, the following steps may occur before or after any of the above steps S1, S2, S3, and the like occurs.

SA 1: the gas flow duration parameter is obtained based on the gas flow timing operation that is performed by the flow meter means 8 and sensed gas flow.

SA 2: when the gas flow time length parameter is larger than a preset time length threshold value, determining that the current gas flow is influenced by human factors;

SA 3: when the conditions are met, outputting a starting control instruction for starting the heating atomization device 4 to act;

specifically, when the flow counting device 8 senses gas flow, timing operation of the gas flow is executed, it should be noted that the influence formed by the gas flow has human factor influence and external factor influence, in this embodiment, the flow counting operation of the flow counting device 8 can be completed by using a gas flow sensor, the electronic atomizer control device obtains a gas flow duration parameter based on the operation of the flow counting device 8, the electronic atomizer control device compares the gas flow duration parameter with a preset duration threshold value to obtain a duration comparison result, when the gas flow duration parameter is greater than the preset duration threshold value, it is determined that current gas flow is the human factor influence, the electronic atomizer control device outputs a start control instruction at this time, and the heat generating and atomizing device 4 can start to operate; when the gas flowing duration parameter is smaller than the duration threshold value, the influence of external factors such as the interference of environmental airflow is judged, and at the moment, the electronic atomizer control device does not act.

Above-mentioned operation has reduced atomizing device 4 that generates heat and has frequently taken place the mistake because of the air current of short time disturbs and touch, leads to atomizing device 4 that generates heat to frequently open and close and impaired condition takes place, has indirectly improved electronic atomizer's life.

Further, for step SA 3: after determining that the current airflow is influenced by human factors, the method further comprises the following steps:

SA 4: sending a speed measurement control instruction;

SA 5: acquiring a flow velocity value of the sucked gas based on the speed measurement operation executed by the speed measurement device 9 in response to the speed measurement control instruction;

SA 6: when the flow rate value of the sucked gas is larger than a preset flow rate threshold value, determining that the sucking rate of the current user is too high;

SA 7: when the above conditions are satisfied, a power control command for increasing the power of the heat generating atomizing device 4 is transmitted.

Specifically, after the user sucks the electronic atomizer, the electronic atomizer control device outputs a speed measurement control instruction for acquiring the flow rate of the gas to the detection device 3, in this embodiment, the detection device 3 may also adopt a flow meter such as a gas flow sensor, after receiving the speed measurement control instruction, the detection device 3 detects the flow rate of the gas in the heating and atomizing device 4 when the user sucks the electronic atomizer, the electronic atomizer control device acquires the flow rate value of the sucked gas and compares the flow rate value of the sucked gas with a preset flow rate threshold value, if the flow rate value of the sucked gas is greater than the flow rate threshold value, the electronic atomizer control device determines that the current user sucking rate is too fast, so the electronic atomizer control device determines to send a power control instruction for increasing the atomizing rate to the heating and atomizing device 4, after the heating and atomizing device 4 receives the power control instruction, the accessible increases rate of heating's mode, improves atomization rate to make the oil in the atomizing device 4 that generates heat accelerate the form of dissolving into the aerosol, in order to reduce the partial oil in the atomizing device 4 that generates heat and can not in time form the fog because of the efficiency of the atomizing device 4 that generates heat is not enough, and is inhaled by the user, and the condition that influences user's taste takes place.

For step SA6, when the value of the inspired gas flow rate is greater than the preset flow rate threshold, after the step of determining that the current user inspired rate is too fast, the method further includes:

SA8, an alarm control command is issued for controlling the alarm device 10 to perform an alarm operation.

Specifically, when the user takes too fast, the electronic atomizer control device sends an alarm control instruction to the alarm device 10, in this embodiment, the alarm device 10 may adopt a buzzer, a vibrator or other devices, and the alarm device 10 acts after receiving the alarm control instruction to give an alarm prompt to the user, so as to remind the user that the current intake rate is too fast.

It should be understood that, the sequence numbers of the steps in the foregoing embodiments do not imply an execution sequence, and the execution sequence of each process should be determined by its function and inherent logic, and should not constitute any limitation to the implementation process of the embodiments of the present invention.

The present embodiment also provides an electronic nebulizer control apparatus, which, referring to fig. 4, includes a memory 1 and a processor 2, specifically,

the storage device 1 is used for storing the obtained environmental air pressure index, flow rate value of the sucked gas and an over-suction protection program;

and the processor 2 executes the steps of any electronic atomizer over-suction protection method when the over-suction protection program is run.

The present embodiment also provides an electronic atomizer apparatus, referring to fig. 4, including:

the detection device 3 is used for executing detection operation to obtain an ambient air pressure index;

the heating atomization device 4 is used for responding to the heating time length control instruction and carrying out heating atomization according to the specified time length;

the oxygen supply device 5 is used for responding to the oxygen supply starting instruction to start oxygen supply;

the detection device 6 is used for sensing the holding operation of a user to obtain a pressure index;

the prompting device 7 is used for responding to the prompting control instruction to perform a prompting action;

a flow metering device 8 for sensing the gas flow and performing a gas flow timing operation;

the speed measuring device 9 is used for executing speed measuring operation to obtain a flow velocity value of the sucked gas;

the alarm device 10 is used for responding to the alarm control command to perform alarm action;

the electronic atomizer control device is used for executing any step of the electronic atomizer over-suction protection method, the input end of the electronic atomizer control device is respectively connected with the detection device 3, the detection device 6, the flow metering device 8 and the speed measuring device 9, and the output end of the electronic atomizer control device is respectively connected with the detection device 3, the heating atomization device 4, the oxygen supply device 5, the prompting device 7, the speed measuring device 9 and the alarm device 10.

The embodiment further provides an over-suction protection system of an electronic atomizer, referring to fig. 5, including a detection control module 11, an ambient air pressure index obtaining module 12, an ambient air pressure determining module 13, a judging module 14, a gas flow duration parameter obtaining module 15, a duration comparison module 16, a start control module 17, a speed measurement control module 18, a food suction gas flow rate value obtaining module, a flow rate comparison module 20, a power control module 20, and an alarm control module 21. The functional modules are explained in detail as follows:

the detection control module 11 is used for responding to a starting request input by a user and outputting a detection control instruction;

an ambient air pressure index obtaining module 12, configured to obtain an ambient air pressure index based on a detection operation that is executed by the detection device 3 in response to the detection instruction;

the environment air pressure determining module 13 is configured to determine that the current environment air pressure is in a first air pressure state if the environment air pressure index falls within a preset air pressure threshold range;

and the judging module 14 is configured to send a heating time duration control instruction for controlling the heating time duration of the heating atomization device 4 if the above condition is met.

The gas flow duration parameter obtaining module 15 obtains a gas flow duration parameter based on the gas flow timing operation performed by the flow counting device 8 when sensing the gas flow.

And the time length comparison module 16 is configured to determine that the current gas flow is influenced by human factors when the gas flow time length parameter is greater than a preset time length threshold.

And the starting control module 17 is used for outputting a starting control instruction for starting the heat-generating atomization device 4 to act when the above conditions are met.

And the speed measurement control module 18 is used for sending a speed measurement control instruction.

And the sucking gas flow velocity value acquisition module is used for responding to the speed measurement control instruction and executing speed measurement operation based on the speed measurement device 9 to acquire a sucking gas flow velocity value.

And the flow rate comparison module 20 is configured to determine that the current user smoking rate is too fast when the smoking gas flow rate value is greater than a preset flow rate threshold value.

And the power control module 21 is configured to send a power control command for increasing the power of the heat-generating atomizing device 4 when the above condition is satisfied.

And the alarm control module 22 is used for sending an alarm control instruction for controlling the alarm device 10 to perform an alarm action.

Specifically, when a user sucks the electronic atomizer, the detection control module 11 responds to a starting request input by the user, outputs a detection control instruction for acquiring ambient air pressure, the ambient air pressure index acquisition module 12 responds to a result detected by the detection control instruction based on the detection device 3, further acquires an ambient air pressure index, the ambient air pressure determination module 13 is used for confirming the current air pressure environment, if the ambient air pressure index falls within a preset air pressure threshold range, it is determined that the current ambient air pressure is in a first air pressure state, the judgment module 14 is used for judging an air pressure comparison result, and if the above conditions are met, a heating time control instruction for controlling the heating time of the heating atomization device 4 is sent.

In addition, in the process of sucking the electronic atomizer by a user, based on the gas flow timing operation which is performed by the gas flow sensed by the flow metering device 8, the gas flow duration parameter is obtained, the duration comparison module 16 compares the gas flow duration parameter with the duration threshold, when the gas flow duration parameter is greater than the preset duration threshold, the current gas flow is determined to be influenced by human factors, and when the current gas flow is determined to be influenced by human factors based on the duration comparison result, the starting control module 17 outputs a starting control instruction for starting the movement of the heating atomization device 4.

Meanwhile, in the process that the user sucks the electronic atomizer, the speed measurement control module 18 generates a speed measurement control instruction, the sucking gas flow speed value acquisition module responds to the speed measurement control instruction and performs speed measurement operation based on the speed measurement device 9 to acquire a sucking gas flow speed value, the sucking gas flow speed value is compared with a preset flow speed threshold value through the flow speed comparison module to acquire a flow speed comparison result, when the sucking gas flow speed value is larger than the preset flow speed threshold value, it is determined that the sucking speed of the current user is too high by 20, the power control module 21 determines to send a power control instruction for improving the power of the heating atomization device 4, the atomization efficiency of the heating atomization device 4 is improved, and meanwhile, the alarm control module 22 sends an alarm control instruction for controlling the alarm device 10 to perform alarm action so as to control the alarm device 10 to warn the user.

For specific limitations of an over-suction protection system of an electronic atomizer, reference may be made to the above limitations of an over-suction protection method of an electronic atomizer, and details thereof are not repeated here. The various modules in the above-described system may be implemented in whole or in part by software, hardware, and combinations thereof. The modules can be embedded in a hardware form or independent from an electronic atomizer control device in the electronic equipment, and can also be stored in a memory 1 in the electronic equipment in a software form, so that the electronic atomizer control device can call and execute operations corresponding to the modules.

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

The above embodiments are only used to illustrate the technical solutions of the present application, and not to limit the same; 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 solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications and substitutions do not substantially depart from the spirit and scope of the embodiments of the present application and are intended to be included within the scope of the present application.

Claims (10)

1. An electronic atomizer over-suction protection method is characterized by comprising the following steps:

responding to a starting request based on user input and outputting a detection control instruction;

acquiring an ambient air pressure index based on detection operation which is performed by the detection device (3) in response to the detection instruction;

if the environmental air pressure index falls into the preset air pressure threshold range, determining that the current environmental air pressure is in a first air pressure state;

and if the conditions are met, sending a heating time control instruction for controlling the heating time of the heating atomization device (4).

2. The over-suction protection method for the electronic atomizer according to claim 1,

the preset air pressure threshold range comprises a first endpoint value and a second endpoint value, and the first endpoint value is smaller than the second endpoint value;

based on the detection operation executed by the detection device (3) in response to the detection control instruction, the method also comprises the following steps after the environmental air pressure index is obtained:

if the ambient air pressure index is smaller than the first endpoint value, determining that the current ambient air pressure is in a second air pressure state;

and if the conditions are met, sending a closing control command for stopping the heating atomization device (4) and sending an oxygen supply starting command for starting the oxygen supply device (5).

3. The method for protecting over-suction of an electronic atomizer according to claim 1, wherein said specific step of responding to an activation request based on a user input comprises:

according to the holding operation of the user, acquiring a pressure index output based on the sensing of the holding operation of the user by the detection device (6);

and if the pressure index is larger than a preset pressure threshold value, taking the pressure index as a starting request input by a user, and responding to the starting request.

4. The electronic atomizer over-suction protection method according to claim 1 or 3, wherein after said response is based on a start request inputted by a user, further comprising the steps of:

and sending out a prompt control command for controlling a prompt device (7) to perform prompt action.

5. The electronic atomizer over-suction protection method according to claim 1 or 3, characterized in that the atomizer over-suction protection method further comprises the steps of:

acquiring an air flow duration parameter based on the air flow timing operation which is induced by the flow metering device (8) and executed by the air flow metering device;

when the gas flow time length parameter is larger than a preset time length threshold value, determining that the current gas flow is influenced by human factors;

when the above conditions are satisfied, a start control command for starting the operation of the heat-generating atomization device (4) is output.

6. The method for protecting over-suction of an electronic atomizer according to claim 5, wherein after determining that the current air flow is influenced by human factors, further comprising the steps of:

sending a speed measurement control instruction;

based on the speed measurement operation which is executed by the speed measurement device (9) in response to the speed measurement control instruction, obtaining the flow velocity value of the sucked gas;

when the flow rate value of the sucked gas is larger than a preset flow rate threshold value, determining that the sucking rate of the current user is too high;

when the above condition is satisfied, a power control command for increasing the power of the heat-generating atomizing device (4) is transmitted.

7. The method for protecting over-suction of the electronic atomizer according to claim 6, wherein after determining that the current user suction rate is too fast when the value of the suction gas flow rate is greater than the preset flow rate threshold, the method further comprises the following steps:

and sending an alarm control instruction for controlling the alarm device (10) to perform an alarm action.

8. An electronic atomizer control device, comprising:

the storage device (1) is used for storing the acquired environmental air pressure index, flow rate value of the sucked gas and an over-suction protection program;

a processor (2) which, when running the over-suction protection program, performs the steps of the electronic atomizer over-suction protection method according to any one of claims 1 to 7.

9. An electronic atomizer apparatus, comprising:

the detection device (3) is used for executing detection operation to obtain an ambient air pressure index;

the heating atomization device (4) is used for responding to the heating time length control instruction and carrying out heating atomization according to the specified time length;

the oxygen supply device (5) is used for responding to the oxygen supply starting instruction to start oxygen supply;

the detection device (6) is used for sensing the holding operation of a user to obtain a pressure index;

the prompting device (7) is used for responding to the prompting control instruction to perform a prompting action;

a flow metering device (8) for sensing the gas flow and performing a gas flow timing operation;

the speed measuring device (9) is used for executing speed measuring operation to obtain a flow velocity value of the sucked gas;

the alarm device (10) is used for responding to the alarm control command to perform alarm action;

the electronic atomizer control device according to claim 8, wherein the input end is connected to the detection device (3), the detection device (6), the flow metering device (8) and the speed measuring device (9), and the output end is connected to the detection device (3), the heat generating atomizer (4), the oxygen supply device (5), the prompting device (7), the speed measuring device (9) and the alarm device (10).

10. An electronic atomizer over-suction protection system, comprising:

the detection control module (11) is used for responding to a starting request input by a user and outputting a detection control instruction;

the environment air pressure index acquisition module (12) is used for acquiring an environment air pressure index based on detection operation which is executed by the detection device (3) in response to the detection instruction;

the environment air pressure determining module (13) is used for determining that the current environment air pressure is in a first air pressure state if the environment air pressure index falls into a preset air pressure threshold range;

and the judging module (14) is used for sending a heating time control instruction for controlling the heating time of the heating atomization device (4) if the conditions are met.

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