CN113693299A - Atomization control method and device - Google Patents

Abstract

The application provides an atomization control method and device; the method comprises the steps of firstly determining current inspiration data according to a detected current suction signal, then reading stored average inspiration data and average aerosol quantity from a memory, comparing the average inspiration data with the current inspiration data to obtain a comparison result, carrying out atomization operation according to the average aerosol quantity when the comparison result represents that the current inspiration data is larger than or equal to the average inspiration data, and obtaining a target aerosol quantity corresponding to the current inspiration data and carrying out atomization operation according to the target aerosol quantity when the comparison result represents that the current inspiration data is smaller than the average inspiration data. The method provided by the application can determine the corresponding aerosol amount according to the magnitude relation between the current inhalation data and the average inhalation data, so that the atomization operation is carried out according to the corresponding aerosol amount to control the aerosol amount inhaled into the body by a user.

Description

Atomization control method and device

Technical Field

The present disclosure relates to atomization technologies, and in particular, to a method and an apparatus for controlling an atomization apparatus.

Background

With the continuous improvement of the living standard of people, various electronic entertainment products appear on the market, and the aerosol generating device is one of the electronic entertainment products which is popular among people.

The aerosol generating device needs a user to start the atomizer in the device to work through suction force generated by the oral cavity during use, and aerosol is generated during the work. However, inhaling a large amount of aerosol at a time can have a bad influence on human health, and therefore, it is necessary to provide an aerosol control method for controlling the amount of aerosol inhaled by a user.

Disclosure of Invention

The application provides an atomization control method and device, which are used for relieving and controlling the aerosol quantity inhaled into a body by a user.

In order to solve the technical problem, the present application provides the following technical solutions:

the application provides an atomization control method, which comprises the following steps:

determining current suction data according to the detected current suction signal;

reading the average inhalation data and the average aerosol amount stored in the memory;

comparing the average inspiration data with the current inspiration data to obtain a comparison result;

when the comparison result represents that the current inspiration data is larger than or equal to the average inspiration data, carrying out atomization operation according to the average aerosol amount;

and when the comparison result represents that the current inspiration data is smaller than the average inspiration data, acquiring a target aerosol quantity corresponding to the current inspiration data, and carrying out atomization operation according to the target aerosol quantity.

Correspondingly, this application still provides an atomizing controlling means, includes:

the data determining module is used for determining current air suction data according to the detected current suction signal;

a data reading module for reading the average inhalation data and the average aerosol amount stored in the memory;

the comparison module is used for comparing the average inspiration data with the current inspiration data to obtain a comparison result;

the first atomization module is used for carrying out atomization operation according to the average aerosol amount when the comparison result represents that the current inspiration data is larger than or equal to the average inspiration data;

and the second atomization module is used for acquiring a target aerosol quantity corresponding to the current inspiration data when the comparison result represents that the current inspiration data is smaller than the average inspiration data, and carrying out atomization operation according to the target aerosol quantity.

Has the advantages that: the application provides an atomization control method and device; the method comprises the steps of determining current air suction data according to a current suction signal after the current suction signal is detected, reading average air suction data and average aerosol quantity stored in a memory, comparing the average air suction data with the current air suction data to obtain a comparison result, carrying out atomization operation according to the average aerosol quantity when the comparison result indicates that the current air suction data is larger than or equal to the average air suction data, and obtaining a target aerosol quantity corresponding to the current air suction data and carrying out atomization operation according to the target aerosol quantity when the comparison result indicates that the current air suction data is smaller than the average air suction data. The method provided by the application determines the amount of the aerosol to be provided according to the magnitude relation of the current inhalation data and the average inhalation data from the health perspective of a user using the aerosol generating device, so that the atomization operation is performed according to the corresponding amount of the aerosol, and the amount of the aerosol inhaled into the body of the user is controlled to be as small as possible.

Drawings

The technical solution and other advantages of the present application will become apparent from the detailed description of the embodiments of the present application with reference to the accompanying drawings.

Fig. 1 is a schematic structural diagram of an atomization control system provided in an embodiment of the present application.

Fig. 2 is a schematic flow chart of an atomization control method provided in an embodiment of the present application.

Fig. 3 is another schematic flow chart of an atomization control method provided in an embodiment of the present application.

Fig. 4 is a schematic structural diagram of an atomization control device provided in an embodiment of the present application.

Fig. 5 is a schematic structural diagram of an aerosol-generating device provided in an embodiment of the present application.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application. It is to be understood that the embodiments described are only a few embodiments of the present application and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

In this application, a suction signal refers to a signal generated by a user using the aerosol generating device when the aerosol generating device is being sucked, the signal comprising a size of an inhalation and a duration of the inhalation.

In this application, aerosol amount refers to the amount of aerosol generated by the aerosol generating device based on the aerosol substrate at a certain inhalation size and inhalation duration.

The application provides an atomization control method and device to achieve the purpose of controlling the amount of aerosol inhaled by a user.

First embodiment

Referring to fig. 1, fig. 1 is a schematic structural diagram of an atomization control system provided in the present application, as shown in fig. 1, the atomization control system mainly includes an aerosol generating device 100 and a terminal 200, where the aerosol generating device 100 further includes a host 110, an atomizer 120 and an interface 130, where:

the aerosol generating apparatus 100 and the terminal 200 are connected and communicated with each other through the internet or the like constituted by various gateways. For example, before the first use, the terminal 200 may perform the pairing connection operation by scanning the factory two-dimensional code of the aerosol-generating device 100; for another example, the user may turn on bluetooth through a bluetooth button of the aerosol-generating device 100, so that the terminal 200 can perform pairing connection with the aerosol-generating device through bluetooth, and the like, and the connection manner between the aerosol-generating device 100 and the terminal 200 is not specifically limited in this application. Wherein the user can send user-defined average inhalation data and average aerosol amount to the aerosol generating device 100 through the terminal 200 so that the aerosol generating device 100 stores them in the memory.

The host 110 includes a circuit board, a Memory, a switch element, and the like, wherein the circuit board is mainly used for supplying power to the host 110 and the nebulizer 120, and the Memory may be a Static Random-Access Memory (SRAM), which has a relatively high speed; or an Electrically Erasable Read-Only Memory (EEPROM), which has a fast update speed and can still store data when power is off; the Memory can also be a Flash Memory (Flash Memory), can be written in and read out, has large capacity and high speed, can improve the storage performance, and can also be other suitable memories; the switching element may include a microphone for sensing an electrical parameter generated by a negative pressure generated by a change in the airflow in the intake passage, outputting a sensing signal to the circuit board according to the change in the electrical parameter, and transmitting the airflow to the suction sensor in the atomizer 120 for detection.

The atomizer 120 includes an atomizing core, a connecting member, an atomizing electrode, a sensor, and the like. The atomizing core comprises an atomizing cavity, an aerosol substrate storage cavity, an air outlet channel, a suction nozzle, a liquid guide part and a heating part; the sensors include a suction sensor, a thermosensitive sensor, a speed sensor, an acceleration sensor and the like, and the suction sensor is mainly used for detecting a suction signal.

The host 110 and the nebulizer 120 are connected through an interface 130, and the interface 130 may be a Type-C interface, a Type-B interface, a USB interface, and the like, and is not limited in detail herein.

Second embodiment

With reference to the above scenario of the atomization control system, the atomization control method in the present application will be described in detail below, please refer to fig. 2, fig. 2 is a schematic flow chart of the atomization control method in the present application, and as shown in fig. 2, the atomization control method in the present application at least includes the following steps:

201: current inhalation data is determined based on the detected current inhalation signal.

The suction signal is a signal generated when a user sends out suction action to the microphone of the aerosol generating device when the aerosol generating device is used. Specifically, the suction signal includes a suction size and a suction time period; the air suction size is the pressure generated by the change of air flow in the air inlet channel in the air suction process of the aerosol generating device by a user; the inhalation duration is the duration of the change in the air flow in the air inlet passage during inhalation by the user of the aerosol generating device (i.e. the duration of one inhalation by the user).

In one embodiment, when the aerosol generating device is used by a user, a corresponding suction signal is generated, and when the aerosol generating device detects the suction signal, corresponding data processing is performed according to the detected suction signal, which includes the following specific steps: by detecting a suction signal; when a suction signal is detected, analyzing the suction signal to obtain the inspiration size and inspiration time, and taking the inspiration size and the inspiration time as current inspiration data. Specifically, after detecting the suction signal, the suction sensor in the atomizer 120 of the aerosol generating device analyzes the suction signal according to the data processing module in the atomizer 120, so as to obtain the inhalation size and inhalation duration corresponding to the suction signal, and the inhalation size and inhalation duration are used as the current inhalation data of the user.

202: the average inhalation data and the average aerosol amount stored in the memory are read.

In one embodiment, when the nebulizer 120 detects that the user is using the aerosol generating device (i.e., detects the suction signal), the average inhalation data and the local aerosol amount are read from the memory of the host 110, and the steps include: triggering a reading instruction according to the current suction signal; and reading the average inspiration data and the average aerosol amount from the memory according to the reading instruction. Specifically, the nebulizer 120 triggers the nebulizer 120 to send a reading command to the host computer when the suction signal is detected, the reading command can be generated by a control main board in the nebulizer 120 and sent to the host computer 110, and the host computer 110 reads the pre-stored average inhalation data and the average aerosol amount from the memory thereof in response to the reading command after receiving the reading command.

The memory includes a Read Only Memory (ROM) and a random access/write memory (RAM). Specifically, the Memory may be a Static Random-Access Memory (SRAM), which is fast; or an Electrically Erasable Read-Only Memory (EEPROM), which has a fast update speed and can still store data when power is off; the Memory can also be a Flash Memory (Flash Memory), which can be written in and read out, has large capacity and high speed, can improve the storage performance, and can also be other suitable memories.

In one embodiment, the host 110 may calculate the historical data stored therein via a data processing module to obtain average inhalation data and average aerosol amount, which includes the following steps: reading the inspiration size, inspiration duration and inspiration times in a preset historical period stored in a memory; determining an average inspiration size according to the inspiration size and the inspiration times; determining an average inspiration time according to the inspiration time and the inspiration times; and taking the average inspiration size and the average inspiration time as average inspiration data, and determining the corresponding average aerosol amount according to the average inspiration data. Specifically, the inhalation size and inhalation duration generated each time the user uses the aerosol generating device are stored in the memory of the host 110, and after the user uses the aerosol generating device for multiple times, the aerosol generating device can calculate the average inhalation data and the corresponding average aerosol amount according to the inhalation data in a certain period.

For example, a user may communicate with the aerosol generating device 100 via the terminal 200, and the user sets 8: 00 to 12: 00 is a preset history period, and then the preset history period is sent to the aerosol generating device 100, and the aerosol generating device 100 specifies that the preset history period is 8 of 2021, 9, 10 days: 00 to 12: 00, therefore, the aerosol generating device 100 reads the inhalation size, inhalation duration and inhalation frequency in the time period from the memory thereof through the host 110, it should be noted that the inhalation size and inhalation duration in the time period are the total inhalation size and total inhalation duration in the time period, the average inhalation size is obtained by dividing the total inhalation size by the inhalation frequency through a mean value calculation method, the average inhalation duration is obtained by dividing the total inhalation duration by the inhalation frequency, and the data composed of the average inhalation size and average inhalation duration is the average inhalation data, and is stored in the memory, and stores 8 of 9 months and 10 days in 2021: 00 to 12: average inspiratory data of 00 ".

In one embodiment, in addition to calculating the average inhalation data in the time period by setting the historical period by the user, the average inhalation data in the set number of times can be calculated by setting a certain inhalation number by the user, which includes the following specific steps: reading the inspiration size and inspiration duration within the preset inspiration times stored in the memory; determining the average inspiration size according to the inspiration size and the preset inspiration times; determining the average inspiration time according to the inspiration time and the preset inspiration times; and taking the average inspiration size and the average inspiration time as average inspiration data, and determining the corresponding average aerosol amount according to the average inspiration data.

For example, a user may be communicatively connected to the aerosol generating device 100 through the terminal 200, the user sets the inhalation frequency between the first use and the tenth use as a preset inhalation frequency through the terminal 200, and then sends the preset inhalation frequency to the aerosol generating device 100, the aerosol generating device 100 specifies that the inhalation frequency is the inhalation frequency between the first use and the tenth use, so that the aerosol generating device 100 reads the inhalation size and the inhalation duration within the inhalation frequency from its memory through the host 110, it is to be noted that the inhalation size and the inhalation duration within the inhalation frequency are the total inhalation size and the total inhalation duration within the inhalation frequency, the average inhalation size is obtained by dividing the total inhalation size by the preset inhalation frequency through an average value calculation method, the average inhalation duration is obtained by dividing the total inhalation duration by the preset inhalation frequency, the data consisting of the average inspiration size and average inspiration time is the average inspiration data and is stored in memory and is identified as "average inspiration data between inspirations between the first and tenth uses".

In one embodiment, in addition to calculating the average inspiration data by specifying a certain number of times of data in a certain period, the average inspiration data can be dynamically updated, which includes the following steps: when the current inspiration data is smaller than the average inspiration data, updating the average inspiration data according to the current inspiration data to obtain updated average inspiration data; determining a corresponding average amount of aerosol from the average inhalation data; storing said updated average inhalation data and said average aerosol quantity in said memory.

For example, the average inhalation data obtained according to any one of the foregoing methods is an average inhalation size of 120Pa, if the current inhalation size of the user is 100Pa, because 100Pa is smaller than 120Pa, that is, the current inhalation data is smaller than the average inhalation data, the data processing module may obtain that the number of inhalation times corresponding to the average inhalation size of 120Pa is 9, then update the average inhalation size through the formula (120Pa × 9+100Pa)/(9+1) to obtain an updated average inhalation size of 118Pa, and after updating the average inhalation data, store the updated average inhalation data through the memory in the host 110.

In one embodiment, in addition to the average inhalation data obtained by calculation through the data processing module of the aerosol generating device 100, the average inhalation data can be set by a user through a terminal, and the method includes the following specific steps: receiving a data storage request from a terminal; obtaining average inspiration data in response to the data storage request; determining a corresponding average amount of aerosol from the average inhalation data; storing said average inhalation data and said average aerosol quantity in said memory. Specifically, when the aerosol generating device 100 is used, a user can communicate with the terminal 200 through the two-dimensional code or bluetooth on the aerosol generating device 100, after the connection is successful, average inhalation data can be set through a related setting interface on the terminal, after the setting is completed, a storage request carrying the average inhalation data is sent to the aerosol generating device 100 through the terminal 200, and after the aerosol generating device 100 receives the storage request, the storage request is responded, and the user-defined average inhalation data and the corresponding aerosol amount are stored in the memory of the host 110.

In one embodiment, the amount of aerosol corresponding to the inhalation data can be uniquely determined by the steps of: acquiring a mapping relation between inspiration data and aerosol quantity; and determining the target aerosol quantity corresponding to the average inspiration data according to the average inspiration data and the mapping relation. Specifically, the aerosol generating device 100 has set attributes at the time of shipment, and the attributes include an aerosol amount corresponding to the inhalation data, that is, a mapping relationship between the inhalation data and the aerosol amount, and the host 110 can store the mapping relationship in the memory, and then determine how much aerosol amount should be supplied according to the mapping relationship when detecting the corresponding inhalation data.

203: and comparing the average inspiration data with the current inspiration data to obtain a comparison result.

The aerosol generating device 100 may perform corresponding data processing operations, such as comparing the magnitude relationship between the average inhalation data and the current inhalation data, and generate corresponding comparison results, through the control motherboard in the host 110.

204: and when the comparison result shows that the current inspiration data is greater than or equal to the average inspiration data, carrying out atomization operation according to the average aerosol amount.

In order to control the amount of aerosol inhaled by the user, when the current inhalation data is greater than or equal to the average inhalation data (for example, the current inhalation data is inhalation size 130Pa, and the average inhalation data is inhalation size 120Pa), the control main board in the host 110 sends an atomization instruction to the atomizer 120 for atomization operation according to the average aerosol amount, and after receiving the relevant instruction, the atomizer 120 controls the aerosol substrate to provide a corresponding amount of aerosol to the atomizer for atomization.

205: and when the comparison result represents that the current inspiration data is smaller than the average inspiration data, acquiring the target aerosol quantity corresponding to the current inspiration data, and carrying out atomization operation according to the target aerosol quantity.

In order to control the aerosol amount inhaled by the user, when the current inhalation data obtained by the control motherboard in the host 110 is smaller than the average inhalation data (for example, the current inhalation data is inhalation size 110Pa, and the average inhalation data is inhalation size 120Pa), the control motherboard first obtains a target aerosol amount corresponding to the inhalation size 110Pa according to the mapping relationship between the inhalation data and the aerosol amount, and then sends an atomization instruction for performing an atomization operation according to the target aerosol amount to the atomizer 120, and after receiving the relevant instruction, the atomizer 120 controls the aerosol substrate to provide the corresponding amount of aerosol to the atomizer for atomization.

In the application, the aerosol generating device provides the aerosol quantity as less as possible to a user according to smaller inspiration data by comparing the current inspiration data with the average inspiration data, so that the aerosol quantity inhaled into the body of the user is controlled, and the harm to the body caused by excessive smoking of the user is avoided.

Third embodiment

Fig. 3 is another flow chart of the aerosol generation device 100, and fig. 3 shows an interaction process between the host 110 and the nebulizer 120 in the aerosol generation device to implement the aerosol generation device.

Specifically, the nebulizer 120 performs step 301 by the suction sensor provided therein: detecting and analyzing the suction signal to obtain current suction data; when the nebulizer detects that there is a suction signal currently, the nebulizer 120 converts the signal into corresponding current suction data, and executes step 302: sending a reading instruction and current inspiration data; so that the host 110 performs step 303: receiving current suction data; the host 110 responds to the read command and performs step 304: reading average inspiration data and average aerosol amount; the host 110 reads the pre-stored data from the memory, and then the control board in the host 110 performs the comparison operation by itself, and performs step 305: comparing the average air suction data with the current suction data to obtain a comparison result; the host 110 then performs step 306: when the comparison result represents that the current inspiration data is larger than or equal to the average inspiration data, generating an atomization instruction according to the average aerosol amount; the nebulization instruction is to provide an average aerosol amount of aerosol to the user, and the host 110 then executes step 307: sending an atomization instruction; that is, the host 110 sends the generated nebulizing instruction to the nebulizer 120, and the nebulizer 120 executes step 308: receiving and carrying out atomization operation based on the atomization instruction; the aerosol substrate storage chamber in the nebulizer 120 is controlled by the corresponding nebulization command to release only an average aerosol amount of aerosol to the nebulization chamber for nebulization.

Further, when the comparison result indicates that the current inhalation data is smaller than the average inhalation data, the host 110 performs step 309: and when the comparison result represents that the current air suction data is smaller than the average air suction data, acquiring the target aerosol quantity corresponding to the current suction data, and generating an atomization instruction according to the target aerosol quantity. Specifically, the host 110 determines a target aerosol amount corresponding to the current inhalation data according to the mapping relationship between the inhalation data and the aerosol amount, and then generates an atomization instruction according to the target aerosol amount (i.e. providing the aerosol of the target aerosol amount to the user), and then the host 110 performs step 310: sending a nebulizing instruction, that is, sending the generated nebulizing instruction to the nebulizer 120, and the nebulizer 120 executing step 311: the nebulization command is received and is based on the nebulization command, i.e. after receiving the nebulization command, the aerosol substrate storage chamber in the nebulizer 120 is controlled to release only the aerosol of the target aerosol amount to the nebulization chamber for nebulization in response to the nebulization command.

It should be noted that, in the above process, the user may also connect to the aerosol generating device through the terminal 200, for example, through bluetooth, wifi, or the like. So that the user can directly set parameters of the aerosol generating device, such as average inhalation data, etc., through the terminal 200.

The atomization control method provided by the application always provides the user with the aerosol amount as small as possible in the mode, so that the user cannot obtain the aerosol amount exceeding the limit, and the body is injured.

Fourth embodiment

Based on the content of the foregoing embodiments, an atomization control device is provided in the embodiments of the present application. The atomization control device is used for executing the atomization control method provided in the above method embodiment, specifically, referring to fig. 4, the device includes:

a data determining module 401, configured to determine current inhalation data according to the detected current inhalation signal;

a data reading module 402 for reading the average inhalation data and the average aerosol amount stored in the memory;

a comparison module 403, configured to compare the average inspiration data with the current inspiration data to obtain a comparison result;

a first atomization module 404, configured to perform an atomization operation according to the average aerosol amount when the comparison result indicates that the current inhalation data is greater than or equal to the average inhalation data;

and a second atomization module 405, configured to, when the comparison result indicates that the current inhalation data is smaller than the average inhalation data, obtain a target aerosol amount corresponding to the current inhalation data, and perform an atomization operation according to the target aerosol amount.

In one embodiment, data reading module 402 includes:

the first reading module is used for reading the inspiration size, inspiration duration and inspiration times in a preset historical period stored in the memory;

the first determination module is used for determining the average inspiration size according to the inspiration size and the inspiration times;

the second determination module is used for determining the average inspiration time according to the inspiration time and the inspiration times;

and the third determining module is used for taking the average inspiration size and the average inspiration time as average inspiration data and determining the corresponding average aerosol amount according to the average inspiration data.

In one embodiment, the data reading module 402 further comprises:

the second reading module is used for reading the inspiration size and inspiration duration within the preset inspiration times stored in the memory;

the fourth determining module is used for determining the average inspiration size according to the inspiration size and the preset inspiration times;

the fifth determining module is used for determining the average inspiration time according to the inspiration time and the preset inspiration times;

and the sixth determining module is used for taking the average inspiration size and the average inspiration time as average inspiration data and determining the corresponding average aerosol amount according to the average inspiration data.

In one embodiment, the atomization control device further includes:

the data updating module is used for updating the average inspiration data according to the current inspiration data when the current inspiration data is smaller than the average inspiration data to obtain updated average inspiration data;

a seventh determining module, configured to determine a corresponding average aerosol amount according to the average inhalation data;

a first data storage module for storing said updated average inspiration data and said average aerosol volume in said memory.

In one embodiment, the atomization control device further includes:

the request receiving module is used for receiving a data storage request from a terminal;

the request response module is used for responding to the data storage request and obtaining average inspiration data;

an eighth determining module, configured to determine a corresponding average aerosol amount according to the average inhalation data;

a second data storage module for storing said average inhalation data and said average aerosol quantity in said memory.

In one embodiment, the atomization control device further includes:

the relation acquisition module is used for acquiring the mapping relation between the inspiration data and the aerosol quantity;

and the ninth determining module is used for determining the target aerosol amount corresponding to the average inspiration data according to the average inspiration data and the mapping relation.

In one embodiment, the data determination module 401 includes:

the signal detection module is used for detecting a suction signal through the suction sensor;

and the signal analysis module is used for analyzing the suction signal when the suction signal is detected to obtain the air suction size and the air suction time length, and taking the air suction size and the air suction time length as the current air suction data.

The memories in the modules include Static Random-Access Memory (SRAM), Electrically Erasable Programmable Read-Only Memory (EEPROM), Flash Memory (Flash Memory), and the like, and each Memory has its own advantages, and different memories can be used for different requirements.

The atomization control device of the embodiment of the application can be used for executing the technical scheme of the method embodiment, the implementation principle and the technical effect are similar, and details are not repeated here.

Different from the prior art, the atomization control device provided by the application is provided with the comparison module, the comparison module can compare the size relationship between the inspiration data and the average inspiration data, and the aerosol quantity to be provided is determined according to the comparison result, so that atomization operation is performed according to the corresponding aerosol quantity, and the aerosol quantity inhaled by a user is controlled to be as small as possible.

Fifth embodiment

Referring to fig. 5, fig. 5 is a schematic structural diagram of an aerosol generating device according to an embodiment of the present disclosure. The aerosol generating device comprises a host 110 and a nebulizer 120.

Specifically, the atomizer 120 includes an atomizing core 70, a connecting member 80, an atomizing electrode 90, an atomizing cavity 71, an aerosol substrate storage cavity 72, an air outlet channel 73, a suction nozzle 74, a liquid guiding member 75, and a heat generating member 76, the atomizing core 70 is connected to the connecting member 80, and the atomizing electrode 90 is fixed in the connecting member 80.

The aerosol substrate storage cavity 72 is communicated with the atomization cavity 71, the atomization cavity 71 is communicated with the air outlet channel 73, the air outlet channel 73 is communicated with the suction nozzle 74, and the liquid guide part 75 and the heat generating part 76 are both located in the atomization cavity 71. The aerosol substrate storage cavity 72 is used for storing aerosol substrates, the liquid guide member 75 is located between the aerosol substrate storage cavity 72 and the heat generating member 76 to guide the aerosol substrates into the atomizing cavity 71, and the heat generating member 76 generates heat under the control of the circuit board 40 to atomize the aerosol substrates to generate aerosol.

The connecting member 80 includes a third receiving groove 81, the atomizing electrode 90 is received and fixed in the third receiving groove 81, the atomizing electrode 90 is electrically connected to the host electrode 30, the atomizing electrode 90 is further electrically connected to the heating element 76 to form a circuit loop, and the circuit board 40 controls the power supply device 50 to supply power to the heating element 76 through the circuit loop, so that the heating element 76 generates heat to atomize the aerosol substrate to generate aerosol.

Wherein the connector 80 further comprises a second air inlet channel 82. One end of the second air inlet channel 82 is communicated with the atomizing cavity 71, and under the action of the suction force generated by the suction nozzle 74, outside air enters the air inlet channel 82, then enters the atomizing cavity 71 from the air inlet channel 82, and drives aerosol generated in the atomizing cavity 71 to enter the air outlet channel 73 and enter the mouth of a user of the aerosol generating device 100 from the suction nozzle 74.

Alternatively, the air intake passage 82 is provided separately from the atomizing electrode 90.

In other embodiments, the air inlet channel 82 and the atomizing electrode 90 are combined, that is, the atomizing electrode 90 is hollow, the hollow part of the atomizing electrode is the air inlet channel 82, and the host electrode is inserted into the atomizing electrode 90.

Optionally, a second magnetic attraction member (not shown in the figure) is further disposed on the atomizer 120, the second magnetic attraction member is disposed on the atomizing connecting end surface 122 of the atomizer 120 and is opposite to the first magnetic attraction member (not shown in the figure), and the host 110 and the atomizer 120 are fixed together through the first magnetic attraction member and the second magnetic attraction member.

In another optional embodiment of this application, only set up first magnetism in host computer 110 and inhale the piece to increase atomizing electrode 90 towards the area of the terminal surface of host computer 110 makes first magnetism inhale piece can hold atomizing electrode 90, realizes magnetism and adsorbs the connection, and at this moment, atomizing electrode 90's material is for having ferromagnetic material, like metals such as iron, nickel, cobalt.

Alternatively, the host 110 may not be provided with the first magnetic attraction member, and the atomizer 120 may not be provided with the second magnetic attraction member, but may be mechanically connected together by a snap, etc.

The method and the device for controlling the atomizing device provided by the embodiment of the present application are described in detail above, and the principle and the embodiment of the present application are explained in the present application by applying specific examples, and the description of the above embodiments is only used to help understand the method and the core idea of the present application; meanwhile, for those skilled in the art, according to the idea of the present application, there may be variations in the specific embodiments and the application scope, and in summary, the content of the present specification should not be construed as a limitation to the present application.

Claims (10)

1. An atomization control method, characterized by comprising:

determining current suction data according to the detected current suction signal;

reading the average inhalation data and the average aerosol amount stored in the memory;

comparing the average inspiration data with the current inspiration data to obtain a comparison result;

when the comparison result represents that the current inspiration data is larger than or equal to the average inspiration data, carrying out atomization operation according to the average aerosol amount;

and when the comparison result represents that the current inspiration data is smaller than the average inspiration data, acquiring a target aerosol quantity corresponding to the current inspiration data, and carrying out atomization operation according to the target aerosol quantity.

2. The aerosol control method according to claim 1, wherein the step of reading the average inhalation data and the average aerosol amount stored in the memory comprises:

reading the inspiration size, inspiration duration and inspiration times in a preset historical period stored in a memory;

determining an average inspiration size according to the inspiration size and the inspiration times;

determining an average inspiration time according to the inspiration time and the inspiration times;

and taking the average inspiration size and the average inspiration time as average inspiration data, and determining the corresponding average aerosol amount according to the average inspiration data.

3. The aerosol control method according to claim 1, wherein the step of reading the average inhalation data and the average aerosol amount stored in the memory comprises:

reading the inspiration size and inspiration duration within the preset inspiration times stored in the memory;

determining the average inspiration size according to the inspiration size and the preset inspiration times;

determining the average inspiration time according to the inspiration time and the preset inspiration times;

and taking the average inspiration size and the average inspiration time as average inspiration data, and determining the corresponding average aerosol amount according to the average inspiration data.

4. The fogging control method according to claim 1, characterized by further comprising:

when the current inspiration data is smaller than the average inspiration data, updating the average inspiration data according to the current inspiration data to obtain updated average inspiration data;

determining a corresponding average amount of aerosol from the average inhalation data;

storing said updated average inhalation data and said average aerosol quantity in said memory.

5. The fogging control method according to claim 1, characterized by further comprising:

receiving a data storage request from a terminal;

obtaining average inspiration data in response to the data storage request;

determining a corresponding average amount of aerosol from the average inhalation data;

storing said average inhalation data and said average aerosol quantity in said memory.

6. The aerosol control method according to any one of claims 2 to 5, wherein the step of determining a corresponding average aerosol quantity from the average inhalation data comprises:

acquiring a mapping relation between inspiration data and aerosol quantity;

and determining the target aerosol quantity corresponding to the average inspiration data according to the average inspiration data and the mapping relation.

7. The fogging control method according to claim 1, wherein said step of determining current inhalation data from the current suction signal detected by the suction sensor comprises:

detecting a suction signal by a suction sensor;

when a suction signal is detected, analyzing the suction signal to obtain the inspiration size and inspiration time, and taking the inspiration size and the inspiration time as current inspiration data.

8. The fogging control method according to claim 1, wherein the memory comprises an electronically erasable read only memory.

9. The aerosol control method of claim 1, wherein the step of reading the average inhalation data and the average aerosol amount stored in the memory comprises:

triggering a reading instruction according to the current suction signal;

and reading the average inspiration data and the average aerosol amount from the memory according to the reading instruction.

10. An atomization control device, characterized by comprising:

the data determining module is used for determining current air suction data according to the detected current suction signal;

a data reading module for reading the average inhalation data and the average aerosol amount stored in the memory;

the comparison module is used for comparing the average inspiration data with the current inspiration data to obtain a comparison result;

the first atomization module is used for carrying out atomization operation according to the average aerosol amount when the comparison result represents that the current inspiration data is larger than or equal to the average inspiration data;

and the second atomization module is used for acquiring a target aerosol quantity corresponding to the current inspiration data when the comparison result represents that the current inspiration data is smaller than the average inspiration data, and carrying out atomization operation according to the target aerosol quantity.

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