CN116570803B - Compression atomizer atomization rate control method, system and medium - Google Patents

Abstract

The application provides a compression atomizer atomization rate control method, a compression atomizer atomization rate control system and a compression atomizer atomization rate control medium, wherein the compression atomizer atomization rate control method comprises the following steps: judging the breathing state of a user according to the air flow direction data, processing according to the obtained breathing state detection data and the spraying flow data to obtain a first atomization rate adjustment parameter, processing according to the user sign data and the user wearing state data to obtain a first correction factor, correcting the first atomization rate adjustment parameter according to the first correction factor to obtain a second atomization rate adjustment parameter, processing according to the atomizing cup characteristic data and the spraying flow data to obtain an atomizing cup adjustment parameter, processing according to the second atomization rate adjustment parameter, combining the atomizing cup adjustment parameter and the air compressor pressure data to obtain a third atomization rate adjustment parameter, further obtaining an atomization rate adjustment parameter grade, and carrying out sectional adjustment on the atomization rate according to the atomization rate adjustment parameter grade so as to realize automatic intelligent adjustment on the atomization rate according to the self condition of the user.

Description

Compression atomizer atomization rate control method, system and medium

Technical Field

The application relates to the technical field of intelligent control, in particular to a compression atomizer atomization rate control method, a compression atomizer atomization rate control system and a compression atomizer atomization rate control medium.

Background

The atomizer and the atomized inhalation are one of common core devices and processing means in a breathing device and a respiratory physiotherapy, the liquid medicine is atomized into tiny particles by the atomizer, so that a user inhales atomized drug particles into the body through breathing, and the purpose of high-efficiency absorption is achieved.

In view of the above problems, an effective technical solution is currently needed.

Disclosure of Invention

The application aims to provide a compression atomizer atomization rate control method, a compression atomizer atomization rate control system and a compression atomizer atomization rate control medium, wherein the user breathing gas state is judged according to air flow direction data, first atomization rate adjustment parameters are obtained through processing according to obtained breathing state detection data and atomizing flow rate data, first correction factors are obtained through processing according to user sign data and user wearing state data, second atomization rate adjustment parameters are obtained through correcting the first atomization rate adjustment parameters according to the first correction factors, atomizing cup adjustment parameters are obtained through processing according to atomizing cup characteristic data and atomizing flow rate data, third atomization rate adjustment parameters are obtained through processing according to the second atomization rate adjustment parameters in combination with atomizing cup adjustment parameters and air compressor pressure data, and then atomizing rate adjustment parameter grades are obtained.

The application also provides a control method for the atomization rate of the compression atomizer, which comprises the following steps:

acquiring airflow direction data, spray flow data, atomizing cup characteristic data and air compressor pressure data of an atomizer;

Judging the breathing state of a user according to the air flow direction data, obtaining breathing state detection data, and analyzing and processing according to the breathing state detection data and the spraying flow data to obtain a first atomization rate adjusting parameter;

acquiring user sign data and user wearing state data, and analyzing and processing according to the user sign data and the user wearing state data to acquire a first correction factor;

correcting the first atomization rate adjustment parameter according to the first correction factor to obtain a second atomization rate adjustment parameter;

analyzing and processing according to the characteristic data of the atomizing cup and the atomizing flow rate data to obtain an adjusting parameter of the atomizing cup;

processing according to the second atomization rate adjusting parameter and the atomization cup adjusting parameter and the air compressor pressure data to obtain a third atomization rate adjusting parameter;

and comparing the third atomization rate adjusting parameter with a preset atomization rate adjusting parameter threshold value to obtain an atomization rate adjusting parameter grade, and adjusting the atomization rate in a sectional manner according to the atomization rate adjusting parameter grade.

Optionally, in the method for controlling the atomization rate of a compressed atomizer according to the present application, the acquiring airflow direction data, spray flow data, atomizing cup characteristic data, and air compressor pressure data of the atomizer includes:

Acquiring airflow direction data, spray flow data, atomizing cup characteristic data and air compressor pressure data of an atomizer;

the spray flow data includes spray particle diameter data and spray concentration data;

the atomizing cup characteristic data comprise atomizing cup aperture data and atomizing cup negative pressure data.

Optionally, in the method for controlling the atomization rate of the compressed atomizer according to the present application, the determining the user's respiratory state according to the airflow direction data, obtaining respiratory state detection data, and performing analysis processing according to the respiratory state detection data and the spray flow data to obtain the first atomization rate adjustment parameter includes:

judging the breathing state of the user according to the air flow direction data, and obtaining breathing state detection data comprising breathing state data, breathing time data, breathing state data and breathing time data;

and inputting the inhalation state data, the inhalation time data, the exhalation state data and the exhalation time data into a preset breathing adjustment parameter model for processing by combining the spray concentration data, so as to obtain a first atomization rate adjustment parameter.

Optionally, in the method for controlling the atomization rate of the compressed atomizer according to the present application, the obtaining the user sign data and the user wearing state data, and performing analysis processing according to the user sign data and the user wearing state data to obtain the first correction factor includes:

Acquiring user sign data, including age data and weight data;

acquiring wearing state data of a user, wherein the wearing state data comprise wearing contact area data and wearing tightness data;

and according to the age data and the weight data, the wearing contact area data and the wearing tightness data are combined for analysis and processing to obtain a first correction factor.

Optionally, in the method for controlling an atomization rate of a compressed atomizer according to the present application, the correcting the first atomization rate adjustment parameter according to the first correction factor to obtain a second atomization rate adjustment parameter includes:

correcting the first atomization rate adjusting parameter according to the first correction factor to obtain a second atomization rate adjusting parameter;

the correction formula of the second atomization rate adjusting parameter is as follows:

；

wherein ,adjusting the parameter for the second nebulization rate, +.>For the first correction factor, +.>Adjusting the parameter for the first nebulization rate, +.>Is a preset characteristic coefficient.

Optionally, in the method for controlling an atomization rate of a compressed atomizer according to the present application, the analyzing and processing according to the characteristic data of the atomizing cup and the spray flow rate data to obtain the adjusting parameters of the atomizing cup includes:

Generating atomizing cup pressure regulating parameter data according to the atomizing cup negative pressure data and the atomizing particle diameter data;

inputting the atomizing cup aperture data and the atomizing cup pressure adjustment parameter data into a preset atomizing cup parameter adjustment model for processing to generate atomizing cup adjustment parameters.

Optionally, in the method for controlling the atomization rate of a compressed atomizer according to the present application, the processing according to the second atomization rate adjustment parameter in combination with the atomizing cup adjustment parameter and the air compressor pressure data to obtain a third atomization rate adjustment parameter includes:

processing according to the second atomization rate adjusting parameter and the atomization cup adjusting parameter to obtain an atomization cup adjusting correction factor;

processing according to the atomizing cup adjusting correction factor and the air compressor pressure data to obtain a third atomizing rate adjusting parameter;

the program processing formula of the third atomization rate adjusting parameter is as follows:

；

wherein ,adjusting the parameter for the third nebulization rate, +.>Adjusting correction factors for the atomizing cup>For air compressor pressure data, < >>Is a preset characteristic coefficient.

Optionally, in the method for controlling the atomization rate of the compressed atomizer according to the present application, the threshold comparing the third atomization rate adjustment parameter with a preset atomization rate adjustment parameter threshold to obtain an atomization rate adjustment parameter level, and adjusting the atomization rate in segments according to the atomization rate adjustment parameter level includes:

Comparing the third atomization rate adjusting parameter with a preset atomization rate adjusting parameter threshold value in a threshold value;

obtaining an atomization rate adjusting parameter grade according to the range grade of the threshold value comparison result;

and carrying out sectional adjustment on the atomization rate according to the atomization rate adjustment parameter grade.

In a second aspect, the present application provides a compression atomizer atomization rate control system comprising: the device comprises a memory and a processor, wherein the memory comprises a program of a compressed atomizer atomization rate control method, and the program of the compressed atomizer atomization rate control method realizes the following steps when being executed by the processor:

acquiring airflow direction data, spray flow data, atomizing cup characteristic data and air compressor pressure data of an atomizer;

judging the breathing state of a user according to the air flow direction data, obtaining breathing state detection data, and analyzing and processing according to the breathing state detection data and the spraying flow data to obtain a first atomization rate adjusting parameter;

acquiring user sign data and user wearing state data, and analyzing and processing according to the user sign data and the user wearing state data to acquire a first correction factor;

correcting the first atomization rate adjustment parameter according to the first correction factor to obtain a second atomization rate adjustment parameter;

Analyzing and processing according to the characteristic data of the atomizing cup and the atomizing flow rate data to obtain an adjusting parameter of the atomizing cup;

processing according to the second atomization rate adjusting parameter and the atomization cup adjusting parameter and the air compressor pressure data to obtain a third atomization rate adjusting parameter;

and comparing the third atomization rate adjusting parameter with a preset atomization rate adjusting parameter threshold value to obtain an atomization rate adjusting parameter grade, and adjusting the atomization rate in a sectional manner according to the atomization rate adjusting parameter grade.

In a third aspect, the present application also provides a computer readable storage medium having embodied therein a compressed nebulizer nebulization rate control method program which, when executed by a processor, implements the steps of a compressed nebulizer nebulization rate control method as described in any one of the preceding claims.

As can be seen from the above, the method, the system and the medium for controlling the atomization rate of the compressed atomizer provided by the application are characterized in that firstly, the respiratory state of a user is determined according to the air flow direction data, the first atomization rate adjusting parameter is obtained by processing according to the obtained respiratory state detection data and the spraying flow data, then the first correction factor is obtained by processing according to the user sign data and the user wearing state data, the second atomization rate adjusting parameter is obtained by correcting the first atomization rate adjusting parameter according to the first correction factor, the atomization cup adjusting parameter is obtained by processing according to the characteristic data of the atomization cup and the spraying flow data, finally, the third atomization rate adjusting parameter is obtained by processing according to the second atomization rate adjusting parameter in combination with the atomization cup adjusting parameter and the pressure data of the air compressor, and then the atomization rate adjusting parameter grade is obtained.

Additional features and advantages of the application will be set forth in the description which follows, and in part will be apparent from the description, or may be learned by practice of the embodiments of the application. The objectives and other advantages of the application will be realized and attained by the structure particularly pointed out in the written description and claims thereof as well as the appended drawings.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are needed in the embodiments of the present application will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present application and should not be considered as limiting the scope, and other related drawings can be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a flow chart of a method for controlling the atomization rate of a compression atomizer according to an embodiment of the present application;

fig. 2 is a flowchart of acquiring airflow direction data, spray flow data, atomizing cup characteristic data and air compressor pressure data of an atomizer according to an embodiment of the present application.

FIG. 3 is a flowchart of a first atomization rate adjustment parameter obtained by processing a compression atomizer atomization rate control method according to an embodiment of the present application;

Fig. 4 is a schematic structural diagram of an atomization rate control system of a compression atomizer according to an embodiment of the present application.

Detailed Description

The following description of the embodiments of the present application will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present application, but not all embodiments. The components of the embodiments of the present application generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the application, as presented in the figures, is not intended to limit the scope of the application, as claimed, but is merely representative of selected embodiments of the application. All other embodiments, which can be made by a person skilled in the art without making any inventive effort, are intended to be within the scope of the present application.

It should be noted that like reference numerals and letters refer to like items in the following figures, and thus once an item is defined in one figure, no further definition or explanation thereof is necessary in the following figures. Meanwhile, in the description of the present application, the terms "first", "second", and the like are used only to distinguish the description, and are not to be construed as indicating or implying relative importance.

Referring to fig. 1, fig. 1 is a flow chart of a method for controlling an atomization rate of a compression atomizer according to some embodiments of the application. The atomization rate control method of the compression atomizer is used in terminal equipment. The atomization rate control method of the compression atomizer comprises the following steps:

s101, acquiring air flow direction data, spray flow data, atomizing cup characteristic data and air compressor pressure data of an atomizer;

s102, judging the breathing state of a user according to the air flow direction data, obtaining breathing state detection data, and analyzing and processing according to the breathing state detection data and the spraying flow data to obtain a first atomization rate adjustment parameter;

s103, acquiring user sign data and user wearing state data, and analyzing and processing according to the user sign data and the user wearing state data to acquire a first correction factor;

s104, correcting the first atomization rate adjustment parameter according to the first correction factor to obtain a second atomization rate adjustment parameter;

s105, analyzing and processing according to the characteristic data of the atomizing cup and the atomizing flow rate data to obtain an adjusting parameter of the atomizing cup;

s106, processing according to the second atomization rate adjusting parameter and the atomization cup adjusting parameter and the air compressor pressure data to obtain a third atomization rate adjusting parameter;

S107, comparing the third atomization rate adjusting parameter with a preset atomization rate adjusting parameter threshold value to obtain an atomization rate adjusting parameter grade, and adjusting the atomization rate in a segmented mode according to the atomization rate adjusting parameter grade.

It should be noted that, in order to achieve the purpose of automatically and intelligently adjusting the atomization rate of the atomizer according to different users, the application firstly identifies the airflow direction so as to conveniently judge the exhalation and inhalation states of the users, and then generates atomization rate adjusting parameters according to the exhalation and inhalation states of the users and the current spray concentration conditions, namely adjusts the atomization rate according to the different states of the exhalation and inhalation states of the users, and the atomization rate of the users with different ages and different weights is different, and the wearing tightness of the atomization mask also has an influence on the atomization effect, so the atomization rate adjusting parameters are required to be corrected according to the age and weight of the users, the wearing area of the mask and the wearing tightness, then the atomization rate adjusting parameters are obtained according to the aperture size of the atomization cup air inlet, the negative pressure data in the cup and the diameter of spray particles, wherein the aperture size of the atomization cup can influence the pressure of the atomization cup, the generated atomization cup negative pressure data and the diameter data of the spray particles are also data used for reflecting the pressure conditions of the atomization cup, and the generated atomization cup adjusting parameters are the parameter data used for reflecting the pressure conditions of the atomization cup, and the pressure of the atomization press can directly influence the atomization rate according to the final effect, and finally the stage speed adjusting parameters are realized, and the atomization rate adjusting parameters can be adjusted according to the stage speed adjusting parameters.

Referring to fig. 2, fig. 2 is a flowchart of an atomization rate control method of a compressed atomizer according to some embodiments of the present application for obtaining airflow direction data, spray flow data, atomizing cup characteristic data, and air compressor pressure data of the atomizer. According to the embodiment of the application, the air flow direction data, the spray flow data, the atomizing cup characteristic data and the air compressor pressure data of the atomizer are obtained, and specifically:

s201, acquiring air flow direction data, spray flow data, atomizing cup characteristic data and air compressor pressure data of an atomizer;

s202, the spraying flow data comprise spraying particle diameter data and spraying concentration data;

s203, the atomizing cup characteristic data comprise atomizing cup aperture data and atomizing cup negative pressure data.

The obtained atomizing cup airflow direction data are used for judging the user's expiration and inspiration states so as to adjust the atomization rate according to different expiration and inspiration states, and then the atomization rate adjusting parameters are generated according to the expiration and inspiration states and the obtained atomization concentration data, the atomization particle diameter data are data reflecting the size of atomized particles, the atomizing cup characteristic data are data reflecting the pressure condition in the atomizing cup, and the air compressor pressure data are data representing the output pressure value of the air compressor.

Referring to fig. 3, fig. 3 is a flowchart illustrating a process of the method for controlling the atomization rate of the compressed atomizer according to some embodiments of the present application to obtain a first atomization rate adjustment parameter. According to an embodiment of the present application, the determining the user respiratory gas state according to the airflow direction data, obtaining respiratory state detection data, and performing analysis processing according to the respiratory state detection data and the spray flow data to obtain a first atomization rate adjustment parameter, specifically includes:

s301, judging the breathing state of a user according to the air flow direction data, and obtaining breathing state detection data, wherein the breathing state detection data comprises breathing state data, breathing time data, breathing state data and breathing time data;

s302, inputting the inhalation state data, the inhalation time data, the exhalation state data and the exhalation time data into a preset breathing adjustment parameter model for processing by combining the spray concentration data, and obtaining a first atomization rate adjustment parameter.

It should be noted that, in order to obtain the atomization rate adjustment parameter according to the user's exhalation and inhalation state and combining with the current spray concentration condition, firstly, the user's inhalation state is determined according to the airflow direction to obtain the respiratory state detection data, then the respiratory state detection data and the spray concentration data are input into a preset respiratory adjustment parameter model to be processed to obtain the first atomization rate adjustment parameter, and the respiratory adjustment parameter model is a model obtained by training the respiratory state detection data, the spray concentration data and the atomization rate adjustment parameter which obtain a large number of historical samples, and the corresponding output atomization rate adjustment parameter can be obtained by inputting relevant information to be processed.

According to the embodiment of the invention, the user sign data and the user wearing state data are obtained, and the first correction factor is obtained by analyzing and processing according to the user sign data and the user wearing state data, specifically:

acquiring user sign data, including age data and weight data;

acquiring wearing state data of a user, wherein the wearing state data comprise wearing contact area data and wearing tightness data;

and according to the age data and the weight data, the wearing contact area data and the wearing tightness data are combined for analysis and processing to obtain a first correction factor.

It should be noted that, because the required atomization rate of the users with different ages and different weights is different, especially, the required atomization amount is less compared with that of the infants and the adults, and the different tightness of the atomizer wear has an influence on the atomization effect, so in order to correct the atomization rate adjusting parameters according to the ages, the weights and the wear conditions of the users, firstly, the user sign data including the age data and the weight data are obtained, then the user wearing state data including the wearing contact area data and the wearing tightness data are obtained, and finally, the first correction factor is obtained by analyzing and processing according to the age data, the weight data, the wearing contact area data and the wearing tightness data.

According to an embodiment of the present invention, the correcting the first atomization rate adjustment parameter according to the first correction factor to obtain a second atomization rate adjustment parameter specifically includes:

correcting the first atomization rate adjusting parameter according to the first correction factor to obtain a second atomization rate adjusting parameter;

the correction formula of the second atomization rate adjusting parameter is as follows:

；

wherein ,adjusting the parameter for the second nebulization rate, +.>For the first correction factor, +.>Adjusting the parameter for the first nebulization rate, +.>Is a preset characteristic coefficient (which can be obtained by inquiring an atomization rate adjustment parameter database).

It should be noted that, in order to achieve more accurate adjustment of the atomization rate, the first atomization rate adjustment parameter needs to be corrected according to the first correction factor to obtain the second atomization rate adjustment parameter.

According to the embodiment of the invention, the atomizing cup adjusting parameters are obtained by analyzing and processing according to the atomizing cup characteristic data and the atomizing flow rate data, and specifically include:

generating atomizing cup pressure regulating parameter data according to the atomizing cup negative pressure data and the atomizing particle diameter data;

inputting the atomizing cup aperture data and the atomizing cup pressure adjustment parameter data into a preset atomizing cup parameter adjustment model for processing to generate atomizing cup adjustment parameters.

In order to calculate the influence degree of the pressure data in the atomizing cup on the atomizing rate, first generating atomizing cup pressure regulating parameter data according to the atomizing cup negative pressure data and the atomizing particle diameter data, inputting the atomizing cup aperture data and the atomizing cup pressure regulating parameter data into a preset atomizing cup parameter regulating model for processing to generate an atomizing cup regulating parameter, wherein the atomizing cup parameter regulating model is a model obtained by training the atomizing cup aperture data, the atomizing cup pressure regulating parameter data and the atomizing cup regulating parameter of a large number of historical samples, and can obtain the atomizing cup regulating parameter corresponding to output through inputting relevant information for processing.

According to the embodiment of the invention, the processing is performed according to the second atomization rate adjustment parameter in combination with the atomization cup adjustment parameter and the air compressor pressure data to obtain a third atomization rate adjustment parameter, which specifically includes:

processing according to the second atomization rate adjusting parameter and the atomization cup adjusting parameter to obtain an atomization cup adjusting correction factor;

processing according to the atomizing cup adjusting correction factor and the air compressor pressure data to obtain a third atomizing rate adjusting parameter;

The program processing formula of the third atomization rate adjusting parameter is as follows:

；

wherein ,adjusting the parameter for the third nebulization rate, +.>Adjusting correction factors for the atomizing cup>For air compressor pressure data, < >>Is a preset characteristic coefficient (which can be obtained by inquiring an atomization rate adjustment parameter database).

It should be noted that, in order to finally obtain the atomization rate adjustment parameter so as to adjust the atomization rate, firstly, according to the second atomization rate adjustment parameter and the atomization cup adjustment parameter, an atomization cup adjustment correction factor is obtained, and a program processing formula of the atomization cup adjustment correction factor is as follows:

；

wherein ,adjusting correction factors for the atomizing cup>Adjusting the parameter for the second nebulization rate, +.>Adjusting parameters for the atomizing cup->、/>、/>Is preset toThe characteristic coefficient can be obtained through the query of an atomization rate adjustment parameter database.

And finally, obtaining a third atomization rate adjusting parameter according to the atomization cup adjusting correction factor and the air compressor pressure data processing.

According to the embodiment of the present invention, the threshold value comparison is performed between the third atomization rate adjustment parameter and a preset atomization rate adjustment parameter threshold value to obtain an atomization rate adjustment parameter level, and the atomization rate is adjusted in segments according to the atomization rate adjustment parameter level, specifically:

Comparing the third atomization rate adjusting parameter with a preset atomization rate adjusting parameter threshold value in a threshold value;

obtaining an atomization rate adjusting parameter grade according to the range grade of the threshold value comparison result;

and carrying out sectional adjustment on the atomization rate according to the atomization rate adjustment parameter grade.

It should be noted that, threshold comparison is performed between the third atomization rate adjustment parameter and a preset atomization rate adjustment parameter threshold to obtain an atomization rate adjustment parameter level, and the atomization rate is adjusted in sections according to the atomization rate adjustment parameter level.

According to an embodiment of the present invention, further comprising:

acquiring body temperature sensing data and distance sensing data of the atomizer;

judging the contact condition of the atomizer and the face according to the body temperature sensing data, the distance sensing data and the wearing contact area data to obtain atomizer contact judgment data;

And automatically adjusting the switching-on and switching-off states of the atomizer according to the atomizer contact judging data.

It should be noted that, in order to determine whether the atomizing mask is worn in place, so as to automatically adjust the switching on and off of the atomizer according to the wearing condition, body temperature sensing data, distance sensing data and contact area data of the atomizer are firstly obtained, then the contact condition of the atomizer and the face is determined according to the body temperature sensing data, the distance sensing data and the contact area data, whether the atomizing mask is worn in place is determined, and then the switching on and off state of the atomizer is automatically adjusted.

According to an embodiment of the present invention, further comprising:

acquiring respiratory frequency data of a wearer of the atomizer and oxygen amount data of an atomization mask;

inputting the respiratory frequency data and the oxygen amount data of the atomized mask into a preset hypoxia monitoring model for analysis and treatment to obtain a hypoxia index;

and comparing the hypoxia index with a preset hypoxia index threshold value, judging the hypoxia condition of the wearer according to a threshold value comparison result, and reminding the wearer of hypoxia.

It should be noted that, because the wearer may have an anoxic condition when atomizing, in order to identify the anoxic condition, firstly, the respiratory frequency data of the wearer of the atomizer and the oxygen amount data of the atomizing mask are obtained, then the respiratory frequency data and the oxygen amount data of the atomizing mask are input into a preset anoxic monitoring model for analysis and processing to obtain an anoxic index, the preset anoxic monitoring model is a model obtained by training the respiratory frequency data, the oxygen amount data of the atomizing mask and the anoxic index which obtain a large number of historical samples, the anoxic index which is correspondingly output can be obtained by inputting relevant information for processing, the anoxic index is compared with a preset anoxic threshold value, and the anoxic condition of the wearer is determined and the anoxic reminding is performed according to the threshold value comparison result.

As shown in fig. 4, the present invention further discloses a compressed atomizer atomization rate control system 4, which includes a memory 41 and a processor 42, wherein the memory includes a compressed atomizer atomization rate control method program, and when the compressed atomizer atomization rate control method program is executed by the processor, the following steps are implemented:

acquiring airflow direction data, spray flow data, atomizing cup characteristic data and air compressor pressure data of an atomizer;

judging the breathing state of a user according to the air flow direction data, obtaining breathing state detection data, and analyzing and processing according to the breathing state detection data and the spraying flow data to obtain a first atomization rate adjusting parameter;

acquiring user sign data and user wearing state data, and analyzing and processing according to the user sign data and the user wearing state data to acquire a first correction factor;

correcting the first atomization rate adjustment parameter according to the first correction factor to obtain a second atomization rate adjustment parameter;

analyzing and processing according to the characteristic data of the atomizing cup and the atomizing flow rate data to obtain an adjusting parameter of the atomizing cup;

processing according to the second atomization rate adjusting parameter and the atomization cup adjusting parameter and the air compressor pressure data to obtain a third atomization rate adjusting parameter;

And comparing the third atomization rate adjusting parameter with a preset atomization rate adjusting parameter threshold value to obtain an atomization rate adjusting parameter grade, and adjusting the atomization rate in a sectional manner according to the atomization rate adjusting parameter grade.

It should be noted that, in order to achieve the purpose of automatically and intelligently adjusting the atomization rate of the atomizer according to different users, the application firstly identifies the airflow direction so as to conveniently judge the exhalation and inhalation states of the users, and then generates atomization rate adjusting parameters according to the exhalation and inhalation states of the users and the current spray concentration conditions, namely adjusts the atomization rate according to the different states of the exhalation and inhalation states of the users, and the atomization rate of the users with different ages and different weights is different, and the wearing tightness of the atomization mask also has an influence on the atomization effect, so the atomization rate adjusting parameters are required to be corrected according to the age and weight of the users, the wearing area of the mask and the wearing tightness, then the atomization rate adjusting parameters are obtained according to the aperture size of the atomization cup air inlet, the negative pressure data in the cup and the diameter of spray particles, wherein the aperture size of the atomization cup can influence the pressure of the atomization cup, the generated atomization cup negative pressure data and the diameter data of the spray particles are also data used for reflecting the pressure conditions of the atomization cup, and the generated atomization cup adjusting parameters are the parameter data used for reflecting the pressure conditions of the atomization cup, and the pressure of the atomization press can directly influence the atomization rate according to the final effect, and finally the stage speed adjusting parameters are realized, and the atomization rate adjusting parameters can be adjusted according to the stage speed adjusting parameters.

According to the embodiment of the invention, the air flow direction data, the spray flow data, the atomizing cup characteristic data and the air compressor pressure data of the atomizer are obtained, and specifically:

acquiring airflow direction data, spray flow data, atomizing cup characteristic data and air compressor pressure data of an atomizer;

the spray flow data includes spray particle diameter data and spray concentration data;

the atomizing cup characteristic data comprise atomizing cup aperture data and atomizing cup negative pressure data.

The obtained atomizing cup airflow direction data are used for judging the user's expiration and inspiration states so as to adjust the atomization rate according to different expiration and inspiration states, and then the atomization rate adjusting parameters are generated according to the expiration and inspiration states and the obtained atomization concentration data, the atomization particle diameter data are data reflecting the size of atomized particles, the atomizing cup characteristic data are data reflecting the pressure condition in the atomizing cup, and the air compressor pressure data are data representing the output pressure value of the air compressor.

According to an embodiment of the present invention, the determining the user respiratory gas state according to the airflow direction data, obtaining respiratory state detection data, and performing analysis processing according to the respiratory state detection data and the spray flow data to obtain a first atomization rate adjustment parameter, specifically includes:

Judging the breathing state of the user according to the air flow direction data, and obtaining breathing state detection data comprising breathing state data, breathing time data, breathing state data and breathing time data;

and inputting the inhalation state data, the inhalation time data, the exhalation state data and the exhalation time data into a preset breathing adjustment parameter model for processing by combining the spray concentration data, so as to obtain a first atomization rate adjustment parameter.

It should be noted that, in order to obtain the atomization rate adjustment parameter according to the user's exhalation and inhalation state and combining with the current spray concentration condition, firstly, the user's inhalation state is determined according to the airflow direction to obtain the respiratory state detection data, then the respiratory state detection data and the spray concentration data are input into a preset respiratory adjustment parameter model to be processed to obtain the first atomization rate adjustment parameter, and the respiratory adjustment parameter model is a model obtained by training the respiratory state detection data, the spray concentration data and the atomization rate adjustment parameter which obtain a large number of historical samples, and the corresponding output atomization rate adjustment parameter can be obtained by inputting relevant information to be processed.

According to the embodiment of the invention, the user sign data and the user wearing state data are obtained, and the first correction factor is obtained by analyzing and processing according to the user sign data and the user wearing state data, specifically:

Acquiring user sign data, including age data and weight data;

acquiring wearing state data of a user, wherein the wearing state data comprise wearing contact area data and wearing tightness data;

and according to the age data and the weight data, the wearing contact area data and the wearing tightness data are combined for analysis and processing to obtain a first correction factor.

It should be noted that, because the user age, weight and atomizer wear condition can influence the atomizer speed, so in order to correct the atomizer speed adjustment parameter according to the user age, weight and atomizer wear condition, firstly obtain user sign data including age data and weight data, then obtain user wear state data including wearing contact area data and wearing tightness data, finally carry out analysis processing according to age data, weight data, wearing contact area data and wearing tightness data and obtain a correction factor.

According to an embodiment of the present invention, the correcting the first atomization rate adjustment parameter according to the first correction factor to obtain a second atomization rate adjustment parameter specifically includes:

correcting the first atomization rate adjusting parameter according to the first correction factor to obtain a second atomization rate adjusting parameter;

The correction formula of the second atomization rate adjusting parameter is as follows:

；

wherein ,adjusting the parameter for the second nebulization rate, +.>For the first correction factor, +.>Adjusting the parameter for the first nebulization rate, +.>Is a preset characteristic coefficient (which can be obtained by inquiring an atomization rate adjustment parameter database).

It should be noted that, in order to achieve more accurate adjustment of the atomization rate, the first atomization rate adjustment parameter needs to be corrected according to the first correction factor to obtain the second atomization rate adjustment parameter.

According to the embodiment of the invention, the atomizing cup adjusting parameters are obtained by analyzing and processing according to the atomizing cup characteristic data and the atomizing flow rate data, and specifically include:

generating atomizing cup pressure regulating parameter data according to the atomizing cup negative pressure data and the atomizing particle diameter data;

inputting the atomizing cup aperture data and the atomizing cup pressure adjustment parameter data into a preset atomizing cup parameter adjustment model for processing to generate atomizing cup adjustment parameters.

It should be noted that, in order to measure the influence of the atomizing cup on the atomizing rate, generating atomizing cup pressure adjustment parameter data according to atomizing cup negative pressure data and atomizing particle diameter data, and inputting the atomizing cup aperture data and the atomizing cup pressure adjustment parameter data into a preset atomizing cup parameter adjustment model for processing to generate an atomizing cup adjustment parameter, where the atomizing cup parameter adjustment model is a model obtained by training the atomizing cup aperture data, the atomizing cup pressure adjustment parameter data and the atomizing cup adjustment parameter of a large number of historical samples, and the atomizing cup adjustment parameter corresponding to the output can be obtained by inputting relevant information for processing.

According to the embodiment of the invention, the processing is performed according to the second atomization rate adjustment parameter in combination with the atomization cup adjustment parameter and the air compressor pressure data to obtain a third atomization rate adjustment parameter, which specifically includes:

processing according to the second atomization rate adjusting parameter and the atomization cup adjusting parameter to obtain an atomization cup adjusting correction factor;

processing according to the atomizing cup adjusting correction factor and the air compressor pressure data to obtain a third atomizing rate adjusting parameter;

the program processing formula of the third atomization rate adjusting parameter is as follows:

；

wherein ,adjusting the parameter for the third nebulization rate, +.>Adjusting correction factors for the atomizing cup>For air compressor pressure data, < >>Is a preset characteristic coefficient (which can be obtained by inquiring an atomization rate adjustment parameter database).

It should be noted that, in order to finally obtain the atomization rate adjustment parameter so as to adjust the atomization rate, firstly, according to the second atomization rate adjustment parameter and the atomization cup adjustment parameter, an atomization cup adjustment correction factor is obtained, and a program processing formula of the atomization cup adjustment correction factor is as follows:

；

wherein ,adjusting correction factors for the atomizing cup>Adjusting the parameter for the second nebulization rate, +. >Adjusting parameters for the atomizing cup->、/>、/>Is a preset characteristic coefficient and can be obtained by inquiring an atomization rate adjustment parameter database. />

And finally, obtaining a third atomization rate adjusting parameter according to the atomization cup adjusting correction factor and the air compressor pressure data processing.

According to the embodiment of the present invention, the threshold value comparison is performed between the third atomization rate adjustment parameter and a preset atomization rate adjustment parameter threshold value to obtain an atomization rate adjustment parameter level, and the atomization rate is adjusted in segments according to the atomization rate adjustment parameter level, specifically:

comparing the third atomization rate adjusting parameter with a preset atomization rate adjusting parameter threshold value in a threshold value;

obtaining an atomization rate adjusting parameter grade according to the range grade of the threshold value comparison result;

and carrying out sectional adjustment on the atomization rate according to the atomization rate adjustment parameter grade.

It should be noted that, threshold comparison is performed between the third atomization rate adjustment parameter and a preset atomization rate adjustment parameter threshold to obtain an atomization rate adjustment parameter level, and the atomization rate is adjusted in sections according to the atomization rate adjustment parameter level.

According to an embodiment of the present invention, further comprising:

acquiring body temperature sensing data and distance sensing data of the atomizer;

judging the contact condition of the atomizer and the face according to the body temperature sensing data, the distance sensing data and the wearing contact area data to obtain atomizer contact judgment data;

and automatically adjusting the switching-on and switching-off states of the atomizer according to the atomizer contact judging data.

It should be noted that, in order to determine whether the atomizing mask is worn in place, so as to automatically adjust the switching on and off of the atomizer according to the wearing condition, body temperature sensing data, distance sensing data and contact area data of the atomizer are firstly obtained, then the contact condition of the atomizer and the face is determined according to the body temperature sensing data, the distance sensing data and the contact area data, whether the atomizing mask is worn in place is determined, and then the switching on and off state of the atomizer is automatically adjusted.

According to an embodiment of the present invention, further comprising:

acquiring respiratory frequency data of a wearer of the atomizer and oxygen amount data of an atomization mask;

inputting the respiratory frequency data and the oxygen amount data of the atomized mask into a preset hypoxia monitoring model for analysis and treatment to obtain a hypoxia index;

And comparing the hypoxia index with a preset hypoxia index threshold value, judging the hypoxia condition of the wearer according to a threshold value comparison result, and reminding the wearer of hypoxia.

It should be noted that, because the wearer may have an anoxic condition when atomizing, in order to identify the anoxic condition, firstly, the respiratory frequency data of the wearer of the atomizer and the oxygen amount data of the atomizing mask are obtained, then the respiratory frequency data and the oxygen amount data of the atomizing mask are input into a preset anoxic monitoring model for analysis and processing to obtain an anoxic index, the preset anoxic monitoring model is a model obtained by training the respiratory frequency data, the oxygen amount data of the atomizing mask and the anoxic index which obtain a large number of historical samples, the anoxic index which is correspondingly output can be obtained by inputting relevant information for processing, the anoxic index is compared with a preset anoxic threshold value, and the anoxic condition of the wearer is determined and the anoxic reminding is performed according to the threshold value comparison result.

A third aspect of the present invention provides a readable storage medium having embodied therein a compressed nebulizer nebulization rate control method program which, when executed by a processor, implements the steps of the compressed nebulizer nebulization rate control method as described in any one of the preceding claims.

According to the atomization rate control method, system and medium of the compression atomizer, the user respiratory gas state is judged according to the air flow direction data, the first atomization rate adjusting parameter is obtained through processing according to the obtained respiratory state detection data and the obtained spray flow data, the first correction factor is obtained through processing according to the user sign data and the user wearing state data, the second atomization rate adjusting parameter is obtained through correcting the first atomization rate adjusting parameter according to the first correction factor, the atomizing cup adjusting parameter is obtained through processing according to the atomizing cup characteristic data and the spray flow data, the third atomization rate adjusting parameter is obtained through processing according to the second atomization rate adjusting parameter, the atomizing cup adjusting parameter and the air compressor pressure data are combined, the atomizing rate adjusting parameter grade is obtained, the atomizing rate is adjusted in a segmented mode according to the atomizing rate adjusting parameter grade, and the purpose of intelligently adjusting the atomizing rate according to the user conditions can be achieved.

In the several embodiments provided by the present application, it should be understood that the disclosed apparatus and method may be implemented in other ways. The above described device embodiments are only illustrative, e.g. the division of the units is only one logical function division, and there may be other divisions in practice, such as: multiple units or components may be combined or may be integrated into another system, or some features may be omitted, or not performed. In addition, the various components shown or discussed may be coupled or directly coupled or communicatively coupled to each other via some interface, whether indirectly coupled or communicatively coupled to devices or units, whether electrically, mechanically, or otherwise.

The units described above as separate components may or may not be physically separate, and components shown as units may or may not be physical units; can be located in one place or distributed to a plurality of network units; some or all of the units may be selected according to actual needs to achieve the purpose of the solution of this embodiment.

In addition, each functional unit in each embodiment of the present invention may be integrated in one processing unit, or each unit may be separately used as one unit, or two or more units may be integrated in one unit; the integrated units may be implemented in hardware or in hardware plus software functional units.

Those of ordinary skill in the art will appreciate that: all or part of the steps for implementing the above method embodiments may be implemented by hardware related to program instructions, and the foregoing program may be stored in a readable storage medium, where the program, when executed, performs steps including the above method embodiments; and the aforementioned storage medium includes: a mobile storage device, a Read-Only Memory (ROM), a random access Memory (RAM, random Access Memory), a magnetic disk or an optical disk, or the like, which can store program codes.

Alternatively, the above-described integrated units of the present invention may be stored in a readable storage medium if implemented in the form of software functional modules and sold or used as separate products. Based on such understanding, the technical solution of the embodiments of the present invention may be embodied in essence or a part contributing to the prior art in the form of a software product stored in a storage medium, including several instructions for causing a computer device (which may be a personal computer, a server, or a network device, etc.) to execute all or part of the methods described in the embodiments of the present invention. And the aforementioned storage medium includes: a removable storage device, ROM, RAM, magnetic or optical disk, or other medium capable of storing program code.

Claims (3)

1. A method of controlling the rate of atomization of a compressed atomizer, comprising the steps of:

acquiring airflow direction data, spray flow data, atomizing cup characteristic data and air compressor pressure data of an atomizer;

judging the breathing state of a user according to the air flow direction data, obtaining breathing state detection data, and analyzing and processing according to the breathing state detection data and the spraying flow data to obtain a first atomization rate adjusting parameter;

Acquiring user sign data and user wearing state data, and analyzing and processing according to the user sign data and the user wearing state data to acquire a first correction factor;

correcting the first atomization rate adjustment parameter according to the first correction factor to obtain a second atomization rate adjustment parameter;

analyzing and processing according to the characteristic data of the atomizing cup and the atomizing flow rate data to obtain an adjusting parameter of the atomizing cup;

processing according to the second atomization rate adjusting parameter and the atomization cup adjusting parameter and the air compressor pressure data to obtain a third atomization rate adjusting parameter;

comparing the third atomization rate adjusting parameter with a preset atomization rate adjusting parameter threshold value to obtain an atomization rate adjusting parameter grade, and adjusting the atomization rate in a sectional manner according to the atomization rate adjusting parameter grade;

the air flow direction data, the spraying flow data, the atomizing cup characteristic data and the air compressor pressure data of the atomizer are obtained, and the method comprises the following steps:

acquiring airflow direction data, spray flow data, atomizing cup characteristic data and air compressor pressure data of an atomizer;

the spray flow data includes spray particle diameter data and spray concentration data;

The atomizing cup characteristic data comprise atomizing cup aperture data and atomizing cup negative pressure data;

the method for determining the respiratory state of the user according to the airflow direction data, obtaining respiratory state detection data, and obtaining a first atomization rate adjustment parameter by analyzing and processing according to the respiratory state detection data and the spray flow data comprises the following steps:

judging the breathing state of the user according to the air flow direction data, and obtaining breathing state detection data comprising breathing state data, breathing time data, breathing state data and breathing time data;

inputting the inhalation state data, inhalation time data, exhalation state data and exhalation time data into a preset breathing adjustment parameter model for processing by combining the spray concentration data, so as to obtain a first atomization rate adjustment parameter;

the step of obtaining the user sign data and the user wearing state data, and obtaining a first correction factor by analyzing and processing according to the user sign data and the user wearing state data comprises the following steps:

acquiring user sign data, including age data and weight data;

acquiring wearing state data of a user, wherein the wearing state data comprise wearing contact area data and wearing tightness data;

according to the age data and the weight data, the wearing contact area data and the wearing tightness data are combined for analysis and processing to obtain a first correction factor;

The correcting the first atomization rate adjustment parameter according to the first correction factor to obtain a second atomization rate adjustment parameter comprises the following steps:

correcting the first atomization rate adjusting parameter according to the first correction factor to obtain a second atomization rate adjusting parameter;

the correction formula of the second atomization rate adjusting parameter is as follows:

；

wherein ,adjusting the parameter for the second nebulization rate, +.>For the first correction factor, +.>Adjusting the parameter for the first nebulization rate, +.>Is a preset characteristic coefficient;

the method for analyzing and processing the atomizing cup characteristic data and the atomizing flow data to obtain atomizing cup adjusting parameters comprises the following steps:

generating atomizing cup pressure regulating parameter data according to the atomizing cup negative pressure data and the atomizing particle diameter data;

inputting the atomizing cup aperture data and the atomizing cup pressure adjustment parameter data into a preset atomizing cup parameter adjustment model for processing to generate an atomizing cup adjustment parameter;

the processing according to the second atomization rate adjustment parameter in combination with the atomization cup adjustment parameter and the air compressor pressure data to obtain a third atomization rate adjustment parameter comprises the following steps:

processing according to the second atomization rate adjusting parameter and the atomization cup adjusting parameter to obtain an atomization cup adjusting correction factor;

Processing according to the atomizing cup adjusting correction factor and the air compressor pressure data to obtain a third atomizing rate adjusting parameter;

the program processing formula of the third atomization rate adjusting parameter is as follows:

；

wherein ,adjusting the parameter for the third nebulization rate, +.>Adjusting correction factors for the atomizing cup>Is the pressure data of the air compressor,is a preset characteristic coefficient;

the threshold value comparison is performed between the third atomization rate adjustment parameter and a preset atomization rate adjustment parameter threshold value, an atomization rate adjustment parameter level is obtained, and the atomization rate is adjusted in a segmented mode according to the atomization rate adjustment parameter level, and the method comprises the following steps:

comparing the third atomization rate adjusting parameter with a preset atomization rate adjusting parameter threshold value in a threshold value;

obtaining an atomization rate adjusting parameter grade according to the range grade of the threshold value comparison result;

and carrying out sectional adjustment on the atomization rate according to the atomization rate adjustment parameter grade.

2. A compression atomizer atomization rate control system, comprising: the device comprises a memory and a processor, wherein the memory comprises a program of a compressed atomizer atomization rate control method, and the program of the compressed atomizer atomization rate control method realizes the following steps when being executed by the processor:

Acquiring airflow direction data, spray flow data, atomizing cup characteristic data and air compressor pressure data of an atomizer;

judging the breathing state of a user according to the air flow direction data, obtaining breathing state detection data, and analyzing and processing according to the breathing state detection data and the spraying flow data to obtain a first atomization rate adjusting parameter;

acquiring user sign data and user wearing state data, and analyzing and processing according to the user sign data and the user wearing state data to acquire a first correction factor;

correcting the first atomization rate adjustment parameter according to the first correction factor to obtain a second atomization rate adjustment parameter;

analyzing and processing according to the characteristic data of the atomizing cup and the atomizing flow rate data to obtain an adjusting parameter of the atomizing cup;

processing according to the second atomization rate adjusting parameter and the atomization cup adjusting parameter and the air compressor pressure data to obtain a third atomization rate adjusting parameter;

comparing the third atomization rate adjusting parameter with a preset atomization rate adjusting parameter threshold value to obtain an atomization rate adjusting parameter grade, and adjusting the atomization rate in a sectional manner according to the atomization rate adjusting parameter grade;

The air flow direction data, the spraying flow data, the atomizing cup characteristic data and the air compressor pressure data of the atomizer are obtained, and the method comprises the following steps:

acquiring airflow direction data, spray flow data, atomizing cup characteristic data and air compressor pressure data of an atomizer;

the spray flow data includes spray particle diameter data and spray concentration data;

the atomizing cup characteristic data comprise atomizing cup aperture data and atomizing cup negative pressure data;

the method for determining the respiratory state of the user according to the airflow direction data, obtaining respiratory state detection data, and obtaining a first atomization rate adjustment parameter by analyzing and processing according to the respiratory state detection data and the spray flow data comprises the following steps:

judging the breathing state of the user according to the air flow direction data, and obtaining breathing state detection data comprising breathing state data, breathing time data, breathing state data and breathing time data;

inputting the inhalation state data, inhalation time data, exhalation state data and exhalation time data into a preset breathing adjustment parameter model for processing by combining the spray concentration data, so as to obtain a first atomization rate adjustment parameter;

the step of obtaining the user sign data and the user wearing state data, and obtaining a first correction factor by analyzing and processing according to the user sign data and the user wearing state data comprises the following steps:

Acquiring user sign data, including age data and weight data;

acquiring wearing state data of a user, wherein the wearing state data comprise wearing contact area data and wearing tightness data;

according to the age data and the weight data, the wearing contact area data and the wearing tightness data are combined for analysis and processing to obtain a first correction factor;

the correcting the first atomization rate adjustment parameter according to the first correction factor to obtain a second atomization rate adjustment parameter comprises the following steps:

correcting the first atomization rate adjusting parameter according to the first correction factor to obtain a second atomization rate adjusting parameter;

the correction formula of the second atomization rate adjusting parameter is as follows:

；

wherein ,adjusting the parameter for the second nebulization rate, +.>For the first correction factor, +.>Adjusting the parameter for the first nebulization rate, +.>Is a preset characteristic coefficient;

the method for analyzing and processing the atomizing cup characteristic data and the atomizing flow data to obtain atomizing cup adjusting parameters comprises the following steps:

generating atomizing cup pressure regulating parameter data according to the atomizing cup negative pressure data and the atomizing particle diameter data;

inputting the atomizing cup aperture data and the atomizing cup pressure adjustment parameter data into a preset atomizing cup parameter adjustment model for processing to generate an atomizing cup adjustment parameter;

The processing according to the second atomization rate adjustment parameter in combination with the atomization cup adjustment parameter and the air compressor pressure data to obtain a third atomization rate adjustment parameter comprises the following steps:

processing according to the second atomization rate adjusting parameter and the atomization cup adjusting parameter to obtain an atomization cup adjusting correction factor;

processing according to the atomizing cup adjusting correction factor and the air compressor pressure data to obtain a third atomizing rate adjusting parameter;

the program processing formula of the third atomization rate adjusting parameter is as follows:

；

wherein ,adjusting the parameter for the third nebulization rate, +.>Adjusting correction factors for the atomizing cup>Is the pressure data of the air compressor,is a preset characteristic coefficient;

the threshold value comparison is performed between the third atomization rate adjustment parameter and a preset atomization rate adjustment parameter threshold value, an atomization rate adjustment parameter level is obtained, and the atomization rate is adjusted in a segmented mode according to the atomization rate adjustment parameter level, and the method comprises the following steps:

comparing the third atomization rate adjusting parameter with a preset atomization rate adjusting parameter threshold value in a threshold value;

obtaining an atomization rate adjusting parameter grade according to the range grade of the threshold value comparison result;

and carrying out sectional adjustment on the atomization rate according to the atomization rate adjustment parameter grade.

3. A computer readable storage medium, characterized in that the computer readable storage medium comprises a compressed nebulizer nebulization rate control method program, which, when executed by a processor, implements the steps of the compressed nebulizer nebulization rate control method as claimed in claim 1.