CN114521684A - Atomization output method based on resonant wave and related equipment thereof - Google Patents

Abstract

The embodiment of the application belongs to the field of aerosol generating devices, and relates to an atomization output method based on resonant waves, which comprises the steps of obtaining an atomization time parameter, a first proportion parameter, a preset electrical parameter, a resonant wave parameter and an amplitude suppression function; calculating an atomization voltage value according to the atomization time parameter, the first proportional parameter, the preset electrical parameter, the resonant wave parameter and the amplitude suppression function; and outputting the atomization voltage value. The application also provides a related device based on the atomization output of the resonant wave. The application is a resonance wave mode atomization output method, after suppression through an amplitude suppression function, if the atomization voltage value obtained through continuous calculation presents an increasing state, the aerosol taste generated by the atomization aerosol substrate is changed, and the fullness is stronger and stronger, if the atomization voltage value obtained through continuous calculation presents a decreasing state, the aerosol taste generated by the atomization aerosol substrate is changed, and the fullness is weaker and stronger, so that the requirements of different users are adapted, and the user smoking experience is improved.

Description

Atomization output method based on resonant wave and related equipment thereof

Technical Field

The application relates to the technical field of aerosol generating devices, in particular to an atomization output method based on resonance waves and related equipment.

Background

At present, the specification of aerosol substrate is various, and the atomizing temperature/heating temperature of the aerosol substrate of different specifications is different, and among the present aerosol generating device, an aerosol generating device can only atomize/heat the aerosol substrate of a specification, and the suitability is poor, causes the taste single, and the problem that the suction experience is poor, leads to having to purchase multiple aerosol generating device like this to satisfy the demand of the different tastes of user, with high costs, also causes the aerosol generating device to be idle easily, the wasting of resources.

Disclosure of Invention

The embodiment of the application aims to provide an atomization output method based on resonant waves and related equipment thereof, which are used for solving the problems of poor applicability and poor suction experience of an aerosol generation device in the prior art.

In order to solve the above technical problem, an embodiment of the present application provides an atomization output method for a resonant wave, which adopts the following technical scheme:

acquiring an atomization time parameter, a first proportion parameter, a preset electrical parameter, a resonant wave parameter and an amplitude suppression function;

calculating an atomization voltage value according to the atomization time parameter, the first proportional parameter, the preset electrical parameter, the resonance wave parameter and the amplitude suppression function;

and outputting the atomization voltage value.

Further, before the step of obtaining the atomization time parameter, the first proportional parameter, the preset electrical parameter, the resonant wave parameter, and the amplitude suppression function, the method further includes:

acquiring a preheating time parameter, an initial voltage value and a preset target voltage value;

and calculating a preheating voltage value according to the preheating time parameter, the initial voltage value and the target voltage value.

The step of obtaining the atomization time parameter, the first proportional parameter, the preset electrical parameter, the resonance wave parameter and the amplitude suppression function comprises:

and when the preheating voltage value meets the target voltage value, acquiring an atomization time parameter, a first proportional parameter, a preset electrical parameter, a resonance wave parameter and an amplitude suppression function.

Further, the step of calculating the preheating voltage value according to the preheating time parameter, the initial voltage value and the target voltage value includes:

according to a first formula U (t)₂)＝U₀+(U_max-U₀)*t₂Calculating the preheating voltage value, wherein U (T)₂) For preheating the voltage value, U₀Is the initial voltage value, U_maxIs the target voltage value, t₂T is U as the preheating time parameter₀To U_maxThe preset required time parameter.

Further, before the step of calculating the atomization voltage value according to the atomization time parameter, the first proportional parameter, the preset electrical parameter, the resonance wave parameter, and the amplitude suppression function, the method further includes:

when an atomization stopping instruction is received, adjusting the first proportional parameter to obtain a new first proportional parameter, wherein the new first proportional parameter is smaller than the first proportional parameter;

and taking the new first scale parameter as the first scale parameter.

Further, before the step of calculating the atomization voltage value according to the atomization time parameter, the first proportional parameter, the preset electrical parameter, the resonance wave parameter, and the amplitude suppression function, the method further includes:

extracting a preset voltage parameter corresponding to the atomization time parameter from the preset electrical parameters, and extracting a current period parameter, a second proportion parameter and an angular frequency parameter from the resonance wave parameter;

and constructing a function according to the atomization time parameter, the preset voltage parameter, the current period parameter, the second proportion parameter and the angular frequency parameter to obtain an amplitude suppression function.

Further, the step of obtaining the amplitude suppression function includes:

the amplitude suppression function is f (t ') -K t' + U₁-K*t₁Wherein f (t ') is the amplitude suppression function, K is the second scaling parameter, t' is the current period parameter, U₁For the preset voltage parameter, t₁Is the atomization time parameter.

Further, the step of calculating the atomization voltage value according to the atomization time parameter, the first proportional parameter, the preset electrical parameter, the resonance wave parameter, and the amplitude suppression function includes:

extracting a preset resistance parameter and a preset power parameter from the preset electrical parameter;

according to a second formula

Calculating the atomization voltage value, wherein U (t)₁) For the atomization voltage value, f (t') is the amplitude suppression function, ω is the angular frequency parameter, t₁And setting beta as the atomization time parameter, beta as the first proportional parameter, R as the preset resistance parameter, and P as the preset power parameter.

In order to solve the above technical problem, an embodiment of the present application further provides an atomization output device based on a resonant wave, which adopts the following technical scheme:

the first acquisition module is used for acquiring an atomization time parameter, a first proportion parameter, a preset electrical parameter, a resonance wave parameter and an amplitude suppression function;

the first calculation module is used for calculating an atomization voltage value according to the atomization time parameter, the first proportion parameter, the preset electrical parameter, the resonance wave parameter and the amplitude suppression function; and

and the output module is used for outputting the atomization voltage value.

In order to solve the above technical problem, an embodiment of the present application further provides a computer device, which adopts the following technical solutions:

comprising a memory in which a computer program is stored and a processor which, when executing said computer program, carries out the steps of the method for outputting nebulisation based on resonant waves as described above.

In order to solve the above technical problem, an embodiment of the present application further provides a computer-readable storage medium, which adopts the following technical solutions:

the computer-readable storage medium has stored thereon a computer program which, when being executed by a processor, realizes the steps of the resonance wave-based fogging output method described above.

Compared with the prior art, the embodiment of the application mainly has the following beneficial effects: obtaining an atomization time parameter, a first proportion parameter, a preset electrical parameter, a resonance wave parameter and an amplitude suppression function; calculating an atomization voltage value according to the atomization time parameter, the first proportional parameter, the preset electrical parameter, the resonant wave parameter and the amplitude suppression function; and outputting the atomization voltage value. The application is atomizing output method of harmonic wave mode, through atomizing time parameter, first scale parameter, preset electrical parameter, harmonic wave parameter and amplitude suppression function calculation atomizing voltage value are like in the atomizing stage, effectively prevent the fried oil phenomenon, restrain the back through the amplitude suppression function simultaneously, if the continuous calculation obtains atomizing voltage value and presents the increasing state, then the aerosol taste that the atomizing aerosol substrate generated changes, the satisfiability is stronger and stronger, if the continuous calculation obtains atomizing voltage value and is the decreasing state, then the aerosol taste that the atomizing aerosol substrate generated changes, the satisfiability is more and more if weak, with different user's of adaptation demand, promote user's suction experience.

Drawings

In order to more clearly illustrate the solution of the present application, the drawings needed for describing the embodiments of the present application will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present application, and that other drawings can be obtained by those skilled in the art without inventive effort.

FIG. 1 is an exemplary system architecture diagram in which the present application may be applied;

FIG. 2 is a flow diagram of one embodiment of a harmonic wave based fogging output method according to the present application;

FIG. 3 is a resonance waveform diagram (K <0) of an embodiment of a harmonic wave based fogging output method according to the application;

FIG. 4 is a resonance waveform diagram (K >0) of an embodiment of a harmonic wave based fogging output method according to the application;

FIG. 5 is a schematic diagram of an embodiment of a harmonic wave based atomizing output device according to the present application;

FIG. 6 is a schematic block diagram of one embodiment of a computer device according to the present application.

Detailed Description

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs; the terminology used in the description of the application herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the application; the terms "including" and "having," and any variations thereof, in the description and claims of this application and the description of the above figures are intended to cover non-exclusive inclusions. The terms "first," "second," and the like in the description and claims of this application or in the above-described drawings are used for distinguishing between different objects and not for describing a particular order.

Reference herein to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment can be included in at least one embodiment of the application. The appearances of the phrase in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. It is explicitly and implicitly understood by one skilled in the art that the embodiments described herein can be combined with other embodiments.

In order to make the technical solutions better understood by those skilled in the art, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the accompanying drawings.

As shown in fig. 1, the system architecture 100 may include terminal devices 101, 102, 103, a network 104, and a server 105. The network 104 serves as a medium for providing communication links between the terminal devices 101, 102, 103 and the server 105. Network 104 may include various connection types, such as wired, wireless communication links, or fiber optic cables, to name a few.

The user may use the terminal devices 101, 102, 103 to interact with the server 105 via the network 104 to receive or send messages or the like. The terminal devices 101, 102, 103 may have various communication client applications installed thereon, such as a web browser application, a shopping application, a search application, an instant messaging tool, a mailbox client, social platform software, and the like.

The terminal devices 101, 102, 103 may be various electronic devices having a display screen and supporting web browsing, including but not limited to smart phones, tablet computers, e-book readers, MP3 players (Moving Picture Experts Group Audio Layer III, mpeg compression standard Audio Layer 3), MP4 players (Moving Picture Experts Group Audio Layer IV, mpeg compression standard Audio Layer 4), laptop portable computers, desktop computers, and the like.

The server 105 may be a server providing various services, such as a background server providing support for pages displayed on the terminal devices 101, 102, 103.

It should be noted that the atomization output method based on resonant waves provided by the embodiments of the present application generally consists ofService Device/terminal equipmentThe execution is carried out correspondingly, the atomization output device based on the resonance wave is generally arrangedServer/terminal deviceIn (1).

It should be understood that the number of terminal devices, networks, and servers in fig. 1 is merely illustrative. There may be any number of terminal devices, networks, and servers, as desired for implementation.

With continued reference to FIG. 2, a flow diagram of one embodiment of a method of nebulized output based on resonant waves in accordance with the present application is shown. The atomization output method based on the resonance wave is suitable for an aerosol generating device, wherein the aerosol generating device is used for atomizing/heating an aerosol substrate to form aerosol; the aerosol generating device comprises a host body (comprising a control chip) and an atomizing assembly (comprising an atomizing core)/a heating assembly (comprising a heating core), wherein the host body is used for controlling the atomizing assembly/the heating assembly to start or stop; the atomization output method based on the resonant wave comprises the following steps:

step S201, obtaining an atomization time parameter, a first proportional parameter, a preset electrical parameter, a resonant wave parameter, and an amplitude suppression function.

In the present embodiment, the above-mentioned atomization time parameter is characterized as the time parameter from the beginning of the atomization phase to the present.

In practical application, the first proportion parameter can be adjusted to adapt to atomization modes of different aerosol substrate specifications, so that the applicability of the method is improved.

The preset electrical parameters comprise preset resistance parameters, preset power parameters and the like, wherein the preset resistance parameters are characterized as the resistance values of the atomizing cores; the preset power parameter can be set by a user to control the atomization efficiency of the aerosol substrate in practical application.

The resonant wave parameters include angular frequency parameters.

The amplitude suppression function is used for suppressing the generated resonance waveform (see fig. 3 and fig. 4), so that the resonance waveform (see fig. 3 and fig. 4) can form an increasing state, the taste of the aerosol formed by final atomization is changed more and more strongly, and the resonance waveform can also form a decreasing state, the taste of the aerosol formed by final atomization is changed more and more weakly, and the requirements of different users are met.

Step S202, calculating an atomization voltage value according to the atomization time parameter, the first proportional parameter, the preset electrical parameter, the resonant wave parameter, and the amplitude suppression function.

In the present embodiment, the atomization voltage value obtained by the amplitude suppression function is calculated, and the atomization voltage value obtained by continuous calculation is in an increasing or decreasing state during the continuous atomization time to form different resonance waveforms (see fig. 3 and 4), so as to meet the requirements of different users.

It should be noted that the atomization voltage value is characterized as the current voltage value in the atomization stage; it is further noted that the waveform generated by the method of the present application is a resonant waveform (see fig. 3 and 4), and the resonant waveform (see fig. 3 and 4) includes a plurality of periods, each period having a maximum value and a minimum value of the atomization voltage, so that during the use of the aerosol generating device, a distinct setback is formed, so that the aerosol formed by the atomization component atomizing the aerosol substrate has a moderate and soft taste.

And step S203, outputting the atomization voltage value.

In this embodiment, during the atomizing voltage value was sent to control chip with the form of signal of telecommunication, control chip carried out atomizing/heating to the aerosol substrate according to atomizing voltage value control atomization component.

In some optional implementations of this embodiment, in step S201, before the step of obtaining the nebulization time parameter, the first scale parameter, the preset electrical parameter, the resonance wave parameter, and the amplitude suppression function, the method further includes:

acquiring a preheating time parameter, an initial voltage value and a preset target voltage value;

and calculating a preheating voltage value according to the preheating time parameter, the initial voltage value and the target voltage value.

In step S201, the step of obtaining the atomization time parameter, the first proportional parameter, the preset electrical parameter, the resonant wave parameter, and the amplitude suppression function includes:

and when the preheating voltage value meets the target voltage value, acquiring an atomization time parameter, a first proportional parameter, a preset electrical parameter, a resonance wave parameter and an amplitude suppression function.

In this embodiment, the preheating time parameter is defined similarly to the atomization time parameter, but the preheating time parameter is characterized as the preheating time of the atomization assembly, and the atomization time parameter is characterized as the atomization time of the atomization assembly.

The initial voltage value is characterized as the voltage value of the atomization component during preheating and starting; the target voltage value is characterized as the voltage value when the preheating of the atomization assembly is finished.

The preheating voltage value is characterized as the current voltage value in the preheating stage; it should be noted that, after the preheating voltage value is equal to or greater than the target voltage value, the atomization phase is entered, i.e., step S201 is executed.

In some optional implementations of this embodiment, the step of calculating the preheating voltage value according to the preheating time parameter, the initial voltage value and the target voltage value includes:

according to a first formula U (t)₂)＝U₀+(U_max-U₀)*t₂Calculating the preheating voltage value, wherein U (T)₂) For preheating the voltage value, U₀Is the initial voltage value, U_maxIs the target voltage value, t₂T is U as the preheating time parameter₀To U_maxThe preset required time parameter.

In the present embodiment, the initial voltage value U₀The voltage detection element can be a fixed value and is pre-stored in the storage element on the host body, and the storage element can be directly called from the storage component when the host body is preset to be obtained, or can be detected by the voltage detection element when the host body is preheated to be obtained, and the voltage detection element is electrically connected with the control chip to transmit data detected by the voltage detection element.

Target voltage value U_maxThe fixed value is set when the device is delivered from a factory or adjusted and set by a user to meet different use requirements.

Initial voltage value U₀To a target voltage value U_maxThe preset required time parameter T can be obtained through experiments in advance.

Note that U is₀＝α*U_max，

Wherein alpha is a proportional parameter, R is a preset resistance parameter, P is a preset power parameter, and the preset resistance parameter R and the preset power parameter P are described above and can be extracted from preset electrical parameters.

It should be noted that the proportional parameter α is obtained through experiments in advance, and the initial voltage value U can be determined through the proportional parameter α₀And a target voltage value U_maxThe mapping relationship between them.

Further, when the initial voltage value U is set₀Or target voltage value U_maxDuring adjustment, a preset required time parameter T and an initial voltage value U are required to be established₀Or target voltage value U_maxThe mapping relation can be obtained by experiments in advance; when the initial voltage value U is₀And a target voltage value U_maxDuring adjustment, an initial voltage value U is required to be established₀Target voltage value U_maxAnd a preset required time parameter T, and the mapping relation between the three parameters can be obtained through experiments in advance.

In some optional implementations of this embodiment, in step S202, before the step of calculating the atomization voltage value according to the atomization time parameter, the first scale parameter, the preset electrical parameter, the resonance wave parameter, and the amplitude suppression function, the method further includes:

when an atomization stopping instruction is received, adjusting the first proportional parameter to obtain a new first proportional parameter, wherein the new first proportional parameter is smaller than the first proportional parameter;

and taking the new first scale parameter as the first scale parameter.

In this embodiment, the atomization stopping instruction may be generated by a user triggering a start-stop switch (such as a start-stop button or a microphone) on the host body, or may be generated when the atomization time parameter reaches a preset value; after receiving the atomization stopping instruction, extracting data (preset when the data leaves a factory or preset when a user starts) from a storage element on the host body, and adjusting the first scale parameter according to the extracted data to obtain a new first scale parameter.

It should be noted that the new first ratio parameter is smaller than the first ratio parameter, so that the atomizing assembly/heating assembly atomizes with a smaller voltage, thereby protecting the atomizing core from being damaged when the high voltage state is switched to the stop state.

It is further noted that, in the above, while the atomizing assembly atomizes at a relatively low voltage, the aerosol substrate is also atomized by using the residual temperature in the thermal environment formed during the atomizing stage/heating stage, so as to facilitate the subsequent smoking of the user during the continuous smoking process.

In some optional implementations of this embodiment, in step S202, before the step of calculating the atomization voltage value according to the atomization time parameter, the first scale parameter, the preset electrical parameter, the resonance wave parameter, and the amplitude suppression function, the method further includes:

extracting a preset voltage parameter corresponding to the atomization time parameter from the preset electrical parameters, and extracting a current period parameter, a second proportion parameter and an angular frequency parameter from the resonance wave parameter;

and constructing a function according to the atomization time parameter, the preset voltage parameter, the current period parameter, the second proportion parameter and the angular frequency parameter to obtain an amplitude suppression function.

In this embodiment, the atomization time parameters and the preset voltage parameters are in a mapping relationship, one of the atomization time parameters corresponds to one of the preset voltage parameters, and the mapping relationship between the atomization time parameters and the preset voltage parameters can be obtained through a preliminary experiment.

The current period parameter is characterized as a period in which the current resonance waveform (see fig. 3 and 4) is located, the current period parameter and the atomization time parameter are in a corresponding relationship, and the current period parameter can be determined from the resonance wave parameter according to the atomization time parameter.

The second proportion parameter can be adjusted in practical application to adapt to atomization modes of different aerosol substrate specifications, and the applicability of the method is improved.

The angular frequency parameter is characterized by the number of periodic changes per unit time.

It should be noted that the amplitude suppression function and the second proportional parameter are in a positive correlation relationship, and when the second proportional parameter is larger, the atomization voltage value calculated by the amplitude suppression function is increased to form a resonance waveform in an increasing state (see fig. 4), whereas when the second proportional parameter is smaller, the atomization voltage value calculated by the amplitude suppression function is decreased to form a resonance waveform in a decreasing state (see fig. 3).

In some optional implementations of this embodiment, the step of obtaining the amplitude suppression function includes:

the amplitude suppression function is f (t ') -K t' + U₁-K*t₁Wherein f (t ') is the amplitude suppression function, K is the second scaling parameter, t' is the current period parameter, U₁For the preset voltage parameter, t₁Is the atomization time parameter.

In the present embodiment, the formula is used

Calculating a second proportional parameter K, wherein two arbitrary continuous points in the resonance waveform (see FIG. 3 and FIG. 4) are arbitrarily taken in the preliminary experiment, (t)₃，U₃) And (t)₄，U₄) Wherein t is₄Greater than t₃It is understood that when U is used₄Greater than U₃Then, the calculated second ratio parameter K is greater than 0, i.e. the amplitude suppression function f (t') is greater than 0, so as to form a resonance waveform in an increasing state in the following process (see fig. 4), when U is greater than 0₄Less than U₃Meanwhile, the calculated second ratio parameter K is smaller than 0, i.e. the amplitude suppression function f (t') is smaller than 0, so as to form a decreasing resonance waveform in the following step (see fig. 3).

In some optional implementations of this embodiment, in step S202, the step of calculating an atomization voltage value according to the atomization time parameter, the first scale parameter, the preset electrical parameter, the resonance wave parameter, and the amplitude suppression function includes:

extracting a preset resistance parameter and a preset power parameter from the preset electrical parameter;

according to a second formula

Calculating the atomization voltage value, wherein U (t)₁) For the atomization voltage value, f (t') is the amplitude suppression function, ω is the angular frequency parameter, t₁And setting beta as the atomization time parameter, beta as the first proportional parameter, R as the preset resistance parameter, and P as the preset power parameter.

In this embodiment, the above-mentioned medium amplitude suppression function f (t') and angular frequency parameter ω are initially set to fixed values during the secondary aerosol substrate atomization; in the second formula, the atomization time parameter t₁As a variable parameter, according to the parameter t of the atomization time₁The calculated atomization voltage value is periodically changed.

The application relates to an atomization output method of a resonance wave mode (please refer to fig. 3 and fig. 4), which effectively prevents oil explosion in an atomization stage by calculating an atomization voltage value through an atomization time parameter, a first proportional parameter, a preset electrical parameter, a resonance wave parameter and an amplitude suppression function, and meanwhile, after the inhibition by the amplitude suppression function, if the atomization voltage value obtained through continuous calculation presents an increasing state, the taste of aerosol generated by an atomized aerosol substrate is changed and the fullness is stronger and stronger, and if the atomization voltage value obtained through continuous calculation presents a decreasing state, the taste of aerosol generated by the atomized aerosol substrate is changed and the fullness is weaker and weaker, so as to adapt to the requirements of different users, and improve the smoking experience of the users.

It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above can be implemented by a computer program, which can be stored in a computer-readable storage medium, and can include the processes of the embodiments of the methods described above when the computer program is executed. The storage medium may be a non-volatile storage medium such as a magnetic disk, an optical disk, a Read-Only Memory (ROM), or a Random Access Memory (RAM).

It should be understood that, although the steps in the flowcharts of the figures are shown in order as indicated by the arrows, the steps are not necessarily performed in order as indicated by the arrows. The steps are not performed in the exact order shown and may be performed in other orders unless explicitly stated herein. Moreover, at least a portion of the steps in the flow chart of the figure may include multiple sub-steps or multiple stages, which are not necessarily performed at the same time, but may be performed at different times, which are not necessarily performed in sequence, but may be performed alternately or alternately with other steps or at least a portion of the sub-steps or stages of other steps.

With further reference to fig. 5, as an implementation of the method shown in fig. 2, the present application provides an embodiment of a resonant wave-based atomization output device, which corresponds to the embodiment of the method shown in fig. 2, and which is particularly applicable to various electronic devices.

As shown in fig. 5, the atomization output device 500 based on the resonant wave according to the present embodiment includes: a first obtaining module 501, a first calculating module 502 and an output module 503. Wherein:

a first obtaining module 501, configured to obtain an atomization time parameter, a first proportional parameter, a preset electrical parameter, a resonant wave parameter, and an amplitude suppression function;

a first calculating module 502, configured to calculate an atomization voltage value according to the atomization time parameter, the first proportional parameter, the preset electrical parameter, the resonance wave parameter, and the amplitude suppression function; and

and an output module 503, configured to output the atomization voltage value.

The application relates to an atomization output method of a resonance wave mode (please refer to fig. 3 and fig. 4), which effectively prevents oil explosion in an atomization stage by calculating an atomization voltage value through an atomization time parameter, a first proportional parameter, a preset electrical parameter, a resonance wave parameter and an amplitude suppression function, and meanwhile, after the inhibition by the amplitude suppression function, if the atomization voltage value obtained through continuous calculation presents an increasing state, the taste of aerosol generated by an atomized aerosol substrate is changed and the fullness is stronger and stronger, and if the atomization voltage value obtained through continuous calculation presents a decreasing state, the taste of aerosol generated by the atomized aerosol substrate is changed and the fullness is weaker and weaker, so as to adapt to the requirements of different users, and improve the smoking experience of the users.

In some optional implementation manners of this embodiment, the system further includes a second obtaining module and a second calculating module. Wherein:

the second acquisition module is used for acquiring a preheating time parameter, an initial voltage value and a preset target voltage value;

and the second calculation module is used for calculating the preheating voltage value according to the preheating time parameter, the initial voltage value and the target voltage value.

The first obtaining module comprises a first obtaining submodule. Wherein:

and the first obtaining submodule is used for obtaining an atomization time parameter, a first proportion parameter, a preset electrical parameter, a resonance wave parameter and an amplitude suppression function when the preheating voltage value meets the target voltage value.

In some optional implementations of the embodiment, the second calculation module includes a preheating calculation submodule. Wherein:

a preheating calculation submodule for calculating the preheating coefficient according to a first formula U (t)₂)＝U₀+(U_max-U₀)*t₂Calculating the preheating voltage value, wherein U (T)₂) For preheating the voltage value, U₀Is an initial voltage value, U_maxIs a target voltage value, t₂T is U as a preheating time parameter₀To U_maxThe preset required time parameter.

In some optional implementations of this embodiment, the apparatus further includes an adjusting module and a replacing module. Wherein:

the adjusting module is used for adjusting the first proportional parameter when an atomization stopping instruction is received to obtain a new first proportional parameter, wherein the new first proportional parameter is smaller than the first proportional parameter;

and the replacing module is used for taking the new first scale parameter as the first scale parameter.

In some optional implementations of this embodiment, the method further includes an extracting module and a constructing module. Wherein:

the extraction module is used for extracting a preset voltage parameter corresponding to the atomization time parameter from the preset electrical parameter and extracting a current period parameter, a second proportion parameter and an angular frequency parameter from the resonance wave parameter;

and the construction module is used for constructing a function according to the atomization time parameter, the preset voltage parameter, the current period parameter, the second proportion parameter and the angular frequency parameter to obtain an amplitude suppression function.

In some optional implementations of the present embodiment, the building block includes an amplitude suppression sub-block. Wherein:

an amplitude suppression submodule for said amplitude suppression function to be f (t ') -K t' + U₁-K*t₁Wherein f (t ') is the amplitude suppression function, K is the second scaling parameter, t' is the current period parameter, U₁For the predetermined voltage parameter, t₁Is the atomization time parameter.

In some optional implementations of the present embodiment, the second calculating module 502 includes an extracting sub-module and a fogging calculating sub-module. Wherein:

the extraction submodule is used for extracting a preset resistance parameter and a preset power parameter from the preset electrical parameter;

an atomization calculation submodule for calculating, according to a second formula:

calculating the atomization voltage value, wherein U (t)₁) For the atomization voltage value, f (t') is the amplitude suppression function, ω is the angular frequency parameter, t₁And setting beta as the atomization time parameter, beta as the first proportional parameter, R as the preset resistance parameter, and P as the preset power parameter.

In order to solve the technical problem, an embodiment of the present application further provides a computer device. Referring to fig. 6, fig. 6 is a block diagram of a basic structure of a computer device according to the present embodiment.

The computer device 6 comprises a memory 61, a processor 62, an interface 63 communicatively connected to each other via a system bus. It is noted that only a computer device 6 having components 61-63 is shown, but it is understood that not all of the shown components are required to be implemented, and that more or fewer components may be implemented instead. As will be understood by those skilled in the art, the computer device is a device capable of automatically performing numerical calculation and/or information processing according to instructions set or stored in advance, and the hardware includes, but is not limited to, a microprocessor, an Application Specific Integrated Circuit (ASIC), a Programmable Gate Array (FPGA), a Digital Signal Processor (DSP), an embedded device, and the like.

The computer device can be a desktop computer, a notebook, a palm computer, a cloud server and other computing devices. The computer equipment can carry out man-machine interaction with a user through a keyboard, a mouse, a remote controller, a touch panel or voice control equipment and the like.

The memory 61 includes at least one type of readable storage medium including a flash memory, a hard disk, a multimedia card, a card type memory (e.g., SD or DX memory, etc.), a Random Access Memory (RAM), a Static Random Access Memory (SRAM), a Read Only Memory (ROM), an Electrically Erasable Programmable Read Only Memory (EEPROM), a Programmable Read Only Memory (PROM), a magnetic memory, a magnetic disk, an optical disk, etc. In some embodiments, the memory 61 may be an internal storage unit of the computer device 6, such as a hard disk or a memory of the computer device 6. In other embodiments, the memory 61 may also be an external storage device of the computer device 6, such as a plug-in hard disk, a Smart Media Card (SMC), a Secure Digital (SD) Card, a Flash memory Card (Flash Card), and the like, which are provided on the computer device 6. Of course, the memory 61 may also comprise both an internal storage unit of the computer device 6 and an external storage device thereof. In this embodiment, the memory 61 is generally used for storing an operating system installed in the computer device 6 and various types of application software, such as program codes of a method for outputting atomized resonance waves. Further, the memory 61 may also be used to temporarily store various types of data that have been output or are to be output.

The processor 62 may be a Central Processing Unit (CPU), controller, microcontroller, microprocessor, or other data Processing chip in some embodiments. The processor 62 is typically used to control the overall operation of the computer device 6. In this embodiment, the processor 62 is configured to run a program code stored in the memory 61 or process data, for example, a program code of a method for outputting the harmonic waves in a nebulized manner.

The interface 63 may comprise a wireless interface or a wired interface, and the interface 63 is typically used for establishing a communication connection between the computer device 6 and other electronic devices for signal transmission or data transmission.

The application relates to an atomization output method of a resonance wave mode (please refer to fig. 3 and fig. 4), which effectively prevents oil explosion in an atomization stage by calculating an atomization voltage value through an atomization time parameter, a first proportional parameter, a preset electrical parameter, a resonance wave parameter and an amplitude suppression function, and meanwhile, after the inhibition by the amplitude suppression function, if the atomization voltage value obtained through continuous calculation presents an increasing state, the taste of aerosol generated by an atomized aerosol substrate is changed and the fullness is stronger and stronger, and if the atomization voltage value obtained through continuous calculation presents a decreasing state, the taste of aerosol generated by the atomized aerosol substrate is changed and the fullness is weaker and weaker, so as to adapt to the requirements of different users, and improve the smoking experience of the users.

The present application further provides another embodiment, which is to provide a computer-readable storage medium, wherein the computer-readable storage medium stores a nebulization output program of a resonant wave, the nebulization output program of the resonant wave being executable by at least one processor to cause the at least one processor to perform the steps of the nebulization output method of a resonant wave as described above.

The application relates to an atomization output method of a resonance wave mode (please refer to fig. 3 and fig. 4), which effectively prevents oil explosion in an atomization stage by calculating an atomization voltage value through an atomization time parameter, a first proportional parameter, a preset electrical parameter, a resonance wave parameter and an amplitude suppression function, and meanwhile, after the inhibition by the amplitude suppression function, if the atomization voltage value obtained through continuous calculation presents an increasing state, the taste of aerosol generated by an atomized aerosol substrate is changed and the fullness is stronger and stronger, and if the atomization voltage value obtained through continuous calculation presents a decreasing state, the taste of aerosol generated by the atomized aerosol substrate is changed and the fullness is weaker and weaker, so as to adapt to the requirements of different users, and improve the smoking experience of the users.

Through the above description of the embodiments, those skilled in the art will clearly understand that the method of the above embodiments can be implemented by software plus a necessary general hardware platform, and certainly can also be implemented by hardware, but in many cases, the former is a better implementation manner. Based on such understanding, the technical solutions of the present application may be embodied in the form of a software product, which is stored in a storage medium (such as ROM/RAM, magnetic disk, optical disk) and includes instructions for enabling a terminal device (such as a mobile phone, a computer, a server, an air conditioner, or a network device) to execute the method according to the embodiments of the present application.

It is to be understood that the above-described embodiments are merely illustrative of some, but not restrictive, of the broad invention, and that the appended drawings illustrate preferred embodiments of the invention and do not limit the scope of the invention. This application is capable of embodiments in many different forms and is provided for the purpose of enabling a thorough understanding of the disclosure of the application. Although the present application has been described in detail with reference to the foregoing embodiments, it will be apparent to one skilled in the art that the present application may be practiced without modification or with equivalents of some of the features described in the foregoing embodiments. All equivalent structures made by using the contents of the specification and the drawings of the present application are directly or indirectly applied to other related technical fields and are within the protection scope of the present application.

Claims (10)

1. An atomization output method based on resonant waves is characterized by comprising the following steps:

obtaining an atomization time parameter, a first proportional parameter, a preset electrical parameter, a resonant wave parameter and an amplitude suppression function;

calculating an atomization voltage value according to the atomization time parameter, the first proportional parameter, the preset electrical parameter, the resonance wave parameter and the amplitude suppression function;

and outputting the atomization voltage value.

2. The resonant wave based atomization output method according to claim 1, wherein the step of obtaining the atomization time parameter, the first scale parameter, the preset electrical parameter, the resonant wave parameter, and the amplitude suppression function is preceded by the step of:

acquiring a preheating time parameter, an initial voltage value and a preset target voltage value;

calculating a preheating voltage value according to the preheating time parameter, the initial voltage value and the target voltage value;

the step of obtaining the atomization time parameter, the first proportional parameter, the preset electrical parameter, the resonance wave parameter and the amplitude suppression function comprises:

and when the preheating voltage value meets the target voltage value, acquiring an atomization time parameter, a first proportional parameter, a preset electrical parameter, a resonance wave parameter and an amplitude suppression function.

3. The resonant wave based fogging output method according to claim 2, wherein the step of calculating a pre-heating voltage value from the pre-heating time parameter, the initial voltage value and the target voltage value comprises:

according to a first formula U (t)₂)＝U₀+(U_max-U₀)*t₂Calculating the preheating voltage value, wherein U (T)₂) For preheating the voltage value, U₀Is the initial voltage value, U_maxIs the target voltage value, t₂T is U as the preheating time parameter₀To U_maxThe preset required time parameter.

4. The resonant wave based atomization output method according to claim 1, further comprising, before the step of calculating an atomization voltage value according to the atomization time parameter, the first scale parameter, the preset electrical parameter, the resonant wave parameter, and the amplitude suppression function:

when an atomization stopping instruction is received, adjusting the first proportional parameter to obtain a new first proportional parameter, wherein the new first proportional parameter is smaller than the first proportional parameter;

and taking the new first scale parameter as the first scale parameter.

5. The resonant wave based atomization output method according to any one of claims 1 to 4, further comprising, before the step of calculating an atomization voltage value according to the atomization time parameter, the first scale parameter, the preset electrical parameter, the resonant wave parameter, and the amplitude suppression function:

extracting a preset voltage parameter corresponding to the atomization time parameter from the preset electrical parameters, and extracting a current period parameter, a second proportion parameter and an angular frequency parameter from the resonance wave parameter;

and constructing a function according to the atomization time parameter, the preset voltage parameter, the current period parameter, the second proportion parameter and the angular frequency parameter to obtain an amplitude suppression function.

6. The resonant wave based fogging output method according to claim 5, characterised in that the step of deriving an amplitude suppression function includes:

the amplitude suppression function is f (t)')＝K*t'+U₁-K*t₁Wherein f (t ') is the amplitude suppression function, K is the second scaling parameter, t' is the current period parameter, U₁For the predetermined voltage parameter, t₁Is the atomization time parameter.

7. The resonant wave based atomization output method according to claim 6, wherein the step of calculating an atomization voltage value according to the atomization time parameter, the first scale parameter, the preset electrical parameter, the resonant wave parameter, and the amplitude suppression function includes:

extracting a preset resistance parameter and a preset power parameter from the preset electrical parameter;

according to a second formula

Calculating the atomization voltage value, wherein U (t)₁) For the atomization voltage value, f (t') is the amplitude suppression function, ω is the angular frequency parameter, t₁And setting beta as the atomization time parameter, beta as the first proportional parameter, R as the preset resistance parameter, and P as the preset power parameter.

8. An atomizing output device based on resonance waves, comprising:

the first acquisition module is used for acquiring an atomization time parameter, a first proportion parameter, a preset electrical parameter, a resonance wave parameter and an amplitude suppression function;

the first calculation module is used for calculating an atomization voltage value according to the atomization time parameter, the first proportion parameter, the preset electrical parameter, the resonance wave parameter and the amplitude suppression function; and

and the output module is used for outputting the atomization voltage value.

9. A computer device comprising a memory having a computer program stored therein and a processor that when executed implements the steps of the resonant wave based nebulisation output method according to any one of claims 1 to 7.

10. A computer-readable storage medium, characterized in that a computer program is stored thereon, which, when being executed by a processor, implements the steps of the resonance wave based fogging output method according to any one of claims 1 to 7.

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