CN117158661A - Laser heating regulation and control method and device for electronic atomization device, computer equipment and storage medium - Google Patents

Abstract

The disclosure provides a laser heating regulation and control method and device for an electronic atomization device, computer equipment and a storage medium. The method comprises the steps of obtaining laser temperature sensing parameters of a laser heating cup of an electronic atomization device; performing temperature detection gauge difference processing on the laser temperature sensing parameters and preset temperature sensing parameters to obtain laser temperature gauge difference; and sending a dimming power signal to a laser heater of the electronic atomization device according to the laser temperature meter difference so as to adjust the laser heating temperature of a laser heating cup of the electronic atomization device. The laser temperature sensing parameters are acquired to acquire the current laser heating temperature condition of the laser heating cup, then the laser temperature sensing parameters and the preset temperature sensing parameters are correspondingly processed to obtain the laser heating state difference degree between the laser temperature sensing parameters and the preset temperature sensing parameters, and finally the dimming power signal is correspondingly sent according to the laser heating state difference condition, so that the laser heating temperature of the laser heating cup is conveniently adjusted, and the laser heating temperature stability is effectively improved.

Description

Laser heating regulation and control method and device for electronic atomization device, computer equipment and storage medium

Technical Field

The disclosure relates to the technical field of electronic atomization devices, and in particular relates to a laser heating regulation and control method, a device, computer equipment and a storage medium of an electronic atomization device.

Background

The conventional electronic atomization device generally comprises a shell, wherein an oil storage bin, a power supply assembly, an atomization assembly and a control board are arranged in the shell. The oil storage bin is used for storing atomized oil and providing the atomized oil for the atomization assembly when the electronic atomization device works; the atomization assembly is used for heating the atomized oil to atomize the atomized oil; the power supply assembly is used for supplying power to the atomizing assembly and the control panel to control the operation of the atomizing assembly and the power supply assembly. The atomizing assembly generally adopts an electric heating wire to heat the atomized oil, and the electric heating wire generates heat after being electrified, so that the atomized oil is heated, and the atomized oil is atomized. When the heating wire heats atomized oil, heavy metals and other harmful substances are easily generated by the heating wire due to overhigh temperature. In order to solve the technical problem, some manufacturers adopt a laser heating mode to replace heating wires for heating.

However, in the conventional laser heating, laser energy is directly projected onto atomized cotton to raise the atomization temperature of atomized oil, and at this time, heat generated by the laser heating is diffused to four sides, so that the atomization temperature is not controlled, harmful substances are generated, and the human body is damaged due to too high inhalation amount.

Disclosure of Invention

The purpose of the present disclosure is to overcome the shortcomings in the prior art, and provide a laser heating regulation and control method, a device, a computer device and a storage medium of an electronic atomization device, which effectively improve the stability of laser heating temperature.

The aim of the disclosure is achieved by the following technical scheme:

a laser heating regulation method of an electronic atomizing device, the method comprising:

acquiring laser temperature sensing parameters of a laser heating cup of the electronic atomization device;

performing temperature detection gauge difference processing on the laser temperature sensing parameters and preset temperature sensing parameters to obtain laser temperature gauge difference;

and sending a dimming power signal to a laser heater of the electronic atomization device according to the laser temperature meter difference so as to adjust the laser heating temperature of a laser heating cup of the electronic atomization device.

In one embodiment, the acquiring the laser temperature sensing parameter of the laser heating cup of the electronic atomization device includes: and acquiring the infrared thermal electromotive force of the laser heating cup of the electronic atomization device.

In one embodiment, the performing temperature gauge difference processing on the laser temperature sensing parameter and a preset temperature sensing parameter to obtain a laser temperature gauge difference value includes: and obtaining the difference value between the infrared thermal electromotive force and the preset thermal electromotive force to obtain the laser infrared temperature difference.

In one embodiment, the sending a dimming power signal to a laser heater of an electronic atomization device according to the laser temperature difference to adjust a laser heating temperature of a laser heating cup of the electronic atomization device includes: detecting whether the laser infrared temperature difference is larger than or equal to a preset infrared temperature difference; and when the laser infrared temperature difference is larger than or equal to the preset infrared temperature difference, sending a dimming power-reducing signal to the laser heater.

In one embodiment, the acquiring the laser temperature sensing parameter of the laser heating cup of the electronic atomization device includes: and obtaining the thermocouple heat radiation intensity of the laser heating cup of the electronic atomization device.

In one embodiment, the performing temperature gauge difference processing on the laser temperature sensing parameter and a preset temperature sensing parameter to obtain a laser temperature gauge difference value includes: and obtaining a difference value between the thermocouple heat radiation intensity and the preset heat radiation intensity to obtain a laser radiation heat quantity difference.

In one embodiment, the sending a dimming power signal to a laser heater of an electronic atomization device according to the laser temperature difference to adjust a laser heating temperature of a laser heating cup of the electronic atomization device includes: detecting whether the laser radiation heat difference is smaller than a preset thermocouple heat difference or not; and when the laser radiation heat quantity difference is smaller than the preset couple heat difference, sending a dimming power-up signal to the laser heater.

A laser heating regulation device, comprising: the laser temperature sensing acquisition module, the laser temperature sensing processing module and the laser power adjustment output module; the laser temperature sensing acquisition module is used for acquiring laser temperature sensing parameters of a laser heating cup of the electronic atomization device; the laser temperature sensing processing module is used for performing temperature detection gauge difference processing on the laser temperature sensing parameters and preset temperature sensing parameters to obtain laser temperature gauge difference; the laser power adjusting output module is used for sending a power adjusting signal to a laser heater of the electronic atomization device according to the laser temperature meter difference so as to adjust the laser heating temperature of a laser heating cup of the electronic atomization device.

A computer device comprising a memory storing a computer program and a processor which when executing the computer program performs the steps of:

acquiring laser temperature sensing parameters of a laser heating cup of the electronic atomization device;

performing temperature detection gauge difference processing on the laser temperature sensing parameters and preset temperature sensing parameters to obtain laser temperature gauge difference;

and sending a dimming power signal to a laser heater of the electronic atomization device according to the laser temperature meter difference so as to adjust the laser heating temperature of a laser heating cup of the electronic atomization device.

A computer readable storage medium having stored thereon a computer program which when executed by a processor performs the steps of:

acquiring laser temperature sensing parameters of a laser heating cup of the electronic atomization device;

performing temperature detection gauge difference processing on the laser temperature sensing parameters and preset temperature sensing parameters to obtain laser temperature gauge difference;

and sending a dimming power signal to a laser heater of the electronic atomization device according to the laser temperature meter difference so as to adjust the laser heating temperature of a laser heating cup of the electronic atomization device.

Compared with the prior art, the method has at least the following advantages:

the laser temperature sensing parameters are acquired to acquire the current laser heating temperature condition of the laser heating cup, then the laser temperature sensing parameters and the preset temperature sensing parameters are correspondingly processed to obtain the laser heating state difference degree between the laser temperature sensing parameters and the preset temperature sensing parameters, finally, the dimming power signals are correspondingly sent according to the laser heating state difference condition, so that the laser heating temperature of the laser heating cup is conveniently adjusted, the heating temperature of a medium to be atomized in the laser heating cup is controlled, and the laser heating temperature stability is effectively improved.

Drawings

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

FIG. 1 is a flow chart of a laser heating control method of an electronic atomizing device according to an embodiment;

fig. 2 is an internal structural diagram of a computer device in one embodiment.

Detailed Description

In order that the disclosure may be understood, a more complete description of the disclosure will be rendered by reference to the appended drawings. Preferred embodiments of the present disclosure are shown in the drawings. This disclosure may, however, be embodied in many different forms and is not limited to the embodiments described herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "fixed to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like are used herein for illustrative purposes only and are not meant to be the only embodiment.

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 disclosure belongs. The terminology used in the description of the disclosure herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the disclosure. The term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

The present disclosure relates to a laser heating regulation method of an electronic atomizing device. In one embodiment, the laser heating regulation method of the electronic atomization device comprises the steps of obtaining laser temperature sensing parameters of a laser heating cup of the electronic atomization device; performing temperature detection gauge difference processing on the laser temperature sensing parameters and preset temperature sensing parameters to obtain laser temperature gauge difference; and sending a dimming power signal to a laser heater of the electronic atomization device according to the laser temperature meter difference so as to adjust the laser heating temperature of a laser heating cup of the electronic atomization device. The laser temperature sensing parameters are acquired to acquire the current laser heating temperature condition of the laser heating cup, then the laser temperature sensing parameters and the preset temperature sensing parameters are correspondingly processed to obtain the laser heating state difference degree between the laser temperature sensing parameters and the preset temperature sensing parameters, finally, the dimming power signals are correspondingly sent according to the laser heating state difference condition, so that the laser heating temperature of the laser heating cup is conveniently adjusted, the heating temperature of a medium to be atomized in the laser heating cup is controlled, and the laser heating temperature stability is effectively improved.

Fig. 1 is a flowchart of a laser heating control method of an electronic atomization device according to an embodiment of the disclosure. The laser heating regulation and control method comprises part or all of the following steps.

S100: and obtaining laser temperature sensing parameters of a laser heating cup of the electronic atomization device.

In this embodiment, the laser temperature sensing parameter is a laser heating induction temperature of a laser heating cup of the electronic atomization device, that is, the laser temperature sensing parameter is a heating temperature of the laser heating cup of the electronic atomization device under laser irradiation, that is, the laser temperature sensing parameter is a cup body induction heating temperature of the laser heating cup of the electronic atomization device after laser heating. The surface temperature of the laser heating cup of the electronic atomization device is conveniently determined by collecting the laser temperature sensing parameters, namely sampling the surface temperature which changes due to the current laser irradiation of the laser heating cup of the electronic atomization device, so that the heating temperature of a medium to be atomized in the laser heating cup of the electronic atomization device is conveniently determined.

S200: and performing temperature detection gauge difference processing on the laser temperature sensing parameters and preset temperature sensing parameters to obtain laser temperature gauge difference.

In this embodiment, the laser temperature sensing parameter is a laser heating induction temperature of a laser heating cup of the electronic atomization device, that is, the laser temperature sensing parameter is a heating temperature of the laser heating cup of the electronic atomization device under laser irradiation, that is, the laser temperature sensing parameter is a cup body induction heating temperature of the laser heating cup of the electronic atomization device after laser heating. The surface temperature of the laser heating cup of the electronic atomization device is conveniently determined by collecting the laser temperature sensing parameters, namely sampling the surface temperature which changes due to the current laser irradiation of the laser heating cup of the electronic atomization device, so that the heating temperature of a medium to be atomized in the laser heating cup of the electronic atomization device is conveniently determined. The preset temperature sensing parameter is the standard induction temperature of the laser heating cup of the electronic atomization device, namely the preset temperature sensing parameter is the reference heating temperature of the laser heating cup of the electronic atomization device under laser irradiation, namely the preset temperature sensing parameter is the specified induction heating temperature of the cup body of the laser heating cup of the electronic atomization device after laser heating. And performing temperature detection gauge difference processing on the laser temperature sensing parameters and the preset temperature sensing parameters to determine the difference degree between the laser heating induction temperature of the laser heating cup of the electronic atomization device and the standard temperature, so that the difference condition of the surface temperature of the laser heating cup of the electronic atomization device is convenient to determine.

S300: and sending a dimming power signal to a laser heater of the electronic atomization device according to the laser temperature meter difference so as to adjust the laser heating temperature of a laser heating cup of the electronic atomization device.

In this embodiment, the laser temperature gauge difference is obtained based on the laser temperature sensing parameter and the preset temperature sensing parameter, where the laser temperature sensing parameter is a laser heating induction temperature of a laser heating cup of the electronic atomization device, that is, the laser temperature sensing parameter is a heating temperature of the laser heating cup of the electronic atomization device under laser irradiation, that is, the laser temperature sensing parameter is a cup body induction heating temperature of the laser heating cup of the electronic atomization device after laser heating. The surface temperature of the laser heating cup of the electronic atomization device is conveniently determined by collecting the laser temperature sensing parameters, namely sampling the surface temperature which changes due to the current laser irradiation of the laser heating cup of the electronic atomization device, so that the heating temperature of a medium to be atomized in the laser heating cup of the electronic atomization device is conveniently determined. The preset temperature sensing parameter is the standard induction temperature of the laser heating cup of the electronic atomization device, namely the preset temperature sensing parameter is the reference heating temperature of the laser heating cup of the electronic atomization device under laser irradiation, namely the preset temperature sensing parameter is the specified induction heating temperature of the cup body of the laser heating cup of the electronic atomization device after laser heating. And performing temperature detection gauge difference processing on the laser temperature sensing parameters and the preset temperature sensing parameters to determine the difference degree between the laser heating induction temperature of the laser heating cup of the electronic atomization device and the standard temperature, so that the difference condition of the surface temperature of the laser heating cup of the electronic atomization device is convenient to determine. After the laser thermometer difference is obtained, whether the current surface temperature of the laser heating cup of the electronic atomization device reaches the specified heating temperature is determined, so that the cup temperature change condition of the laser heating cup of the electronic atomization device during laser heating is determined, the luminous power of the laser heater can be conveniently adjusted according to the laser heating temperature difference condition, and the laser heating temperature of the laser heating cup can be conveniently adjusted.

In the above embodiment, the current laser heating temperature condition of the laser heating cup is collected by acquiring the laser temperature sensing parameter, then the laser temperature sensing parameter and the preset temperature sensing parameter are correspondingly processed to obtain the laser heating state difference degree between the two, and finally the dimming power signal is correspondingly sent according to the laser heating state difference condition, so that the laser heating temperature of the laser heating cup is conveniently adjusted, the heating temperature of the medium to be atomized in the laser heating cup is controlled, and the laser heating temperature stability is effectively improved.

In one embodiment, the acquiring the laser temperature sensing parameter of the laser heating cup of the electronic atomization device includes: and acquiring the infrared thermal electromotive force of the laser heating cup of the electronic atomization device. In this embodiment, the laser temperature sensing parameter is a laser heating induction temperature of a laser heating cup of the electronic atomization device, that is, the laser temperature sensing parameter is a heating temperature of the laser heating cup of the electronic atomization device under laser irradiation, that is, the laser temperature sensing parameter is a cup body induction heating temperature of the laser heating cup of the electronic atomization device after laser heating. The surface temperature of the laser heating cup of the electronic atomization device is conveniently determined by collecting the laser temperature sensing parameters, namely sampling the surface temperature which changes due to the current laser irradiation of the laser heating cup of the electronic atomization device, so that the heating temperature of a medium to be atomized in the laser heating cup of the electronic atomization device is conveniently determined. The laser temperature sensing parameters comprise infrared thermal electromotive force of the laser heating cup of the electronic atomization device, the infrared thermal electromotive force is infrared induction electromotive force after laser heating of the laser heating cup of the electronic atomization device, specifically, the infrared thermal electromotive force is thermal electromotive force collected by the infrared sensor after laser heating of the laser heating cup of the electronic atomization device, the integral temperature of the laser heating cup is determined through the infrared induction electromotive force, and the surface temperature of the laser heating cup of the electronic atomization device, which changes after laser heating, is convenient to determine.

Further, the performing temperature detection table difference processing on the laser temperature sensing parameter and the preset temperature sensing parameter to obtain a laser temperature table difference, including: and obtaining the difference value between the infrared thermal electromotive force and the preset thermal electromotive force to obtain the laser infrared temperature difference. In this embodiment, the laser temperature sensing parameter is a laser heating induction temperature of a laser heating cup of the electronic atomization device, that is, the laser temperature sensing parameter is a heating temperature of the laser heating cup of the electronic atomization device under laser irradiation, that is, the laser temperature sensing parameter is a cup body induction heating temperature of the laser heating cup of the electronic atomization device after laser heating. The surface temperature of the laser heating cup of the electronic atomization device is conveniently determined by collecting the laser temperature sensing parameters, namely sampling the surface temperature which changes due to the current laser irradiation of the laser heating cup of the electronic atomization device, so that the heating temperature of a medium to be atomized in the laser heating cup of the electronic atomization device is conveniently determined. The preset temperature sensing parameter is the standard induction temperature of the laser heating cup of the electronic atomization device, namely the preset temperature sensing parameter is the reference heating temperature of the laser heating cup of the electronic atomization device under laser irradiation, namely the preset temperature sensing parameter is the specified induction heating temperature of the cup body of the laser heating cup of the electronic atomization device after laser heating. And performing temperature detection gauge difference processing on the laser temperature sensing parameters and the preset temperature sensing parameters to determine the difference degree between the laser heating induction temperature of the laser heating cup of the electronic atomization device and the standard temperature, so that the difference condition of the surface temperature of the laser heating cup of the electronic atomization device is convenient to determine. The laser temperature sensing parameters comprise infrared thermal electromotive force of the laser heating cup of the electronic atomization device, the infrared thermal electromotive force is infrared induction electromotive force after laser heating of the laser heating cup of the electronic atomization device, specifically, the infrared thermal electromotive force is thermal electromotive force collected by the infrared sensor after laser heating of the laser heating cup of the electronic atomization device, the integral temperature of the laser heating cup is determined through the infrared induction electromotive force, and the surface temperature of the laser heating cup of the electronic atomization device, which changes after laser heating, is convenient to determine. And solving the difference value of the infrared thermal electromotive force and the preset thermal electromotive force, so as to conveniently determine the surface infrared temperature difference degree of the laser heating cup of the electronic atomization device, thereby conveniently determining the infrared temperature difference condition of the laser heating cup of the electronic atomization device after laser heating.

Still further, the sending a dimming power signal to a laser heater of the electronic atomization device according to the laser temperature meter difference to adjust a laser heating temperature of a laser heating cup of the electronic atomization device includes: detecting whether the laser infrared temperature difference is larger than or equal to a preset infrared temperature difference; and when the laser infrared temperature difference is larger than or equal to the preset infrared temperature difference, sending a dimming power-reducing signal to the laser heater. In this embodiment, the laser temperature gauge difference is obtained based on the laser temperature sensing parameter and the preset temperature sensing parameter, where the laser temperature sensing parameter is a laser heating induction temperature of a laser heating cup of the electronic atomization device, that is, the laser temperature sensing parameter is a heating temperature of the laser heating cup of the electronic atomization device under laser irradiation, that is, the laser temperature sensing parameter is a cup body induction heating temperature of the laser heating cup of the electronic atomization device after laser heating. The surface temperature of the laser heating cup of the electronic atomization device is conveniently determined by collecting the laser temperature sensing parameters, namely sampling the surface temperature which changes due to the current laser irradiation of the laser heating cup of the electronic atomization device, so that the heating temperature of a medium to be atomized in the laser heating cup of the electronic atomization device is conveniently determined. The preset temperature sensing parameter is the standard induction temperature of the laser heating cup of the electronic atomization device, namely the preset temperature sensing parameter is the reference heating temperature of the laser heating cup of the electronic atomization device under laser irradiation, namely the preset temperature sensing parameter is the specified induction heating temperature of the cup body of the laser heating cup of the electronic atomization device after laser heating. And performing temperature detection gauge difference processing on the laser temperature sensing parameters and the preset temperature sensing parameters to determine the difference degree between the laser heating induction temperature of the laser heating cup of the electronic atomization device and the standard temperature, so that the difference condition of the surface temperature of the laser heating cup of the electronic atomization device is convenient to determine. After the laser thermometer difference is obtained, whether the current surface temperature of the laser heating cup of the electronic atomization device reaches the specified heating temperature is determined, so that the cup temperature change condition of the laser heating cup of the electronic atomization device during laser heating is determined, the luminous power of the laser heater can be conveniently adjusted according to the laser heating temperature difference condition, and the laser heating temperature of the laser heating cup can be conveniently adjusted. The laser temperature sensing parameters comprise infrared thermal electromotive force of the laser heating cup of the electronic atomization device, the infrared thermal electromotive force is infrared induction electromotive force after laser heating of the laser heating cup of the electronic atomization device, specifically, the infrared thermal electromotive force is thermal electromotive force collected by the infrared sensor after laser heating of the laser heating cup of the electronic atomization device, the integral temperature of the laser heating cup is determined through the infrared induction electromotive force, and the surface temperature of the laser heating cup of the electronic atomization device, which changes after laser heating, is convenient to determine. And solving the difference value of the infrared thermal electromotive force and the preset thermal electromotive force, so as to conveniently determine the surface infrared temperature difference degree of the laser heating cup of the electronic atomization device, thereby conveniently determining the infrared temperature difference condition of the laser heating cup of the electronic atomization device after laser heating. The laser infrared temperature difference is larger than or equal to the preset infrared temperature difference, so that the condition that the effective components of the medium to be atomized in the laser heating cup fail due to the fact that the atomization temperature is too high is indicated, at the moment, a dimming power-reducing signal is sent to the laser heater, so that the luminous power of the laser heater is reduced, the surface infrared temperature of the laser heating cup of the electronic atomization device is reduced, and the condition that the effective components of the medium to be atomized in the laser heating cup fail due to the fact that the atomization temperature is too high is avoided.

In another embodiment, when the laser infrared temperature difference is smaller than the preset infrared temperature difference, a dimming power-up signal is sent to the laser heater so as to increase the luminous power of the laser heater, so that the temperature of the laser heating cup is increased, and atomizing heating of the medium to be atomized in the laser heating cup is facilitated.

In one embodiment, the acquiring the laser temperature sensing parameter of the laser heating cup of the electronic atomization device includes: and obtaining the thermocouple heat radiation intensity of the laser heating cup of the electronic atomization device. In this embodiment, the laser temperature sensing parameter is a laser heating induction temperature of a laser heating cup of the electronic atomization device, that is, the laser temperature sensing parameter is a heating temperature of the laser heating cup of the electronic atomization device under laser irradiation, that is, the laser temperature sensing parameter is a cup body induction heating temperature of the laser heating cup of the electronic atomization device after laser heating. The surface temperature of the laser heating cup of the electronic atomization device is conveniently determined by collecting the laser temperature sensing parameters, namely sampling the surface temperature which changes due to the current laser irradiation of the laser heating cup of the electronic atomization device, so that the heating temperature of a medium to be atomized in the laser heating cup of the electronic atomization device is conveniently determined. The laser temperature sensing parameters comprise the thermocouple heat radiation intensity of the laser heating cup of the electronic atomization device, wherein the thermocouple heat radiation intensity is the thermocouple induction heat degree of the laser heating cup of the electronic atomization device after laser heating, specifically, the thermocouple heat radiation intensity is the heat receiving amount of the laser heating cup of the electronic atomization device, which is collected by an infrared sensor after laser heating, and the integral temperature of the laser heating cup is determined through the thermocouple induction heat degree, so that the surface temperature of the laser heating cup of the electronic atomization device, which is changed after laser heating, is convenient to determine.

Further, the performing temperature detection table difference processing on the laser temperature sensing parameter and the preset temperature sensing parameter to obtain a laser temperature table difference, including: and obtaining a difference value between the thermocouple heat radiation intensity and the preset heat radiation intensity to obtain a laser radiation heat quantity difference. In this embodiment, the laser temperature sensing parameter is a laser heating induction temperature of a laser heating cup of the electronic atomization device, that is, the laser temperature sensing parameter is a heating temperature of the laser heating cup of the electronic atomization device under laser irradiation, that is, the laser temperature sensing parameter is a cup body induction heating temperature of the laser heating cup of the electronic atomization device after laser heating. The surface temperature of the laser heating cup of the electronic atomization device is conveniently determined by collecting the laser temperature sensing parameters, namely sampling the surface temperature which changes due to the current laser irradiation of the laser heating cup of the electronic atomization device, so that the heating temperature of a medium to be atomized in the laser heating cup of the electronic atomization device is conveniently determined. The preset temperature sensing parameter is the standard induction temperature of the laser heating cup of the electronic atomization device, namely the preset temperature sensing parameter is the reference heating temperature of the laser heating cup of the electronic atomization device under laser irradiation, namely the preset temperature sensing parameter is the specified induction heating temperature of the cup body of the laser heating cup of the electronic atomization device after laser heating. And performing temperature detection gauge difference processing on the laser temperature sensing parameters and the preset temperature sensing parameters to determine the difference degree between the laser heating induction temperature of the laser heating cup of the electronic atomization device and the standard temperature, so that the difference condition of the surface temperature of the laser heating cup of the electronic atomization device is convenient to determine. The laser temperature sensing parameters comprise the thermocouple heat radiation intensity of the laser heating cup of the electronic atomization device, wherein the thermocouple heat radiation intensity is the thermocouple induction heat degree of the laser heating cup of the electronic atomization device after laser heating, specifically, the thermocouple heat radiation intensity is the heat receiving amount of the laser heating cup of the electronic atomization device, which is collected by an infrared sensor after laser heating, and the integral temperature of the laser heating cup is determined through the thermocouple induction heat degree, so that the surface temperature of the laser heating cup of the electronic atomization device, which is changed after laser heating, is convenient to determine. And solving the difference value between the thermocouple heat radiation intensity and the preset heat radiation intensity, so as to be convenient for determining the degree of difference of the heat radiation on the surface of the laser heating cup of the electronic atomization device, thereby being convenient for determining the thermocouple induction temperature difference condition of the laser heating cup of the electronic atomization device after laser heating.

Still further, the sending a dimming power signal to a laser heater of the electronic atomization device according to the laser temperature meter difference to adjust a laser heating temperature of a laser heating cup of the electronic atomization device includes: detecting whether the laser radiation heat difference is smaller than a preset thermocouple heat difference or not; and when the laser radiation heat quantity difference is smaller than the preset couple heat difference, sending a dimming power-up signal to the laser heater. In this embodiment, the laser temperature gauge difference is obtained based on the laser temperature sensing parameter and the preset temperature sensing parameter, where the laser temperature sensing parameter is a laser heating induction temperature of a laser heating cup of the electronic atomization device, that is, the laser temperature sensing parameter is a heating temperature of the laser heating cup of the electronic atomization device under laser irradiation, that is, the laser temperature sensing parameter is a cup body induction heating temperature of the laser heating cup of the electronic atomization device after laser heating. The surface temperature of the laser heating cup of the electronic atomization device is conveniently determined by collecting the laser temperature sensing parameters, namely sampling the surface temperature which changes due to the current laser irradiation of the laser heating cup of the electronic atomization device, so that the heating temperature of a medium to be atomized in the laser heating cup of the electronic atomization device is conveniently determined. The preset temperature sensing parameter is the standard induction temperature of the laser heating cup of the electronic atomization device, namely the preset temperature sensing parameter is the reference heating temperature of the laser heating cup of the electronic atomization device under laser irradiation, namely the preset temperature sensing parameter is the specified induction heating temperature of the cup body of the laser heating cup of the electronic atomization device after laser heating. And performing temperature detection gauge difference processing on the laser temperature sensing parameters and the preset temperature sensing parameters to determine the difference degree between the laser heating induction temperature of the laser heating cup of the electronic atomization device and the standard temperature, so that the difference condition of the surface temperature of the laser heating cup of the electronic atomization device is convenient to determine. After the laser thermometer difference is obtained, whether the current surface temperature of the laser heating cup of the electronic atomization device reaches the specified heating temperature is determined, so that the cup temperature change condition of the laser heating cup of the electronic atomization device during laser heating is determined, the luminous power of the laser heater can be conveniently adjusted according to the laser heating temperature difference condition, and the laser heating temperature of the laser heating cup can be conveniently adjusted. The laser temperature sensing parameters comprise the thermocouple heat radiation intensity of the laser heating cup of the electronic atomization device, wherein the thermocouple heat radiation intensity is the thermocouple induction heat degree of the laser heating cup of the electronic atomization device after laser heating, specifically, the thermocouple heat radiation intensity is the heat receiving amount of the laser heating cup of the electronic atomization device, which is collected by an infrared sensor after laser heating, and the integral temperature of the laser heating cup is determined through the thermocouple induction heat degree, so that the surface temperature of the laser heating cup of the electronic atomization device, which is changed after laser heating, is convenient to determine. And solving the difference value between the thermocouple heat radiation intensity and the preset heat radiation intensity, so as to conveniently determine the degree of the difference of the surface thermocouple induction temperature of the laser heating cup of the electronic atomization device, thereby conveniently determining the temperature difference condition of the laser heating cup of the electronic atomization device after laser heating. The laser radiation heat quantity difference is smaller than the preset couple heat difference, which indicates that the surface couple induction temperature of the laser heating cup of the electronic atomization device is too low, and at the moment, a dimming power-up signal is sent to the laser heater, so that the luminous power of the laser heater is increased, the surface infrared temperature of the laser heating cup of the electronic atomization device is increased, and the temperature of a medium to be atomized in the laser heating cup is ensured to be within a proper atomization temperature.

In another embodiment, when the laser radiation heat quantity difference is greater than or equal to the preset couple heat difference, a dimming power-down signal is sent to the laser heater so as to reduce the light-emitting power of the laser heater, so that the temperature of the laser heating cup is reduced, and atomization heating of the medium to be atomized in the laser heating cup is facilitated.

In the actual heating process of the laser heating cup of the electronic atomization device, the heating of the laser heating cup of the electronic atomization device is realized through the laser irradiation emitted by the laser heater, the laser heater emits laser to the laser heating cup through an internal laser emitting chip, and particularly, the laser emitted by the laser chip in the electronic atomization device irradiates on the laser heating cup, so that the laser heating cup is convenient for carrying out atomization heating on a medium to be atomized stored in the laser heating cup.

However, the laser emission chip of the laser heater heats the medium to be atomized in a non-contact manner, so that the light-emitting energy of the laser emission chip is large, and the heat aggregation around the light-emitting end of the laser emission chip is increased, so that the laser emission chip is easy to burn out.

In order to improve the stability and safety of the laser heating cup, the method sends a dimming power signal to a laser heater of the electronic atomization device according to the laser temperature meter difference so as to adjust the laser heating temperature of the laser heating cup of the electronic atomization device, and the method further comprises the following steps:

acquiring the heat of the end point of the laser chip of the laser heater;

detecting whether the endpoint heat of the laser chip is larger than or equal to the preset endpoint heat;

and when the endpoint heat of the laser chip is greater than or equal to the preset endpoint heat, feeding back a thermal recovery alarm signal to the laser heater.

In this embodiment, the heat of the end point of the laser chip is the light-emitting heat of the laser emitting chip in the laser heater, that is, the heat of the end point of the laser chip is the heat of the emitting end of the laser emitting chip in the laser heater, that is, the heat of the end point of the laser chip corresponds to the thermodynamic system balance of the emitting end of the laser emitting chip in the laser heater. The terminal point heat of the laser chip is larger than or equal to the preset terminal point heat, the fact that the heat of the transmitting end of the laser transmitting chip in the laser heater is overlarge is shown, namely that the thermodynamic balance of the transmitting end of the laser transmitting chip in the laser heater is broken, namely that the heat balance unbalance condition of the transmitting end appears on the surface of the laser transmitting chip in the laser heater, at the moment, the situation that the heat of the laser transmitting chip in the laser heater instantaneously rises is shown, and the current situation of heat shock appearing on the laser transmitting chip is conveniently and timely alarmed by feeding back a thermal acquisition alarm signal to the laser heater, so that the probability of burning out of the laser transmitting chip due to overheat of the transmitting end is effectively reduced, and the normal operation of the laser transmitting chip is ensured.

In another embodiment, when the laser chip endpoint heat is less than a preset endpoint heat, step S300 is performed.

Further, when the end point heat of the laser chip is greater than or equal to the preset end point heat, a thermal recovery alarm signal is fed back to the laser heater, and then the method further comprises the following steps:

acquiring the alarm duration time of the laser heater;

detecting whether the alarm duration is less than a preset duration;

and when the alarm duration is smaller than the preset duration, feeding back a double-pass alternating signal to the laser heater.

In this embodiment, the alarm duration is an alarm time when the laser emission chip generates abnormal heat at the emission end, that is, the alarm duration is a time before the laser emission chip is turned off, that is, the alarm duration is a time when the laser emission chip continuously generates abnormal heat at the emission end. The alarm duration is smaller than the preset duration, the duration of abnormal heat of the emitting end of the laser emitting chip is indicated to be within the allowable abnormal time, namely, the emitting end of the laser emitting chip is indicated to be in an abnormal state before being closed, namely, the laser emitting chip is also indicated to be in a process of waiting for a closing signal, at the moment, in order to reduce the abnormal heat of the laser emitting chip, a double-pass alternating signal is fed back to the laser heater, so that the auxiliary laser emitting chip in the laser heater is started, the laser heater works in a double-chip mode, and in addition, the two chips are operated in an alternating emitting mode, specifically, the duty ratio of PWM driving signals of the two laser chips is adjusted to be 50%, so that the laser heating of the double channels is realized, the damage probability of the laser emitting chip before the laser heater is closed is effectively reduced, and the heating speed and the efficiency of the laser heating temperature of the laser heating cup are also improved.

Still further, the detecting whether the alarm duration is less than a preset duration further includes:

and when the alarm duration is greater than or equal to the preset duration, feeding back a single-channel emission signal to the laser heater.

In this embodiment, the alarm duration is greater than or equal to the preset duration, which indicates that the duration of occurrence of abnormal heat of the transmitting end of the laser transmitting chip is outside the allowable abnormal time, that is, indicates that the transmitting end of the laser transmitting chip is still in an abnormal state that is not closed, that is, indicates that the laser transmitting chip is still waiting for a closing signal and exceeds the allowable closing time. In order to avoid the situation that the laser emission chip cannot be closed, the laser irradiation is continuously performed according to the previous mode, so that the laser emission chip outputs laser in a single channel by feeding back a single-channel emission signal to the laser heater, specifically, the laser emission chip is in a single-frequency laser emission mode, the laser emitted by the laser emission chip is in a single frequency, the duty ratio of the PWM driving signal of the laser emission chip is maintained at 10-15%, and the laser emission chip is in a working mode under standby power consumption, namely, the emission power at the initial start-up time, so that the probability of damaging the laser emission chip is further reduced.

The above-mentioned various preset variables all set up in the database, are convenient for in time draw, and different preset variables are put in different memory cell, namely in different storage stacks, and laser chip endpoint heat and warning duration accessible corresponding detector gathers, for example, gathers through the calorimeter and the time-recorder in the laser temperature sense collection module.

In one embodiment, the disclosure further provides a laser heating regulation and control device, which comprises a laser temperature sensing acquisition module, a laser temperature sensing processing module and a laser power regulation output module; the laser temperature sensing acquisition module is used for acquiring laser temperature sensing parameters of a laser heating cup of the electronic atomization device; the laser temperature sensing processing module is used for performing temperature detection gauge difference processing on the laser temperature sensing parameters and preset temperature sensing parameters to obtain laser temperature gauge difference; the laser power adjusting output module is used for sending a power adjusting signal to a laser heater of the electronic atomization device according to the laser temperature meter difference so as to adjust the laser heating temperature of a laser heating cup of the electronic atomization device.

In this embodiment, the laser temperature sensing acquisition module acquires the laser temperature sensing parameters to acquire the current laser heating temperature condition of the laser heating cup, then the laser temperature sensing processing module correspondingly processes the laser temperature sensing parameters and the preset temperature sensing parameters to obtain the laser heating state difference degree between the laser temperature sensing parameters and the preset temperature sensing parameters, and finally the laser power adjustment output module correspondingly sends a power adjustment signal according to the laser heating state difference condition, so that the laser heating temperature of the laser heating cup is conveniently adjusted, the heating temperature of a medium to be atomized in the laser heating cup is controlled, and the laser heating temperature stability is effectively improved.

In one embodiment, a computer device is provided, which may be a server, the internal structure of which may be as shown in FIG. 2. The computer device includes a processor, a memory, and a network interface connected by a system bus. Wherein the processor of the computer device is configured to provide computing and control capabilities. The memory of the computer device includes a non-volatile storage medium and an internal memory. The non-volatile storage medium stores an operating system, computer programs, and a database. The internal memory provides an environment for the operation of the operating system and computer programs in the non-volatile storage media. The database of the computer equipment is used for storing laser temperature sensing parameters, preset temperature sensing parameters, dimming power signals and other data. The network interface of the computer device is used for communicating with an external terminal through a network connection. The computer program is executed by a processor to implement a laser heating regulation method.

Those skilled in the art will appreciate that the architecture shown in fig. 2 is merely a block diagram of some of the architecture relevant to the disclosed aspects and is not limiting of the computer device to which the disclosed aspects apply, and that a particular computer device may include more or fewer components than shown, or may combine some of the components, or have a different arrangement of components.

In one embodiment, the present disclosure further provides a computer device, including a memory and a processor, where the memory stores a computer program, and the processor implements the steps of the method embodiments described above when the processor executes the computer program.

In one embodiment, the present disclosure also provides a computer-readable storage medium having stored thereon a computer program which, when executed by a processor, performs the steps of the method embodiments described above.

Those skilled in the art will appreciate that implementing all or part of the above described methods may be accomplished by way of a computer program stored on a non-transitory computer readable storage medium, which when executed, may comprise the steps of the embodiments of the methods described above. Any reference to memory, storage, database, or other medium used in embodiments provided by the present disclosure may include at least one of non-volatile and volatile memory, among others. The nonvolatile Memory may include Read-Only Memory (ROM), magnetic tape, floppy disk, flash Memory, optical Memory, or the like. Volatile memory can include random access memory (Random Access Memory, RAM) or external cache memory. By way of illustration, and not limitation, RAM can be in the form of a variety of forms, such as static random access memory (Static Random Access Memory, SRAM) or dynamic random access memory (Dynamic Random Access Memory, DRAM), and the like.

The foregoing examples represent only a few embodiments of the present disclosure, which are described in more detail and are not to be construed as limiting the scope of the invention. It should be noted that variations and modifications can be made by those skilled in the art without departing from the spirit of the disclosure, which are within the scope of the disclosure. Accordingly, the scope of protection of the present disclosure should be determined by the following claims.

Claims (10)

1. The laser heating regulation and control method of the electronic atomization device is characterized by comprising the following steps of:

acquiring laser temperature sensing parameters of a laser heating cup of the electronic atomization device;

performing temperature detection gauge difference processing on the laser temperature sensing parameters and preset temperature sensing parameters to obtain laser temperature gauge difference;

and sending a dimming power signal to a laser heater of the atomization heating system according to the laser temperature meter difference so as to adjust the laser heating temperature of the laser heating cup of the electronic atomization device.

2. The method for adjusting and controlling laser heating of an electronic atomizing device according to claim 1, wherein the step of obtaining the laser temperature sensing parameter of the laser heating cup of the electronic atomizing device comprises the steps of:

And acquiring the infrared thermal electromotive force of the laser heating cup of the electronic atomization device.

3. The method for adjusting and controlling laser heating of an electronic atomizing device according to claim 2, wherein the performing temperature-sensing table difference processing on the laser temperature-sensing parameter and a preset temperature-sensing parameter to obtain a laser temperature-sensing table difference comprises:

and obtaining the difference value between the infrared thermal electromotive force and the preset thermal electromotive force to obtain the laser infrared temperature difference.

4. The method for controlling laser heating of an electronic atomizing device according to claim 3, wherein the sending a light power adjusting signal to a laser heater of an atomizing heating system according to the laser temperature meter difference to adjust a laser heating temperature of a laser heating cup of the electronic atomizing device comprises:

detecting whether the laser infrared temperature difference is larger than or equal to a preset infrared temperature difference;

and when the laser infrared temperature difference is larger than or equal to the preset infrared temperature difference, sending a dimming power-reducing signal to the laser heater.

5. The method for adjusting and controlling laser heating of an electronic atomizing device according to claim 1, wherein the step of obtaining the laser temperature sensing parameter of the laser heating cup of the electronic atomizing device comprises the steps of:

And obtaining the thermocouple heat radiation intensity of the laser heating cup of the electronic atomization device.

6. The method for adjusting and controlling laser heating of an electronic atomizing device according to claim 5, wherein the performing temperature-sensing table difference processing on the laser temperature-sensing parameter and a preset temperature-sensing parameter to obtain a laser temperature-sensing table difference comprises:

and obtaining a difference value between the thermocouple heat radiation intensity and the preset heat radiation intensity to obtain a laser radiation heat quantity difference.

7. The method of claim 6, wherein the sending a light power adjustment signal to a laser heater of an atomization heating system according to the laser temperature meter delta to adjust a laser heating temperature of a laser heating cup of the electronic atomization device comprises:

detecting whether the laser radiation heat difference is smaller than a preset thermocouple heat difference or not;

and when the laser radiation heat quantity difference is smaller than the preset couple heat difference, sending a dimming power-up signal to the laser heater.

8. A laser heating regulation device, comprising:

the laser temperature sensing acquisition module is used for acquiring laser temperature sensing parameters of a laser heating cup of the electronic atomization device;

The laser temperature sensing processing module is used for performing temperature detection gauge difference processing on the laser temperature sensing parameters and preset temperature sensing parameters to obtain laser temperature gauge difference quantity;

and the laser power adjustment output module is used for sending a power adjustment signal to a laser heater of the electronic atomization device according to the laser temperature meter difference so as to adjust the laser heating temperature of a laser heating cup of the electronic atomization device.

9. A computer device comprising a memory and a processor, the memory storing a computer program, characterized in that the processor implements the steps of the method of any of claims 1 to 7 when the computer program is executed.

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