CN111672658A - Method for detecting and controlling optimal atomization temperature of electronic atomization equipment and electronic atomization equipment - Google Patents

Abstract

The invention discloses a method for detecting and controlling the optimal atomization temperature of electronic atomization equipment and the electronic atomization equipment, comprising the following steps: setting a light source component and a spectrum sensor component, and respectively carrying out spectrum detection on various sample solutions to obtain various calibration spectrum information; respectively testing the atomizers of the various sample solutions to obtain respective optimal atomization temperatures, and writing the corresponding relations into a microcontroller; the spectral sensor assembly performs spectral detection on the solution to be atomized to obtain detection spectral information; after the detection spectral information and various calibration spectral information are analyzed and compared, the solution to be atomized is determined to be consistent with any sample solution; further determining the optimal atomization temperature, adjusting the output power of the power control circuit by the microcontroller, and further adjusting the output power to achieve the optimal atomization temperature by detecting the atomization temperature and feeding the atomization temperature back to the microcontroller; the electronic atomization device has the beneficial effects that the electronic atomization device works at the optimal atomization temperature to obtain the best atomization effect.

Description

Method for detecting and controlling optimal atomization temperature of electronic atomization equipment and electronic atomization equipment

Technical Field

The invention relates to the technical field of electronic atomization equipment, in particular to a method for detecting and controlling the optimal atomization temperature of electronic atomization equipment and the electronic atomization equipment.

Background

The electronic atomization device comprises an electronic cigarette, a medical medicine atomization device and the like, and the basic task of the electronic atomization device is to provide a heating process and convert a solution such as tobacco juice or liquid medicine and the like stored in the electronic atomization device into vapor, aerosol, steam or electronic cigarette smoke and the like.

Electronic atomization devices typically include a power supply device and an atomizer. The user experiences to the use of electronic atomization equipment, and above all obtains good taste, and atomizing temperature's control is the electronic atomization equipment and produces the important factor of good effect, user's obtaining good taste.

The power supply device of the existing electronic atomization equipment can be adapted to atomizers of various solutions to be atomized with different tastes for use, and the components and contents of specific substances of the solutions with different tastes are different, so that the parameters of the solution such as the flowing property, the viscosity, the temperature characteristic and the like are completely different, the optimal atomization temperature is different when the solution is to achieve the best atomization effect, the control programs of the power supply device are the same, the power supply device cannot distinguish the atomizers with different tastes, and after the atomizers with different tastes are used, the power supply device of the electronic atomization equipment in the prior art still atomizes the solution at the same atomization temperature, so that the optimal atomization effect cannot be achieved, and a user cannot obtain the best atomization use experience.

Disclosure of Invention

The present invention is directed to a method for detecting and controlling an optimal atomization temperature of an electronic atomization apparatus and an electronic atomization apparatus thereof.

The technical scheme of the invention is realized as follows: a method for detecting and controlling the optimal atomization temperature of electronic atomization equipment comprises the following steps: a light source assembly and a spectrum sensor assembly are arranged in an interface which is used for inserting and connecting the insertion part of the atomizer on the power supply device, and spectrum detection is respectively carried out on various sample solutions of the atomizer to obtain various calibration spectrum information which is written into a microcontroller arranged in the power supply device; respectively testing the atomizers of the multiple sample solutions to obtain the respective optimal atomization temperatures of the multiple sample solutions, and writing the corresponding relations into the microcontroller; connecting the atomizer with a power supply device, and carrying out spectrum detection on the solution to be atomized in the atomizer by using the spectrum sensor assembly to obtain detection spectrum information; after the detection spectral information and the various calibration spectral information are analyzed and compared by the microcontroller, determining which sample solution is consistent with the solution to be atomized and used by the atomizer; the microcontroller further determines the optimal atomization temperature required by the solution to be atomized, adjusts the output power of the power control circuit to the atomization unit, and further adjusts the output power to reach the optimal atomization temperature by detecting the atomization temperature and feeding back to the microcontroller.

Preferably, the method further comprises the following steps: the atomization resistor is set as a thermistor, and a resistance value detection unit is arranged in the power supply device.

Preferably, the method further comprises the following steps: and presetting the corresponding relation between the resistance value of the atomization resistor and the temperature in the microcontroller.

Preferably, the method further comprises the following steps: and respectively arranging the light source assembly and the spectrum sensor assembly on the battery supports on two opposite sides in the interface.

Preferably, the method further comprises the following steps: the light source assembly and the spectrum sensor assembly are respectively arranged on the battery bracket at the same side in the interface, and a reflecting material is also arranged in the inserting part and used for reflecting light rays emitted by the light source assembly to the spectrum sensor assembly.

Preferably, the method further comprises the following steps: the housing of the plug-in part is entirely made of a light-transmitting material and serves as a light-transmitting window.

Preferably, the method further comprises the following steps: and the light emitted by the light source assembly is set as visible light, and the spectrum sensor assembly is set as a spectrum sensor assembly with visible light color.

Preferably, the method further comprises the following specific operation steps:

(1) the light source assembly and the spectrum sensor assembly are arranged in an interface of the power supply device, so that light rays emitted by the light source assembly can be received by the spectrum sensor assembly through the light transmitting window and the atomizer solution;

(2) respectively carrying out spectrum detection on the various sample solutions of the atomizer to obtain various calibration spectrum information and writing the calibration spectrum information into a microcontroller arranged in a power supply device;

(3) respectively testing the atomizers of the various sample solutions to obtain the respective optimal atomization temperatures of the various sample solutions and writing the corresponding relations into the microcontroller;

(4) setting other parameters of the electronic atomization equipment and initializing;

(5) judging whether the electronic atomization device is in a standby state, if so, entering the step (7), and if not, carrying out the next step;

(6) carrying out starting operation;

(7) the light source assembly and the spectrum sensor assembly are electrified to perform spectrum detection on the solution to be atomized in the atomizer to obtain detection spectrum information;

(8) the microcontroller analyzes and compares the detection spectrum information with the various calibration spectrum information;

(9) matching the detection spectral information with one of the plurality of calibration spectral information, and determining by the microcontroller which sample solution the solution to be atomized used by the atomizer is consistent with;

(10) according to the corresponding relation between the sample solution and the optimal atomization temperature, the optimal atomization temperature required by the solution to be atomized can be further determined through the microcontroller;

(11) according to the required optimal atomization temperature, the microcontroller adjusts the output power of the power control circuit, the atomization unit emits corresponding heat, and the atomization temperature changes;

(12) and by detecting the atomization temperature and feeding back to the microcontroller, the microcontroller further adjusts the output power to achieve the optimal atomization temperature.

Preferably, the method further comprises the following specific operation steps:

(1) the light source assembly and the spectrum sensor assembly are arranged in an interface of the power supply device, so that light rays emitted by the light source assembly can be received by the spectrum sensor assembly through the light transmitting window and the atomizer solution;

(2) respectively carrying out spectrum detection on the various sample solutions of the atomizer to obtain various calibration spectrum information and writing the calibration spectrum information into a microcontroller arranged in a power supply device;

(3) respectively testing the atomizers of the various sample solutions to obtain the respective optimal atomization temperatures of the various sample solutions and writing the corresponding relations into the microcontroller;

(4) writing the corresponding relation between the resistance value of the atomizing unit and the temperature into the microcontroller;

(5) setting other parameters of the electronic atomization equipment and initializing;

(6) judging whether the electronic atomization equipment is in a standby state, if so, entering the step, and if not, carrying out the next step;

(7) carrying out starting operation;

(8) the light source assembly and the spectrum sensor assembly are electrified to perform spectrum detection on the solution to be atomized in the atomizer to obtain detection spectrum information;

(9) the microcontroller analyzes and compares the detection spectrum information with the various calibration spectrum information;

(10) matching the detection spectral information with one of the plurality of calibration spectral information, and determining by the microcontroller which sample solution the solution to be atomized used by the atomizer is consistent with;

(11) according to the corresponding relation between the sample solution and the optimal atomization temperature, the optimal atomization temperature required by the solution to be atomized can be further determined through the microcontroller;

(12) according to the required optimal atomization temperature, the microcontroller adjusts the output power of the power control circuit, the atomization unit emits corresponding heat, the atomization temperature changes, and the resistance value of the atomization unit also changes;

(13) detecting the resistance value of the atomization unit through a resistance value detection unit;

(14) the microcontroller can determine the temperature of the resistor, namely the atomization temperature according to the measured resistance value of the resistor and the corresponding relation between the resistance value of the resistor and the temperature;

(15) and feeding back the atomization temperature to the microcontroller, wherein the microcontroller further adjusts the output power to achieve the optimal atomization temperature.

The other technical solution of the invention is as follows: an electronic atomization device for a method for detecting and controlling an optimal atomization temperature comprises an atomizer and a power supply device which are detachably connected, the atomizer comprises a mouthpiece part and a plug part, the power supply device comprises an interface for accommodating the plug part to be plugged and connected, a liquid storage cavity and an atomizing unit are arranged in the atomizer, the liquid storage cavity is filled with solution to be atomized, a light source component and a spectrum sensor component are arranged in the interface, a light-transmitting window made of light-transmitting material is arranged on the inserting part, the light emitted by the light source component can penetrate through the light-transmitting window and the solution to be atomized to be received by the spectrum sensor component, still be equipped with microcontroller and power control circuit in the power supply unit, power control circuit output power gives the atomizing unit, microcontroller includes memory cell, analysis comparing unit and the control unit.

The invention has the following beneficial effects: carry out spectral measurement through the spectral sensor subassembly that is equipped with to treat various materials that contain in the atomizing solution to spectral information and the spectral information that marks that record carry out the comparison, can analyze like this and obtain which kind of solution that the atomizer used, further confirm this kind treat the required best atomizing temperature of atomizing solution, microcontroller carries out power control according to this best atomizing temperature, the atomizing temperature that makes the atomizer reaches this best atomizing temperature, so that this atomizer obtains best atomization effect, make the user obtain the best taste of atomizing.

Drawings

FIG. 1 is a perspective exploded view of the electronic atomizer of the present invention;

FIG. 2 is a cross-sectional view of the power unit housing of the present invention;

FIG. 3 is a first cross-sectional view of the electronic atomizer device of the present invention;

FIG. 4 is a first perspective exploded view of the atomizer of the present invention;

FIG. 5 is a second cross-sectional view of the electronic atomizer device of the present invention;

FIG. 6 is a second perspective exploded view of the atomizer of the present invention;

FIG. 7 is a functional block diagram I of an electronic atomizer according to the present invention;

FIG. 8 is a first flowchart of a method for detecting and controlling an optimal atomization temperature of an electronic atomization device according to the present invention;

FIG. 9 is a second flowchart of the method for detecting and controlling the optimal atomization temperature of the electronic atomization device of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Example (b):

as shown in fig. 1-4, the electronic atomization device for implementing the method of the invention includes an atomizer 1 and a power supply device 2 that are detachably connected, where the atomizer 1 includes a mouthpiece portion 11 and a plug portion 10, the power supply device 2 includes a connector 20 for receiving the plug portion 10 to be inserted and connected, and a liquid storage chamber 12 and an atomization unit 13 are provided in the atomizer 1. Be equipped with light source subassembly 24 and spectral sensor subassembly 25 in the interface 20, be equipped with the light trap 100 that printing opacity material made on grafting portion 10, the light that light source subassembly 24 sent can see through light trap 100 and treat that atomized solution is received by spectral sensor subassembly 25.

As shown in fig. 7, the power supply apparatus 2 is further provided with a microcontroller 27 and a power control circuit 28, the microcontroller 27 includes a storage unit 271, an analysis and comparison unit 272, and a control unit 273, and the control unit 273 can send out a control signal, such as controlling the output power of the power control circuit 28, and the power control circuit 28 outputs the power to the atomization unit 13. The power control circuit outputs power to the atomizing unit 13, and the atomizing unit 13 generates heat to heat and atomize the solution 120 to be atomized. The liquid storage chamber 12 contains a solution 120 to be atomized, and the solution 120 to be atomized may be a liquid substance such as a liquid medicine or an electronic cigarette liquid.

In the invention, the sample solution is a solution which is used for sampling solutions to be atomized in atomizers with different taste models to be sold in advance, the atomizers with different taste models are stored with the solutions to be atomized with different tastes, solute components contained in the solutions to be atomized with different tastes are different, and therefore, the corresponding sample solution of each taste atomizer needs to be subjected to spectrum detection and calibration in advance so as to obtain calibration spectrum information.

As shown in fig. 1-4 and 7, the method for detecting and controlling the optimal atomization temperature of the electronic atomization device of the present embodiment includes: a light-transmitting window 100 made of a light-transmitting material is arranged on the inserting part 10, and a light source assembly 24 and a spectrum sensor assembly 25 are arranged on the interface 20, so that light rays (as shown by continuous arrows from left to right in fig. 3) emitted by the light source assembly 25 can be received by the spectrum sensor assembly 25 through the light-transmitting window 100 and the solution; respectively carrying out spectrum detection on various sample solutions of the atomizer 1 to obtain various calibration spectrum information, and writing the calibration spectrum information into a microcontroller arranged in the power supply device 1; respectively testing the atomizers of the various sample solutions to obtain the respective optimal atomization temperatures of the various sample solutions and writing the corresponding relations into a microcontroller; connecting the atomizer with a power supply device 1, and carrying out spectrum detection on the solution to be atomized in the atomizer 1 by a spectrum sensor assembly 25 to obtain detection spectrum information; after the detection spectral information and the various calibration spectral information are analyzed and compared by the microcontroller, determining the solution to be atomized used by the atomizer to be consistent with the sample solution; the microcontroller further determines the optimal atomization temperature required by the solution to be atomized, adjusts the output power of the power control circuit to the atomization unit 13, and further adjusts the output power to achieve the optimal atomization temperature by detecting the atomization temperature and feeding back the atomization temperature to the microcontroller.

The above-mentioned output to the resistance of atomizing unit 13 changes, makes the heat that the resistance of atomizing unit sent also change, and atomizing temperature changes thereupon, and when reaching best atomizing temperature, this atomizer reaches best atomization effect, and the taste that the user inhaled the steam fog is best.

As shown in fig. 1 to 4, the method for detecting and controlling an optimal atomization temperature of an electronic atomization apparatus according to this embodiment further includes: the light source assembly 24 and the spectral sensor assembly 25 are respectively disposed on the battery holders 26 at opposite sides within the interface 20.

As shown in fig. 5-6, in another embodiment, the method for detecting and controlling the optimal atomization temperature of the electronic atomization device further includes: the light source assembly 24 and the spectrum sensor assembly 25 are respectively disposed on the battery holder 26 at the same side in the interface 20, and the light-reflecting material 14 is further disposed in the inserting portion 10 for reflecting the light emitted from the light source assembly to the spectrum sensor assembly 26. The light source assembly 24 emits light from the lower portion at an incident angle, and the spectral sensor assembly 25 receives light reflected by the reflective material 14 from the upper portion at a reflection angle.

As shown in fig. 1 to 4, the method for detecting and controlling an optimal atomization temperature of an electronic atomization apparatus according to this embodiment further includes: the light-transmissive window 100 is formed by making the housing of the entire socket 10 of a light-transmissive material, i.e., the light-transmissive window 100 is formed by the housing of the entire socket 10, which is entirely made of a light-transmissive material.

As shown in fig. 1 to 4, the method for detecting and controlling an optimal atomization temperature of an electronic atomization apparatus according to this embodiment further includes: the light emitted from the light source unit 24 is set to visible light, and the spectrum sensor unit 25 is set to a spectrum sensor unit of visible light color.

As shown in fig. 1 to 8, the method for detecting and controlling the optimal atomization temperature of the electronic atomization device of the present embodiment further includes the following specific operation steps:

(1) during production, a light-transmitting window 100 made of light-transmitting materials is arranged on the insertion part 10 of the atomizer 1, and a light source assembly 24 and a spectrum sensor assembly 25 are arranged in the interface 20 of the power supply device 2, so that light rays emitted by the light source assembly 24 can penetrate through the light-transmitting window 100 and a solution to be atomized to be received by the spectrum sensor assembly 25;

(2) respectively carrying out spectrum detection on the multiple sample solutions of the atomizer 1 to obtain multiple calibration spectrum information, and writing the calibration spectrum information into a microcontroller arranged in the power supply device 2;

(3) respectively testing the atomizers of the various sample solutions to obtain the respective optimal atomization temperatures of the various sample solutions and writing the corresponding relations into the microcontroller;

(4) setting other parameters of the electronic atomization equipment and initializing;

(5) judging whether the electronic atomization device is in a standby state, if so, entering the step (7), and if not, carrying out the next step;

(6) carrying out starting operation;

(7) the light source component 24 and the spectrum sensor component 25 are electrified to carry out spectrum detection on the solution 120 to be atomized in the atomizer 1 to obtain detection spectrum information;

(8) the microcontroller 27 analyzes and compares the detected spectrum information with various calibration spectrum information;

(9) the detection spectrum information is matched with one of the plurality of calibration spectrum information, and the microcontroller 27 determines the solution to be atomized used by the atomizer to be consistent with which sample solution;

(10) according to the corresponding relation between the sample solution and the optimal atomization temperature, the optimal atomization temperature required by the solution to be atomized can be further determined through the microcontroller 27;

(11) according to the required optimal atomization temperature, the microcontroller 27 adjusts the output power of the power control circuit 28, the atomization unit 13 emits corresponding heat, and the atomization temperature changes;

(12) the microcontroller 27 further adjusts the output power to achieve the optimum atomization temperature by detecting the atomization temperature and feeding it back to the microcontroller.

The method for detecting the atomization temperature in the step (12) is to provide a temperature sensor in the atomization chamber (not shown) where the atomization unit 13 is located, and the temperature sensor directly detects the atomization temperature in the atomization chamber.

As shown in fig. 9, the method for detecting and controlling an optimal atomization temperature of an electronic atomization device according to another embodiment further includes the following specific operation steps:

(1) during production, a light-transmitting window 100 made of light-transmitting materials is arranged on the insertion part 10 of the atomizer 1, and a light source assembly 24 and a spectrum sensor assembly 25 are arranged in the interface 20 of the power supply device 2, so that light rays emitted by the light source assembly 24 can penetrate through the light-transmitting window 100 and a solution to be atomized to be received by the spectrum sensor assembly 25;

(2) respectively carrying out spectrum detection on the multiple sample solutions of the atomizer 1 to obtain multiple calibration spectrum information, and writing the calibration spectrum information into a microcontroller arranged in the power supply device 2;

(3) respectively testing the atomizers of the various sample solutions to obtain the respective optimal atomization temperatures of the various sample solutions and writing the corresponding relations into the microcontroller;

(4) writing the corresponding relation between the resistance value of the atomizing unit and the temperature into the microcontroller;

(5) setting other parameters of the electronic atomization equipment and initializing;

(6) judging whether the electronic atomization equipment is in a standby state, if so, entering the step, and if not, carrying out the next step;

(7) carrying out starting operation;

(8) the light source component 24 and the spectrum sensor component 25 are electrified to carry out spectrum detection on the solution 120 to be atomized in the atomizer 1 to obtain detection spectrum information;

(9) the microcontroller 27 analyzes and compares the detected spectrum information with various calibration spectrum information;

(10) the detection spectrum information is matched with one of the plurality of calibration spectrum information, and the microcontroller 27 determines the solution to be atomized used by the atomizer to be consistent with which sample solution;

(11) according to the corresponding relation between the sample solution and the optimal atomization temperature, the optimal atomization temperature required by the solution to be atomized can be further determined through the microcontroller 27;

(12) according to the required optimal atomization temperature, the microcontroller 27 adjusts the output power of the power control circuit 28, the atomization unit 13 generates corresponding heat, the atomization temperature changes, and the resistance value of the resistor of the atomization unit 13 also changes;

(13) detecting the resistance value of the atomization unit through a resistance value detection unit;

(14) the microcontroller 27 can determine the temperature of the resistor, namely the atomization temperature, according to the measured resistance value of the resistor and the corresponding relation between the resistance value of the resistor and the temperature;

(15) the atomization temperature is fed back to the microcontroller, which further adjusts the output power to achieve the optimum atomization temperature.

The above description is only for the preferred embodiment of the present invention, and the above specific embodiments are not intended to limit the present invention. Various modifications and alterations may occur to those skilled in the art without departing from the spirit and scope of the invention, and such modifications and alterations should be accorded the broadest interpretation so as to encompass all such modifications and alterations.

Claims (10)

1. A method for detecting and controlling the optimal atomization temperature of electronic atomization equipment is characterized by comprising the following steps: a light source assembly and a spectrum sensor assembly are arranged in an interface which is used for inserting and connecting the insertion part of the atomizer on the power supply device, and spectrum detection is respectively carried out on various sample solutions of the atomizer to obtain various calibration spectrum information which is written into a microcontroller arranged in the power supply device; respectively testing the atomizers of the multiple sample solutions to obtain the respective optimal atomization temperatures of the multiple sample solutions, and writing the corresponding relations into the microcontroller; connecting the atomizer with a power supply device, and carrying out spectrum detection on the solution to be atomized in the atomizer by using the spectrum sensor assembly to obtain detection spectrum information; after the detection spectral information and the various calibration spectral information are analyzed and compared by the microcontroller, determining which sample solution is consistent with the solution to be atomized and used by the atomizer; the microcontroller further determines the optimal atomization temperature required by the solution to be atomized, adjusts the output power of the power control circuit to the atomization unit, and further adjusts the output power to reach the optimal atomization temperature by detecting the atomization temperature and feeding back to the microcontroller.

2. The method for detecting and controlling the optimal atomization temperature of the electronic atomization device according to claim 1, further comprising: the atomization resistor is set as a thermistor, and a resistance value detection unit is arranged in the power supply device.

3. The method for detecting and controlling the optimal atomization temperature of the electronic atomization device according to claim 2, further comprising: and presetting the corresponding relation between the resistance value of the atomization resistor and the temperature in the microcontroller.

4. The method for detecting and controlling the optimal atomization temperature of the electronic atomization device according to claim 1, further comprising: and respectively arranging the light source assembly and the spectrum sensor assembly on the battery supports on two opposite sides in the interface.

5. The method for detecting and controlling the optimal atomization temperature of the electronic atomization device according to claim 1, further comprising: the light source assembly and the spectrum sensor assembly are respectively arranged on the battery bracket at the same side in the interface, and a reflecting material is also arranged in the inserting part and used for reflecting light rays emitted by the light source assembly to the spectrum sensor assembly.

6. The method for detecting and controlling the optimal atomization temperature of the electronic atomization device according to claim 1, further comprising: the housing of the plug-in part is entirely made of a light-transmitting material and serves as a light-transmitting window.

7. The method for detecting and controlling the optimal atomization temperature of the electronic atomization device according to claim 1, further comprising: and the light emitted by the light source assembly is set as visible light, and the spectrum sensor assembly is set as a spectrum sensor assembly with visible light color.

8. The method for detecting and controlling the optimal atomization temperature of the electronic atomization device according to claim 1, which is characterized by comprising the following specific operation steps:

(1) the light source assembly and the spectrum sensor assembly are arranged in an interface of the power supply device, so that light rays emitted by the light source assembly can be received by the spectrum sensor assembly through the light transmitting window and the atomizer solution;

(2) respectively carrying out spectrum detection on the various sample solutions of the atomizer to obtain various calibration spectrum information and writing the calibration spectrum information into a microcontroller arranged in a power supply device;

(3) respectively testing the atomizers of the various sample solutions to obtain the respective optimal atomization temperatures of the various sample solutions and writing the corresponding relations into the microcontroller;

(4) setting other parameters of the electronic atomization equipment and initializing;

(5) judging whether the electronic atomization device is in a standby state, if so, entering the step (7), and if not, carrying out the next step;

(6) carrying out starting operation;

(7) connecting the atomizer with a power supply device, and carrying out spectrum detection on the solution to be atomized in the atomizer by the spectrum sensor assembly to obtain detection spectrum information;

(8) the microcontroller analyzes and compares the detection spectrum information with the various calibration spectrum information;

(9) matching the detection spectral information with one of the plurality of calibration spectral information, and determining by the microcontroller which sample solution the solution to be atomized used by the atomizer is consistent with;

(10) according to the corresponding relation between the sample solution and the optimal atomization temperature, the optimal atomization temperature required by the solution to be atomized can be further determined through the microcontroller;

(11) according to the required optimal atomization temperature, the microcontroller adjusts the output power of the power control circuit, the atomization unit emits corresponding heat, and the atomization temperature changes;

(12) and by detecting the atomization temperature and feeding back to the microcontroller, the microcontroller further adjusts the output power to achieve the optimal atomization temperature.

9. The method for detecting and controlling the optimal atomization temperature of the electronic atomization device according to claim 3, which is characterized by comprising the following specific operation steps:

(1) the light source assembly and the spectrum sensor assembly are arranged in an interface of the power supply device, so that light rays emitted by the light source assembly can be received by the spectrum sensor assembly through the light transmitting window and the atomizer solution;

(2) respectively carrying out spectrum detection on the various sample solutions of the atomizer to obtain various calibration spectrum information and writing the calibration spectrum information into a microcontroller arranged in a power supply device;

(3) respectively testing the atomizers of the various sample solutions to obtain the respective optimal atomization temperatures of the various sample solutions and writing the corresponding relations into the microcontroller;

(4) writing the corresponding relation between the resistance value of the atomizing unit and the temperature into the microcontroller;

(5) setting other parameters of the electronic atomization equipment and initializing;

(6) judging whether the electronic atomization equipment is in a standby state, if so, entering the step, and if not, carrying out the next step;

(7) carrying out starting operation;

(8) connecting the atomizer with a power supply device, and carrying out spectrum detection on the solution to be atomized in the atomizer by the spectrum sensor assembly to obtain detection spectrum information;

(9) the microcontroller analyzes and compares the detection spectrum information with the various calibration spectrum information;

(10) matching the detection spectral information with one of the plurality of calibration spectral information, and determining by the microcontroller which sample solution the solution to be atomized used by the atomizer is consistent with;

(11) according to the corresponding relation between the sample solution and the optimal atomization temperature, the optimal atomization temperature required by the solution to be atomized can be further determined through the microcontroller;

(12) according to the required optimal atomization temperature, the microcontroller adjusts the output power of the power control circuit, the atomization unit emits corresponding heat, the atomization temperature changes, and the resistance value of the atomization unit also changes;

(13) detecting the resistance value of the atomization unit through a resistance value detection unit;

(14) the microcontroller can determine the temperature of the resistor, namely the atomization temperature according to the measured resistance value of the resistor and the corresponding relation between the resistance value of the resistor and the temperature;

(15) and feeding back the atomization temperature to the microcontroller, wherein the microcontroller further adjusts the output power to achieve the optimal atomization temperature.

10. An electronic atomisation device for carrying out the method according to claim 1 or 8 or 9, comprising a detachably connected atomiser and power supply means, the atomizer comprises a mouthpiece part and a plug part, the power supply device comprises an interface for accommodating the plug part to be plugged and connected, a liquid storage cavity and an atomizing unit are arranged in the atomizer, the liquid storage cavity is filled with solution to be atomized, a light source component and a spectrum sensor component are arranged in the interface, a light-transmitting window made of light-transmitting material is arranged on the inserting part, the light emitted by the light source component can penetrate through the light-transmitting window and the solution to be atomized to be received by the spectrum sensor component, still be equipped with microcontroller and power control circuit in the power supply unit, power control circuit output power gives the atomizing unit, microcontroller includes memory cell, analysis comparing unit and the control unit.

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