JP6879497B2 - Electronic cigarette appliances and their control methods, heat generation modules, electronic devices and storage media - Google Patents

Description

The present invention relates to the field of tobacco substitutes, and more particularly to electronic cigarette appliances and control methods thereof, heat generation modules, electronic devices and storage media.

An e-cigarette appliance that heats without burning is an electronic product that mimics a cigarette and has a cigarette-like appearance, smoke, taste and sensation. It is a product in which nicotine and the like are converted into vapor through means such as atomization and sucked by the user.

The heating element of an electronic cigarette appliance that heats without burning is a part that is easily damaged because it operates at a high temperature for a long period of time. It has a very short service life compared to other parts, and if the heating element is damaged, the entire product may have to be discarded.

The technical means provided by the present invention provides an e-cigarette appliance, the e-cigarette appliance comprising a device body and a heating module that are detachably connected. The heating module includes a storage chip and a heating element, and the storage chip stores the heat generation parameters, and the heat generation parameters are the correspondence between the resistance value of the heating element and the temperature. The appliance body includes a battery and a control unit , the control unit is coupled to the battery, and when the appliance body is electrically connected to the heating module, the control unit is used to obtain the heating parameters and heat generation based on the heating parameters. Control the heating of the body.

Other technical means provided by the present invention provide a heating module, which includes a storage chip and a heating element, the storage chip storing heat generation parameters, and the heating module electrically connected to the appliance body. When the heat generation parameter is provided to the instrument body, the instrument body heats and controls the heating element based on the heat generation parameter.

Other technical means provided by the present invention provide a method of controlling an e-cigarette appliance, the method being applied to an e-cigarette appliance, the e-cigarette appliance comprising a device body and a heating module that are detachably connected. .. In the control method, the heat generation parameter stored in the heat generation module is acquired, and the heat generation parameter is a step indicating the correspondence between the resistance value and the temperature of the heating element in the heat generation module, and the heating element is heated and controlled based on the heat generation parameter. Includes steps.

Other technical means provided by the present invention provide an electronic device, the electronic device including a memory, a processor, and instructions stored in the memory and executed by the electronic device operating on the processor. The electronic device is made to execute a command to realize the above-mentioned control method.

Other technical means adopted by the present invention provide a storage medium, the storage medium stores commands, and the commands are executed by a processor to complete the control method described above.

The electronic cigarette device provided by the present invention includes a device body and a heat generating module that are detachably connected. The heating module includes a storage chip and a heating element, and the storage chip stores the heat generation parameters, and the heat generation parameters are the correspondence between the resistance value of the heating element and the temperature. The appliance body includes a battery and a control unit , the control unit is coupled to the battery, and when the appliance body is electrically connected to the heating module, the control unit is used to acquire the heating parameters and heat generation based on the heating parameters. Control the heating of the body. Based on the above-mentioned form, by providing a removable connection method between the instrument body and the heating module, damaged parts can be easily replaced, providing convenience for the user, while generating heat in the heating module. The parameters can be stored and different heating controls can be applied to different heating elements to further heat the tobacco.

Hereinafter, in order to explain the technical means of the examples of the present invention in more detail, the drawings necessary for the description of the examples will be briefly described. Of course, the drawings in the description below are only a few examples of the present invention, and one of ordinary skill in the art may obtain other drawings based on these drawings on the premise that he / she will not perform creative labor. it can.
It is a structural schematic diagram of one Example of the storage device of this invention. It is a figure which shows the position structure inside the heat generation module. It is a schematic diagram of the connection structure of a part module inside the heat generation module and a part module inside the appliance main body. It is a figure which shows the circuit of one Example of the electronic cigarette device provided by this invention. It is a curve diagram of "temperature-time" of one Example in the control method of the electronic cigarette device provided by this invention. It is a figure which shows the pulse voltage of one Example in the control method of the electronic cigarette apparatus provided by this invention. It is a flowchart of one Example in the control method of the electronic cigarette apparatus provided by this invention. It is a flowchart of another one Example in the control method of the electronic cigarette apparatus provided by this invention. It is a structural schematic diagram of one Example of the electronic apparatus provided by this invention. It is a structural schematic diagram of one Example of the storage medium provided by this invention. It is a structural schematic diagram of one Example in the calibration apparatus of the electronic cigarette apparatus provided by this invention. It is a flowchart of one Example in the calibration method of the electronic cigarette apparatus provided by this invention.

"Examples" as used herein mean that at least one example of the present invention includes a particular feature, structure or property described in conjunction with an example. The appearance of the same word in each place herein does not indicate the same embodiment, nor does it indicate an independent or preselected example that is mutually exclusive with the other examples. One of ordinary skill in the art should understand that the embodiments disclosed herein are manifested or implied to be associated with other embodiments.

FIG. 1 is a structural schematic view of one embodiment of the electronic cigarette device provided by the present invention, which includes a device body 10 and a heat generating module 20 which are detachably connected to each other.

The appliance body 10 is mainly used to provide a battery (not shown), the heating module 20 is provided with a heating element, and a container used for arranging tobacco / tobacco liquid is provided, and the appliance body 10 is provided with a heating module 20. When connected to, the battery feeds on the heating element to heat the heating element and heat the tobacco in it.

It should be noted that the appliance body 10 and the heating module 20 shown in FIG. 1 are in a removable state, and in the process of using the electronic cigarette appliance, the heating module 20 is inserted into the appliance body 10 and electrically connected. To form.

FIG. 2 is a schematic diagram of a partial structure inside the heat generating module, and the heat generating module 20 includes a first circuit board 21 and a storage chip 22 and a heating element 23 provided on the first circuit board 21.

The storage chip 22 is provided on the first circuit board 21 by welding means, and the heating element 23 is welded to the first circuit board 21 through the heat conductive member 23a. Specifically, the heat conductive member 23a is excellent in heat conduction performance. It may be a metal material. It should be understood that the storage chip 22 and the heating element 23 are each provided on the upper side surface of the first circuit board 21, and contact springs are provided on the lower side surface of the first circuit board 21. A contact spring is connected to the storage chip 22, the heat conductive member 23a is connected to another contact spring, the heat generating module 20 is inserted into the instrument body 10, and the heat generating module 20 comes into contact with the circuit member of the instrument body 10 through the spring to be electrically connected. To form.

Preferably, the number of heat conductive members 23a may be plural, and may include, for example, a positive electrode, a negative electrode, and the like.

FIG. 3 shows a connecting structure of a part of the module inside the heat generating module and a part of the module inside the main body of the appliance. The second circuit board 11 is provided inside the main body of the appliance 10, and the connecting portion 12 is provided on the second circuit board 11. Is provided, and when the heat generating module 20 is inserted into the instrument body 10, the contact spring on the first circuit board 21 is electrically connected to the contact spring on the connecting portion 12, and the instrument body 10 and the heat generating module 20 are connected. Achieves energization and communication between.

It should be understood that the heating element 23 of the e-cigarette appliance is a fragile part because it operates at high temperatures for a long period of time, but the design means of conventional products package the heating element 23 inside the e-cigarette appliance. The service life of the heating element 23 is very short compared to other parts, and if the heating element 23 is damaged, the entire product must be discarded.

In addition, as the tobacco material dries, it emits many corrosive and sticky substances. In many heating means, the heating element 23 comes into contact with the tobacco material, and the heat-produced tobacco derivative inevitably adheres to the surface of the heating element 23, causing contamination and affecting smoke quality. The method of attaching the heating element 23 of the current product poses a great difficulty in the operation of cleaning, and since the bristle brush is placed in a narrow heating chamber for rough cleaning, the tobacco residue on the surface of the heating element 23 is thoroughly removed. Cannot be removed.

Therefore, in this embodiment, the instrument body 10 and the heat generating module 20 are installed so as to be detachably connected to each other, so that when the heat generating module 20 is damaged or contaminated, it can be removed and replaced, and the instrument body 10 can be replaced. Can be used continuously.

However, the heating module 20 must be replaced by the user himself, and when the user selects the heating module, many problems must be faced, and the heating element 23 in the heating module 20 is different in material, volume, and shape. The heating performance is different depending on the type, and when heating the tobacco, temperature control is very important, which directly affects the taste of the tobacco, which is inconvenient for the user.

FIG. 4 is a schematic circuit diagram of an embodiment of an electronic cigarette appliance provided by the present invention. In this embodiment, the appliance body 10 includes a battery 13 and a control unit 14, and the control unit 14 is the second circuit. It may be provided on the substrate 11, and the battery 13 is electrically connected to the control unit 14.

The heat generation parameter is stored in the storage chip 22, and the control unit 14 combines with the storage chip 22 and the heat generating body 23 in a state where the instrument main body 10 is connected to the heat generating module 20, and the heat generated stored in the storage chip 22. The parameters are acquired, and the heating element 23 is heated and controlled based on the heat generation parameters.

Preferably, in one embodiment, the heating parameter includes a correspondence between the resistance value of the heating element and the temperature.

When electric energy is supplied to heat the heating element 23 to different temperatures, the electric resistance of the heating element 23 itself changes depending on the temperature, and the correspondence between the electric resistance of the heating element and the temperature is changed to the "temperature (T)) of the heating element. If the "-electrical resistance (R)" curve is used, that is, if the electric resistance of the heating element 23 is detected in real time, the real-time temperature of the heating element 23 can be known. Different heating elements have different parameters such as "temperature (T) -electrical resistance (R)" curve, starting electric resistance R0, and TCR (temperature coefficient of resistance) due to the influence of factors such as materials, processes, and manufacturing equipment. It exists and such parameters are referred to as "heating parameters".

Preferably, in a specific embodiment, the control unit 14 includes a detection module 141, a timekeeping module 142 and a control module 143. The detection module 141 is used to detect the resistance value of the heating element, the timekeeping module 142 is used to acquire the time information of the operation of the electronic cigarette device, and the control module 143 acquires the real-time temperature of the heating element acquired by the heating parameter. Moreover, the temperature of the heating element 23 is controlled by the real-time temperature and time information of the heating element 23 and a preset temperature-time change curve.

The operating time information of the electronic cigarette device is the operating time obtained by timing from the time when the operation of the electronic cigarette device is started.

Specifically, the detection module 141 may calculate and obtain the electrical resistance of the heating element 23 through parameters such as current, voltage, and some other means, such as resonance, ohmmetry, DC bridge. A method, a digital ohm metering method, or the like may be used, and is not limited here.

Further, the control module 143 controls the temperature of the heating element 23 based on a preset temperature-time change curve and using a PID algorithm. The "temperature-time" curve shows a heating curve for tobacco.

In the following, a specific example will be described.

When the user smokes a cigarette with an electronic cigarette device, the device body 10 and the heating module 20 are connected, and preferably, when the switch button provided on the device body 10 is turned on, the control unit 14, the storage chip 22, and the heating element 23 move. Electrically connected, the e-cigarette appliance goes into operation.

The control module 143 first acquires the heat generation parameter of the storage chip 22, acquires the correspondence between the resistance value of the heating element 23 and the temperature, and starts timing through the timing module 142. Then, the current resistance value of the heating element 23 is obtained through the detection module 141, the current temperature is obtained by the heating parameter, and finally, the voltage of the heating element 23 based on the "temperature-time" curve through the control module 143. To control.

It should be understood that different heating temperatures are usually required at different times to heat tobacco for a better taste. In one embodiment, as shown in FIG. 5, the abscissa indicates time and the ordinate indicates temperature.

In the T0-T1 time zone, the heating element is heated, and the temperature rises from room temperature W0 to temperature W1.
During the T1-T2 time zone, the temperature of the heating element is maintained in W1 and
In the T2-T3 time zone, the temperature of the heating element is lowered, and the temperature is lowered from the temperature W1 to the temperature W2.
In the T3-T4 time zone, the temperature of the heating element is maintained in W2, and the temperature is maintained in W2.
After T4, the temperature of the heating element is lowered to lower the temperature from W2 to room temperature.

In a specific embodiment, the T1 value may be 5-10 s, the T2 value may be 12-18 s, the W1 value may be 320-360 ° C, and the W2 value may be 300-340 ° C.

In one example, when T1 = 7s, T2 = 15s, W1 = 340 ° C., W2 = 320 ° C., when the temperature of the heating element of this example drops by 1 ° C., its resistance decreases by 2.28 mΩ. When the temperature drops from W1 to W2, that is, the temperature drops by 20 ° C., it is necessary to adjust the resistance value to 20 * 2.28 mΩ.

Further, when the heating temperature is controlled for the heating element using electric energy, the pulse frequency and / or the pulse width and / or the duty ratio of the power supplied to the heating element is changed to control the temperature for the heating element. This allows the e-cigarette appliance to be controlled to emit tasty smoke. As shown in FIG. 6, when the enable switch is turned on during the t1 time zone, the battery supplies electrical energy to the heating element, and when the enable switch is turned off during the t2 time zone, the battery does not supply electrical energy to the heating element. .. Therefore, the temperature of the heating element is adjusted by adjusting the ratio of t1 within the period T. Specifically, when the duty ratio of t1 increases, the temperature of the heating element rises, and when the duty ratio of t1 decreases, the temperature of the heating element decreases.

What should be understood here is that, in the above-described embodiment, the detection module 141, the timekeeping module 142, and the control module 143 are distributed in the form of a physical circuit, and even if they are realized by using, for example, a detection circuit, a timekeeping device, and a control device. Well, or any two or three of them may be assembled on the processing chip and realized using, for example, a processing chip having detection, timing and control performance.

The e-cigarette appliance provided by this embodiment includes an appliance body and a heating module that are detachably connected. The heating module includes a storage chip and a heating element, and the storage chip stores the heat generation parameters, and the heat generation parameters are the correspondence between the resistance value of the heating element and the temperature. The appliance body includes a battery and a control unit , the control unit is coupled to the battery, and when the appliance body is electrically connected to the heating module, the control unit is used to obtain the heating parameters and heat generation based on the heating parameters. Control the heating of the body. Based on the above-mentioned form, by providing a removable connection method between the instrument body and the heating module, damaged parts can be easily replaced, providing convenience for the user, while generating heat in the heating module. The parameters can be stored and different heating controls can be applied to different heating elements to further heat the tobacco.

Preferably, as shown in FIG. 4, in another embodiment, the storage chip 22 further stores the first encrypted data, and the first encrypted data is a set key and encryption based on the stored heat generation parameters. It is formed through an algorithm.

The control unit 14 forms the second encrypted data through the set key and the encryption algorithm based on the acquired heat generation parameters, and reads the first encrypted data from the storage chip 22, and the second encrypted data and the first encrypted data. The data are collated, and when the first encrypted data and the second encrypted data are equal, the heating element 23 is heated and controlled.

The encryption means is mainly to prevent counterfeiting of the heating module to be replaced, and such means can guarantee the authenticity of the authentication of the heating module and the appliance body.

FIG. 7 is a flowchart of one embodiment in the control method of the electronic cigarette device provided by the present invention, the control method is applied to the electronic cigarette device, and the electronic cigarette device is detachably connected to the device body. And a heat generating module, the specific structure thereof is not described here because it is desired to refer to the examples of FIGS. 1 to 4.

The control method of this embodiment includes steps 71-74.
In step 71, the heat generation parameter stored in the heat generation module is acquired, and the heat generation parameter indicates the correspondence between the resistance value of the heating element in the heating module and the temperature.

In step 72, the first encrypted data stored in the heat generation module is acquired, and the first encrypted data is formed by the set key and the encryption algorithm based on the stored heat generation parameters.

In step 73, the second cryptographic data is formed through the set key and cryptographic algorithm based on the acquired heat generation parameters.

In step 74, the second encrypted data and the first encrypted data are collated, and it is determined whether or not the first encrypted data and the second encrypted data are the same.
If the judgment in step 74 is "yes", step 75 is executed.

In step 75, the heating element is heated and controlled based on the heat generation parameters.

Preferably, step 75 specifically controls the temperature of the heating element with a heating parameter and a preset temperature-time change curve.

The control method provided by this embodiment is the above-mentioned control method for the electronic cigarette device, and its structure and operating principle are similar to those of the above-described embodiment, and therefore will not be described here.

FIG. 8 is a flowchart of one embodiment in the control method of the electronic cigarette device provided by the present invention, the control method is applied to the electronic cigarette device, and the electronic cigarette device is detachably connected to the device body. And a heat generating module, the specific structure thereof is not described here because it is desired to refer to the examples of FIGS. 1 to 4.

The control method of this embodiment includes steps 81-84.
In step 81, the heat generation parameter stored in the heat generation module is acquired, and the heat generation parameter indicates the correspondence between the resistance value of the heating element in the heating module and the temperature.

In step 82, the real-time temperature of the heating element is acquired using the correspondence between the resistance value of the heating element and the temperature.

In step 83, the operation time information of the electronic cigarette device is acquired.

In step 84, the temperature of the heating element is adjusted based on the real-time temperature of the heating element, time information and a preset temperature-time change curve.
The control method provided by this embodiment is the above-mentioned control method for the electronic cigarette device, and its structure and operating principle are similar to those of the above-described embodiment, and therefore will not be described here.

FIG. 9 is a schematic structural diagram of an embodiment of the electronic device provided by the present invention. The electronic device 90 includes a memory 91, a processor 92, and a program or instruction stored in the memory 91 and operated on the processor 92. A step of acquiring the heating parameters stored in the heating module when the program or instruction specifically operates on the processor 92, and the heating parameters indicating the correspondence between the resistance value of the heating element in the heating module and the temperature. And the step of heating and controlling the heating element based on the heating parameters.

Preferably, in one embodiment, the step of acquiring the heat generation parameters stored in the heat generation module when the program or instruction is specifically operated on the processor 92.
The first encrypted data stored in the heat generation module is acquired, and the first encrypted data is formed through a set key and a cryptographic algorithm based on the stored heat generation parameters.
Based on the acquired heat generation parameters, the step of forming the second cryptographic data through the set key and cryptographic algorithm,
A step of collating the second encrypted data with the first encrypted data and controlling heating of the heating element based on the heat generation parameter when the first encrypted data and the second encrypted data are the same is included.

Preferably, in one other embodiment, the step of acquiring the heat generation parameters stored in the heat generation module when the program or instruction is applied and operated on the processor 92.
A step of detecting the resistance value of the heating element and a step of acquiring the real-time temperature of the heating element by using the correspondence between the resistance value of the heating element and the temperature.
Steps to get information on the operating time of e-cigarette appliances,
It involves adjusting the temperature of the heating element with real-time temperature, time information and a preset temperature-time change curve of the heating element.

FIG. 10 is a schematic structural diagram of an embodiment of the storage medium provided by the present invention. A program or command 101 is stored in the storage medium 100, and when the program or command 101 is specifically applied to a processor and operated, the heat generation parameter stored in the heat generation module is acquired, and the heat generation parameter generates heat. It includes a step of showing the correspondence between the resistance value of the heating element in the module and the temperature, and a step of heating and controlling the heating element based on the heating parameters.

Preferably, in one embodiment, the step of acquiring the heat generation parameters stored in the heat generation module when the program or command 101 is specifically operated on the processor 92.
The first encrypted data stored in the heat generation module is acquired, and the first encrypted data is formed through a set key and a cryptographic algorithm based on the stored heat generation parameters.
Based on the acquired heat generation parameters, the step of forming the second cryptographic data through the set key and cryptographic algorithm,
A step of collating the second encrypted data with the first encrypted data and controlling heating of the heating element based on the heat generation parameter when the first encrypted data and the second encrypted data are the same is included.

Preferably, in another embodiment, the step of acquiring the heat generation parameters stored in the heat generation module when the program or directive 101 is applied and operated on the processor.
Steps to detect the resistance value of the heating element and
The step of acquiring the real-time temperature of the heating element using the correspondence between the resistance value of the heating element and the temperature,
Steps to get information on the operating time of e-cigarette appliances,
It involves adjusting the temperature of the heating element with real-time temperature, time information and a preset temperature-time change curve of the heating element.

FIG. 11 is a structural schematic diagram of one embodiment of the electronic cigarette appliance calibration device provided by the present invention, in which the calibration device is connected to the heat generation module of the electronic cigarette device when the heat generation module is electrically connected. Used for calibrating.

The calibration device is mainly used to confirm the heating parameters of the heating element of the heating module, that is, the correspondence between the resistance value of the heating element and the temperature.

In this embodiment, the calibration device 110 includes a processor 111, a power supply 112 coupled to the processor 111, a sensor 113, and a communication module 114.

The power supply 112 is used to provide electrical energy, the sensor 113 acquires the resistance value and temperature of the heating element of the external heat generation module, and the processor 111 forms a heat generation parameter based on the correspondence between the acquired resistance value and temperature, and communicates. The module 114 transmits the heat generation parameter to the heat generation module and stores it in the heat generation module.

Power supply 112 The battery may be a battery inside the calibration device, or may be a power supply connected to the outside, and is not limited here.

It should be understood that the calibrator is a device used in combination with an e-cigarette appliance, which typically detects and stores parameters for the e-cigarette appliance or heat-generating module during the production and manufacturing process.

FIG. 12 is a flowchart of one embodiment of the method for calibrating an electronic cigarette device provided by the present invention, the calibration method is applied to a calibration device for an electronic cigarette device, and the calibration method includes steps 121 and 122. ..

In step 121, when the calibration device is connected to the heating module, it detects the heating element of the heating element and acquires the heating parameter of the heating element, which is between the resistance value of the heating element and the temperature. Including correspondence.

In step 122, the heat generation parameter is transmitted to the heat generation module and stored in the heat generation module.

Further, preferably, the calibration method forms encrypted data through a set key and a cryptographic algorithm based on the acquired heat generation parameters. The encrypted data is used for pair verification when the heat generating module is connected to the instrument body. It may further include transmitting the encrypted data to the heat generation module and storing it in the heat generation module.

It should be understood that the calibration method provided by this embodiment may be stored in memory by means of a computer program and performs the method described above when the processor executes the computer program in memory.

In an embodiment of the invention, it is realized through the means of a soft functional unit and, when sold or produced as an independent product, is stored in a computer and readable in a storage medium. As mentioned above, the technical means of the present invention is embodied in the form of a software product, in essence or in part or in whole or in part of the technical means that has contributed to the prior art. The computer software product is stored in a storage medium and includes a plurality of instructions in which a computer device (such as a personal computer, server, or network device) or processor is all of the methods according to each embodiment of the present invention. Or perform some steps. The storage medium includes media of various storage program codes such as USB memory, mobile hard disk, read-only memory (ROM, Read-Only Memory), random access memory (RAM, Random Access Memory), disk or CD.

The above is only an embodiment of the present invention and does not limit the scope of protection of the present invention. It is within the scope of the invention for the same reason that any modification of the equivalent structure or equivalent flow made by the specification and accompanying drawings of the present invention is directly or indirectly carried out in other related technical fields. Should be included in.

Claims (10)

An e-cigarette appliance that includes a detachably connected appliance body and a heating module.
The heating module includes a storage chip and a heating element, and the storage chip stores heat generation parameters. The heat generation parameters are the correspondence between the resistance value of the heating element and the temperature.
The appliance body includes a battery and a control unit , the control unit is coupled to the battery, and when the appliance body is electrically connected to the heating module, the control unit is used to acquire the heat generation parameters. An electronic cigarette device that heats and controls the heating element based on the heat generation parameter. The control unit includes a detection module, a timekeeping module, and a control module.
The detection module is used to detect the resistance value of the heating element.
The timekeeping module is used to acquire time information of the operation of the electronic cigarette device.
The control module acquires the real-time temperature of the heating element by the heating parameter, and controls the temperature of the heating element by the real-time temperature of the heating element, the time information, and a preset temperature-time change curve. The electronic cigarette device according to claim 1, wherein the electronic cigarette device is characterized in that. The electronic cigarette appliance according to claim 2, wherein the control module controls the temperature of the heating element by changing the pulse frequency and / or pulse width and / or duty of the electric power supplied to the heating element. .. The first cryptographic data is further stored in the storage chip, and the first cryptographic data is formed through a set key and a cryptographic algorithm based on the stored heat generation parameters.
The control unit forms the second encrypted data through the set key and the encryption algorithm based on the acquired heat generation parameter, and reads the first encrypted data from the storage chip to obtain the second encrypted data and the said. The electronic tobacco device according to claim 1, wherein the first encrypted data is collated, and when the first encrypted data and the second encrypted data are equal, the heating element is heated and controlled. It is a heating module and includes a storage chip and a heating element. The storage chip stores heat generation parameters, and the heat generation parameters are the correspondence between the resistance value of the heating element and the temperature.
When the heating module is electrically connected to the appliance body, it supplies the appliance body with the heating parameters stored in the storage chip, whereby the appliance body heats the heating element based on the heating parameters. A heating module characterized by being controlled. A method of controlling an e-cigarette appliance that is used in an e-cigarette appliance and includes a detachably connected appliance body and a heating module.
The heat generation parameter stored in the heat generation module is acquired, and the heat generation parameter is the correspondence between the resistance value of the heating element and the temperature.
A method for controlling an electronic cigarette device, which comprises controlling the heating of the heating element based on the heat generating parameter. The step of heating and controlling the heating element based on the heat generating parameter is
The step of detecting the resistance value of the heating element and
Using the correspondence between the resistance value of the heating element and the temperature, the step of acquiring the real-time temperature of the heating element and
The step of acquiring the operation time information of the electronic cigarette device and
The electronic cigarette device according to claim 6, further comprising a step of adjusting the temperature of the heating element based on the real-time temperature of the heating element, the time information, and a preset temperature-time change curve. Control method. After the step of acquiring the heat generation parameters stored in the heat generation module,
A step of acquiring the first encrypted data stored in the heat generating module, and the first encrypted data is formed by a set key and a cryptographic algorithm based on the stored heat generation parameters.
Based on the acquired heat generation parameters, the step of forming the second encrypted data through the set key and the encryption algorithm, and
The step of collating the second encrypted data with the first encrypted data and controlling the heating of the heating element based on the heating parameter when the first encrypted data and the second encrypted data are the same is included. The method for controlling an electronic cigarette device according to claim 6, wherein the electronic cigarette device is characterized. An electronic device comprising a memory, a processor, and a program or instruction stored in the memory and operating on the processor, wherein the processor executes the program or the instruction according to any one of claims 6 to 8. An electronic device characterized by realizing the control method described in the section. A storage medium, characterized in that a program or instruction is stored in the storage medium, and the program or instruction is executed by a processor to complete the control method according to any one of claims 6 to 8. Storage medium.

Images