WO2024016436A1 - Temperature control system, temperature control method and anti-counterfeiting system for atomization piece - Google Patents
Temperature control system, temperature control method and anti-counterfeiting system for atomization piece Download PDFInfo
- Publication number
- WO2024016436A1 WO2024016436A1 PCT/CN2022/116599 CN2022116599W WO2024016436A1 WO 2024016436 A1 WO2024016436 A1 WO 2024016436A1 CN 2022116599 W CN2022116599 W CN 2022116599W WO 2024016436 A1 WO2024016436 A1 WO 2024016436A1
- Authority
- WO
- WIPO (PCT)
- Prior art keywords
- module
- heating
- resistance change
- change value
- acquisition module
- Prior art date
Links
- 238000000034 method Methods 0.000 title claims abstract description 18
- 238000000889 atomisation Methods 0.000 title abstract description 13
- 230000008859 change Effects 0.000 claims abstract description 146
- 238000010438 heat treatment Methods 0.000 claims description 222
- 239000007788 liquid Substances 0.000 claims description 21
- 239000000443 aerosol Substances 0.000 claims description 10
- 230000035515 penetration Effects 0.000 claims description 7
- 230000007423 decrease Effects 0.000 claims description 5
- 238000004364 calculation method Methods 0.000 claims description 4
- 230000020169 heat generation Effects 0.000 abstract description 11
- 238000009688 liquid atomisation Methods 0.000 abstract description 2
- 238000010586 diagram Methods 0.000 description 3
- 229910021421 monocrystalline silicon Inorganic materials 0.000 description 3
- 230000035699 permeability Effects 0.000 description 3
- 230000003247 decreasing effect Effects 0.000 description 2
- 230000009286 beneficial effect Effects 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
Classifications
-
- A—HUMAN NECESSITIES
- A24—TOBACCO; CIGARS; CIGARETTES; SIMULATED SMOKING DEVICES; SMOKERS' REQUISITES
- A24F—SMOKERS' REQUISITES; MATCH BOXES; SIMULATED SMOKING DEVICES
- A24F40/00—Electrically operated smoking devices; Component parts thereof; Manufacture thereof; Maintenance or testing thereof; Charging means specially adapted therefor
- A24F40/40—Constructional details, e.g. connection of cartridges and battery parts
-
- A—HUMAN NECESSITIES
- A24—TOBACCO; CIGARS; CIGARETTES; SIMULATED SMOKING DEVICES; SMOKERS' REQUISITES
- A24F—SMOKERS' REQUISITES; MATCH BOXES; SIMULATED SMOKING DEVICES
- A24F40/00—Electrically operated smoking devices; Component parts thereof; Manufacture thereof; Maintenance or testing thereof; Charging means specially adapted therefor
- A24F40/40—Constructional details, e.g. connection of cartridges and battery parts
- A24F40/42—Cartridges or containers for inhalable precursors
-
- A—HUMAN NECESSITIES
- A24—TOBACCO; CIGARS; CIGARETTES; SIMULATED SMOKING DEVICES; SMOKERS' REQUISITES
- A24F—SMOKERS' REQUISITES; MATCH BOXES; SIMULATED SMOKING DEVICES
- A24F40/00—Electrically operated smoking devices; Component parts thereof; Manufacture thereof; Maintenance or testing thereof; Charging means specially adapted therefor
- A24F40/40—Constructional details, e.g. connection of cartridges and battery parts
- A24F40/46—Shape or structure of electric heating means
-
- A—HUMAN NECESSITIES
- A24—TOBACCO; CIGARS; CIGARETTES; SIMULATED SMOKING DEVICES; SMOKERS' REQUISITES
- A24F—SMOKERS' REQUISITES; MATCH BOXES; SIMULATED SMOKING DEVICES
- A24F40/00—Electrically operated smoking devices; Component parts thereof; Manufacture thereof; Maintenance or testing thereof; Charging means specially adapted therefor
- A24F40/50—Control or monitoring
-
- A—HUMAN NECESSITIES
- A24—TOBACCO; CIGARS; CIGARETTES; SIMULATED SMOKING DEVICES; SMOKERS' REQUISITES
- A24F—SMOKERS' REQUISITES; MATCH BOXES; SIMULATED SMOKING DEVICES
- A24F40/00—Electrically operated smoking devices; Component parts thereof; Manufacture thereof; Maintenance or testing thereof; Charging means specially adapted therefor
- A24F40/50—Control or monitoring
- A24F40/53—Monitoring, e.g. fault detection
-
- A—HUMAN NECESSITIES
- A24—TOBACCO; CIGARS; CIGARETTES; SIMULATED SMOKING DEVICES; SMOKERS' REQUISITES
- A24F—SMOKERS' REQUISITES; MATCH BOXES; SIMULATED SMOKING DEVICES
- A24F40/00—Electrically operated smoking devices; Component parts thereof; Manufacture thereof; Maintenance or testing thereof; Charging means specially adapted therefor
- A24F40/50—Control or monitoring
- A24F40/57—Temperature control
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B05—SPRAYING OR ATOMISING IN GENERAL; APPLYING FLUENT MATERIALS TO SURFACES, IN GENERAL
- B05B—SPRAYING APPARATUS; ATOMISING APPARATUS; NOZZLES
- B05B17/00—Apparatus for spraying or atomising liquids or other fluent materials, not covered by the preceding groups
- B05B17/04—Apparatus for spraying or atomising liquids or other fluent materials, not covered by the preceding groups operating with special methods
Definitions
- the invention relates to the technical field of liquid atomization, and in particular to a temperature control system, a temperature control method and an anti-counterfeiting system for an atomization sheet.
- Electronic atomization equipment includes an atomization device and a power supply that supplies power to the atomization device.
- the atomization device is internally constructed with a liquid storage chamber, an air flow channel, and an electronic atomization component.
- the power supply is provided with an accommodating slot, and the atomizing device is installed in the accommodating slot and is electrically connected to the power supply. When the power supply supplies power to the electronic atomization component inside the atomization device, the atomization component atomizes the solution stored in the liquid storage chamber into aerosol and discharges it.
- the atomizing piece is one of the necessary components of the atomizing device.
- the function of the atomizing piece is to heat or vibrate liquids and other objects to produce atomized gas. Vibration atomization is generally achieved through ultrasonic waves, and heating atomization generally uses heating wires or heating sheets for heating.
- the heating temperature of existing atomizer sheets is basically set at a fixed value, which cannot be effectively changed and controlled, affecting practicality.
- the present invention provides a heating temperature control for the atomizer sheet.
- the acquisition module obtains the resistance change value generated by the heating module during the heating process, and sends the resistance change value parameter to the control module.
- the control module controls the heating process.
- the resistance change value of the module changes to realize the temperature control system, temperature control method and anti-counterfeiting system of the atomizer sheet.
- a temperature control system for an atomizer sheet including a heating module, an acquisition module, and a control module.
- the heating module is used to generate heat and generate resistance change values when heating at different powers;
- the acquisition module is used to acquire the The resistance change value generated when the heating module generates heat;
- the control module is used to control the heating of the heating module and is connected to the acquisition module.
- the acquisition module sends the obtained resistance change value parameter to the control module, and the control module Obtain the resistance change value sent by the module to control the power of the heating module to change the heating temperature.
- a temperature control method for an atomizer sheet including a temperature control system.
- the temperature control system includes a heating module, an acquisition module, and a control module.
- the heating module is used to generate heat and generate resistance change values when heating at different powers.
- the acquisition module is used to obtain the resistance change value generated when the heating module generates heat
- the control module is used to control the heating module to heat and is connected to the acquisition module, and the acquisition module converts the obtained resistance change value parameter Sent to the control module, the control module controls the power of the heating module to change the heating temperature according to the resistance change value sent by the acquisition module.
- the method includes the following steps.
- step S1 the control module sets a fixed value, and the control module controls the heating module to generate heat through the fixed value.
- Step S2 The heating module uses the fixed value of the control module to control the resistance change value generated when heating at different powers, and the acquisition module obtains the resistance change value generated when heating.
- step S3 the acquisition module sends the acquired resistance change value to the control module.
- Step S4 The control module calculates the current temperature value of the heating module based on the change in the received resistance change value.
- Step S5 The control module increases or decreases the output power of the heating module to implement temperature control according to the current temperature value obtained by calculation.
- An anti-counterfeiting system for atomized tablets including a heating module, an acquisition module, a control module, and an identification module.
- the heating module is used to generate heat and generate resistance change values when heating at different powers; the acquisition module is used to obtain The resistance change value generated when the heating module generates heat; the control module is used to control the heating module to generate heat and is connected to the acquisition module.
- the acquisition module sends the obtained resistance change value parameter to the control module.
- the module controls the power of the heating module to change the heating temperature according to the resistance change value sent by the acquisition module;
- the identification module is located in the control module and is used to identify the resistance change value obtained by the acquisition module.
- the identification module will identify whether the resistance change value is consistent with the control module.
- the control of the module is consistent to determine whether the heating module matches it.
- the present invention is used to control the heating temperature of the atomizer sheet.
- the acquisition module obtains the resistance change value generated by the heating module during the heating process, and sends the resistance change value parameter to the control module.
- the module realizes temperature control by changing the resistance change value of the heating module, which solves the problem that the existing atomizer sheet cannot be temperature controlled.
- different temperature controls can be achieved according to different liquids, which is highly practical.
- a heating module, an acquisition module, and a control module are provided.
- the heating module is used to generate heat and generate resistance change values when heating at different powers; the acquisition module is used to acquire the resistance value generated when the heating module generates heat.
- the resistance change value of The change value controls the power of the heating module to change the heating temperature.
- the present invention also involves a temperature control method, including a temperature control system, and performs temperature control in the following manner.
- the control module sets a fixed value, and the control module controls heat generation through the fixed value.
- the module generates heat;
- the heating module uses the fixed value of the control module to control the resistance change value generated when heating under different powers, and the acquisition module obtains the resistance change value generated when heating;
- Step S3, the acquisition module obtains the resistance change value Sent to the control module;
- the control module calculates the current temperature value of the heating module based on the received resistance change value;
- Step S5 the control module increases or decreases the temperature of the heating module based on the calculated current temperature value.
- the output power realizes temperature control. Temperature control is achieved by increasing or decreasing the resistance change value, which is highly intelligent, does not require redundant components, and has low structural cost.
- the present invention also relates to an anti-counterfeiting system, which specifically includes a heating module, an acquisition module, a control module, and an identification module.
- the heating module is used to generate heat and generates heat when generating heat at different powers.
- the change value parameter is sent to the control module, which controls the power of the heating module to change the heating temperature according to the resistance change value sent by the acquisition module;
- the identification module is provided in the control module and is used to identify the resistance change value acquired by the acquisition module.
- the identification module will identify whether the resistance change value is consistent with that controlled by the control module to determine whether the heating module matches it. The authenticity of the heating module is judged by identifying whether the resistance change value is consistent with the controlled resistance change value. No redundant components are required, and the structure cost is low.
- Figure 1 is a schematic connection diagram of the temperature control system of the atomizer sheet of the present invention.
- Figure 2 is a three-dimensional schematic diagram of the chip body of the temperature control system of the atomizer sheet of the present invention.
- Figure 3 is a schematic three-dimensional view of the chip body of the temperature control system of the atomizer sheet of the present invention from another perspective.
- Figure 4 is a schematic connection diagram of the anti-counterfeiting system of the atomized sheet of the present invention.
- heating module 1 chip body 11, first surface 111, second surface 112, heating element 12, heating circuit 121, first contact position 122, second contact position 123, penetration area 13, acquisition module 2 , control module 3, resistance change value 4, identification module 5.
- a temperature control system for an atomizer sheet is provided with a heating module 1, an acquisition module 2, and a control module 3.
- the heating module 1 is used to generate heat and generate resistance when heating at different powers.
- the change value is 4;
- the acquisition module 2 is used to obtain the resistance change value 4 produced when the heating module 1 generates heat;
- the control module 3 is used to control the heating module 1 to generate heat and is connected to the acquisition module 2, and the acquisition module 2 obtains the resistance change
- the value 4 parameter is sent to the control module 3, and the control module 3 controls the heating temperature of the heating module 1 according to the resistance change value 4 sent by the acquisition module 2.
- the heating module 1 includes a chip body 11 and a heating element 12 provided on the chip body 11.
- the chip body 11 has a first surface 111 and a second surface 112.
- the heating element 12 is provided on the first surface 111.
- the heating element 12 includes a heating circuit 121 provided on the first surface 111 and passing through the penetration area 13. The two ends of the heating circuit 121 are respectively provided with a first contact position 122 and a second contact position 123.
- the heating circuit 121 generates heat under different powers.
- the acquisition module 2 is used to obtain the resistance change value 4 generated when the heating circuit 121 generates heat; it is electrically connected to the control module 3 through two contact positions for electrical contact, and through the heating circuit 121 at different powers When heating is generated, the resistance change value is 4 to achieve temperature control.
- a permeable area 13 is provided between the first surface 111 and the second surface 112.
- the permeable area 13 can be used for liquid to pass through and can be heated by the heating element 12 to form aerosol.
- the chip body 11 adopts In the single crystal silicon wafer, the permeability area 13 is composed of multiple micropores. The micropores can pass liquid when subjected to negative pressure, and the liquid forms aerosol after being heated by the heating circuit 121.
- the invention is used to control the heating temperature of the atomizer piece.
- the acquisition module 2 obtains the resistance change value 4 generated by the heating module 1 during the heating process, and sends the resistance change value 4 parameter to the control module 3.
- the control module 3 controls the heating module 1
- the resistance change value of 4 changes to achieve temperature control, which solves the problem that the existing atomizer sheet cannot be temperature controlled. In actual use, different temperature controls can be achieved according to different liquids, which is highly practical.
- a heating module 1, an acquisition module 2, and a control module 3 are provided.
- the heating module 1 is used to generate heat and generate a resistance change value 4 when heating at different powers; the acquisition module 2 is used to obtain the resistance change value 4 when the heating module 1 generates heat.
- the generated resistance change value 4; the control module 3 is used to control the heating module 1 to generate heat and is connected to the acquisition module 2.
- the acquisition module 2 sends the obtained resistance change value 4 parameters to the control module 3.
- the control module 3 controls the heating module 1 according to the acquisition module 2.
- the sent resistance change value 4 controls the heating temperature of the heating module 1 .
- a temperature control method for an atomizer tablet includes a temperature control system.
- the temperature control system includes a heating module 1, an acquisition module 2, and a control module 3.
- the heating module 1 is used to generate heat and The resistance change value 4 is generated when heating at different powers;
- the acquisition module 2 is used to obtain the resistance change value 4 generated when the heating module 1 is heated;
- the control module 3 is used to control the heating module 1 to generate heat and is connected to the acquisition module 2, and the acquisition module 2.
- the control module 3 controls the heating temperature of the heating module 1 according to the resistance change value 4 sent by the acquisition module 2; the acquisition module 2 obtains the heating temperature of the heating module 1 during the heating process.
- the generated resistance change value 4 is sent to the control module 3 as the resistance change value 4 parameter.
- the control module 3 changes the resistance change value 4 of the heating module 1 to implement temperature control, which solves the problem that the existing atomizer sheet cannot be temperature controlled. In actual use, different temperature controls can be achieved according to different liquids, which is highly practical.
- the method includes the following steps.
- step S1 the control module 3 sets a fixed value, and the control module 3 controls the heating module 1 to generate heat through the fixed value.
- step S2 the heating module uses the fixed value of the control module 3 to control the resistance change value 4 generated when heating at different powers, and the acquisition module 2 obtains the resistance change value 4 generated during heating.
- step S3 the acquisition module 2 sends the acquired resistance change value 4 to the control module 3.
- step S4 the control module 3 calculates the current temperature value of the heating module 1 based on the change in the received resistance change value 4.
- Step S5 The control module 3 increases or decreases the resistance change value 4 of the heating module 1 according to the calculated current temperature value to implement temperature control.
- the heating module 1 includes a chip body 11 and a heating element 12 provided on the chip body 11.
- the chip body 11 has a first side 111 and a second side 112.
- the heating element 12 is provided on the first side 111; the first side 111 and the second side
- a permeable area 13 is provided between the surfaces 112.
- the permeable area 13 can be used for liquid to pass through and can be heated by the heating element 12 to form aerosol; two contact positions are used for electrical contact and are electrically connected to the control module 3, and through
- the heating circuit 121 When the heating circuit 121 generates heat at different powers, it generates a resistance change value of 4 to achieve temperature control.
- the heating element 12 includes a heating circuit 121 provided on the first surface 111 and passing through the penetration area 13.
- the heating circuit 121 is provided with a first contact position 122 and a second contact position 123 at both ends.
- the resistance change value 4 is generated, and the acquisition module 2 is used to obtain the resistance change value 4 generated when the heating circuit 121 is heated;
- the chip body 11 is made of a single crystal silicon wafer, and the permeability area 13 is composed of multiple micropores, and the micropores are subjected to negative pressure.
- the liquid can pass through the liquid, and the liquid forms aerosol after being heated by the heating circuit 121.
- step S4 the change in resistance change value 4 is calculated as follows.
- the control module 3 is an MCU controller, which can be written into a calculation program to calculate and control the temperature.
- the present invention also relates to a temperature control method, including a temperature control system, and performs temperature control in the following manner: the control module 3 sets a fixed value, and the control module 3 controls the heating module 1 to generate heat through the fixed value; the heating module passes through the control module 3
- the fixed value controls the resistance change value 4 generated when heating at different powers.
- the acquisition module 2 obtains the resistance change value 4 generated during heating; the acquisition module 2 sends the obtained resistance change value 4 to the control module 3; the control module 3 is based on
- the current temperature value of the heating module 1 is calculated by changing the received resistance change value 4; the control module 3 increases or decreases the output power of the heating module 1 according to the calculated current temperature value to implement temperature control.
- Temperature control is achieved by increasing or decreasing the resistance change value 4, which is highly intelligent, does not require redundant components, and has low structural cost.
- an anti-counterfeiting system for atomized tablets includes a heating module 1, an acquisition module 2, a control module 3, and an identification module 5.
- the heating module 1 is used to generate heat and produce resistance changes when it is heated at different powers. Value 4;
- the acquisition module 2 is used to acquire the resistance change value 4 produced when the heating module 1 generates heat;
- the control module 3 is used to control the heating module 1 to generate heat and is connected to the acquisition module 2, and the acquisition module 2 obtains the resistance change value 4 parameters are sent to the control module 3.
- the control module 3 controls the heating temperature of the heating module 1 according to the resistance change value 4 sent by the acquisition module 2;
- the identification module 5 is provided in the control module 3 and is used to identify the resistance change acquired by the acquisition module 2.
- the identification module 5 will identify whether the resistance change value 4 is consistent with that controlled by the control module 3 to determine whether the heating module 1 matches it.
- the acquisition module 2 obtains the resistance change value 4 generated by the heating module 1 during the heating process, and sends the resistance change value 4 parameter to the control module 3.
- the control module 3 implements temperature control on the output power of the heating module 1, solving the existing fog problem. The problem that the tablet cannot be temperature controlled can achieve different temperature control according to different liquids in actual use, which is highly practical.
- the heating module 1 includes a chip body 11 and a heating element 12 provided on the chip body 11.
- the chip body 11 has a first side 111 and a second side 112.
- the heating element 12 is provided on the first side 111; the first side 111 and the second side
- a permeable area 13 is provided between the surfaces 112.
- the permeable area 13 can be used for liquid to pass through and can be heated by the heating element 12 to form aerosol; two contact positions are used for electrical contact and are electrically connected to the control module 3, and through
- the heating circuit 121 When the heating circuit 121 generates heat at different powers, it generates a resistance change value of 4 to achieve temperature control.
- the heating element 12 includes a heating circuit 121 provided on the first surface 111 and passing through the penetration area 13.
- the heating circuit 121 is provided with a first contact position 122 and a second contact position 123 at both ends.
- the resistance change value 4 is generated, and the acquisition module 2 is used to obtain the resistance change value 4 generated when the heating circuit 121 is heated;
- the chip body 11 is made of a single crystal silicon wafer, and the permeability area 13 is composed of multiple micropores, and the micropores are subjected to negative pressure.
- the liquid can pass through the liquid, and the liquid forms aerosol after being heated by the heating circuit 121.
- the invention also relates to an anti-counterfeiting system, which specifically includes a heating module 1, an acquisition module 2, a control module 3, and an identification module 5.
- the heating module 1 is used to generate heat and generate a resistance change value 4 when heating at different powers;
- the acquisition module 2 is used to obtain the resistance change value 4 generated when the heating module 1 generates heat;
- the control module 3 is used to control the heating module 1 to generate heat and is connected to the acquisition module 2.
- the acquisition module 2 sends the obtained resistance change value 4 parameters to the control Module 3, the control module 3 controls the heating temperature of the heating module 1 according to the resistance change value 4 sent by the acquisition module 2; the identification module 5 is provided in the control module 3 and is used to identify the resistance change value 4 obtained by the acquisition module 2, the identification module 5 will identify whether the resistance change value 4 is consistent with that controlled by the control module 3 to determine whether the heating module 1 matches it.
- the authenticity of the heating module 1 is determined by identifying whether the resistance change value 4 is consistent with the controlled resistance change value 4. No redundant components are required, and the structure cost is low.
Landscapes
- Control Of Resistance Heating (AREA)
Abstract
The present invention relates to the technical field of liquid atomization, and particularly relates to a temperature control system, temperature control method and anti-counterfeiting system for an atomization piece. The temperature control system comprises a heat generation module, an acquisition module and a control module, wherein the heat generation module is used for generating heat, and generating a resistance change value when generating heat at different powers; the acquisition module is used for acquiring the resistance change value generated by means of the heat generation module during heat generation; and the control module is used for controlling the heat generation module to generate heat and is connected to the acquisition module, the acquisition module sends an acquired resistance change value parameter to the control module, and the control module controls the power of the heat generation module according to the resistance change value sent by the acquisition module, so as to change a heat generation temperature. In the present invention, the acquisition module acquires the resistance change value generated by means of the heat generation module during heat generation and sends the resistance change value parameter to the control module, and the control module changes the resistance change value of the heat generation module, so as to realize temperature control. The system is also applicable to a temperature control method and an anti-counterfeiting system.
Description
相关申请的交叉引用。Cross-references to related applications.
本申请要求于2022年07月18日提交中国专利局,申请号为202210840999.5,发明名称为“雾化片的温控系统、温控方法及防伪系统”的中国专利申请的优先权,其全部内容通过引用结合在本申请中。This application requires the priority of the Chinese patent application submitted to the China Patent Office on July 18, 2022, with the application number 202210840999.5, and the invention name is "Temperature control system, temperature control method and anti-counterfeiting system of atomized sheets", and its entire content incorporated herein by reference.
本发明涉及液体雾化技术领域,特别是涉及一种雾化片的温控系统、温控方法及防伪系统。The invention relates to the technical field of liquid atomization, and in particular to a temperature control system, a temperature control method and an anti-counterfeiting system for an atomization sheet.
电子雾化设备包括雾化装置和为雾化装置供电的供电器,雾化装置内部构建有储液腔、气流通道及电子雾化组件。供电器开设有容纳槽,雾化装置安装于容纳槽内,并与供电器建立电性连接。当供电器为雾化装置内部的电子雾化组件供电时,雾化组件将储液腔内部存储的溶液雾化成气雾排出。Electronic atomization equipment includes an atomization device and a power supply that supplies power to the atomization device. The atomization device is internally constructed with a liquid storage chamber, an air flow channel, and an electronic atomization component. The power supply is provided with an accommodating slot, and the atomizing device is installed in the accommodating slot and is electrically connected to the power supply. When the power supply supplies power to the electronic atomization component inside the atomization device, the atomization component atomizes the solution stored in the liquid storage chamber into aerosol and discharges it.
雾化片是雾化装置必备的元器件之一,雾化片的作用是将液体等物进行加热或震动产生雾化气体。震动雾化一般是通过超声波实现,加热雾化现有一般采用发热丝或发热片进行加热。现有的雾化片加热温度基本都是定值设定的,不能进行有效改变和控制,影响实用性。The atomizing piece is one of the necessary components of the atomizing device. The function of the atomizing piece is to heat or vibrate liquids and other objects to produce atomized gas. Vibration atomization is generally achieved through ultrasonic waves, and heating atomization generally uses heating wires or heating sheets for heating. The heating temperature of existing atomizer sheets is basically set at a fixed value, which cannot be effectively changed and controlled, affecting practicality.
为解决上述问题,本发明提供一种用于雾化片的发热温度控制,通过获取模块获取发热模块在发热过程中产生的电阻变化值,将电阻变化值参数发送给控制模块,控制模块对发热模块的电阻变化值改变实现温控的雾化片的温控系统、温控方法及防伪系统。In order to solve the above problems, the present invention provides a heating temperature control for the atomizer sheet. The acquisition module obtains the resistance change value generated by the heating module during the heating process, and sends the resistance change value parameter to the control module. The control module controls the heating process. The resistance change value of the module changes to realize the temperature control system, temperature control method and anti-counterfeiting system of the atomizer sheet.
上述目的可采用下列技术方案来实现。The above objectives can be achieved using the following technical solutions.
一种雾化片的温控系统,包括发热模块,获取模块,以及控制模块,所述发热模块用于发热、并在不同功率下发热时产生电阻变化值;所述获取模块用于获取所述发热模块发热时所产生的电阻变化值;所述控制模块用于控制发热模块发热、并与获取模块连接,所述获取模块将所获取的电阻变化值参数发送给控制模块,所述控制模块根据获取模块所发送的电阻变化值控制发热模块的功率改变发热温度。A temperature control system for an atomizer sheet, including a heating module, an acquisition module, and a control module. The heating module is used to generate heat and generate resistance change values when heating at different powers; the acquisition module is used to acquire the The resistance change value generated when the heating module generates heat; the control module is used to control the heating of the heating module and is connected to the acquisition module. The acquisition module sends the obtained resistance change value parameter to the control module, and the control module Obtain the resistance change value sent by the module to control the power of the heating module to change the heating temperature.
一种雾化片的温控方法,包括温控系统,所述温控系统包括发热模块,获取模块,以及控制模块,所述发热模块用于发热、并在不同功率下发热时产生电阻变化值;所述获取模块用于获取所述发热模块发热时所产生的电阻变化值;所述控制模块用于控制发热模块发热、并与获取模块连接,所述获取模块将所获取的电阻变化值参数发送给控制模块,所述控制模块根据获取模块所发送的电阻变化值控制发热模块的功率改变发热温度。A temperature control method for an atomizer sheet, including a temperature control system. The temperature control system includes a heating module, an acquisition module, and a control module. The heating module is used to generate heat and generate resistance change values when heating at different powers. ; The acquisition module is used to obtain the resistance change value generated when the heating module generates heat; the control module is used to control the heating module to heat and is connected to the acquisition module, and the acquisition module converts the obtained resistance change value parameter Sent to the control module, the control module controls the power of the heating module to change the heating temperature according to the resistance change value sent by the acquisition module.
所述方法包括如下步骤。The method includes the following steps.
步骤S1,控制模块设置固定值,控制模块通过固定值控制发热模块发热。In step S1, the control module sets a fixed value, and the control module controls the heating module to generate heat through the fixed value.
步骤S2,发热模组经过控制模块的固定值控制不同功率下发热时产生电阻变化值,获取模块获取在发热时产生的电阻变化值。Step S2: The heating module uses the fixed value of the control module to control the resistance change value generated when heating at different powers, and the acquisition module obtains the resistance change value generated when heating.
步骤S3,获取模块将所获取的电阻变化值发送给到控制模块。In step S3, the acquisition module sends the acquired resistance change value to the control module.
步骤S4,控制模块根据所接收到的电阻变化值的变化计算得到发热模块当前温度值。Step S4: The control module calculates the current temperature value of the heating module based on the change in the received resistance change value.
步骤S5,控制模块根据计算所获得的当前温度值增大或减小对发热模块的输出功率实现温控。Step S5: The control module increases or decreases the output power of the heating module to implement temperature control according to the current temperature value obtained by calculation.
一种雾化片的防伪系统,包括发热模块,获取模块,控制模块,以及识别模块,所述发热模块用于发热、并在不同功率下发热时产生电阻变化值;所述获取模块用于获取所述发热模块发热时所产生的电阻变化值;所述控制模块用于控制发热模块发热、并与获取模块连接,所述获取模块将所获取的电阻变化值参数发送给控制模块,所述控制模块根据获取模块所发送的电阻变化值控制发热模块的功率改变发热温度;所述识别模块设于控制模块、并用于识别获取模块所获取的电阻变化值,识别模块将识别电阻变化值是否与控制模块所控制的一致来判断发热模块与其是否匹配。An anti-counterfeiting system for atomized tablets, including a heating module, an acquisition module, a control module, and an identification module. The heating module is used to generate heat and generate resistance change values when heating at different powers; the acquisition module is used to obtain The resistance change value generated when the heating module generates heat; the control module is used to control the heating module to generate heat and is connected to the acquisition module. The acquisition module sends the obtained resistance change value parameter to the control module. The module controls the power of the heating module to change the heating temperature according to the resistance change value sent by the acquisition module; the identification module is located in the control module and is used to identify the resistance change value obtained by the acquisition module. The identification module will identify whether the resistance change value is consistent with the control module. The control of the module is consistent to determine whether the heating module matches it.
本发明的一个或多个实施例的细节在下面的附图和描述中提出。本发明的其它特征、目的和优点将从说明书、附图以及权利要求书变得明显。The details of one or more embodiments of the invention are set forth in the accompanying drawings and the description below. Other features, objects and advantages of the invention will become apparent from the description, drawings and claims.
相比现有的雾化片温控,本发明用于雾化片的发热温度控制,通过获取模块获取发热模块在发热过程中产生的电阻变化值,将电阻变化值参数发送给控制模块,控制模块对发热模块的电阻变化值改变实现温控,解决了现有雾化片不能温控的问题,在实际使用时可根据液体的不同实现不同的温度控制,实用性强。具体是,设置了发热模块,获取模块,以及控制模块,所述发热模块用于发热、并在不同功率下发热时产生电阻变化值;所述获取模块用于获取所述发热模块发热时所产生的电阻变化值;所述控制模块用于控制发热模块发热、并与获取模块连接,所述获取模块将所获取的电阻变化值参数发送给控制模块,所述控制模块根据获取模块所发送的电阻变化值控制发热模块的功率改变发热温度。Compared with the existing atomizer sheet temperature control, the present invention is used to control the heating temperature of the atomizer sheet. The acquisition module obtains the resistance change value generated by the heating module during the heating process, and sends the resistance change value parameter to the control module. The module realizes temperature control by changing the resistance change value of the heating module, which solves the problem that the existing atomizer sheet cannot be temperature controlled. In actual use, different temperature controls can be achieved according to different liquids, which is highly practical. Specifically, a heating module, an acquisition module, and a control module are provided. The heating module is used to generate heat and generate resistance change values when heating at different powers; the acquisition module is used to acquire the resistance value generated when the heating module generates heat. The resistance change value of The change value controls the power of the heating module to change the heating temperature.
相比现有的雾化片温控,本发明还涉及了温度控制方法,包含了温控系统,并通过如下方式进行温度控制,步骤S1,控制模块设置固定值,控制模块通过固定值控制发热模块发热;步骤S2,发热模组经过控制模块的固定值控制不同功率下发热时产生电阻变化值,获取模块获取在发热时产生的电阻变化值;步骤S3,获取模块将所获取的电阻变化值发送给到控制模块;步骤S4,控制模块根据所接收到的电阻变化值的变化计算得到发热模块当前温度值;步骤S5,控制模块根据计算所获得的当前温度值增大或减小对发热模块的输出功率实现温控。通过增大或减小电阻变化值实现温控,智能性强,不需要设置多余的元件,结构成本低。Compared with the existing atomizer sheet temperature control, the present invention also involves a temperature control method, including a temperature control system, and performs temperature control in the following manner. In step S1, the control module sets a fixed value, and the control module controls heat generation through the fixed value. The module generates heat; Step S2, the heating module uses the fixed value of the control module to control the resistance change value generated when heating under different powers, and the acquisition module obtains the resistance change value generated when heating; Step S3, the acquisition module obtains the resistance change value Sent to the control module; Step S4, the control module calculates the current temperature value of the heating module based on the received resistance change value; Step S5, the control module increases or decreases the temperature of the heating module based on the calculated current temperature value. The output power realizes temperature control. Temperature control is achieved by increasing or decreasing the resistance change value, which is highly intelligent, does not require redundant components, and has low structural cost.
相比现有的雾化片防伪,本发明还涉及了防伪系统,具体设置了发热模块,获取模块,控制模块,以及识别模块,所述发热模块用于发热、并在不同功率下发热时产生电阻变化值;所述获取模块用于获取所述发热模块发热时所产生的电阻变化值;所述控制模块用于控制发热模块发热、并与获取模块连接,所述获取模块将所获取的电阻变化值参数发送给控制模块,所述控制模块根据获取模块所发送的电阻变化值控制发热模块的功率改变发热温度;所述识别模块设于控制模块、并用于识别获取模块所获取的电阻变化值,识别模块将识别电阻变化值是否与控制模块所控制的一致来判断发热模块与其是否匹配。通过识别电阻变化值与控制的电阻变化值是否一致进行判断该发热模块的真伪,不需要多余的元件,结构成本低。Compared with the existing anti-counterfeiting of atomized tablets, the present invention also relates to an anti-counterfeiting system, which specifically includes a heating module, an acquisition module, a control module, and an identification module. The heating module is used to generate heat and generates heat when generating heat at different powers. The resistance change value; the acquisition module is used to obtain the resistance change value generated when the heating module generates heat; the control module is used to control the heating module to heat and is connected to the acquisition module, and the acquisition module converts the acquired resistance The change value parameter is sent to the control module, which controls the power of the heating module to change the heating temperature according to the resistance change value sent by the acquisition module; the identification module is provided in the control module and is used to identify the resistance change value acquired by the acquisition module. , the identification module will identify whether the resistance change value is consistent with that controlled by the control module to determine whether the heating module matches it. The authenticity of the heating module is judged by identifying whether the resistance change value is consistent with the controlled resistance change value. No redundant components are required, and the structure cost is low.
为了更好地描述和说明这里公开的那些发明的实施例和/或示例,可以参考一幅或多幅附图。用于描述附图的附加细节或示例不应当被认为是对所公开的发明、目前描述的实施例和/或示例以及目前理解的这些发明的最佳模式中的任何一者的范围的限制。To better describe and illustrate embodiments and/or examples of those inventions disclosed herein, reference may be made to one or more of the accompanying drawings. The additional details or examples used to describe the drawings should not be construed as limiting the scope of any of the disclosed inventions, the embodiments and/or examples presently described, and the best modes currently understood of these inventions.
图1 为本发明雾化片的温控系统的连接示意图。Figure 1 is a schematic connection diagram of the temperature control system of the atomizer sheet of the present invention.
图2 为本发明雾化片的温控系统的芯片本体的立体示意图。Figure 2 is a three-dimensional schematic diagram of the chip body of the temperature control system of the atomizer sheet of the present invention.
图3 为本发明雾化片的温控系统的芯片本体另一视角的立体示意图。Figure 3 is a schematic three-dimensional view of the chip body of the temperature control system of the atomizer sheet of the present invention from another perspective.
图4 为本发明雾化片的防伪系统的连接示意图。Figure 4 is a schematic connection diagram of the anti-counterfeiting system of the atomized sheet of the present invention.
附图标记说明:发热模块1、芯片本体11、第一面111、第二面112、发热元件12、发热线路121、第一接触位122、第二接触位123、渗透区13、获取模块2、控制模块3、电阻变化值4、识别模块5。Explanation of reference signs: heating module 1, chip body 11, first surface 111, second surface 112, heating element 12, heating circuit 121, first contact position 122, second contact position 123, penetration area 13, acquisition module 2 , control module 3, resistance change value 4, identification module 5.
为了便于理解本发明,下面将参照相关附图对本发明进行更全面的描述。附图中给出了本发明的较佳实施例。但是,本发明可以以许多不同的形式来实现,并不限于本文所描述的实施例。相反地,提供这些实施例的目的是使对本发明的公开内容的理解更加透彻全面。In order to facilitate understanding of the present invention, the present invention will be described more fully below with reference to the relevant drawings. Preferred embodiments of the invention are shown in the accompanying drawings. However, the invention may be embodied in many different forms and is not limited to the embodiments described herein. Rather, these embodiments are provided so that a thorough understanding of the present disclosure will be provided.
需要说明的是,当元件被称为“固定于”另一个元件,它可以直接在另一个元件上或者也可以存在居中的元件。当一个元件被认为是“连接”另一个元件,它可以是直接连接到另一个元件或者可能同时存在居中元件。It should be noted 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 said to be "connected" to another element, it can be directly connected to the other element or there may also be intervening elements present.
除非另有定义,本文所使用的所有的技术和科学术语与属于本发明的技术领域的技术人员通常理解的含义相同。本文中在本发明的说明书中所使用的术语只是为了描述具体的实施例的目的,不是旨在于限制本发明。Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the technical field to which the invention belongs. The terminology used herein in the description of the invention is for the purpose of describing specific embodiments only and is not intended to limit the invention.
如图1~图3所示,一种雾化片的温控系统,设置了发热模块1,获取模块2,以及控制模块3,发热模块1用于发热、并在不同功率下发热时产生电阻变化值4;获取模块2用于获取发热模块1发热时所产生的电阻变化值4;控制模块3用于控制发热模块1发热、并与获取模块2连接,获取模块2将所获取的电阻变化值4参数发送给控制模块3,控制模块3根据获取模块2所发送的电阻变化值4控制发热模块1的发热温度。As shown in Figures 1 to 3, a temperature control system for an atomizer sheet is provided with a heating module 1, an acquisition module 2, and a control module 3. The heating module 1 is used to generate heat and generate resistance when heating at different powers. The change value is 4; the acquisition module 2 is used to obtain the resistance change value 4 produced when the heating module 1 generates heat; the control module 3 is used to control the heating module 1 to generate heat and is connected to the acquisition module 2, and the acquisition module 2 obtains the resistance change The value 4 parameter is sent to the control module 3, and the control module 3 controls the heating temperature of the heating module 1 according to the resistance change value 4 sent by the acquisition module 2.
发热模块1包括芯片本体11、以及设于芯片本体11的发热元件12,芯片本体11具有第一面111和第二面112,发热元件12设于第一面111,在进一步的优选实施例中,发热元件12包括设于第一面111并通过渗透区13的发热线路121,发热线路121的两端分别设有第一接触位122以及第二接触位123,发热线路121在不同功率下发热时产生电阻变化值4,获取模块2用于获取发热线路121发热时所产生的电阻变化值4;通过两个接触位用于电接触与控制模块3电连接,并通过发热线路121在不同功率下发热时产生电阻变化值4来实现温控。The heating module 1 includes a chip body 11 and a heating element 12 provided on the chip body 11. The chip body 11 has a first surface 111 and a second surface 112. The heating element 12 is provided on the first surface 111. In a further preferred embodiment , the heating element 12 includes a heating circuit 121 provided on the first surface 111 and passing through the penetration area 13. The two ends of the heating circuit 121 are respectively provided with a first contact position 122 and a second contact position 123. The heating circuit 121 generates heat under different powers. When the resistance change value 4 is generated, the acquisition module 2 is used to obtain the resistance change value 4 generated when the heating circuit 121 generates heat; it is electrically connected to the control module 3 through two contact positions for electrical contact, and through the heating circuit 121 at different powers When heating is generated, the resistance change value is 4 to achieve temperature control.
在优选的实施例中,第一面111与第二面112之间设置渗透区13,受到负压时渗透区13可用于液体通过、并能够通过发热元件12加热形成气雾,芯片本体11采用单晶硅片,渗透区13由多个微孔组成,微孔在受到负压时可通过液体,液体经过发热线路121加热后形成气雾。In a preferred embodiment, a permeable area 13 is provided between the first surface 111 and the second surface 112. When subjected to negative pressure, the permeable area 13 can be used for liquid to pass through and can be heated by the heating element 12 to form aerosol. The chip body 11 adopts In the single crystal silicon wafer, the permeability area 13 is composed of multiple micropores. The micropores can pass liquid when subjected to negative pressure, and the liquid forms aerosol after being heated by the heating circuit 121.
本发明用于雾化片的发热温度控制,通过获取模块2获取发热模块1在发热过程中产生的电阻变化值4,将电阻变化值4参数发送给控制模块3,控制模块3对发热模块1的电阻变化值4改变实现温控,解决了现有雾化片不能温控的问题,在实际使用时可根据液体的不同实现不同的温度控制,实用性强。具体是,设置了发热模块1,获取模块2,以及控制模块3,发热模块1用于发热、并在不同功率下发热时产生电阻变化值4;获取模块2用于获取发热模块1发热时所产生的电阻变化值4;控制模块3用于控制发热模块1发热、并与获取模块2连接,获取模块2将所获取的电阻变化值4参数发送给控制模块3,控制模块3根据获取模块2所发送的电阻变化值4控制发热模块1的发热温度。The invention is used to control the heating temperature of the atomizer piece. The acquisition module 2 obtains the resistance change value 4 generated by the heating module 1 during the heating process, and sends the resistance change value 4 parameter to the control module 3. The control module 3 controls the heating module 1 The resistance change value of 4 changes to achieve temperature control, which solves the problem that the existing atomizer sheet cannot be temperature controlled. In actual use, different temperature controls can be achieved according to different liquids, which is highly practical. Specifically, a heating module 1, an acquisition module 2, and a control module 3 are provided. The heating module 1 is used to generate heat and generate a resistance change value 4 when heating at different powers; the acquisition module 2 is used to obtain the resistance change value 4 when the heating module 1 generates heat. The generated resistance change value 4; the control module 3 is used to control the heating module 1 to generate heat and is connected to the acquisition module 2. The acquisition module 2 sends the obtained resistance change value 4 parameters to the control module 3. The control module 3 controls the heating module 1 according to the acquisition module 2. The sent resistance change value 4 controls the heating temperature of the heating module 1 .
参阅图1~图3所示,一种雾化片的温控方法,包括温控系统,温控系统包括发热模块1,获取模块2,以及控制模块3,发热模块1用于发热、并在不同功率下发热时产生电阻变化值4;获取模块2用于获取发热模块1发热时所产生的电阻变化值4;控制模块3用于控制发热模块1发热、并与获取模块2连接,获取模块2将所获取的电阻变化值4参数发送给控制模块3,控制模块3根据获取模块2所发送的电阻变化值4控制发热模块1的发热温度;通过获取模块2获取发热模块1在发热过程中产生的电阻变化值4,将电阻变化值4参数发送给控制模块3,控制模块3对发热模块1的电阻变化值4改变实现温控,解决了现有雾化片不能温控的问题,在实际使用时可根据液体的不同实现不同的温度控制,实用性强。Referring to Figures 1 to 3, a temperature control method for an atomizer tablet includes a temperature control system. The temperature control system includes a heating module 1, an acquisition module 2, and a control module 3. The heating module 1 is used to generate heat and The resistance change value 4 is generated when heating at different powers; the acquisition module 2 is used to obtain the resistance change value 4 generated when the heating module 1 is heated; the control module 3 is used to control the heating module 1 to generate heat and is connected to the acquisition module 2, and the acquisition module 2. Send the obtained resistance change value 4 parameters to the control module 3. The control module 3 controls the heating temperature of the heating module 1 according to the resistance change value 4 sent by the acquisition module 2; the acquisition module 2 obtains the heating temperature of the heating module 1 during the heating process. The generated resistance change value 4 is sent to the control module 3 as the resistance change value 4 parameter. The control module 3 changes the resistance change value 4 of the heating module 1 to implement temperature control, which solves the problem that the existing atomizer sheet cannot be temperature controlled. In actual use, different temperature controls can be achieved according to different liquids, which is highly practical.
方法包括如下步骤。The method includes the following steps.
步骤S1,控制模块3设置固定值,控制模块3通过固定值控制发热模块1发热。In step S1, the control module 3 sets a fixed value, and the control module 3 controls the heating module 1 to generate heat through the fixed value.
步骤S2,发热模组经过控制模块3的固定值控制不同功率下发热时产生电阻变化值4,获取模块2获取在发热时产生的电阻变化值4。In step S2, the heating module uses the fixed value of the control module 3 to control the resistance change value 4 generated when heating at different powers, and the acquisition module 2 obtains the resistance change value 4 generated during heating.
步骤S3,获取模块2将所获取的电阻变化值4发送给到控制模块3。In step S3, the acquisition module 2 sends the acquired resistance change value 4 to the control module 3.
步骤S4,控制模块3根据所接收到的电阻变化值4的变化计算得到发热模块1当前温度值。In step S4, the control module 3 calculates the current temperature value of the heating module 1 based on the change in the received resistance change value 4.
步骤S5,控制模块3根据计算所获得的当前温度值增大或减小对发热模块1的电阻变化值4实现温控。Step S5: The control module 3 increases or decreases the resistance change value 4 of the heating module 1 according to the calculated current temperature value to implement temperature control.
发热模块1包括芯片本体11、以及设于芯片本体11的发热元件12,芯片本体11具有第一面111和第二面112,发热元件12设于第一面111;第一面111与第二面112之间设置渗透区13,受到负压时渗透区13可用于液体通过、并能够通过发热元件12加热形成气雾;通过两个接触位用于电接触与控制模块3电连接,并通过发热线路121在不同功率下发热时产生电阻变化值4来实现温控。The heating module 1 includes a chip body 11 and a heating element 12 provided on the chip body 11. The chip body 11 has a first side 111 and a second side 112. The heating element 12 is provided on the first side 111; the first side 111 and the second side A permeable area 13 is provided between the surfaces 112. When subjected to negative pressure, the permeable area 13 can be used for liquid to pass through and can be heated by the heating element 12 to form aerosol; two contact positions are used for electrical contact and are electrically connected to the control module 3, and through When the heating circuit 121 generates heat at different powers, it generates a resistance change value of 4 to achieve temperature control.
发热元件12包括设于第一面111并通过渗透区13的发热线路121,发热线路121的两端分别设有第一接触位122以及第二接触位123,发热线路121在不同功率下发热时产生电阻变化值4,获取模块2用于获取发热线路121发热时所产生的电阻变化值4;芯片本体11采用单晶硅片,渗透区13由多个微孔组成,微孔在受到负压时可通过液体,液体经过发热线路121加热后形成气雾。The heating element 12 includes a heating circuit 121 provided on the first surface 111 and passing through the penetration area 13. The heating circuit 121 is provided with a first contact position 122 and a second contact position 123 at both ends. When the heating circuit 121 generates heat at different powers, The resistance change value 4 is generated, and the acquisition module 2 is used to obtain the resistance change value 4 generated when the heating circuit 121 is heated; the chip body 11 is made of a single crystal silicon wafer, and the permeability area 13 is composed of multiple micropores, and the micropores are subjected to negative pressure. The liquid can pass through the liquid, and the liquid forms aerosol after being heated by the heating circuit 121.
步骤S4中,计算电阻变化值4的变化计算方式如下。In step S4, the change in resistance change value 4 is calculated as follows.
已知发热模块1的电阻值为:1Ω;已知发热模块1的发热系数为:1820ppm;当发热模块1每提升1℃时,电阻变化值4的变化为:1820/1000000*1=0.00182Ω;当然,以上为一种计算方式,实际温度是根据环境温度计算的,控制模块3为MCU控制器,可写入计算程序计算和控制温度。It is known that the resistance value of heating module 1 is: 1Ω; it is known that the heating coefficient of heating module 1 is: 1820ppm; when heating module 1 increases by 1°C every time, the change of resistance change value 4 is: 1820/1000000*1=0.00182Ω ; Of course, the above is a calculation method, and the actual temperature is calculated based on the ambient temperature. The control module 3 is an MCU controller, which can be written into a calculation program to calculate and control the temperature.
本发明还涉及了温度控制方法,包含了温控系统,并通过如下方式进行温度控制,控制模块3设置固定值,控制模块3通过固定值控制发热模块1发热;发热模组经过控制模块3的固定值控制不同功率下发热时产生电阻变化值4,获取模块2获取在发热时产生的电阻变化值4;获取模块2将所获取的电阻变化值4发送给到控制模块3;控制模块3根据所接收到的电阻变化值4的变化计算得到发热模块1当前温度值;控制模块3根据计算所获得的当前温度值增大或减小对发热模块1的输出功率实现温控。通过增大或减小电阻变化值4实现温控,智能性强,不需要设置多余的元件,结构成本低。The present invention also relates to a temperature control method, including a temperature control system, and performs temperature control in the following manner: the control module 3 sets a fixed value, and the control module 3 controls the heating module 1 to generate heat through the fixed value; the heating module passes through the control module 3 The fixed value controls the resistance change value 4 generated when heating at different powers. The acquisition module 2 obtains the resistance change value 4 generated during heating; the acquisition module 2 sends the obtained resistance change value 4 to the control module 3; the control module 3 is based on The current temperature value of the heating module 1 is calculated by changing the received resistance change value 4; the control module 3 increases or decreases the output power of the heating module 1 according to the calculated current temperature value to implement temperature control. Temperature control is achieved by increasing or decreasing the resistance change value 4, which is highly intelligent, does not require redundant components, and has low structural cost.
参阅图4所示,一种雾化片的防伪系统,包括发热模块1,获取模块2,控制模块3,以及识别模块5,发热模块1用于发热、并在不同功率下发热时产生电阻变化值4;获取模块2用于获取发热模块1发热时所产生的电阻变化值4;控制模块3用于控制发热模块1发热、并与获取模块2连接,获取模块2将所获取的电阻变化值4参数发送给控制模块3,控制模块3根据获取模块2所发送的电阻变化值4控制发热模块1的发热温度;识别模块5设于控制模块3、并用于识别获取模块2所获取的电阻变化值4,识别模块5将识别电阻变化值4是否与控制模块3所控制的一致来判断发热模块1与其是否匹配。通过获取模块2获取发热模块1在发热过程中产生的电阻变化值4,将电阻变化值4参数发送给控制模块3,控制模块3对发热模块1的输出功率实现温控,解决了现有雾化片不能温控的问题,在实际使用时可根据液体的不同实现不同的温度控制,实用性强。Referring to Figure 4, an anti-counterfeiting system for atomized tablets includes a heating module 1, an acquisition module 2, a control module 3, and an identification module 5. The heating module 1 is used to generate heat and produce resistance changes when it is heated at different powers. Value 4; the acquisition module 2 is used to acquire the resistance change value 4 produced when the heating module 1 generates heat; the control module 3 is used to control the heating module 1 to generate heat and is connected to the acquisition module 2, and the acquisition module 2 obtains the resistance change value 4 parameters are sent to the control module 3. The control module 3 controls the heating temperature of the heating module 1 according to the resistance change value 4 sent by the acquisition module 2; the identification module 5 is provided in the control module 3 and is used to identify the resistance change acquired by the acquisition module 2. Value 4, the identification module 5 will identify whether the resistance change value 4 is consistent with that controlled by the control module 3 to determine whether the heating module 1 matches it. The acquisition module 2 obtains the resistance change value 4 generated by the heating module 1 during the heating process, and sends the resistance change value 4 parameter to the control module 3. The control module 3 implements temperature control on the output power of the heating module 1, solving the existing fog problem. The problem that the tablet cannot be temperature controlled can achieve different temperature control according to different liquids in actual use, which is highly practical.
发热模块1包括芯片本体11、以及设于芯片本体11的发热元件12,芯片本体11具有第一面111和第二面112,发热元件12设于第一面111;第一面111与第二面112之间设置渗透区13,受到负压时渗透区13可用于液体通过、并能够通过发热元件12加热形成气雾;通过两个接触位用于电接触与控制模块3电连接,并通过发热线路121在不同功率下发热时产生电阻变化值4来实现温控。The heating module 1 includes a chip body 11 and a heating element 12 provided on the chip body 11. The chip body 11 has a first side 111 and a second side 112. The heating element 12 is provided on the first side 111; the first side 111 and the second side A permeable area 13 is provided between the surfaces 112. When subjected to negative pressure, the permeable area 13 can be used for liquid to pass through and can be heated by the heating element 12 to form aerosol; two contact positions are used for electrical contact and are electrically connected to the control module 3, and through When the heating circuit 121 generates heat at different powers, it generates a resistance change value of 4 to achieve temperature control.
发热元件12包括设于第一面111并通过渗透区13的发热线路121,发热线路121的两端分别设有第一接触位122以及第二接触位123,发热线路121在不同功率下发热时产生电阻变化值4,获取模块2用于获取发热线路121发热时所产生的电阻变化值4;芯片本体11采用单晶硅片,渗透区13由多个微孔组成,微孔在受到负压时可通过液体,液体经过发热线路121加热后形成气雾。The heating element 12 includes a heating circuit 121 provided on the first surface 111 and passing through the penetration area 13. The heating circuit 121 is provided with a first contact position 122 and a second contact position 123 at both ends. When the heating circuit 121 generates heat at different powers, The resistance change value 4 is generated, and the acquisition module 2 is used to obtain the resistance change value 4 generated when the heating circuit 121 is heated; the chip body 11 is made of a single crystal silicon wafer, and the permeability area 13 is composed of multiple micropores, and the micropores are subjected to negative pressure. The liquid can pass through the liquid, and the liquid forms aerosol after being heated by the heating circuit 121.
本发明还涉及了防伪系统,具体设置了发热模块1,获取模块2,控制模块3,以及识别模块5,发热模块1用于发热、并在不同功率下发热时产生电阻变化值4;获取模块2用于获取发热模块1发热时所产生的电阻变化值4;控制模块3用于控制发热模块1发热、并与获取模块2连接,获取模块2将所获取的电阻变化值4参数发送给控制模块3,控制模块3根据获取模块2所发送的电阻变化值4控制发热模块1的发热温度;识别模块5设于控制模块3、并用于识别获取模块2所获取的电阻变化值4,识别模块5将识别电阻变化值4是否与控制模块3所控制的一致来判断发热模块1与其是否匹配。通过识别电阻变化值4与控制的电阻变化值4是否一致进行判断该发热模块1的真伪,不需要多余的元件,结构成本低。The invention also relates to an anti-counterfeiting system, which specifically includes a heating module 1, an acquisition module 2, a control module 3, and an identification module 5. The heating module 1 is used to generate heat and generate a resistance change value 4 when heating at different powers; the acquisition module 2 is used to obtain the resistance change value 4 generated when the heating module 1 generates heat; the control module 3 is used to control the heating module 1 to generate heat and is connected to the acquisition module 2. The acquisition module 2 sends the obtained resistance change value 4 parameters to the control Module 3, the control module 3 controls the heating temperature of the heating module 1 according to the resistance change value 4 sent by the acquisition module 2; the identification module 5 is provided in the control module 3 and is used to identify the resistance change value 4 obtained by the acquisition module 2, the identification module 5 will identify whether the resistance change value 4 is consistent with that controlled by the control module 3 to determine whether the heating module 1 matches it. The authenticity of the heating module 1 is determined by identifying whether the resistance change value 4 is consistent with the controlled resistance change value 4. No redundant components are required, and the structure cost is low.
以上所述实施例仅表达了本发明的几种实施方式,其描述较为具体和详细,但并不能因此而理解为对本发明专利范围的限制。应当指出的是,对于本领域的普通技术人员来说,在不脱离本发明构思的前提下,还可以做出若干变形和改进,这些都属于本发明的保护范围。因此,本发明专利的保护范围应以所附权利要求为准。The above-mentioned embodiments only express several implementation modes of the present invention, and their descriptions are relatively specific and detailed, but they should not be construed as limiting the patent scope of the present invention. It should be noted that, for those of ordinary skill in the art, several modifications and improvements can be made without departing from the concept of the present invention, and these all belong to the protection scope of the present invention. Therefore, the scope of protection of the patent of the present invention should be determined by the appended claims.
Claims (10)
- 雾化片的温控系统,其特征在于:包括The temperature control system of the atomizer sheet is characterized by: including发热模块,所述发热模块用于发热、并在不同功率下发热时产生电阻变化值;A heating module, which is used to generate heat and generate resistance change values when generating heat at different powers;获取模块,所述获取模块用于获取所述发热模块发热时所产生的电阻变化值;An acquisition module, the acquisition module is used to acquire the resistance change value generated when the heating module generates heat;控制模块,所述控制模块用于控制发热模块发热、并与获取模块连接,所述获取模块将所获取的电阻变化值参数发送给控制模块,所述控制模块根据获取模块所发送的电阻变化值控制发热模块的功率改变发热温度。Control module, the control module is used to control the heating module to generate heat and is connected to the acquisition module. The acquisition module sends the acquired resistance change value parameters to the control module. The control module controls the resistance change value sent by the acquisition module. Control the power of the heating module to change the heating temperature.
- 根据权利要求1所述的雾化片的温控系统,其特征在于:所述发热模块包括芯片本体、以及设于芯片本体的发热元件,所述芯片本体具有第一面和第二面,所述发热元件设于第一面,所述发热元件在不同功率下发热时产生电阻变化值,所述获取模块用于获取发热元件发热时产生的电阻变化值。The temperature control system of the atomizer sheet according to claim 1, characterized in that: the heating module includes a chip body and a heating element provided on the chip body, and the chip body has a first surface and a second surface. The heating element is disposed on the first surface. The heating element generates a resistance change value when it generates heat at different powers. The acquisition module is used to obtain the resistance change value generated when the heating element generates heat.
- 根据权利要求2所述的雾化片的温控系统,其特征在于:所述第一面与第二面之间设置渗透区,受到负压时所述渗透区可用于液体通过、并能够通过发热元件加热形成气雾。The temperature control system of the atomizing sheet according to claim 2, characterized in that: a permeable area is provided between the first surface and the second surface, and the permeable area can be used for liquid to pass through when subjected to negative pressure, and can pass through The heating element heats to form aerosol.
- 根据权利要求3所述的雾化片的温控系统,其特征在于:所述发热元件包括设于第一面并通过渗透区的发热线路,所述发热线路的两端分别设有第一接触位以及第二接触位,所述发热线路在不同功率下发热时产生电阻变化值,所述获取模块用于获取发热线路发热时所产生的电阻变化值。The temperature control system of the atomizer sheet according to claim 3, characterized in that: the heating element includes a heating circuit provided on the first surface and passing through the penetration area, and first contacts are provided at both ends of the heating circuit. and the second contact position, the heating circuit generates a resistance change value when the heating circuit generates heat at different powers, and the acquisition module is used to obtain the resistance change value generated when the heating circuit generates heat.
- 雾化片的温控方法,其特征在于:包括温控系统,所述温控系统包括发热模块,获取模块,以及控制模块,所述发热模块用于发热、并在不同功率下发热时产生电阻变化值;所述获取模块用于获取所述发热模块发热时所产生的电阻变化值;所述控制模块用于控制发热模块发热、并与获取模块连接,所述获取模块将所获取的电阻变化值参数发送给控制模块,所述控制模块根据获取模块所发送的电阻变化值控制发热模块的功率改变发热温度;The temperature control method of the atomizer tablet is characterized by: including a temperature control system. The temperature control system includes a heating module, an acquisition module, and a control module. The heating module is used to generate heat and generate resistance when generating heat at different powers. Change value; the acquisition module is used to obtain the resistance change value generated when the heating module generates heat; the control module is used to control the heating module to heat and is connected to the acquisition module, and the acquisition module obtains the resistance change value The value parameter is sent to the control module, and the control module controls the power of the heating module to change the heating temperature according to the resistance change value sent by the acquisition module;所述方法包括如下步骤:The method includes the following steps:步骤S1,控制模块设置固定值,控制模块通过固定值控制发热模块发热;Step S1, the control module sets a fixed value, and the control module controls the heating module to generate heat through the fixed value;步骤S2,发热模组经过控制模块的固定值控制不同功率下发热时产生电阻变化值,获取模块获取在发热时产生的电阻变化值;Step S2, the heating module uses the fixed value of the control module to control the resistance change value generated when heating at different powers, and the acquisition module obtains the resistance change value generated when heating;步骤S3,获取模块将所获取的电阻变化值发送给到控制模块;Step S3, the acquisition module sends the acquired resistance change value to the control module;步骤S4,控制模块根据所接收到的电阻变化值的变化计算得到发热模块当前温度值;Step S4: The control module calculates the current temperature value of the heating module based on the change in the received resistance change value;步骤S5,控制模块根据计算所获得的当前温度值增大或减小对发热模块的输出功率实现温控。Step S5: The control module increases or decreases the output power of the heating module to implement temperature control according to the current temperature value obtained by calculation.
- 根据权利要求5所述的雾化片的温控方法,其特征在于:所述发热模块包括芯片本体、以及设于芯片本体的发热元件,所述芯片本体具有第一面和第二面,所述发热元件设于第一面;所述第一面与第二面之间设置渗透区,受到负压时所述渗透区可用于液体通过、并能够通过发热元件加热形成气雾。The temperature control method of the atomizer sheet according to claim 5, characterized in that: the heating module includes a chip body and a heating element provided on the chip body, and the chip body has a first surface and a second surface. The heating element is disposed on the first surface; a permeable area is provided between the first surface and the second surface. When subjected to negative pressure, the permeable area can be used for liquid to pass through and can be heated by the heating element to form aerosol.
- 根据权利要求6所述的温控方法,其特征在于:所述发热元件包括设于第一面并通过渗透区的发热线路,所述发热线路的两端分别设有第一接触位以及第二接触位,所述发热线路在不同功率下发热时产生电阻变化值,所述获取模块用于获取发热线路发热时所产生的电阻变化值。The temperature control method according to claim 6, characterized in that: the heating element includes a heating circuit provided on the first surface and passing through the penetration area, and the two ends of the heating circuit are respectively provided with a first contact position and a second contact position. At the contact position, the heating circuit generates a resistance change value when the heating circuit generates heat at different powers, and the acquisition module is used to obtain the resistance change value generated when the heating circuit generates heat.
- 根据权利要求5所述的雾化片的温控方法,其特征在于:所述步骤S4中,计算电阻变化值的变化计算方式如下:The temperature control method of the atomizer sheet according to claim 5, characterized in that: in the step S4, the change calculation method of calculating the resistance change value is as follows:已知发热模块的电阻值为:1Ω;It is known that the resistance value of the heating module is: 1Ω;已知发热模块的发热系数为:1820ppm;The known heating coefficient of the heating module is: 1820ppm;当发热模块每提升1℃时,电阻变化值的变化为:1820/1000000*1=0.00182Ω。When the heating module increases by 1°C, the resistance change value is: 1820/1000000*1=0.00182Ω.
- 雾化片的防伪系统,其特征在于:包括The anti-counterfeiting system of atomized tablets is characterized by: including发热模块,所述发热模块用于发热、并在不同功率下发热时产生电阻变化值;A heating module, which is used to generate heat and generate resistance change values when generating heat at different powers;获取模块,所述获取模块用于获取所述发热模块发热时所产生的电阻变化值;An acquisition module, the acquisition module is used to acquire the resistance change value generated when the heating module generates heat;控制模块,所述控制模块用于控制发热模块发热、并与获取模块连接,所述获取模块将所获取的电阻变化值参数发送给控制模块,所述控制模块根据获取模块所发送的电阻变化值控制发热模块的功率改变发热温度;Control module, the control module is used to control the heating module to generate heat and is connected to the acquisition module. The acquisition module sends the acquired resistance change value parameters to the control module. The control module controls the resistance change value sent by the acquisition module. Control the power of the heating module to change the heating temperature;识别模块,所述识别模块设于控制模块、并用于识别获取模块所获取的电阻变化值,识别模块将识别电阻变化值是否与控制模块所控制的一致来判断发热模块与其是否匹配。The identification module is located in the control module and is used to identify the resistance change value obtained by the acquisition module. The identification module will identify whether the resistance change value is consistent with that controlled by the control module to determine whether the heating module matches it.
- 根据权利要求9所述的雾化片的防伪系统,其特征在于:所述发热模块包括芯片本体、以及设于芯片本体的发热元件,所述芯片本体具有第一面和第二面,所述发热元件设于第一面;所述第一面与第二面之间设置渗透区,受到负压时所述渗透区可用于液体通过、并能够通过发热元件加热形成气雾;The anti-counterfeiting system of atomized tablets according to claim 9, characterized in that: the heating module includes a chip body and a heating element provided on the chip body, the chip body has a first surface and a second surface, and the The heating element is provided on the first surface; a permeable area is provided between the first surface and the second surface, and the permeable area can be used for liquid to pass when subjected to negative pressure, and can be heated by the heating element to form aerosol;所述发热元件包括设于第一面并通过渗透区的发热线路,所述发热线路的两端分别设有第一接触位以及第二接触位,所述发热线路在不同功率下发热时产生电阻变化值,所述获取模块用于获取发热线路发热时所产生的电阻变化值。The heating element includes a heating circuit provided on the first surface and passing through the penetration area. The two ends of the heating circuit are respectively provided with a first contact position and a second contact position. The heating circuit generates resistance when heating under different powers. Change value, the acquisition module is used to obtain the resistance change value generated when the heating circuit generates heat.
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN202210840999.5 | 2022-07-18 | ||
CN202210840999.5A CN115053989A (en) | 2022-07-18 | 2022-07-18 | Temperature control system, temperature control method and anti-counterfeiting system of atomization sheet |
Publications (1)
Publication Number | Publication Date |
---|---|
WO2024016436A1 true WO2024016436A1 (en) | 2024-01-25 |
Family
ID=83205919
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
PCT/CN2022/116599 WO2024016436A1 (en) | 2022-07-18 | 2022-09-01 | Temperature control system, temperature control method and anti-counterfeiting system for atomization piece |
Country Status (2)
Country | Link |
---|---|
CN (1) | CN115053989A (en) |
WO (1) | WO2024016436A1 (en) |
Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN111802710A (en) * | 2020-08-13 | 2020-10-23 | 深圳市菲墨科技有限公司 | Electronic atomization device, atomization heating control method and device and atomizer main body |
CN112535325A (en) * | 2020-11-30 | 2021-03-23 | 深圳市吉迩科技有限公司 | Heating control method of electronic cigarette and electronic cigarette |
CN113115986A (en) * | 2021-04-21 | 2021-07-16 | 东莞市阿尔法电子科技有限公司 | Atomizing core and cigarette bullet |
CN216165205U (en) * | 2021-11-10 | 2022-04-05 | 深圳雷炎科技有限公司 | Constant current source atomizer heating circuit, true and false verification circuit and electronic atomization device |
-
2022
- 2022-07-18 CN CN202210840999.5A patent/CN115053989A/en active Pending
- 2022-09-01 WO PCT/CN2022/116599 patent/WO2024016436A1/en unknown
Patent Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN111802710A (en) * | 2020-08-13 | 2020-10-23 | 深圳市菲墨科技有限公司 | Electronic atomization device, atomization heating control method and device and atomizer main body |
CN112535325A (en) * | 2020-11-30 | 2021-03-23 | 深圳市吉迩科技有限公司 | Heating control method of electronic cigarette and electronic cigarette |
CN113115986A (en) * | 2021-04-21 | 2021-07-16 | 东莞市阿尔法电子科技有限公司 | Atomizing core and cigarette bullet |
CN216165205U (en) * | 2021-11-10 | 2022-04-05 | 深圳雷炎科技有限公司 | Constant current source atomizer heating circuit, true and false verification circuit and electronic atomization device |
Also Published As
Publication number | Publication date |
---|---|
CN115053989A (en) | 2022-09-16 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
WO2024011728A1 (en) | Atomization sheet and atomization device | |
WO2021104151A1 (en) | Heat-generating body assembly and manufacturing method therefor, and electronic atomization apparatus | |
EP4000427A1 (en) | Atomizing assembly, atomizer and aerosol generating device | |
CN216906846U (en) | Atomizing core with micropore heating sheet | |
WO2021073261A1 (en) | Heating atomization core having multi-core porous liquid-conducting material and assembly | |
WO2024016436A1 (en) | Temperature control system, temperature control method and anti-counterfeiting system for atomization piece | |
WO2019000489A1 (en) | Novel high-efficiency environmental steam generator | |
AU2001276442A1 (en) | Thermal injection and proportioning head, method for making same and functionalising or addressing system comprising same | |
WO2024082647A1 (en) | Split glass heating sheet and atomization device | |
WO2024011730A1 (en) | Integrated guide and atomization structure and atomization device | |
CN104611902A (en) | Voice control electric iron | |
CN210326036U (en) | Unmanned aerial vehicle lithium cell temperature control device | |
CN209861454U (en) | Portable piezoelectricity atomizing spraying cold drawing | |
CN204551100U (en) | A kind of acoustic control electric iron | |
CN109244193A (en) | A kind of solar battery sheet preparation process and process control system | |
CN105201888A (en) | Intelligent fan | |
CN218219093U (en) | Electronic atomizer | |
CN203678562U (en) | Electrostatic PTC film coating machine | |
CN207882778U (en) | Circuit board automatic control heating device | |
CN114794567A (en) | Heating element, atomization component and electronic atomization device | |
CN215689791U (en) | Atomization device capable of automatically adjusting air pressure | |
CN220343705U (en) | Aerosol forming device | |
CN220269554U (en) | Membrane contact humidifying device | |
WO2019047903A1 (en) | Control circuit and method for generating nano water ionic steam | |
CN111059686A (en) | Air conditioner dry-heating-preventing humidifying device, control method thereof and air conditioner |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
121 | Ep: the epo has been informed by wipo that ep was designated in this application |
Ref document number: 22951702 Country of ref document: EP Kind code of ref document: A1 |