WO2020223913A1 - 电子雾化装置及其雾化器、电源和控制方法 - Google Patents
电子雾化装置及其雾化器、电源和控制方法 Download PDFInfo
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- WO2020223913A1 WO2020223913A1 PCT/CN2019/085924 CN2019085924W WO2020223913A1 WO 2020223913 A1 WO2020223913 A1 WO 2020223913A1 CN 2019085924 W CN2019085924 W CN 2019085924W WO 2020223913 A1 WO2020223913 A1 WO 2020223913A1
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- atomization device
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- suction nozzle
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- A—HUMAN NECESSITIES
- A24—TOBACCO; CIGARS; CIGARETTES; SIMULATED SMOKING DEVICES; SMOKERS' REQUISITES
- A24F—SMOKERS' REQUISITES; MATCH BOXES; SIMULATED SMOKING DEVICES
- A24F47/00—Smokers' requisites not otherwise provided for
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- This application relates to the technical field of electronic atomization, and in particular to an atomizer, a power supply, an electronic atomization device including the atomizer and the power supply, and a control method of the electronic atomization device.
- the electronic atomization device can atomize the aerosol generating substrate, and the smoke formed after the atomization of the aerosol generating substrate does not contain harmful components such as tar and suspended particles, so that the electronic atomization device can be used as a substitute for cigarettes.
- the start-up speed is slow, the start-up accuracy rate is not high, and the structure is complicated.
- a technical problem solved by this application is how to improve the start sensitivity of the electronic atomization device.
- An electronic atomization device including:
- the atomization component is provided with a suction nozzle opening that communicates with the outside, and the suction nozzle opening is in communication with an air flow channel opened in the electronic atomization device;
- the magnetic component can move relative to the airflow channel.
- the magnetic component moves due to the change of the air pressure of the airflow channel to generate a changing magnetic field signal
- a sensing unit for receiving the changing magnetic field signal
- the processing unit is connected with the induction unit and the battery, and is used to determine the changing magnetic field signal and control the heating of the atomization assembly by the battery accordingly.
- the electronic atomization device includes a battery, a sensing unit, and a processing unit.
- the atomizer includes:
- the atomization component is provided with an air flow channel and a suction nozzle connecting the air flow channel and the outside;
- Magnetic components can move relative to the air flow channel
- the magnetic component moves due to the air pressure change of the air flow channel, and the sensing unit receives the changing magnetic field signal generated by the magnetic component and transmits the changing magnetic field signal to The processing unit determines the changing magnetic field signal and controls the heating of the atomization assembly by the battery accordingly.
- the electronic atomization device includes a magnetic component, an induction unit, and an atomizer with a suction nozzle.
- the power supply includes a battery and a processing unit, and the battery and the induction unit are both connected to the processing unit.
- the unit is electrically connected; wherein, when sucking from the mouth of the suction nozzle, the sensing unit receives the changing magnetic field signal generated by the magnetic component and transmits the changing magnetic field signal to the processing unit, and the processing unit determines the changing magnetic field signal The heating of the atomizer by the battery is controlled accordingly.
- a control method of an electronic atomization device includes the following steps:
- the magnetic component of the electronic atomization device is moved relative to the air flow channel of the electronic atomization device by suction, and the magnetic component generates a changing magnetic field signal due to the movement;
- the changing magnetic field signal is judged and the heating of the electronic atomization device is controlled accordingly.
- FIG. 1 is a schematic diagram of a three-dimensional cross-sectional view of an electronic atomization device provided by an embodiment after magnetic components are removed.
- Fig. 2 shows the state of the magnetic component in the air flow channel when the suction is stopped in the first example of Fig. 1.
- Fig. 3 shows the state of the magnetic component in the air flow channel during suction in the first example of Fig. 1.
- Fig. 4 is a schematic top view of Fig. 3.
- Fig. 5 shows the state of the magnetic component in the air flow channel when the suction or stop of the suction in the second example of Fig. 1 occurs.
- Fig. 6 shows the structure of the magnetic component in the third example of Fig. 1.
- Fig. 7 shows the structure of the magnetic component in the fourth example of Fig. 1.
- FIG. 8 is a block diagram of an implementation of the atomization method of the electronic atomization device provided.
- Figure 9 is a schematic diagram of signals generated by abnormal interference.
- Figure 10 is a schematic diagram of the signal generated by the suction airflow.
- FIG. 11 is a schematic three-dimensional cross-sectional view of an electronic atomization device provided by another embodiment.
- the electronic atomization device 10 provided by an embodiment of the present application includes an atomizer 101 and a power supply 300, and the atomizer 101 includes an atomization component 100 and a magnetic component 200.
- the electronic atomization device 10 is provided with an airflow channel 110, and the airflow channel 110 is a channel through which outside air enters the electronic atomization device 10 from at least one inlet and reaches the outlet for suction by the user.
- the electronic atomization device 10 may include one or more airflow channels 110, for example, the airflow channels 110 are all opened on the atomization assembly 100, the magnetic assembly 200 may be located inside the airflow channel 110, or the magnetic assembly 200 may be located outside the airflow channel 110 and It is arranged close to the port of the air flow channel 110, and the power source 300 is arranged opposite to the atomization assembly 100.
- the atomization assembly 100 is used to store the aerosol-generating substrate and at the same time can heat the aerosol-generating substrate for atomization.
- the smoke formed by the atomization of the aerosol-generating substrate can circulate in the airflow channel 110, and the upper end of the airflow channel 110 forms a mouthpiece 112 on the atomization assembly 100, and the mouthpiece 112 communicates with the outside.
- the atomization assembly 100 is further provided with an air inlet 121.
- the air inlet 121 is arranged on the side or bottom surface of the atomization assembly 100, and the air inlet 121 is arranged away from the nozzle opening 112.
- the air intake hole 121 communicates the air flow channel 110 with the outside.
- outside air enters the airflow channel 110 from the air inlet 121 to form a suction airflow, and the suction airflow passes through the airflow channel 110 to carry the aerosol generating matrix atomized smoke through the suction nozzle
- the mouth 112 enters the user's mouth, thereby realizing the user's suction of smoke.
- the power supply 300 is connected to the atomization assembly 100.
- the power supply 300 includes a battery 310, a sensing unit 320, a processing unit 330 and a housing.
- the battery 310, the sensing unit 320 and the processing unit 330 are all housed in the housing, and the sensing unit 320 can be housed in the housing , It can also be installed on the atomization assembly 100, and the sensing unit 320 and the processing unit 300 are electrically connected to the battery 310.
- the battery 310 heats the atomization assembly 100
- the atomization assembly 100 atomizes the aerosol generating substrate, and the atomized smoke passes through the mouthpiece 112 for the user to inhale.
- the sensing unit 320 may be a magnetic sensor, etc.
- the processing unit 330 may be a microcontroller (Microcontroller Unit, MCU), etc.
- the sensing unit 320 is used to sense a changing magnetic field signal (the changing magnetic field signal includes changes in the direction of the magnetic field, changes in the magnitude of the magnetic field, and The direction and size of the magnetic field change simultaneously), and transmit the changed magnetic field signal to the processing unit 330.
- the processing unit 330 analyzes and judges the changed magnetic field signal.
- the processing unit 330 can control whether the battery 310 heats the atomization assembly 100 or not, Furthermore, the purpose of whether to atomize the aerosol generating substrate is achieved.
- the magnetic assembly 200 When the magnetic assembly 200 is located in the airflow channel 110, the magnetic assembly 200 can be located close to the power supply 300. When the user is sucking at the mouth 112 of the suction nozzle, the magnetic assembly 200 can be relatively foggy with the suction airflow.
- the chemical component 100 moves, and the sensing unit 320 receives the changing magnetic field signal generated by the movement of the magnetic component 200.
- the sensing unit 320 is disposed at a position where the battery 310 is close to the atomizing assembly 100, for example, the sensing unit 320 is disposed below the atomizing assembly 100. This facilitates the sensing unit 320 to accurately and quickly sense the changing magnetic field signal generated by the movement of the magnetic assembly 200, and improves the sensitivity of the sensing unit 320 and the response speed of the entire electronic device to the user's suction.
- the processing unit 330 has a good filtering function. In the process of analyzing the changing magnetic field signal, the processing unit 330 can accurately determine whether the changing magnetic field signal is a normal suction signal generated by the user's suction airflow to push the magnetic assembly 200 to move. For example, when the magnetic assembly 200 vibrates due to an abnormal disturbance such as an external impact and causes a changing magnetic field signal, the processing unit 330 can effectively eliminate the interference information, so that the battery 310 will not heat the atomization assembly 100 to atomize the aerosol generating substrate . Therefore, only when the changing magnetic field signal is a normal suction signal, the processing unit 330 can react to the heating of the atomization assembly 100 by the battery 310.
- the processing unit 330 can process The unit 330 does not react to the heating of the atomizing assembly 100 by the control battery 310.
- the sensing unit 320 senses that the signal generated by abnormal interference such as external impact is an irregular signal.
- the sensing unit 320 senses that the signal generated by the suction airflow is a regular signal. Therefore, the processing unit 330 It is easy to determine whether the signal is generated by the suction air flow by analyzing whether the signal shows a certain law.
- the power supply 300 further includes an attitude sensor, which is arranged on the housing.
- the attitude sensor is used to sense the changing magnetic field signal generated by the movement of the magnetic assembly 200 caused by abnormal interference such as external vibration.
- the attitude sensor does not transmit the changing magnetic field signal to the processing unit 330 for analysis and filtering, so as to prevent the changing magnetic field signal from causing the battery 310 to
- the atomization assembly 100 is heated, which can be understood as the attitude sensor replacing the filtering function of the processing unit 330 for interference information, thereby improving the response speed of the processing unit 330.
- the attitude sensor can also sense a changing magnetic field signal from the outside, which is not caused by the movement of the magnetic assembly 200.
- the attitude sensor will also prevent the changing magnetic field signal from being transmitted to the processing unit 330.
- the magnetic assembly 200 When the magnetic assembly 200 is arranged inside the airflow channel 110 of the atomization assembly 100, the magnetic assembly 200 can make full use of the space of the existing airflow channel 110 without occupying the space outside the airflow channel 110, making the entire electronic atomization device 10 structure More compact.
- the power supply 300 receives the changing magnetic field signal generated by the movement of the magnetic assembly 200, and can quickly determine the changing magnetic field signal and control the heating of the atomization assembly 100 accordingly, thereby improving the sensitivity of the electronic atomization device 10 to start.
- the magnetic assembly 200 includes two magnetic units.
- suction is performed from the suction nozzle 112
- the suction airflow entering the airflow channel 110 from the air inlet 121 will push the two magnetic units.
- the two magnetic units slide relative to each other, thereby changing the distance between the two magnetic units to produce changes in magnetic field strength.
- the two magnetic units are respectively denoted as a fixed magnetic unit 210 and a sliding magnetic unit 220, and the fixed magnetic unit 210 is fixed at a position away from the nozzle opening 112.
- the sliding magnetic unit 220 is slidably arranged in the air flow channel 110, and the sliding magnetic unit 220 is located above the fixed magnetic unit 210.
- the air flow channel 110 above the sliding magnetic unit 220 will form a certain space Because the airflow channel 110 is located under the sliding magnetic unit 220, the space is connected to the outside through the air inlet 121, so that there is a pressure difference between the upper and lower sides of the sliding magnetic unit 220, and finally the airflow channel 110 moves from bottom to top.
- the sliding magnetic unit 220 moves toward the nozzle mouth 112 and away from the fixed magnetic unit 210 (that is, moves upward), that is, the distance between the fixed magnetic unit 210 and the sliding magnetic unit 220 changes, and the distance increases During the process, the magnetic field strength of the entire magnetic assembly 200 at the location of the sensing unit 320 also changes. At this time, the sensing unit 320 will sense the changed magnetic field signal so that the processing unit 330 can analyze the changed magnetic field signal to control the battery 310 The atomization assembly 100 is heated.
- the sensing unit 320 can also sense the changing magnetic field signal at its own position.
- the processing unit 330 has a filtering function, the processing unit 330 can accurately determine that the changing magnetic field signal is not caused by the extraction. It is caused by the suction air to push the magnetic assembly 200 to move, so the processing unit 330 will not control the battery 310 to heat the atomization assembly 100.
- the electronic atomization device 10 further includes a first bump 141 and a second bump 142.
- the shape of the first bump 141 and the second bump 142 may be approximately the same.
- the air flow channel 110 is cylindrical
- the first bump 141 Both the first and second bumps 142 are annular
- the edges of the first bump 141 and the second bump 142 are both connected with the inner wall of the airflow channel 110
- the first bump 141 is arranged close to the nozzle mouth 112
- the first bump A first communication hole 141a is provided on the 141, and the first communication hole 141a can allow air to pass through, preventing the first protrusion 141 from blocking the air flow channel 110.
- the second protrusion 142 is arranged close to the fixed magnetic unit 210.
- the second protrusion 142 is provided with a second communication hole 142a, and the second communication hole 142a can allow air to pass through, preventing the second protrusion 142 from forming the airflow channel 110 Blocking effect.
- the second bump 142 is located between the first bump 141 and the fixed magnetic unit 210.
- the first bump 141, the sliding magnetic unit 220, the second bump 142 and the fixed magnetic unit 210 are arranged in order from top to bottom along the airflow channel 110 . 3, when sucking from the nozzle opening 112, the sliding magnetic unit 220 moves upward until it abuts the first protrusion 141, and the first protrusion 141 limits the limit distance of the sliding magnetic unit 220 toward the suction nozzle opening 112 . Referring to FIG.
- first protrusion 141, the sliding magnetic unit 220, the fixed magnetic unit 210, and the second protrusion 142 can be arranged in order from top to bottom along the air flow channel 110, and the second protrusion 142 fixes the fixed magnetic unit 210.
- the second bump 142 can even be omitted.
- each magnetic unit in the magnetic assembly 200 is slidable; the first protrusion 141 and the second protrusion 142 can also be replaced by grooves opened on the inner wall of the air flow channel 110, The upper and lower side walls can limit the stroke of the sliding magnetic unit 220.
- both the first communication hole 141a and the second communication hole 142a may be circular, and the sliding magnetic unit 220 and the fixed magnetic unit 210 may be bar-shaped permanent magnets. Or electromagnetic solenoid. Since the strip permanent magnets or electromagnetic solenoids are both elongated, when the sliding magnetic unit 220 abuts the first bump 141, the elongated sliding magnetic unit 220 cannot connect the entire circular first communicating hole 141a. Blocking is performed so that the airflow can circulate through the unblocked part of the first communication hole 141a, so that the user can smoke cigarette smoke. Similarly, the elongated fixed magnetic unit 210 cannot block the entire circular second communicating hole 142a.
- the fixed magnetic unit 210 can be eliminated, so that the magnetic assembly 200 includes only one sliding magnetic unit 220.
- the sliding magnetic unit 220 slides between the first protrusion 141 and the second protrusion 142, and the first protrusion 141 and the second protrusion 142 limit the limit distance of the sliding magnetic unit 220 toward or away from the nozzle mouth 112. , That is, the limit stroke of the up and down movement of the sliding magnetic unit 220 is limited.
- the sliding magnetic unit 220 moves upward toward the suction nozzle opening 112.
- the magnetic assembly 200 can also include an elastic body 221.
- the elastic body 221 can be a spring or a diaphragm. One end of the elastic body 221 is fixed to the second bump 142, and the other end of the elastic body 221 is fixed to the sliding magnetic unit 220.
- the sliding magnetic unit 220 overcomes the elastic force of the elastic body 221 to move upwards.
- the elastic body 221 can provide restoring force, so that the sliding magnetic unit 220 quickly moves to and The position where the second bump 142 abuts.
- the magnetic assembly 200 includes two magnetic units.
- suction is performed from the suction nozzle port 112
- the suction airflow entering the airflow channel 110 from the air inlet 121 The two magnetic units will be pushed to rotate relative to each other, thereby changing the distance between the two magnetic units to produce changes in magnetic field strength.
- the two magnetic units are respectively denoted as a fixed magnetic unit 230 and a rotating magnetic unit 240, and the fixed magnetic unit 230 is fixed at a position close to the mouth 112 of the suction nozzle.
- the rotating magnetic unit 240 is rotatably arranged at a position away from the suction nozzle opening 112.
- the rotating magnetic unit 240 can be arranged opposite to the air inlet hole 121.
- the fixed magnetic unit 230 and the rotating magnetic unit 240 may both be strip-shaped permanent magnets or electromagnetic solenoids; of course, the fixed magnetic unit 230 adopts a strip-shaped permanent magnet or an electromagnetic solenoid, and the rotating magnetic unit 240 adopts a flat permanent magnet.
- the rotating magnetic unit 240 rotates around the rotating shaft 241, which is parallel to or coincides with the central axis of the air flow channel 110, that is, the rotating shaft 241 is arranged vertically; of course, the rotating shaft 241 can also be perpendicular to the air flow
- the central axis of the channel 110, that is, the rotating shaft 241 is arranged transversely.
- each magnetic unit in the magnetic assembly 200 is rotatable.
- the magnetic assembly 200 may also include only one rotating magnetic unit 240 that rotates.
- the present application also provides an electronic atomization device 10a of another embodiment.
- the main difference between the electronic atomization device 10a of this other embodiment and the electronic atomization device 10 of the above-mentioned embodiment is that the airflow channel 110a is partially opened.
- the other part of the airflow channel 110a is opened on the atomization assembly 100 to communicate with the mouth 112 of the suction nozzle.
- the magnetic assembly 200a is located in the airflow channel 110 opened in the power supply 300a.
- the electronic atomization device 10a of this other embodiment includes a power supply 300a and an atomizer 101a.
- the atomizer 101a includes an atomization assembly 100a, and the atomization assembly 100a is provided with a suction nozzle 112.
- the power supply 300a includes a battery 310a, a sensing unit 320a, a processing unit 330a, a magnetic assembly 200a and a housing.
- the battery 310a, the sensing unit 320a, and the processing unit 330a are all contained in the housing.
- the battery 310a and the sensing unit 320a are all electrically connected to the processing unit 330a.
- the processing unit 330a is arranged on the housing, and the sensing unit 320a can be arranged in the housing or mist ⁇ component 100a.
- the battery 310a is provided with an airflow channel 110a.
- the airflow channel 110a on the battery 310a is in communication with the suction nozzle 112 on the atomizer 101a.
- the magnetic assembly 200a is located in the airflow channel 110a of the battery 310a and can move relative to the battery 310a.
- the structure of the magnetic component 200 in the electronic atomization device 10 of 200a and the above-mentioned embodiment may be the same.
- the magnetic component 200a moves due to the pressure change in the air flow channel 110a, and the sensing unit 320a receives the changing magnetic field signal generated by the movement of the magnetic component 200a and transmits it to the processing unit.
- the unit 330a and the processing unit 330a determine the changing magnetic field signal and control the heating of the atomizer 101a by the battery 310a accordingly.
- the present application also provides an atomizer 101, which is used to connect to a power supply 300.
- the atomizer 101 includes an atomization assembly 100 and a magnetic attraction assembly 200.
- the atomization assembly 100 is provided with an airflow channel 110 and communication. The outside and the suction nozzle opening 112 of the air flow channel 110, the magnetic attraction assembly 200 can move relative to the air flow channel 110, and the magnetic attraction assembly 200 may be located inside the air flow channel 110.
- the power supply 300 includes a battery 310 and a processing unit 330.
- the magnetic assembly 200 moves due to changes in the air pressure of the air flow channel 110, and the processing unit 330 determines the changing magnetic field signal generated by the movement of the magnetic assembly 200 and controls the atomization assembly 100 accordingly. Heating.
- the atomizer 101 may further include a sensing unit 320.
- the sensing unit 320 is disposed on the atomizing assembly 100.
- the sensing unit 320 receives the changing magnetic field signal generated by the movement of the magnetic assembly 200, and the sensing unit 320 will The changing magnetic field signal is transmitted to the processing unit 330.
- the present application also provides a power supply 300 for the electronic atomization device 10, the electronic atomization device 10 includes a magnetic assembly 200, a sensing unit 320 and an atomizer 101 with a nozzle 112.
- the power supply 300 includes a battery 310 and a processing unit 330.
- the processing unit 330 is arranged on the housing of the power supply 300.
- the sensing unit 320 and the processing unit 330 are electrically connected to the battery 310.
- the sensing unit 320 receives the changing magnetic field signal generated by the magnetic assembly 200 and transmits the changing magnetic field signal to the processing unit 330.
- the processing unit 330 determines the changing magnetic field signal and controls the heating of the atomizer 101 by the battery 310 accordingly.
- the magnetic component 200 on the electronic atomization device 10 is a component of the power supply 300, that is, the power supply 300 also includes a magnetic component 200.
- the battery 310 is provided with an airflow channel 110 communicating with the nozzle 112, and the magnetic component
- the magnetic assembly 200 can be located in the airflow channel 110.
- the magnetic assembly 200 can move relative to the airflow channel 110. When sucking from the suction nozzle 112, the magnetic assembly 200 moves due to the change of the air pressure in the airflow channel 110, and the magnetic assembly 200 is generated by the movement. Change the magnetic field signal.
- the sensing unit 320 on the electronic atomization device 10 is also a component of the power supply 300, that is, the power supply 300 may further include a sensing unit 320, and the sensing unit 320 is disposed on the housing of the power supply 300.
- the present application also provides a control method of the electronic atomization device 10, which is used to control the electronic atomization device 10 in the foregoing embodiment and mainly includes the following steps:
- the magnetic component 200 of the electronic atomization device 10 is moved relative to the air flow channel 110 of the electronic atomization device 10 by suction, and the magnetic component 200 generates a changing magnetic field signal due to the movement;
- the changing magnetic field signal is determined and the heating of the electronic atomization device 10 is controlled accordingly.
- the movement of the magnetic assembly 200 relative to the air flow channel 110 may be sliding, rotating, a combination of sliding and rotating, and so on.
- the changing magnetic field signal is received by a sensing unit 320 such as a magnetic sensor.
- the changing magnetic field signal includes a change in the direction of the magnetic field, a change in the magnitude of a magnetic field, or a simultaneous change in the direction and magnitude of the magnetic field.
- the sensing unit 320 transmits the changing magnetic field signal to the processing unit 330 such as a single-chip microcomputer.
- the processing unit 330 analyzes the changing magnetic field signal.
- the battery 310 is controlled to perform the atomization assembly 100 Heating; if it is determined that the changing magnetic field signal is caused by an external impact or an external magnetic field, the battery 310 is controlled not to heat the atomizing assembly 100.
- the attitude sensor can also be directly used to sense the changing magnetic field signal caused by the abnormal suction air flow such as external impact or external magnetic field, and stop transmitting the changed magnetic field signal caused by the abnormal suction air flow to the processing unit 330, so that the processing The unit 330 cannot receive the changing magnetic field signal caused by the abnormal suction airflow, that is, the attitude sensor has a filtering function to eliminate interference information.
- the control method can improve the start sensitivity on the basis of making the electronic atomization device compact.
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Claims (16)
- 一种电子雾化装置,其特征在于,包括:雾化组件,开设有与外界连通的吸嘴口,所述吸嘴口与所述电子雾化装置中开设的气流通道连通;电池,用于为所述雾化组件提供电能;磁性组件,能够相对所述气流通道运动,当用户从所述吸嘴口抽吸时,所述磁性组件因所述气流通道的气压变化而运动以产生变化磁场信号;感应单元,用于接收所述变化磁场信号;及处理单元,与所述感应单元和所述电池连接,用于判断所述变化磁场信号并据以控制所述电池对所述雾化组件的加热。
- 根据权利要求1所述的电子雾化装置,其特征在于,所述磁性组件位于所述气流通道中或靠近所述气流通道的端口设置。
- 根据权利要求1所述的电子雾化装置,其特征在于,所述磁性组件包括两个磁性单元,当从所述吸嘴口抽吸时,两个磁性单元相对滑动而改变两者间距以产生磁场变化。
- 根据权利要求3所述的电子雾化装置,其特征在于,所述两个磁性单元包括固定磁性单元和滑动磁性单元,所述固定磁性单元固定在远离所述吸嘴口的位置处,所述滑动磁性单元滑动设置在所述气流通道中,当从所述吸嘴口抽吸时,所述滑动磁性单元相对固定磁性单元运动。
- 根据权利要求4所述的电子雾化装置,其特征在于,还包括第一凸块和第二凸块,所述第一凸块与所述气流通道的内壁连接并靠近吸嘴口设置,所述第一凸块上开设有供气流通过的第一连通孔;所述第二凸块与所述气流通道的内壁连接并靠近固定磁性单元设置,所述第二凸块上开设有供气流通过的第二连通孔;所述第二凸块位于所述第一凸块与所述固定磁性单元之间,所述第一凸块和第二凸块用于限制滑动磁性单元运动的极限距离。
- 根据权利要求1所述的电子雾化装置,其特征在于,所述磁性组件包括滑动设置在所述气流通道中的滑动磁性单元,当从所述吸嘴口抽吸时,所 述滑动磁性单元朝向吸嘴口运动。
- 根据权利要求6所述的电子雾化装置,其特征在于,还包括第一凸块和第二凸块,第一、第二凸块均与所述气流通道的内壁连接,所述滑动磁性单元位于第一、第二凸块之间;第一、第二凸块分别能够限制滑动磁性单元朝向或远离吸嘴口运动的极限距离。
- 根据权利要求7所述的电子雾化装置,其特征在于,所述磁性组件还包括弹性体,所述第一凸块靠近所述吸嘴口设置,所述弹性体连接在所述滑动磁性单元和第二凸块之间,当停止抽吸时,所述弹性体对所述滑动磁性单元施加作用力使其靠近第二凸块运动。
- 根据权利要求1所述的电子雾化装置,其特征在于,所述磁性组件包括两个磁性单元,当从所述吸嘴口抽吸时,两个磁性单元相对转动以产生磁场变化。
- 根据权利要求9所述的电子雾化装置,其特征在于,所述两个磁性单元包括固定磁性单元和转动磁性单元,所述固定磁性单元固定在靠近所述吸嘴口的位置处,所述转动磁性单元转动设置在远离所述吸嘴口的位置处;当从所述吸嘴口抽吸时,所述转动磁性单元相对所述固定磁性组件转动。
- 一种电子雾化装置的雾化器,电子雾化装置包括电池、感应单元和处理单元,其特征在于,所述雾化器包括:雾化组件,开设有气流通道以及连通气流通道与外界的吸嘴口;及磁性组件,能够相对气流通道运动;其中,当从所述吸嘴口抽吸时,所述磁性组件因所述气流通道的气压变化而产生运动,所述感应单元接收所述磁性组件产生的变化磁场信号并将变化磁场信号传输至所述处理单元,所述处理单元判断变化磁场信号并据以控制所述电池对所述雾化组件的加热。
- 根据权利要求11所述的雾化器,其特征在于,还包括感应单元,所述感应单元设置在所述雾化器上。
- 一种电子雾化装置的电源,电子雾化装置包括磁性组件、感应单元 和带有吸嘴口的雾化器,其特征在于,所述电源包括电池和处理单元,所述电池和感应单元均与所述处理单元电性连接;其中,当从所述吸嘴口抽吸时,所述感应单元接收磁性组件产生的变化磁场信号并将变化磁场信号传输至所述处理单元,所述处理单元判断变化磁场信号并据以控制所述电池对所述雾化器的加热。
- 根据权利要求13所述的电源,其特征在于,还包括磁性组件,所述电源上开设有与所述吸嘴口连通的气流通道,所述磁性组件能够相对所述气流通道运动;其中,当从所述吸嘴口抽吸时,所述磁性组件因所述气流通道的气压变化而产生运动,所述磁性组件因运动而产生变化磁场信号。
- 根据权利要求13所述的电源,其特征在于,还包括感应单元,所述感应单元接收因所述磁性组件运动而产生的变化磁场信号并将变化磁场信号传输至所述处理单元。
- 一种电子雾化装置的控制方法,其特征在于,所述方法包括如下步骤:通过抽吸使得电子雾化装置的磁性组件相对所述电子雾化装置的气流通道运动,所述磁性组件因运动而产生变化磁场信号;接收所述变化磁场信号;及判断所述变化磁场信号并据以控制电子雾化装置的加热。
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