CN113693300A - Atomization control method and aerosol generating device - Google Patents

Abstract

The embodiment of the application provides an atomization control method and an aerosol generating device, wherein the atomization control method comprises the following steps: firstly, obtaining an action signal, then analyzing the action signal to obtain action data in the action signal, comparing the action data with preset trigger data based on the action data to obtain a comparison result, and executing a preset operation when the comparison result represents that the action data belongs to the preset trigger data, wherein the preset operation comprises atomization operation. Different users can generate action signals through interaction between the aerosol generating devices and then execute preset operation according to the action signals, so that interaction between the aerosol generating devices can be realized, the functions of the aerosol generating devices are enriched, and the technical problem that the functions of the current aerosol generating devices cannot meet the entertainment requirements of the users is effectively solved.

Description

Atomization control method and aerosol generating device

Technical Field

The present disclosure relates to the field of atomization control technologies, and in particular, to an atomization control method and an aerosol generating device.

Background

Along with the improvement of living standard, people's recreational mode is also more and more abundant, and aerosol generating device is as an electronic entertainment equipment, receives young people's favor widely.

Current aerosol generating devices are used in the following ways: the aerosol substrate is heated by the atomizer in the aerosol generating device under the control of the suction force generated by the oral cavity of a user, so that the aerosol substrate is atomized to form aerosol, and different users cannot directly interact with each other through the aerosol generating device when using the aerosol generating device, so that the aerosol generating device has a single function and cannot meet the entertainment requirements of the users.

Disclosure of Invention

The embodiment of the application provides an atomization control method and an aerosol generating device, which can solve the technical problem that the function of the existing aerosol generating device cannot meet the entertainment requirement of a user.

The embodiment of the application provides an atomization control method, which is applied to an aerosol generating device and comprises the following steps:

acquiring an action signal;

analyzing the action signal to obtain action data in the action signal;

comparing the action data with preset trigger data to obtain a comparison result;

and when the comparison result represents that the action data belongs to the preset trigger data, executing a preset operation, wherein the preset operation comprises an atomization operation.

Wherein, the acquiring the action signal comprises:

when a pressure sensor in the aerosol generating device detects a pressure signal, an acceleration sensor in the aerosol generating device is triggered to detect an action signal, and a host and an atomizer are arranged in the aerosol generating device.

Wherein, before the step of detecting the motion signal by the sensing unit, the method further comprises:

receiving preset trigger data sent by a terminal;

and storing the preset trigger data to a storage module.

Wherein, the action data include the motion trail data of the aerosol generating device, the preset trigger data include the preset motion trail data, the action data and the preset trigger data are compared to obtain a comparison result, the method comprises the following steps:

comparing the motion trail data of the aerosol generating device with the preset motion trail data to obtain the similarity between the motion trail data of the aerosol generating device and the preset motion trail data;

and determining the similarity as a comparison result.

Wherein, the action data still includes aerosol generating device and other aerosol generating device's collision data, predetermine trigger data still includes and predetermines collision data, based on action data compares with predetermine trigger data, obtains the comparison result, still includes:

comparing collision data of the aerosol generating device and the other aerosol generating devices with preset collision data to obtain a difference value between the collision data of the aerosol generating device and the other aerosol generating devices and the preset collision data;

and determining the difference as an alignment result.

When the comparison result represents that the action data belongs to the preset trigger data, executing a preset operation, including:

and when the similarity is equal to a preset similarity, determining that the action data belong to the preset trigger data represented by the comparison result, and controlling the host to start the atomizer so as to atomize the aerosol base material in the atomizer to form aerosol.

Wherein, when the comparison result represents that the action data belongs to the preset trigger data, executing a preset operation, further comprising:

and when the difference value is equal to a preset difference value, determining that the action data belongs to the preset trigger data represented by the comparison result, and controlling the host to start the atomizer so as to atomize the aerosol base material in the atomizer to form aerosol.

An embodiment of the present application further provides an aerosol generating device, including:

the acquisition module is used for acquiring action signals;

the analysis module is used for analyzing the action signal to obtain action data in the action signal;

the comparison module is used for comparing the action data with preset trigger data to obtain a comparison result;

and the execution module is used for executing preset operation when the comparison result represents that the action data belongs to the preset trigger data, wherein the preset operation comprises atomization operation.

The embodiment of the application provides an atomization control method and an aerosol generating device. Different users can generate action signals through interaction between the aerosol generating devices and then execute preset operation according to the action signals, so that interaction between the aerosol generating devices can be realized, the functions of the aerosol generating devices are enriched, and the technical problem that the functions of the current aerosol generating devices cannot meet the entertainment requirements of the users is effectively solved.

Drawings

The technical solution and other advantages of the present application will become apparent from the detailed description of the embodiments of the present application with reference to the accompanying drawings.

Fig. 1 is a schematic structural diagram of an atomization control system according to an embodiment of the present application.

Fig. 2 is a schematic flow chart of an atomization control method according to an embodiment of the present disclosure.

Fig. 3 is a scene schematic diagram of an atomization control method provided in an embodiment of the present application.

Fig. 4 is another schematic flow chart of an atomization control method according to an embodiment of the present disclosure.

Fig. 5 is a schematic structural diagram of an aerosol-generating device according to an embodiment of the present application.

Fig. 6 is another schematic structural diagram of an aerosol-generating device according to an embodiment of the present disclosure.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

The embodiment of the application provides an atomization control method and an aerosol generating device.

First embodiment

As shown in fig. 1, fig. 1 is a schematic structural diagram of an atomization control system provided in an embodiment of the present application.

Wherein, the aerosol generating device 100 comprises a host 110, a nebulizer 120 and an interface 130, the other aerosol generating device 200 comprises another host 210, another nebulizer 220 and another interface 230, wherein:

the aerosol-generating device 100 and the terminal 300 and the other aerosol-generating device 200 and the terminal 300 are connected and communicated with each other through the internet or the like constituted by various gateways. For example, before the first use, the terminal 300 may perform a pairing connection operation by scanning a factory two-dimensional code of the aerosol-generating device 100; for another example, the user may turn on bluetooth through a bluetooth button of the aerosol-generating device 100, so that the terminal 300 can perform pairing connection with the aerosol-generating device through bluetooth, and the like, and the present application does not specifically limit the connection manner between the aerosol-generating device 100, the other aerosol-generating devices 200, and the terminal 300. Wherein, the user can send the preset trigger data customized by the user to the aerosol-generating device 100 through the terminal 300, so that the aerosol-generating device 100 stores the preset trigger data in the memory (optionally, the preset trigger data can also be written into the memory of the aerosol-generating device 100 in advance for storage when the aerosol-generating device is shipped out), and the aerosol-generating device 100 and the other aerosol-generating devices 200 can interact with each other.

The host 110 and the other hosts 210 each include circuit boards, memory, switching elements, sensors, and the like. The circuit board in the host 110 is mainly used for supplying power to the host 110 and the atomizer 120, the circuit boards in the other hosts 210 are mainly used for supplying power to the other hosts 210 and the other atomizers 220, and the memories in the host 210 and the memories in the other hosts 210 can be Static Random-Access memories (SRAMs), which are high in speed; or an Electrically Erasable Read-Only Memory (EEPROM), which has a fast update speed and can still store data when power is off; the Memory can also be a Flash Memory (Flash Memory), can be written in and read out, has large capacity and high speed, can improve the storage performance, and can also be other suitable memories; the switching element may include a microphone, which is mainly used to sense an electrical parameter generated by a negative pressure generated by a change in airflow in the intake passage, output a sensing signal to the circuit board according to the change in the electrical parameter, and transmit the airflow to the suction sensor in the atomizer 120 for detection; the sensors include pressure sensors, distance sensors, heat sensitive sensors, speed sensors, acceleration sensors, and the like.

Atomizer 120 and other atomizers 220 all include atomizing core, atomizing electrode, connecting piece, atomizing chamber, aerosol substrate storage chamber, air outlet channel, suction nozzle, drain and generate heat the piece.

The host 110 and the nebulizer 120 are electrically connected, and the other host 210 and the other nebulizer 220 are electrically connected, as shown in fig. 1, the host 110 and the nebulizer 120 may be electrically connected through an interface 130, and the other host 210 and the other nebulizer 220 may be electrically connected through an interface 230, wherein the interface 130 and the interface 230 may be a Type-C interface, a Type-B interface, a USB interface, or the like, and the form of the interface 130 and the interface 230 is not specifically limited herein; optionally, electrodes may also be disposed on the host 110, the atomizer 120, the other hosts 210, and the other atomizers 220, so that the host 110 and the atomizer 120 are electrically connected through the electrodes, and the other hosts 210 and the other atomizers 220 are electrically connected through the electrodes.

Second embodiment

As shown in fig. 2, fig. 2 is a schematic flow chart of an atomization control method provided in the embodiment of the present application, and a specific flow may be as follows:

201. and acquiring a motion signal.

Wherein the motion signal is a signal generated according to a motion state. In particular, the action signal comprises a signal generated in dependence on a state of motion of the aerosol generating device.

For example, a signal generated when the aerosol-generating device is shaken, a signal generated when the aerosol-generating device is displaced, or a signal generated when the aerosol-generating device is collided.

In the prior art, the aerosol generating device is used in the following manner: the aerosol substrate is heated by the atomizer in the aerosol generating device under the control of the suction force generated by the oral cavity of a user, so that the aerosol substrate is atomized to form aerosol, and different users cannot directly interact with each other through the aerosol generating device when using the aerosol generating device, so that the aerosol generating device has a single function and cannot meet the entertainment requirements of the users.

In the embodiment, when a plurality of users use different aerosol generating devices, action signals can be generated through interaction among the aerosol generating devices, and preset operation is executed according to the action signals, so that interaction among the aerosol generating devices can be realized, the functions of the aerosol generating devices are enriched, and the technical problem that the functions of the existing aerosol generating devices cannot meet entertainment requirements of the users is effectively solved.

Furthermore, the aerosol generating device is provided with a sensing unit, the sensing unit comprises an acceleration sensor (or a gyroscope), a speed sensor and a pressure sensor, the acceleration sensor (or the gyroscope) is used for sensing and detecting the action signal, and the situation of false detection is easy to occur in the actual use process.

In order to avoid false detection of the motion signal, a pressure sensor (e.g., a button) is optionally provided in the aerosol generating device, and the pressure sensor detects the pressure signal when a user presses/touches the pressure sensor, and the acceleration sensor is triggered to start sensing and detecting the motion signal only when the pressure sensor detects the pressure signal.

202. And analyzing the action signal to obtain action data in the action signal.

The motion data is data carried in the motion signal. For example, motion trajectory data of the aerosol-generating device, vibration data of the aerosol-generating device, or collision data generated by the aerosol-generating device during a collision with another aerosol-generating device.

Specifically, the motion trajectory data includes a plurality of position coordinates that the aerosol generating device passes from the beginning to the end of the motion within a certain time, and the trajectory formed by the aerosol generating device can be obtained through the position coordinates, for example, the motion trajectory of the aerosol generating device within 2s is an ellipse.

The vibration data may comprise a value of the vibration frequency of the aerosol generating device over a period of time, or a cumulative number of vibrations of the aerosol generating device over a period of time, for example, a vibration frequency of the aerosol generating device of 2 vibrations/second over 4s, or a cumulative number of vibrations of the aerosol generating device of 6 times over 3 s.

The collision data generated by the aerosol generating device and the other aerosol generating devices in the collision process comprises the number of times that the aerosol generating device and the other aerosol generating devices collide (or contact) with each other in a certain time, optionally, in the first embodiment, the collision (or contact) is sensed by a pressure sensor in the aerosol generating device and the other aerosol generating devices to obtain the number of times that the aerosol generating device and the other aerosol generating devices collide (or contact) with each other in a certain time; in a second embodiment, a sensing region for sensing collision (or contact) is provided in the aerosol-generating device and the other aerosol-generating device in advance to obtain the number of times the aerosol-generating device and the other aerosol-generating device collide (or contact) with each other in a certain period of time.

203. And comparing the action data with preset trigger data to obtain a comparison result.

The preset trigger data is action data generated by the aerosol generating device within a certain time, can be preset and stored, and is used for comparing the action data with action data actually generated by the aerosol generating device to obtain a comparison result. Optionally, the preset data includes preset motion trajectory data, preset vibration data, or preset collision data.

Optionally, the motion data in step 203 includes motion trajectory data actually generated by the aerosol generating device within a certain time, the motion trajectory data of the aerosol generating device is compared with preset motion trajectory data in preset data, a similarity between the motion trajectory data of the aerosol generating device and the preset motion trajectory data is obtained through calculation, and the similarity is determined as a comparison result.

For example, if the preset motion trajectory data is that the motion trajectory formed by the aerosol generating device in 2s is an ellipse, and the motion trajectory formed by the aerosol generating device in 2s is an ellipse, the similarity between the motion trajectory data and the preset motion trajectory data is 100% through calculation, and then 100% is determined as the comparison result.

Optionally, the action data includes a numerical value of an actual vibration frequency of the aerosol generating device within a certain time, the vibration data of the aerosol generating device is compared with preset vibration data in the preset data, a difference between the vibration data of the aerosol generating device and the preset vibration data is obtained through calculation, and the difference is determined as a comparison result.

For example, if the preset vibration data is that the vibration frequency of the aerosol generating device within 2s is 2 times/second, and the vibration frequency of the aerosol generating device within 2s is 2 times/second, the difference between the vibration data of the aerosol generating device and the preset vibration data is calculated to be 0, and then 0 is determined as the comparison result.

Optionally, the action data may further include the number of times of mutual collision (or contact) between the aerosol generating device and another aerosol generating device within a certain time, compare the number of times of mutual collision (or contact) with preset collision data (including the preset number of times of collision), obtain a difference value between the number of times of mutual collision (or contact) between the aerosol generating device and another aerosol generating device within a certain time and the preset collision data through calculation, and determine the difference value as a comparison result.

For example, if the preset collision data is that the number of times of collision between the aerosol generating device and other aerosol generating devices in 2s is 4, and the difference between the number of times of mutual collision (or contact) between the aerosol generating device and other aerosol generating devices in a certain time and the preset collision data is obtained through calculation and is 0, then 0 is determined as the comparison result.

204. And when the comparison result represents that the action data belong to the preset trigger data, executing preset operation, wherein the preset operation comprises atomization operation.

The preset trigger data is reference data used for judging whether to execute preset operation, the preset trigger data can be preset through the terminal before the action signal is detected through the sensing unit, and after the preset trigger data is set, the preset trigger data is sent to the storage module in the aerosol generating device by the terminal to be stored. Specifically, the terminal is an electronic terminal (for example, a smart phone or an iPad) with a preset trigger data setting function.

Optionally, the terminal queries a nearby aerosol generating device in advance through bluetooth broadcast, initiates a pairing request to the aerosol generating device after querying the aerosol generating device, completes pairing with the aerosol generating device after the aerosol generating device receives the pairing request, initiates a connection request to the aerosol generating device, establishes connection between the terminal and the aerosol generating device when the aerosol generating device receives the connection request, and can set preset trigger data through the terminal.

For example, as shown in fig. 3, a user clicks a preset trigger setting control 3002 in a preset trigger setting interface 3001 to set drawing of a rectangular motion trajectory as a preset trigger, and generates preset trigger data corresponding to the rectangular motion trajectory to send the preset trigger data to a flash memory in the aerosol generating device for storage, and at the same time, displays "setting is successful |)! "to prompt the user that the preset trigger action is set to be completed.

Wherein the preset operation comprises an atomization operation, and specifically, the atomization operation is as follows: the atomizer is activated by a host of the aerosol generating device, thereby heating the aerosol substrate in the atomizer to form an aerosol.

Optionally, the similarity between the motion trajectory data of the aerosol generating device and the preset motion trajectory data is used as a comparison result, and when the similarity between the motion trajectory data of the aerosol generating device and the preset motion trajectory data is equal to the preset similarity, the comparison result represents that the motion data belongs to the preset trigger operation, and the atomization operation is executed.

For example, the similarity between the motion trajectory data of the aerosol generation device and the preset motion trajectory data is 100%, and the preset similarity is 100%, so that the host of the aerosol generation device is controlled to activate the atomizer, so as to heat the aerosol substrate in the atomizer and form the aerosol.

Optionally, a difference between the vibration data of the aerosol generating device and the preset vibration data is used as a comparison result, and when the difference between the vibration data of the aerosol generating device and the preset vibration data is equal to a preset value, the comparison result represents that the action data belongs to a preset trigger operation, and the atomization operation is executed.

For example, the difference between the vibration data of the aerosol generating device and the preset vibration data is 0, and the preset value is 0, so that the host of the aerosol generating device is controlled to activate the atomizer, thereby heating the aerosol substrate in the atomizer to form the aerosol.

In prior art, because the user lacks the interdynamic at the in-process that uses the aerosol to produce the device to the ceremony that leads to the use feels and the taste is lower, and then leads to the not good problem of user experience sense.

In order to improve the ceremonial sensation and the interestingness of the aerosol generating device in the using process, optionally, a difference value between the mutual collision (or contact) times of the aerosol generating device and other aerosol generating devices in a certain time and preset collision data is used as a comparison result, and when the difference value between the mutual collision (or contact) times of the aerosol generating device and other aerosol generating devices in a certain time and the preset collision data is equal to the preset difference value, the comparison result represents that the action data belongs to preset triggering operation, and atomization operation is executed.

For example, the difference between the number of times of mutual collision (or contact) between the aerosol generating device and the other aerosol generating devices in a certain period of time and the preset collision data is 0, and the preset difference is 0, so that the host of the aerosol generating device is controlled to activate the atomizer, thereby heating the aerosol substrate in the atomizer to form the aerosol, and at the same time, the host of the other aerosol generating devices is controlled to activate the atomizers in the other aerosol generating devices, thereby heating the aerosol substrate in the other aerosol generating devices to form the aerosol.

Therefore, the interaction function between the aerosol generating devices is added in the atomization operation process, so that the ceremonial feeling and the interesting degree of a user in the process of using the aerosol generating devices are increased, and the experience feeling of the user is further improved.

Optionally, the preset operation may further include an atomizing power control operation. When the aerosol generating device forms aerosol, the voltage (or current) provided by the host machine is increased to improve the atomization power of the aerosol substrate in the aerosol generating device, so that a large amount of aerosol is generated.

In addition, the preset operation may further include an aerosol spray control operation, a fan may be previously provided in the aerosol generating device, and the suction nozzle of the aerosol generating device is set in a nozzle shape, and the fan is turned on after the aerosol generating device generates a large amount of aerosol, so that the generated large amount of aerosol keeps a straight line spray shape within a certain distance from the suction nozzle of the aerosol generating device by rotation of the fan, and a user may draw the aerosol shape by moving the aerosol generating device. For example, the user makes the drawn aerosol rectangular in shape by moving the aerosol generating device such that the motion trajectory of the aerosol generating device is rectangular.

Optionally, during the process of moving the aerosol generating device by the user, the moving speed of the aerosol generating device may be detected in real time by a speed sensor in the aerosol generating device, and the rotating speed of the fan is controlled in real time according to the detection result, so that the rotating speed of the fan matches with the moving speed of the aerosol generating device, for example: when the moving speed of the aerosol generating device is greater than a preset threshold value, the rotating speed of the fan is controlled to be increased to a first preset rotating speed, and when the moving speed of the aerosol generating device is smaller than the preset threshold value, the rotating speed of the fan is controlled to be reduced to a second preset rotating speed (the second preset rotating speed is smaller than the first preset rotating speed), so that the condition that the linear spraying shape of the aerosol is changed due to the change of the moving speed of the aerosol generating device is avoided, and the user is not influenced by the moving speed when the aerosol generating device is moved to draw the shape of the aerosol.

For example, when the moving speed of the aerosol generating device is more than 2m/s, the rotating speed of the fan is controlled to be increased to 10r/s, and when the moving speed of the aerosol generating device is less than 2m/s, the rotating speed of the fan is controlled to be decreased to 5 r/s.

Further, if the aerosol generating device and the other aerosol generating devices both form aerosol and the distance between the aerosol generating device and the other aerosol generating devices is detected to be smaller than the preset distance by the distance sensors in the aerosol generating device and the other aerosol generating devices, when the preset condition is met, the voltage (or the current) provided by the host machine of the aerosol generating device and the host machines of the other aerosol generating devices is increased to improve the atomizing power of the aerosol base material, so that a large amount of aerosol is generated, and the fans in the aerosol generating devices are respectively started after the aerosol generating devices and the other aerosol generating devices generate a large amount of aerosol, so that the generated large amount of aerosol keeps a linear spraying shape within a certain distance from the suction nozzle (nozzle shape) of the aerosol generating device and/or the suction nozzle (nozzle shape) of the other aerosol generating devices through the rotation of the fans, a user may draw the shape of the aerosol by moving the aerosol-generating device and/or other aerosol-generating devices. Likewise, the moving speed can be detected in real time by the speed sensor in the aerosol generating device and other aerosol generating devices, and the fan rotating speed in the aerosol generating device and other aerosol generating devices can be controlled in real time according to the detected moving speed, so that the user is not influenced by the moving speed when moving the aerosol generating device and/or other aerosol generating devices to draw the shape of the aerosol.

In one embodiment, the preset condition is satisfied by: when the aerosol generating device establishes a wireless connection (e.g., through a bluetooth connection or NFC connection) with the other aerosol generating device, then it is determined that the preset condition is satisfied, thereby increasing the voltage (or current) provided by the host of the aerosol generating device and the host of other aerosol generating devices, so as to improve the atomization power of the aerosol substrate, thereby generating a large amount of aerosol, and respectively starting the fans inside the aerosol generating device and other aerosol generating devices after the aerosol generating device and other aerosol generating devices generate a large amount of aerosol, so that the generated mass of aerosol is kept in a straight spray pattern by the rotation of the fan within a certain distance from the suction nozzle (nozzle shape) of the aerosol generating device and/or the suction nozzle (nozzle shape) of other aerosol generating devices, the user can draw the shape of the aerosol by moving the aerosol generating device and/or other aerosol generating devices.

For example, when detecting that the bluetooth connection is established between the aerosol generating device and another aerosol generating device, the voltages provided by the host of the aerosol generating device and the hosts of the other aerosol generating devices are increased, and the fans inside the aerosol generating devices are respectively turned on after the aerosol generating devices and the other aerosol generating devices generate a large amount of aerosol, the user a moves the aerosol generating device to make the aerosol of the aerosol generating device draw a rectangular shape, and the user B moves the other aerosol generating device to make the aerosol of the other aerosol generating device draw a heart shape.

In another embodiment, the preset condition is satisfied by: after the aerosol generating device and other aerosol generating devices are wirelessly connected (including Bluetooth connection or NFC connection), the aerosol generating device and other aerosol generating devices are moved to form a motion track, the motion tracks generated by the aerosol generating device and the other aerosol generating devices in the moving process are detected by using acceleration sensors (or gyroscopes) in the aerosol generating device and the other aerosol generating devices, the motion tracks detected by the acceleration sensors are sent to an opposite side to be compared to obtain a comparison result, if the motion tracks generated by the aerosol generating device and the other aerosol generating devices in the moving process are the same as each other in the comparison result, a preset condition is determined to be met, so that the voltage (or current) provided by a host of the aerosol generating device and hosts of the other aerosol generating devices is increased to improve the atomization power of aerosol base materials, a large amount of aerosol is generated, and fans in the aerosol generating devices and the other aerosol generating devices are respectively started, so that the generated mass of aerosol is kept in a straight spray pattern by the rotation of the fan within a certain distance from the suction nozzle (nozzle shape) of the aerosol generating device and/or the suction nozzle (nozzle shape) of other aerosol generating devices, the user can draw the shape of the aerosol by moving the aerosol generating device and/or other aerosol generating devices.

For example, after the bluetooth connection is established between the aerosol generating device and other aerosol generating devices, the aerosol generating device and other aerosol generating devices are moved, the acceleration sensor in the aerosol generating device detects that the motion track of the aerosol generating device is circular, the acceleration sensor in other aerosol generating devices detects that the motion track of the aerosol generating device is also circular, the aerosol generating device sends the motion track of the aerosol generating device to other aerosol generating devices for comparison by the other aerosol generating devices, meanwhile, the other aerosol generating devices send the motion track of the aerosol generating device to the aerosol generating device for comparison by the aerosol generating device, and as the comparison result shows that the motion tracks of the aerosol generating device and the aerosol generating device are the same, the host of the aerosol generating device and the host of the other aerosol generating devices are triggered to increase the supplied voltage, and the fans inside the aerosol generating device and the other aerosol generating devices are respectively started after generating a large amount of aerosol, the user A enables the aerosol drawing shape of the aerosol generating device to be rectangular by moving the aerosol generating device, and the user B enables the aerosol drawing shape of other aerosol generating devices to be heart-shaped by moving other aerosol generating devices.

Third embodiment

As shown in fig. 4, fig. 4 is another schematic flow chart of the atomization control method provided in the embodiment of the present application. Wherein, the terminal 400 first executes step 4001: sending a bluetooth pairing request to aerosol generating device 410, aerosol generating device 410 performs step 4002: receiving the bluetooth pairing request, the terminal 400 then performs step 4003: initiating a bluetooth connection request to the aerosol generating device 410, the aerosol generating device 410 performs step 4004: the bluetooth connection request is received, and a connection is established with the terminal 400.

Further, the terminal 400 performs step 4005: generating preset trigger data after the preset trigger action is set, and executing step 4006: sending preset trigger data to the aerosol-generating device 410, the aerosol-generating device 410 performing step 4007: receiving and storing the preset trigger data, and then executing step 4008: detecting the action signal by the sensing unit, and then executing step 4009: analyzing the action signal to obtain action data in the action signal, and executing step 4010: comparing the action data with preset trigger data to obtain a comparison result, and finally executing the step 4011: and when the comparison result represents that the action data belong to the preset trigger data, the control host starts the atomizer to heat the aerosol base material in the atomizer to form aerosol.

According to the above description, the atomization control method provided by the application is applied to an aerosol generating device, firstly, the action signal is obtained, then, the action signal is analyzed to obtain the action data in the action signal, the action data is compared with the preset trigger data based on the action data to obtain the comparison result, and the preset operation (including the atomization operation) is executed when the comparison result represents that the action data belongs to the preset trigger data. Different users can generate action signals through interaction between the aerosol generating devices and then execute preset operation according to the action signals, so that interaction between the aerosol generating devices can be realized, the functions of the aerosol generating devices are enriched, and the technical problem that the functions of the current aerosol generating devices cannot meet the entertainment requirements of the users is effectively solved.

Fourth embodiment

In accordance with the method described in the above embodiments, this embodiment will be further described from the perspective of an aerosol generating device, please refer to fig. 5, in which fig. 5 specifically describes an aerosol generating device provided in this embodiment of the present application, and the aerosol generating device may include: an obtaining module 51, an analyzing module 52, a comparing module 53 and an executing module 54, wherein:

(1) acquisition module 51

And an obtaining module 51, configured to obtain the motion signal.

(2) Parsing module 52

And the analysis module 52 is configured to analyze the motion signal to obtain motion data in the motion signal.

(3) Comparison module 53

And the comparison module 53 is configured to compare the action data with preset trigger data to obtain a comparison result.

(4) Execution Module 54

And the executing module 54 is configured to execute a preset operation when the comparison result indicates that the action data belongs to the preset trigger data, where the preset operation includes an atomizing operation.

Alternatively, the programs executed by the modules (or part of the modules) may be burned into a circuit board in the host of the aerosol generating device in advance, so as to control the execution of the programs by the circuit board.

As can be seen from the above, in the aerosol generating device provided in the present application, the obtaining module 51 obtains the action signal, the analyzing module 52 analyzes the action signal to obtain the action data in the action signal, the comparing module 53 compares the action data with the preset trigger data to obtain the comparison result, and when the comparison result indicates that the action data belongs to the preset trigger data, the executing module 54 executes the preset operation (including the atomizing operation). Different users can generate action signals through interaction between the aerosol generating devices and then execute preset operation according to the action signals, so that interaction between the aerosol generating devices can be realized, the functions of the aerosol generating devices are enriched, and the technical problem that the functions of the current aerosol generating devices cannot meet the entertainment requirements of the users is effectively solved.

Fifth embodiment

Referring to fig. 6, fig. 6 is another schematic structural diagram of an aerosol generating device according to an embodiment of the present disclosure. The aerosol generating device comprises a host 110 and a nebulizer 120.

Specifically, the atomizer 120 includes an atomizing core 70, a connecting member 80, an atomizing electrode 90, an atomizing cavity 71, an aerosol substrate storage cavity 72, an air outlet channel 73, a suction nozzle 74, a liquid guiding member 75, and a heat generating member 76, the atomizing core 70 is connected to the connecting member 80, and the atomizing electrode 90 is fixed in the connecting member 80.

The aerosol substrate storage cavity 72 is communicated with the atomization cavity 71, the atomization cavity 71 is communicated with the air outlet channel 73, the air outlet channel 73 is communicated with the suction nozzle 74, and the liquid guide part 75 and the heat generating part 76 are both located in the atomization cavity 71. The aerosol substrate storage cavity 72 is used for storing aerosol substrates, the liquid guide member 75 is located between the aerosol substrate storage cavity 72 and the heat generating member 76 to guide the aerosol substrates into the atomizing cavity 71, and the heat generating member 76 generates heat under the control of the circuit board 40 to atomize the aerosol substrates to generate aerosol.

The connecting member 80 includes a third receiving groove 81, the atomizing electrode 90 is received and fixed in the third receiving groove 81, the atomizing electrode 90 is electrically connected to the host electrode 30, the atomizing electrode 90 is further electrically connected to the heating element 76 to form a circuit loop, and the circuit board 40 controls the power supply device 50 to supply power to the heating element 76 through the circuit loop, so that the heating element 76 generates heat to atomize the aerosol substrate to generate aerosol.

Wherein the connector 80 further comprises an air inlet channel 82. One end of the air inlet channel 82 is communicated with the atomizing cavity 71, and under the action of the suction force generated by the suction nozzle 74, the outside air enters the air inlet channel 82, then enters the atomizing cavity 71 from the air inlet channel 82, and drives the aerosol generated in the atomizing cavity 71 to enter the air outlet channel 73 and enter the mouth of the user of the aerosol generating device 100 from the suction nozzle 74.

Alternatively, the air intake passage 82 is provided separately from the atomizing electrode 90.

In other embodiments, the air inlet channel 82 and the atomizing electrode 90 are combined, that is, the atomizing electrode 90 is hollow, the hollow part of the atomizing electrode is the air inlet channel 82, and the host electrode is inserted into the atomizing electrode 90.

Optionally, a second magnetic attraction member (not shown in the figure) is further disposed on the atomizer 120, the second magnetic attraction member is disposed on the atomizing connecting end surface 122 of the atomizer 120 and is opposite to the first magnetic attraction member (not shown in the figure), and the host 110 and the atomizer 120 are fixed together through the first magnetic attraction member and the second magnetic attraction member.

In another optional embodiment of this application, only set up first magnetism in host computer 110 and inhale the piece to the area of the terminal surface of increase atomizing electrode 90 towards host computer 110 makes first magnetism inhale piece can hold atomizing electrode 90, realizes magnetism and adsorbs the connection, and at this moment, atomizing electrode 90's material is for having ferromagnetic material, like metals such as iron, nickel, cobalt.

Alternatively, the host 110 may not be provided with the first magnetic attraction member, and the atomizer 120 may not be provided with the second magnetic attraction member, but may be mechanically connected together by a snap, etc.

In summary, although the present application has been described with reference to the preferred embodiments, the above-described preferred embodiments are not intended to limit the present application, and those skilled in the art can make various changes and modifications without departing from the spirit and scope of the present application, so that the scope of the present application shall be determined by the scope of the appended claims.

Claims (10)

1. An atomization control method applied to an aerosol generating device comprises the following steps:

acquiring an action signal;

analyzing the action signal to obtain action data in the action signal;

comparing the action data with preset trigger data to obtain a comparison result;

and when the comparison result represents that the action data belongs to the preset trigger data, executing a preset operation, wherein the preset operation comprises an atomization operation.

2. The fogging control method according to claim 1, wherein said acquiring an action signal includes:

when a pressure sensor in the aerosol generating device detects a pressure signal, an acceleration sensor in the aerosol generating device is triggered to detect an action signal, and a host and an atomizer are arranged in the aerosol generating device.

3. The fogging control method according to claim 1, further comprising, before the step of detecting an action signal by a sensor unit:

receiving preset trigger data sent by a terminal;

and storing the preset trigger data to a storage module.

4. The aerosol generation control method according to claim 2, wherein the motion data includes motion trajectory data of the aerosol generation device, the preset trigger data includes preset motion trajectory data, and the comparing, based on the motion data and the preset trigger data, obtains a comparison result, including:

comparing the motion trail data of the aerosol generating device with the preset motion trail data to obtain the similarity between the motion trail data of the aerosol generating device and the preset motion trail data;

and determining the similarity as a comparison result.

5. The aerosol control method according to claim 2, wherein the action data further includes collision data of the aerosol generating device with other aerosol generating devices, the preset trigger data further includes preset collision data, and the comparing, based on the action data and the preset trigger data, obtains a comparison result, further comprising:

comparing collision data of the aerosol generating device and the other aerosol generating devices with preset collision data to obtain a difference value between the collision data of the aerosol generating device and the other aerosol generating devices and the preset collision data;

and determining the difference as an alignment result.

6. The atomization control method according to claim 4, wherein when the comparison result indicates that the action data belongs to the preset trigger data, a preset operation is performed, including:

and when the similarity is equal to a preset similarity, determining that the action data belong to the preset trigger data represented by the comparison result, and controlling the host to start the atomizer so as to atomize the aerosol base material in the atomizer to form aerosol.

7. The atomization control method according to claim 5, wherein when the comparison result indicates that the action data belongs to the preset trigger data, a preset operation is performed, and further comprising:

and when the difference value is equal to a preset difference value, determining that the action data belongs to the preset trigger data represented by the comparison result, and controlling the host to start the atomizer so as to atomize the aerosol base material in the atomizer to form aerosol.

8. An aerosol generating device, comprising:

the acquisition module is used for acquiring action signals;

the analysis module is used for analyzing the action signal to obtain action data in the action signal;

the comparison module is used for comparing the action data with preset trigger data to obtain a comparison result;

and the execution module is used for executing preset operation when the comparison result represents that the action data belongs to the preset trigger data, wherein the preset operation comprises atomization operation.

9. An aerosol generating device according to claim 8, wherein the acquisition module is specifically configured to:

when a pressure sensor in the aerosol generating device detects a pressure signal, an acceleration sensor in the aerosol generating device is triggered to detect an action signal, and a host and an atomizer are arranged in the aerosol generating device.

10. An aerosol generating device according to claim 8, wherein the motion data comprises collision data of the aerosol generating device with other aerosol generating devices, the preset trigger data comprises preset collision data, and the comparison module is specifically configured to:

comparing collision data of the aerosol generating device and the other aerosol generating devices with preset collision data to obtain a difference value between the collision data of the aerosol generating device and the other aerosol generating devices and the preset collision data;

and determining the difference as an alignment result.

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