CN113812678B - Device status management method, device and storage medium - Google Patents

Abstract

The present invention discloses a device state management method, apparatus and storage medium, the method comprising determining the current working state of an aerosol generating device according to the current heating power of a heating component, then sensing the current concentration of aerosol generated by an atomizer through a first sensor, generating a target state switching instruction when the current concentration and the actual concentration matching the current working state satisfy a preset relationship, and based on the target state switching instruction, controlling the output power of a power supply component to make the heating component heat at the target power, thereby putting the aerosol generating device in the target working state. By adopting the embodiment of the present invention, different working states of the aerosol generating device can be selected according to actual conditions and needs, so as to solve the problem that the user's needs for different powers cannot be met.

Description

Device state management method, device and storage medium

Technical Field

The present invention relates to the field of data processing technologies, and in particular, to a device state management method, device, and storage medium.

Background

The aerosol generating device is a portable device for replacing the conventional cigarettes, and is usually inserted on a host by an atomizer so as to heat an aerosol substrate in the atomizer to form aerosol, thereby achieving the effect of smoke output.

In the existing aerosol generating equipment, the output power is constant, the adjustment of the power cannot be performed, the aerosol base material is atomized by a fixed heating power no matter the suction force or the suction time of a user, and the requirements of the user on different powers cannot be met.

Disclosure of Invention

The embodiment of the invention aims to provide a device state management method, a device and a storage medium, which can select different working states of aerosol generating devices according to actual conditions and needs so as to solve the problem that the requirements of users on different powers cannot be met.

In order to achieve the above object, an embodiment of the present invention provides an apparatus state management method applied to an aerosol-generating apparatus to control an operation state of the aerosol-generating apparatus, the aerosol-generating apparatus including a nebulizer and a power supply assembly, the nebulizer including a heating assembly, and a first sensor for sensing a concentration of aerosol generated by the nebulizer, the apparatus state management method comprising:

Determining a current operating state of the aerosol-generating device according to a current heating power of the heating assembly;

sensing, by the first sensor, a current concentration of aerosol produced by the nebulizer;

When the actual concentration matched with the current working state meets a preset relation, generating a target state switching instruction;

And controlling the output power of the power supply component based on the target state switching instruction to enable the heating component to heat at the target power so as to enable the aerosol generating device to be in a target working state.

In order to solve the same technical problems, an embodiment of the present invention provides a device state management apparatus applied to an aerosol generating device to control an operation state of the aerosol generating device, the aerosol generating device including a nebulizer and a power supply assembly, the nebulizer including a heating assembly, and a first sensor for sensing a concentration of aerosol generated by the nebulizer, the device state management apparatus comprising:

A state determining module for determining a current operating state of the aerosol-generating device according to a current heating power of the heating assembly;

A concentration sensing module for sensing a current concentration of aerosol produced by the atomizer through the first sensor;

The instruction generation module is used for generating a target state switching instruction when the actual concentration matched with the current working state meets a preset relation;

and the state management module is used for controlling the output power of the power supply component based on the target state switching instruction to heat the heating component with the target power so as to enable the aerosol generating device to be in a target working state.

In a third aspect, an embodiment of the present invention further provides a computer readable storage medium, where a computer program is stored, where when the computer program runs, a device where the computer readable storage medium is controlled to execute any of the above-mentioned device state management methods.

The embodiment of the invention provides a device state management method, a device and a storage medium, wherein the method can generate different target state switching instructions according to different preset relations of the actual concentration matched with the current working state, so that the aerosol generating device can be controlled to be switched into different working states according to the different target state switching instructions, and the problem that the conventional aerosol generating device cannot meet the requirements of users on different powers is solved.

Drawings

FIG. 1 is a schematic diagram of an operating environment of an aerosol-generating device according to an embodiment of the present invention;

FIG. 2 is a schematic flow chart of a device status management method according to an embodiment of the present invention;

FIG. 3 is a schematic view of a nebulizer according to an embodiment of the invention;

FIG. 4 is a schematic view of another embodiment of the atomizer of the present invention;

FIG. 5 is a schematic flow chart of another method for managing device status according to an embodiment of the present invention;

Fig. 6 is a schematic structural diagram of an apparatus state management device according to an embodiment of the present invention;

fig. 7 is a schematic structural view of an aerosol-generating device according to an embodiment of the present invention.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

It should be understood that the various steps recited in the method embodiments of the present disclosure may be performed in a different order and/or performed in parallel. Furthermore, method embodiments may include additional steps and/or omit performing the illustrated steps. The scope of the present disclosure is not limited in this respect.

The term "including" and variations thereof as used herein are intended to be open-ended, i.e., including, but not limited to. The term "based on" is based at least in part on. The term "one embodiment" means "at least one embodiment," another embodiment "means" at least one additional embodiment, "and" some embodiments "means" at least some embodiments. Related definitions of other terms will be given in the description below.

Example 1:

Referring to fig. 1, fig. 1 is a schematic structural diagram of an operation environment of an aerosol generating apparatus according to an embodiment of the present invention, as shown in fig. 1, an aerosol generating apparatus 10 provided in this embodiment includes an atomizer 11, a power supply assembly 12, and an interface 13 for connecting the atomizer 11 and the power supply assembly 12, where the interface 13 may be a Type-C interface, a Type-B interface, or a USB interface, and the atomizer 11 has an oil chamber, a suction nozzle, and a heating assembly (not shown in the drawings), and the power supply assembly 12 supplies power to the heating assembly through the interface 13, so that the heating assembly heats aerosol substrates in the oil chamber, thereby generating aerosol for a user to suck from the suction nozzle.

Optionally, referring to fig. 1, the aerosol generating device 10 provided in this embodiment may be further connected to the terminal 20 in a communication manner, where the terminal 20 may be a PC, or may be a mobile terminal device such as a smart phone, a smart watch, a tablet computer, or a portable computer, so that the aerosol generating device 10 is managed by the mobile terminal 20, for example, data such as the number of times of sucking the aerosol generating device 10 by a user, displaying the remaining situation of the aerosol substrate in the oil cavity, or displaying the electric quantity situation of the aerosol generating device 10 is recorded, and these data are stored in a memory (not shown in the drawing) of the aerosol generating device 10, so that after the bluetooth pairing with the aerosol generating device 10 is successful, the mobile terminal 20 can acquire the data stored in the memory of the aerosol generating device 10 in real time.

It will be appreciated by those skilled in the art that the aerosol-generating device illustrated in fig. 1 is not limiting and may include more or fewer components than shown, or may combine certain components, or a different arrangement of components.

The invention will now be described in further detail with reference to the accompanying drawings by means of specific examples.

Example 2:

The working power of the existing aerosol generating device shown in fig. 1 is generally constant, no matter how much or less aerosol substrate is left in the oil cavity, or how much or less remaining power of the aerosol generating device is left in the oil cavity, or when a user needs to change the working power of the aerosol generating device, the existing aerosol generating device cannot select different working states of the aerosol generating device according to actual situations (such as that the amount of the remaining aerosol substrate in the oil cavity is small or the remaining power of the aerosol generating device is small) or needs of the user for different powers (such as that the user wants to work states with lower power), so that the existing aerosol generating device cannot meet the needs of the user for different powers according to the actual situations, and thus the use experience of the user for the aerosol generating device is reduced.

Based on the technical problems of the prior art mentioned above, an embodiment of the present invention provides a device state management method applied to an aerosol generating device to control an operating state of the aerosol generating device, the aerosol generating device includes a nebulizer and a power supply assembly, the nebulizer includes a heating assembly, and a first sensor for sensing a concentration of aerosol generated by the nebulizer, please refer to fig. 2, fig. 2 is a schematic flow chart of the device state management method provided by the embodiment of the present invention, as shown in fig. 2, the device state management method provided by the embodiment of the present invention includes steps 201 to 204;

step 201, determining a current operating state of the aerosol-generating device based on a current heating power of the heating assembly.

The heating component in the embodiment is an electronic component formed by a plurality of heating elements for heating, and can control one or more heating elements to work independently or simultaneously by controlling the plurality of heating elements respectively, and in addition, the purpose of controlling the heating component to work at different heating powers can be achieved by providing different currents/voltages for one or more heating elements in the heating component.

In this embodiment, the aerosol generating device provided in this embodiment has a plurality of operation modes, each operation mode corresponds to one heating power of the heating element, for example, the aerosol generating device provided in this embodiment has a normal mode and a power saving mode, and the heating element may be 2 electric heating elements, so that in the normal mode, 2 electric heating elements in the aerosol generating device perform heating operation simultaneously, and in the power saving mode, only one electric heating element in the aerosol generating device performs heating operation. Therefore, when the aerosol generating device works, the current working state of the aerosol generating device can be determined by detecting the working state of the electric heating elements in the heating assembly, namely according to the detected heating power of the heating assembly, for example, when 2 electric heating elements are detected to simultaneously perform heating work, the current working state of the aerosol generating device is determined to be a normal mode, and when only 1 electric heating element is detected to perform heating work, the current working state of the aerosol generating device is determined to be a power saving mode.

In addition, when the aerosol generating device works, the current/voltage of the electric heating element in the heating assembly is detected to determine the heating power of the heating assembly according to the detected current/voltage value, so that the current working state of the aerosol generating device is determined, for example, when the current/voltage of the electric heating element working in the heating assembly is detected to be greater than or equal to a preset target threshold value, the current working state of the aerosol generating device is determined to be a normal mode, and when the current/voltage of the electric heating element working in the heating assembly is detected to be less than the preset target threshold value, the current working state of the aerosol generating device is determined to be a power saving mode.

Step 202, sensing a current concentration of aerosol produced by a nebulizer by a first sensor.

The aerosol generated by the atomizer each time is sensed in real time by the gas concentration sensor, so that the concentration of the aerosol generated by the aerosol generating device each time can be obtained.

And 203, when the actual concentration matched with the current working state meets the preset relation, generating a target state switching instruction.

In this embodiment, the aerosol generating apparatus provided in this embodiment can generate aerosols with different concentrations in different working states, for example, when the aerosol generating apparatus is in a normal mode, 2 electrothermal elements perform heating operation simultaneously, so that aerosols with higher concentrations can be generated, so that a user can experience a feeling of large smoke, and when the aerosol generating apparatus is in a power saving mode, only 1 electrothermal element performs heating operation, so that aerosols with smaller concentrations can be generated, thereby achieving the purpose of saving aerosol substrates, and further prolonging the working time of the aerosol generating apparatus.

Because the aerosol generating device can correspondingly generate the same aerosol concentration under different working states, different target state switching instructions can be determined and generated by detecting the actual concentration of the current concentration matched with the current working state of the aerosol generating device, and the instructions can be used for controlling the aerosol generating device to switch the corresponding target working states, so that the requirements of users on different powers are met.

It should be noted that, the operation modes of the aerosol generating device provided in this embodiment are not limited to the normal mode and the power saving mode mentioned in the foregoing embodiments, and the number of the electric heating elements in the heating assembly is not limited to 2, and specifically, a person skilled in the art can set different operation modes of the aerosol generating device in different practical application scenarios, and can set multiple operation modes for the aerosol generating device according to the actual number of the electric heating elements in the power assembly, where specific setting modes are not exemplified herein.

Step 204, based on the target state switching instruction, controlling the output power of the power supply component to heat the heating component with the target power so as to enable the aerosol generating device to be in the target working state.

In this embodiment, after the aerosol generating device generates the target state switching instruction, the current working state is automatically switched to the target working state, and the power supply component is controlled to adjust the output power of the power supply component to the output power which should be provided in the target working state, so that the heating component can perform heating work with the target power in the target working state, and the aerosol generating device is further in the target working state, thereby achieving the purpose of switching the working state of the aerosol generating device.

The device state management method provided in this embodiment will be described below in a specific application scenario:

In one embodiment, step 203 specifically includes generating a first state switching command when the current concentration is less than the actual concentration that matches the current operating state. Step 204 specifically includes reducing the output power of the power supply assembly to heat the heating assembly at the first power based on the first state switching command.

In this embodiment, when detecting that the concentration of the aerosol generated by the aerosol generating device is smaller, but the current working state of the aerosol generating device is a normal state, the corresponding generated actual aerosol concentration should be larger and larger than the current aerosol concentration, so that it can be determined that the heating component cannot sufficiently contact with the aerosol base material, that is, the current aerosol base material is smaller, so that the aerosol generating device will generate a power-saving state switching instruction, and the aerosol generating device is controlled to switch the working state of the current normal mode into the working state of the power-saving mode according to the power-saving state switching instruction, so that invalid work performed by the heating component is avoided, and the purpose of saving electric energy is achieved.

Specifically, after the aerosol generating device in the normal mode generates the power saving state switching instruction, the aerosol generating device automatically switches the current working state in the normal mode to the working state in the power saving mode, and simultaneously controls the power supply assembly to adjust the larger output power to the smaller output power, so that the number of the electric heating elements in the heating assembly to work is reduced, the heating assembly is heated with the smaller power, and the aerosol generating device is in the working state in the power saving mode.

In this embodiment, referring to fig. 3, fig. 3 is a schematic structural diagram of an atomizer provided in the embodiment of the present invention, as shown in fig. 3, the atomizer 30 further includes an oil chamber 31 for storing an aerosol substrate, a second sensor 32 and a third sensor 33 for detecting a liquid level 40 of the aerosol substrate are disposed in the oil chamber 31, a heating component is disposed in the oil chamber, the heating component includes a first heating wire 34 disposed at a first position in the oil chamber and a second heating wire 35 disposed at a second position in the oil chamber, the second sensor 32 is disposed at the first position to detect whether the liquid level 40 of the aerosol substrate is beyond the first position, the third sensor 33 is disposed at the second position to detect whether the liquid level 40 of the aerosol substrate is beyond the second position, and the first state switching command includes a second state switching command.

With continued reference to fig. 3, step 203 further specifically includes generating a second state switching command when the current concentration is less than the actual concentration matched with the current working state and the second sensor 32 detects that the liquid level 40 of the aerosol substrate is not over the first position and the third sensor 33 detects that the liquid level 40 of the aerosol substrate is not over the second position, and step 204 further specifically includes reducing the output power of the power supply assembly to control the first heating wire 34 to work and the second heating wire 35 to stop working based on the second state switching command.

As shown in fig. 3, the current application scenario of the aerosol generating device is in an inclined state, the second sensor 32 detects that the liquid level 40 of the aerosol substrate in the oil cavity 31 only passes through the first position where the first heating wire 34 is located, the third sensor 33 detects that the liquid level 40 of the aerosol substrate in the oil cavity 31 does not pass through the second position where the second heating wire 35 is located, and when detecting that the concentration of the aerosol generated by the aerosol generating device is smaller than the actual concentration matched with the current working state, a second state switching instruction is generated, so that the output power of the power supply assembly can be controlled to be reduced by the aerosol generating device, the first heating wire 34 is controlled to work, and the second heating wire 35 is controlled to stop working.

It should be noted that, the first heating wire/the second heating wire are both formed by one or more electric heating elements for heating, and the electric heating elements may be iron-chromium-aluminum heating wires or nickel-chromium heating wires, or elements formed by combining the two, where the heating material of the electric heating element is not specifically limited in this embodiment.

Optionally, the first state switching instruction further includes a third state switching instruction, step 203 further specifically includes generating the third state switching instruction when the current concentration is less than the actual concentration matched with the current working state and the second sensor 32 detects that the liquid level 40 of the aerosol substrate does not exceed the first position and the third sensor 33 detects that the liquid level 40 of the aerosol substrate does not exceed the second position, and step 204 further specifically includes reducing the output power of the power supply assembly based on the third state switching instruction to control the first heating wire 34 to stop working and the second heating wire 35 to work.

Similarly, when the aerosol generating device is in an inclined state, the liquid level 40 of the aerosol substrate only passes through the second heating wire 35 and does not pass through the first heating wire 34, and when the concentration of the aerosol generated by the aerosol generating device is detected to be smaller than the actual concentration matched with the current working state, a third state switching instruction is generated, so that the aerosol generating device can be controlled to reduce the output power of the power supply assembly, the second heating wire 35 is controlled to work, and the first heating wire 34 is controlled to stop working.

Further, the first state switching instruction further includes a fourth state switching instruction, and step 203 further specifically includes generating the fourth state switching instruction when the current concentration is smaller than the actual concentration matched with the current working state and the second sensor 32 detects that the liquid level 40 of the aerosol substrate does not exceed the first position and the third sensor 33 detects that the liquid level 40 of the aerosol substrate does not exceed the second position, and stopping the output of the power supply assembly based on the fourth state switching instruction to simultaneously control the first heating wire 34 and the second heating wire 35 to stop working.

In this embodiment, as long as the liquid level 40 of the aerosol substrate does not exceed the positions of the first heating wire 34 and the second heating wire 35 at the same time, and the concentration of the aerosol generated by the aerosol generating device is detected to be smaller than the actual concentration matched with the current working state, a third state switching instruction is generated, so that the aerosol generating device can be controlled to stop the output of the power supply assembly, and the first heating wire 34 and the second heating wire 35 can be controlled to stop working at the same time, so that excessive idle work is avoided from being performed by the heating assembly, and the electric energy of the aerosol generating device is saved.

In another implementation, referring to fig. 4, fig. 4 is a schematic diagram of another structure of the atomizer provided in the embodiment of the present invention, as shown in fig. 4, a fourth sensor 36 for detecting the liquid level 40 of the aerosol substrate is further disposed in the oil chamber 31, where the fourth sensor 36 is disposed at a third position on a sidewall of the oil chamber to detect whether the liquid level 40 of the aerosol substrate is over the third position, the target state switching command further includes a fifth state switching command, step 203 specifically further includes reducing the output power of the power supply assembly to control only the first heating wire 34 or the second heating wire 35 to operate based on the fifth state switching command, when the current concentration is equal to the actual concentration matched with the current operating state, the second sensor 32 detects that the liquid level 40 of the aerosol substrate is over the first position, the third sensor 33 detects that the liquid level 40 of the aerosol substrate is over the second position, and the fourth sensor 36 detects that the liquid level 40 of the aerosol substrate is over the third position.

Optionally, step 204 may specifically further include reducing the voltage or current provided by the power supply component to the first heating wire 34 or the second heating wire 35 based on the fifth state switching command, so as to adjust the working power of the first heating wire 34 or the second heating wire 35, so that the heating power of the heating component can be reduced.

In this embodiment, when the liquid level 40 of the aerosol substrate is above the first position and the second position of the second sensor 32 and the third sensor 33, but below the third position of the fourth sensor 36, a fifth state switching command is generated, so that the output power of the power supply assembly can be controlled to be reduced according to the fifth state switching command, and the heating power of the heating assembly can be reduced, thereby achieving the purpose of saving electric energy.

The device state management method further comprises the step of controlling the alarm to generate and send corresponding alarm information according to different state switching instructions.

For example, when the power saving state switching command is detected, the alarm is controlled to generate and send out the alarm information in the form of words such as electric energy saving, and specifically, according to the actual situation, the person skilled in the art can also control the alarm to generate and send out the corresponding alarm information according to other state switching commands, which is not exemplified herein.

Example 3:

referring to fig. 5, fig. 5 is another flow chart of the device state management method according to the embodiment of the present invention, and as shown in fig. 5, the device state management method according to the embodiment of the present invention includes steps 501 to 503;

Step 501, a control instruction sent by a mobile terminal in communication with an aerosol generating device is received.

With continued reference to fig. 1, as shown in fig. 1, the aerosol generating device provided in the embodiment of the present invention can be communicatively connected to the mobile terminal 20, so as to receive, in real time, a control instruction sent by the mobile terminal 20.

Step 502, the control command is parsed to obtain a sixth state switching command.

Specifically, when the control instruction sent by the mobile terminal 20 is text or audio data, by parsing the text or audio data and detecting whether there is content related to the seventh state in the data, for example, when it is detected that the content "switch to the seventh state" is included in the data sent by the mobile terminal 20, it can be determined that the sixth state switch instruction is sent by the mobile terminal 20.

Step 503, based on the target state switching instruction, controlling the output power of the power supply component to heat the heating component with the target power, so as to make the aerosol generating device in the target working state.

In this embodiment, the sixth state switching instruction includes any one of the first state switching instruction to the fifth state switching instruction mentioned in the foregoing embodiment, where, as in the device state management method provided in the foregoing embodiment, when the aerosol generating device of this embodiment receives the target state switching instruction, for example, the sixth state switching instruction sent by the mobile terminal 20, it will control the aerosol generating device according to the device state management method provided in the foregoing embodiment, so as to switch the working state of the aerosol generating device, and solve the problem that the user cannot meet the requirement of different powers.

Example 4:

According to the method described in the above embodiments, this embodiment will be further described from the viewpoint of an apparatus state management device, which is mainly applied to an aerosol generating apparatus to control an operation state of the aerosol generating apparatus, the aerosol generating apparatus including a nebulizer and a power supply assembly, the nebulizer including a heating assembly, and a first sensor for sensing a concentration of aerosol generated by the nebulizer. Referring to fig. 6, fig. 6 is a schematic structural diagram of an apparatus state management device according to an embodiment of the present invention, and as shown in fig. 6, an apparatus state management device 600 according to an embodiment of the present invention includes:

The state determining module 601 is configured to determine a current operating state of the aerosol-generating device according to a current heating power of the heating assembly.

A concentration sensing module 602 for sensing a current concentration of aerosol produced by the nebulizer through the first sensor.

The instruction generating module 603 is configured to generate a target state switching instruction when the actual concentration matching the current concentration and the current working state meets a preset relationship.

The state management module 604 is configured to control the output power of the power supply component to heat the heating component with the target power based on the target state switching instruction, so as to enable the aerosol generating device to be in the target working state.

In one embodiment, the instruction generating module 603 is specifically configured to generate the first state switching instruction when the current concentration is less than the actual concentration matched with the current working state. The state management module 604 is specifically configured to reduce the output power of the power supply component to heat the heating component with the first power based on the first state switching command.

Optionally, referring to fig. 3, the atomizer 30 in the aerosol generating device further includes an oil chamber 31 for storing an aerosol substrate, a second sensor 32 and a third sensor 33 for detecting a liquid level 40 of the aerosol substrate are disposed in the oil chamber 31, a heating assembly is disposed in the oil chamber, the heating assembly includes a first heating wire 34 disposed at a first position in the oil chamber and a second heating wire 35 disposed at a second position in the oil chamber, the second sensor 32 is disposed at the first position to detect whether the liquid level 40 of the aerosol substrate is beyond the first position, the third sensor 33 is disposed at the second position to detect whether the liquid level 40 of the aerosol substrate is beyond the second position, and the first state switching command includes a second state switching command. The instruction generating module 603 is specifically further configured to generate a second state switching instruction when the current concentration is less than the actual concentration matched with the current working state and the second sensor 32 detects that the liquid level 40 of the aerosol substrate does not exceed the first position and the third sensor 33 detects that the liquid level 40 of the aerosol substrate does not exceed the second position, and the state management module 604 is specifically further configured to reduce the output power of the power supply assembly to control the first heating wire 34 to work and control the second heating wire 35 to stop working based on the second state switching instruction.

Similarly, the first state switching instruction further includes a third state switching instruction, the instruction generating module 603 is specifically further configured to generate the third state switching instruction when the current concentration is smaller than the actual concentration matched with the current working state and the second sensor 32 detects that the liquid level 40 of the aerosol substrate does not exceed the first position and the third sensor 33 detects that the liquid level 40 of the aerosol substrate does not exceed the second position, and the state management module 604 is specifically further configured to reduce the output power of the power supply assembly to control the first heating wire 34 to stop working and control the second heating wire 35 to work based on the third state switching instruction.

Further, the first state switching instruction further includes a fourth state switching instruction, the instruction generating module 603 is specifically further configured to generate the fourth state switching instruction when the current concentration is smaller than the actual concentration matched with the current working state and the second sensor 32 detects that the liquid level 40 of the aerosol substrate does not exceed the first position and the third sensor 33 detects that the liquid level 40 of the aerosol substrate does not exceed the second position, and the state management module 604 is specifically further configured to stop the output of the power supply assembly to simultaneously control the first heating wire 34 and the second heating wire 35 to stop working based on the fourth state switching instruction.

In another embodiment, referring to fig. 4, a fourth sensor 36 for detecting the liquid level 40 of the aerosol substrate is further disposed in the oil chamber 31, the fourth sensor 36 is disposed at a third position on the sidewall of the oil chamber to detect whether the liquid level 40 of the aerosol substrate is over the third position, the target state switching command further includes a fifth state switching command, the command generating module 603 is specifically configured to generate the fifth state switching command when the current concentration is equal to the actual concentration matched with the current working state, the second sensor 32 detects that the liquid level 40 of the aerosol substrate is over the first position, the third sensor 33 detects that the liquid level 40 of the aerosol substrate is over the second position, and the fourth sensor 36 detects that the liquid level 40 of the aerosol substrate is not over the third position, and the state managing module 604 is specifically configured to reduce the output power of the power supply assembly to control only the first heating wire 34 or the second heating wire 35 to work based on the fifth state switching command.

In the implementation, each module and/or unit may be implemented as an independent entity, or may be combined arbitrarily and implemented as the same entity or a plurality of entities, where the implementation of each module and/or unit may refer to the foregoing method embodiment, and the specific beneficial effects that may be achieved may refer to the beneficial effects in the foregoing method embodiment, which are not described herein again.

Example 5:

Referring to fig. 7, fig. 7 is a schematic structural diagram of an aerosol generating apparatus according to an embodiment of the present invention, and as shown in fig. 7, an aerosol generating apparatus 100 according to an embodiment of the present invention includes a main unit 110 and an atomizer 120, wherein the main unit 110 and the atomizer 120 are electrically connected together.

The host 110 includes a housing 10, a support 20 accommodated in the housing 10, a host electrode 30 accommodated in the support 20, a circuit board 40 electrically connected with the host electrode 30, a power module 50 electrically connected with the circuit board 40, and a microphone 60 fixed in the support 20 and electrically connected with the circuit board 40, wherein the microphone 60 is communicated with a first air inlet channel (not shown in the figure), the microphone 60 senses an electrical parameter generated by a negative pressure generated by a change of an air flow in the first air inlet channel, and outputs a sensing signal to the circuit board 40 according to the change of the electrical parameter, and the circuit board 40 determines whether to control the power module 50 to supply power to the atomizer 120 according to the sensing signal.

Specifically, the atomizer 120 includes an atomizing core 70, a connecting member 80 and an atomizing electrode 90, the atomizing core 70 is connected with the connecting member 80, the atomizing electrode 90 is fixed in the connecting member 80, and in this embodiment, the atomizing core 70 includes an atomizing chamber 71, an oil chamber 72, an air outlet channel 73, a suction nozzle 74, a liquid guiding member 75 and a heating component 76. The oil 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 member 75 and the heating component 76 are both positioned in the atomization cavity 71. The oil cavity 72 is used for storing aerosol substrates, the liquid guide 75 is located between the oil cavity 72 and the heating component 76 to guide the aerosol substrates into the atomization cavity 71, and the heating component 76 heats to atomize the aerosol substrates under the control of the circuit board 40 to generate aerosol.

The connecting piece 80 includes a third accommodating groove 81, the atomizing electrode 90 is accommodated in and fixed to the third accommodating groove 81, the atomizing electrode 90 is electrically connected with the host electrode 30, the atomizing electrode 90 is further electrically connected with the heating component 76 to form a circuit loop, and the circuit board 40 controls the power supply component 50 to supply power to the heating component 76 through the circuit loop, so that the heating component 76 generates heat to atomize the aerosol substrate, and aerosol is generated.

Wherein the connecting member 80 further includes a second air intake passage 82. One end of the second air inlet channel 82 is communicated with the atomization cavity 71, and under the suction force generated by the suction nozzle 74, the external air enters the second air inlet channel 82 from the air inlet, then enters the atomization cavity 71 from the second air inlet channel 82, and drives the aerosol generated in the atomization cavity 71 to enter the air outlet channel 73, and then enters the mouth of a user of the aerosol generating device 100 from the suction nozzle 74.

The first sensors for sensing the aerosol concentration of the aerosol generated by the atomizer 120 may be disposed at the atomizing chamber 71 and/or the air outlet channel 73, and when a plurality of first sensors are disposed, the aerosol concentration of the aerosol generated by the atomizer 120 may be comprehensively sensed by the plurality of first sensors, so as to avoid sensing occurrence errors of the aerosol concentration.

Optionally, the atomizer 120 further includes a second magnetic component (not shown in the figure), where the second magnetic component is disposed on the atomization connection end surface 122 of the atomizer 120 and opposite to the first magnetic component (not shown in the figure), and the host 110 and the atomizer 120 are fixed together by the first magnetic component and the second magnetic component.

In addition, the aerosol-generating device 100 provided in this embodiment further includes other liquid level sensors besides the second sensor, the third sensor and the fourth sensor, and these liquid level sensors may be disposed in different areas, not limited to the first position, the second position or the third position mentioned in the foregoing embodiment, where the liquid level sensor disposed in each area may include a plurality of sub-sensors, and only if the plurality of sub-sensors in the same area are not simultaneously being used by the aerosol substrate liquid level, the liquid level sensor corresponding to that area is not deemed to be used by the aerosol substrate liquid level, otherwise the liquid level sensor is deemed to be used by the aerosol substrate, so as to prevent the aerosol-generating device 100 from shaking during use and causing unnecessary adjustment of the operating state.

Further, other liquid level sensors provided by the embodiment of the invention can be arranged outside the pipe wall corresponding to the atomizing cavity 71, so that the first sensor, the liquid level sensor and the heating component can be integrated better, and the purposes of saving space, reducing cost and being convenient for assembly are realized.

Those of ordinary skill in the art will appreciate that all or a portion of the steps of the various methods of the above embodiments may be performed by instructions, or by instructions controlling associated hardware, which may be stored in a computer-readable storage medium and loaded and executed by a processor. To this end, an embodiment of the present invention provides a storage medium having stored therein a plurality of instructions capable of being loaded by a processor to perform the steps of any one of the embodiments of the device state management method provided by the embodiment of the present invention.

The storage medium may include a Read Only Memory (ROM), a random access Memory (RAM, random Access Memory), a magnetic disk, an optical disk, or the like.

The steps in any embodiment of the device state management method provided by the embodiment of the present invention can be executed by the instructions stored in the storage medium, so that the beneficial effects that any device state management method provided by the embodiment of the present invention can achieve can be achieved, and detailed descriptions of the previous embodiments are omitted.

The foregoing describes in detail a device state management method, apparatus and storage medium according to embodiments of the present application, and specific examples are provided herein to illustrate the principles and embodiments of the present application, and the above description of the embodiments is only for aiding in understanding the method and core concept of the present application, and meanwhile, to those skilled in the art, according to the concept of the present application, there are variations in the specific embodiments and application ranges, so the disclosure should not be construed as limiting the present application. Moreover, it will be apparent to those skilled in the art that various modifications and variations can be made without departing from the principles of the present application, and such modifications and variations are also considered to be within the scope of the application.

Claims (7)

1. A device state management method, characterized in that it is applied to an aerosol generating device to control the working state of the aerosol generating device, wherein the aerosol generating device comprises an atomizer and a power supply component, the atomizer comprises a heating component, and a first sensor for sensing the concentration of the aerosol generated by the atomizer; the device state management method comprises: Determining the current working state of the aerosol generating device according to the current heating power of the heating component; sensing the current concentration of the aerosol generated by the atomizer through the first sensor; When the current concentration and the actual concentration matching the current working state satisfy a preset relationship, a target state switching instruction is generated; Based on the target state switching instruction, controlling the output power of the power supply component to make the heating component heat at the target power, so that the aerosol generating device is in the target working state; The step of generating a target state switching instruction when the current concentration and the actual concentration matching the current working state satisfy a preset relationship comprises: When the current concentration is less than the actual concentration matched with the current working state, generating a first state switching instruction; The step of controlling the output power of the power supply component to make the heating component perform heating at the target power based on the target state switching instruction includes: Based on the first state switching instruction, reducing the output power of the power supply component so that the heating component performs heating at the first power; The atomizer further comprises an oil chamber for storing aerosol substrate, a second sensor and a third sensor for detecting the liquid level of the aerosol substrate are arranged in the oil chamber, the second sensor and the third sensor are arranged on both sides of the bottom of the oil chamber, the heating component is arranged in the oil chamber, the heating component comprises a first heating wire arranged at a first position in the oil chamber and a second heating wire arranged at a second position in the oil chamber, the second sensor is arranged at the first position to detect whether the liquid level of the aerosol substrate is submerged in the first position, and the third sensor is arranged at the second position to detect whether the liquid level of the aerosol substrate is submerged in the second position; the first state switching instruction comprises a second state switching instruction; The step of generating a first state switching instruction when the current concentration is less than the actual concentration matching the current working state comprises: When the current concentration is less than the actual concentration matching the current working state, and the second sensor detects that the liquid level of the aerosol substrate is below the first position, and the third sensor detects that the liquid level of the aerosol substrate is below the second position, a second state switching instruction is generated; The step of reducing the output power of the power supply component based on the first state switching instruction so that the heating component performs heating at the first power includes: Based on the second state switching instruction, reducing the output power of the power supply assembly to control the first heating wire to work, and controlling the second heating wire to stop working; The oil chamber is also provided with a fourth sensor for detecting the liquid level of the aerosol substrate, and the fourth sensor is provided at a third position on the side wall of the oil chamber to detect whether the liquid level of the aerosol substrate is above the third position; the target state switching instruction also includes a fifth state switching instruction; The step of generating a target state switching instruction when the current concentration and the actual concentration matching the current working state satisfy a preset relationship further includes: When the current concentration is equal to the actual concentration matching the current working state, and the second sensor detects that the liquid level of the aerosol substrate is below the first position, the third sensor detects that the liquid level of the aerosol substrate is below the second position, and the fourth sensor detects that the liquid level of the aerosol substrate is below the third position, a fifth state switching instruction is generated; The step of controlling the output power of the power supply component to make the heating component perform heating at the target power based on the target state switching instruction further includes: Based on the fifth state switching instruction, the output power of the power supply component is reduced to control only the first heating wire or the second heating wire to work. 2. The device state management method according to claim 1, wherein the first state switching instruction further comprises a third state switching instruction; and when the current concentration is less than the actual concentration matching the current working state, the step of generating the first state switching instruction further comprises: When the current concentration is less than the actual concentration matching the current working state, and the second sensor detects that the liquid level of the aerosol substrate is not above the first position, and the third sensor detects that the liquid level of the aerosol substrate is above the second position, a third state switching instruction is generated; The step of reducing the output power of the power supply component based on the first state switching instruction so that the heating component performs heating at the first power also includes: Based on the third state switching instruction, the output power of the power supply component is reduced to control the first heating wire to stop working, and control the second heating wire to work. 3. The device state management method according to claim 1, wherein the first state switching instruction further comprises a fourth state switching instruction; and when the current concentration is less than the actual concentration matching the current working state, the step of generating the first state switching instruction further comprises: When the current concentration is less than the actual concentration matching the current working state, and the second sensor detects that the liquid level of the aerosol substrate does not exceed the first position, and the third sensor detects that the liquid level of the aerosol substrate does not exceed the second position, a fourth state switching instruction is generated; The step of reducing the output power of the power supply component based on the first state switching instruction so that the heating component performs heating at the first power also includes: Based on the fourth state switching instruction, the output of the power supply component power is stopped to simultaneously control the first heating wire and the second heating wire to stop working. 4. The device state management method according to any one of claims 1 to 3, characterized in that the aerosol generating device further comprises an alarm; the device state management method further comprises: According to different state switching instructions, the alarm is controlled to generate and send out corresponding alarm information. 5. The device state management method according to claim 4, characterized in that the target state switching instruction includes a sixth state switching instruction; before the step of controlling the output power of the power supply component to make the heating component heat at the target power based on the target state switching instruction so that the aerosol generating device is in the target working state, the device state management method further includes: receiving a control instruction sent by a mobile terminal that is communicatively connected to the aerosol generating device; The control instruction is parsed to obtain a sixth state switching instruction. 6. A device state management device, characterized in that it is applied to an aerosol generating device to control the working state of the aerosol generating device, the aerosol generating device comprising an atomizer and a power supply component, the atomizer comprising a heating component, and a first sensor for sensing the concentration of the aerosol generated by the atomizer; the device state management device comprises: a state determination module, for determining a current working state of the aerosol generating device according to a current heating power of the heating component; a concentration sensing module, used for sensing the current concentration of the aerosol generated by the atomizer through the first sensor; and a command generating module, used for generating a target state switching command when the current concentration and the actual concentration matching the current working state satisfy a preset relationship; a state management module, for controlling the output power of the power supply component to make the heating component perform heating at a target power based on the target state switching instruction, so that the aerosol generating device is in a target working state; Wherein, when the current concentration and the actual concentration matching the current working state satisfy a preset relationship, the step of generating a target state switching instruction includes: When the current concentration is less than the actual concentration matched with the current working state, generating a first state switching instruction; The step of controlling the output power of the power supply component to make the heating component perform heating at the target power based on the target state switching instruction includes: Based on the first state switching instruction, reducing the output power of the power supply component so that the heating component performs heating at the first power; The atomizer further comprises an oil chamber for storing aerosol substrate, a second sensor and a third sensor for detecting the liquid level of the aerosol substrate are arranged in the oil chamber, the second sensor and the third sensor are arranged on both sides of the bottom of the oil chamber, the heating component is arranged in the oil chamber, the heating component comprises a first heating wire arranged at a first position in the oil chamber and a second heating wire arranged at a second position in the oil chamber, the second sensor is arranged at the first position to detect whether the liquid level of the aerosol substrate is submerged in the first position, and the third sensor is arranged at the second position to detect whether the liquid level of the aerosol substrate is submerged in the second position; the first state switching instruction comprises a second state switching instruction; The step of generating a first state switching instruction when the current concentration is less than the actual concentration matching the current working state comprises: When the current concentration is less than the actual concentration matching the current working state, and the second sensor detects that the liquid level of the aerosol substrate is below the first position, and the third sensor detects that the liquid level of the aerosol substrate is below the second position, a second state switching instruction is generated; The step of reducing the output power of the power supply component based on the first state switching instruction so that the heating component performs heating at the first power includes: Based on the second state switching instruction, reducing the output power of the power supply assembly to control the first heating wire to work, and controlling the second heating wire to stop working; The oil chamber is also provided with a fourth sensor for detecting the liquid level of the aerosol substrate, and the fourth sensor is provided at a third position on the side wall of the oil chamber to detect whether the liquid level of the aerosol substrate is above the third position; the target state switching instruction also includes a fifth state switching instruction; The step of generating a target state switching instruction when the current concentration and the actual concentration matching the current working state satisfy a preset relationship further includes: When the current concentration is equal to the actual concentration matching the current working state, and the second sensor detects that the liquid level of the aerosol substrate is below the first position, the third sensor detects that the liquid level of the aerosol substrate is below the second position, and the fourth sensor detects that the liquid level of the aerosol substrate is below the third position, a fifth state switching instruction is generated; The step of controlling the output power of the power supply component to make the heating component perform heating at the target power based on the target state switching instruction further includes: Based on the fifth state switching instruction, the output power of the power supply component is reduced to control only the first heating wire or the second heating wire to work. 7. A computer-readable storage medium, characterized in that the computer-readable storage medium stores a computer program, wherein when the computer program is running, the device where the computer-readable storage medium is located is controlled to execute the device status management method according to any one of claims 1 to 5.