WO2021072755A1 - Atomizing assembly heating control method, computer device, and storage medium - Google Patents

Abstract

An atomizing assembly heating control method, a computer device, and a storage medium. The control method comprises: S100, controlling an atomizing assembly to heat at preset first power as output power; S200, obtaining a real-time resistance value of a heating body of the atomizing assembly; and S300, comparing the real-time resistance value of the heating body with a preset first protection resistance value range, and when the real-time resistance value falls into the first protection resistance value range, adjusting the output power. By means of the control method, dry heating protection can be achieved, and the safety of an electronic atomizing apparatus is improved.

Description

Heating control method of atomization component, computer equipment and storage medium Technical field

The application relates to a heating control method of an atomization component, a computer device and a storage medium.

Background technique

Electronic cigarettes are also known as virtual cigarettes and electronic atomization devices. E-cigarettes are used as a substitute for cigarettes. Electronic cigarettes have a similar appearance and taste to cigarettes, but generally do not contain other harmful components such as tar and suspended particles in cigarettes. An electronic atomization device generally includes a liquid storage component, an atomization component, and a battery component. In the existing electronic atomization device, the main purpose of preventing dry burning is to prevent the generation of harmful substances and burnt smell. Because once the burnt smell is produced, some unhealthy substances will be produced, thus endangering human health.

However, the inventor realizes that dry burning is not caused by exhaustion of e-liquid during the heating process of the electronic atomization device. As long as the liquid guiding efficiency of the liquid guide and the atomization efficiency of the atomizing assembly are out of balance, dry burning will result.

Summary of the invention

According to various embodiments disclosed in the present application, a heating control method of an atomization assembly is provided.

A heating control method of an atomization component is applied to an electronic atomization device, and the method includes:

Control the atomization component to use the preset first power as the output power for heating;

Obtain the real-time resistance value of the heating element of the atomization component; and

The real-time resistance of the heating element is compared with the preset first protection resistance interval, and when the real-time resistance falls within the first protection resistance interval, the output power is adjusted.

A computer device, including a memory and one or more processors, the memory stores computer readable instructions, and when the computer readable instructions are executed by the processor, the one or more processors execute The following steps:

Control the atomization component to use the preset first power as the output power for heating;

Obtain the real-time resistance value of the heating element of the atomization component; and

The real-time resistance of the heating element is compared with the preset first protection resistance interval, and when the real-time resistance falls within the first protection resistance interval, the output power is adjusted.

One or more non-volatile storage media storing computer-readable instructions. When the computer-readable instructions are executed by one or more processors, the one or more processors perform the following steps:

Control the atomization component to use the preset first power as the output power for heating;

Obtain the real-time resistance value of the heating element of the atomization component; and

The real-time resistance of the heating element is compared with the preset first protection resistance interval, and when the real-time resistance falls within the first protection resistance interval, the output power is adjusted.

The details of one or more embodiments of the present application are set forth in the following drawings and description. Other features and advantages of this application will become apparent from the description, drawings and claims.

Description of the drawings

In order to more clearly describe the technical solutions in the embodiments of the present application, the following will briefly introduce the drawings needed in the embodiments. Obviously, the drawings in the following description are only some embodiments of the present application. For those of ordinary skill in the art, without creative work, other drawings can be obtained from these drawings.

Fig. 1 is a schematic flowchart of a heating control method for an atomization assembly according to one or more embodiments.

Fig. 2 is a schematic flow chart of a heating control method of an atomization assembly in another embodiment.

Fig. 3 is a schematic flow chart of power adjustment when the real-time resistance of the heating element falls within the first protection resistance interval according to one or more embodiments.

Fig. 4 is a schematic flow chart of power regulation after the output power is adjusted to the second power according to one or more embodiments.

Fig. 5 is a schematic flow chart of power adjustment when the real-time resistance of the heating element is greater than the second target value and less than the first median value according to one or more embodiments.

Fig. 6 is a schematic flow chart of power adjustment when the real-time resistance of the heating element is greater than or equal to the first median value and less than the first target value according to one or more embodiments.

FIG. 7 is a schematic flowchart of power adjustment after the output power is adjusted to the third power according to one or more embodiments.

FIG. 8 is a schematic flowchart of power adjustment after the output power is adjusted to the fourth power according to one or more embodiments.

Fig. 9 is a schematic flowchart of a prompt information generating step according to one or more embodiments.

Fig. 10 is a block diagram of a heating control device for an atomization assembly according to one or more embodiments.

Fig. 11 is a block diagram of a heating control device for an atomization assembly in another embodiment.

Figure 12 is a block diagram of a computer device according to one or more embodiments.

FIG. 13 is a schematic diagram of the protection resistance interval according to one or more embodiments.

FIG. 14 is a schematic diagram of the protection resistance interval in another embodiment.

Detailed ways

In order to make the technical solutions and advantages of the present application clearer, the following further describes the present application in detail with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described here are only used to explain the present application, and are not used to limit the present application.

In one of the embodiments, as shown in the figure, a method for controlling heating of an atomization component is provided. Taking the method applied to a control device in an electronic atomization device as an example for description, the method includes the following steps:

Step S100, controlling the atomizing assembly to use the preset first power as the output power for heating.

Among them, the atomization component uses the first power as the output power for heating, atomizes the e-liquid in the electronic atomization device, and generates smoke for the user to inhale.

In step S200, the real-time resistance value of the heating element of the atomization assembly is obtained.

Obtain the real-time resistance value of the heating element after the atomization component is heated by the first power. When the atomization component is heated at constant power, according to the law of conservation of energy, the energy output generated at the preset time is certain. Part of this energy is absorbed by the smoke oil, and part of the energy is absorbed by the heating element in the atomization component. When the temperature rises, according to the resistance temperature characteristic, it can be known that the resistance of the heating element will change with the change of temperature, and the temperature can be judged according to the resistance value, and then it can be judged whether the liquid conduction atomization of the atomization component corresponding to the resistance value at this time is balanced .

In step S300, the real-time resistance of the heating element is compared with a preset first protection resistance interval, and when the real-time resistance falls within the first protection resistance interval, the output power is adjusted.

Wherein, the first protection resistance interval is determined based on the first power from the preset protection resistance interval. Under different output power, the corresponding protection resistance interval is different; in different electronic atomization devices, the maximum power of the electronic atomization device is different, and the protection resistance interval is not necessarily the same.

If the resistance of the heating element falls within the first protection resistance range, it means that the atomization efficiency of the current atomization component does not match the oil content on the heating wire. The liquid velocity slows down. It is also possible that the liquid guiding element of the liquid storage cavity is blocked and the liquid guiding speed is too slow, making the current guiding element liquid flow rate lower than the normal liquid guiding speed of the liquid guiding element, resulting in the oil content on the heating wire Does not match the atomization efficiency. At this time, if the first power heating is still used, it will cause dry burning. Therefore, it is necessary to adjust the output power to match the atomization speed and the liquid guide speed to reconstruct the relationship between the atomization efficiency and the liquid guide speed. Balance.

Wherein, each protection resistance value interval in the set of protection resistance value intervals respectively corresponds to a resistance value range corresponding to a different output power when the heating element is unbalanced when the liquid conduction atomization of the heating body is unbalanced.

When a certain amount of power is applied to the heating element, the resistance of the heating element changes depending on the oil content on the heating element. The more e-liquid on the heating element, the more heat will be lost to the e-liquid, which will slow down the rate of increase of the resistance of the heating element. When the liquid guiding efficiency of the atomization component is not balanced with the atomization efficiency, the e-liquid on the heating element becomes less. At this time, the original output power is used for heating, and the heat will be more absorbed by the heating element, and the heating element will generate heat. The resistance of the body rises.

In the above heating control method of the atomization component, the atomization component is controlled to be heated by the first power, and the real-time resistance value of the heating element of the heating element after heating is obtained, and the real-time resistance value of the heating element and the preset resistance value of the heating element The interval judges whether to adjust the output power. If the real-time resistance value of the heating element falls within the preset resistance value interval, the output power is adjusted to balance the atomization efficiency and the liquid guide efficiency to avoid the atomization efficiency being higher than the liquid guide efficiency The resulting dry burning can achieve dry burning protection when the smoke oil is sufficient or when the smoke oil is insufficient, and the safety of the electronic atomization device is improved.

Obtain the real-time resistance value of the heating element after the atomization component is heated by the first power. When the atomization component is heated at constant power, according to the law of conservation of energy, the energy output generated at the preset time is certain. Part of this energy is absorbed by the smoke oil, and part of the energy is absorbed by the heating element in the atomization component. When the temperature rises, according to the resistance temperature characteristic, it can be known that the resistance of the heating element will change with the change of temperature, and the temperature can be judged according to the resistance value, and then it can be judged whether the liquid conduction atomization of the atomization component corresponding to the resistance value at this time is balanced .

In step S300, the real-time resistance of the heating element is compared with a preset first protection resistance interval, and when the real-time resistance falls within the first protection resistance interval, the output power is adjusted.

Wherein, the first protection resistance interval is determined based on the first power from the preset protection resistance interval. Under different output power, the corresponding protection resistance interval is different; in different electronic atomization devices, the maximum power of the electronic atomization device is different, and the protection resistance interval is not necessarily the same.

If the resistance of the heating element falls within the first protection resistance range, it means that the atomization efficiency of the current atomization component does not match the oil content on the heating wire. The liquid velocity slows down. It is also possible that the liquid guiding element of the liquid storage cavity is blocked and the liquid guiding speed is too slow, making the current guiding element liquid flow rate lower than the normal liquid guiding speed of the liquid guiding element, resulting in the oil content on the heating wire Does not match the atomization efficiency. At this time, if the first power heating is still used, it will cause dry burning. Therefore, it is necessary to adjust the output power to match the atomization speed and the liquid guide speed to reconstruct the relationship between the atomization efficiency and the liquid guide speed. Balance.

Wherein, each of the protection resistance value intervals in the set of protection resistance value intervals corresponds to the corresponding resistance value range when the heating element is unbalanced in the liquid conduction atomization under different output powers.

When a certain amount of power is applied to the heating element, the resistance of the heating element changes depending on the oil content on the heating element. The more e-liquid on the heating element, the more heat will be lost to the e-liquid, which will slow down the rate of increase of the resistance of the heating element. When the liquid guiding efficiency of the atomization component is not balanced with the atomization efficiency, the e-liquid on the heating element becomes less. At this time, the original output power is used for heating, and the heat will be more absorbed by the heating element, and the heating element will generate heat. The resistance of the body rises.

In the above heating control method of the atomization component, the atomization component is controlled to be heated by the first power, and the real-time resistance value of the heating element of the heating element after heating is obtained, and the real-time resistance value of the heating element and the preset resistance value of the heating element The interval judges whether to adjust the output power. If the real-time resistance value of the heating element falls within the preset resistance value interval, the output power is adjusted to balance the atomization efficiency and the liquid guide efficiency to avoid the atomization efficiency being higher than the liquid guide efficiency The resulting dry burning can achieve dry burning protection when the smoke oil is sufficient or when the smoke oil is insufficient, and the safety of the electronic atomization device is improved.

In one of the embodiments, as shown in FIG. 13, the first protection resistance interval includes at least a first target value R _1H and a second target value R _1L , where the first target value R _1H is the first protection resistance interval The second target value R _1L is the lower limit of the first protection resistance interval.

The first protection resistance interval corresponds to the output power of the first power P1, _{and the relationship between the first target value R 1H} and the second target value R _1L and the real-time resistance of the heating element has a preset corresponding power adjustment In this embodiment, the adjustment modes can be divided only by the first target value R _1H and the second target value R _1L.

In one of the embodiments, the first protection resistance value interval further includes several target values, and a subdivision interval is formed between every two adjacent target values. According to the subdivision interval into which the real-time resistance value falls, the output power Adjust to the power corresponding to the subdivision interval.

In one of the embodiments, more target values can be set corresponding to more power adjustment modes. In one of the embodiments, the first protection resistance interval can also include a third target value and a fourth target value. , And the first target value is greater than the third target value, the third target value is greater than the fourth target value, and the fourth target value is greater than the second target value. When the real-time resistance of the heating element falls within the second target value and the fourth target value Adjust the output power to the fifth power when the heating element is between the fourth and third target values. When the real-time resistance of the heating element falls between the fourth target value and the third target value, adjust the output power to the sixth power. When the value falls between the third target value and the first target value, the output power is adjusted to the seventh power, that is, the first protection resistance interval can be further divided into more intervals by setting more target values. Each interval corresponds to a different output power. The more target values you set, the more accurate the power adjustment of dry burn protection can be realized. The same is true for the protection resistance interval corresponding to other power values.

The specific value of each protection resistance interval needs to be determined according to the specific heating element resistance characteristics and different output powers. Therefore, the specific value of the protection resistance interval is not limited in this application, and those skilled in the art can combine actual values. It is necessary to select the parameters and test to obtain the determined protection resistance interval.

In one of the embodiments, as shown in FIG. 14, the preset resistance interval further includes a first median value R ₁ , and the first median value R ₁ is a value between the first target value R _1H and the second target value R _1L Median.

The first median value R ₁ divides the protection resistance interval formed between the first target value R _1H and the second target value R _1L into two cells. Each cell can correspond to a power value, so that the output power is The adjustment is more precise, and the balance between atomization efficiency and liquid guide efficiency can be quickly reached again.

In one of the embodiments, as shown in FIG. 2, the heating control method of the atomization assembly further includes the following steps:

In step S400, when the real-time resistance of the heating element is greater than or equal to the first target value in the first protection resistance interval, the atomizing assembly is controlled to stop heating.

The first target value R _1H is the upper limit of the first protection resistance interval. The setting of the upper limit generally corresponds to the worst-case parameter value that can be allowed in normal operation, that is, corresponds to the allowable value of the atomization component. In the most serious dry burning situation, if the real-time resistance of the heating element reaches the first target value R1 and the heating continues, a more serious dry burning problem will occur. The dry burning problem may not be solved by adjusting the power, so it is necessary at this time Control the atomization component to stop heating, and the user can eliminate the dry burning problem by adding e-liquid or checking whether the guiding liquid is normal or not after stopping the heating.

In one of the embodiments, as shown in FIG. 3, the real-time resistance of the heating element is compared with the preset first protection resistance interval, and when the real-time resistance falls within the first protection resistance interval, the output power is adjusted The steps include:

Step S310, comparing the real-time resistance of the heating element with a preset first protection resistance interval, when the real-time resistance of the heating element is greater than or equal to the second target value of the first protection resistance interval and less than the first protection resistance. When the first target value is in the value interval, the output power is adjusted to the second power; wherein, the second power is less than the first power.

When the real-time resistance value of the heating element is greater than or equal to the second target value of the first protection resistance value interval and less than the first target value of the first protection resistance value interval, the atomization component is in a dry burning state, and the output power is reduced to and The corresponding second power attempts to rebalance the atomization efficiency of the heating element and the efficiency of the liquid guide.

In one of the embodiments, as shown in FIG. 4, the heating control method of the atomization assembly further includes the following steps:

Step S510, controlling the atomizing assembly to use the preset second power as the output power for heating.

After the foregoing steps, the output power is adjusted to the second power for heating, so that the atomization assembly reaches a state where the atomization efficiency and the liquid guiding efficiency are balanced again.

In step S520, the real-time resistance value of the heating element of the atomization assembly is obtained.

After adjusting the power and heating for a period of time, the imbalance of the atomization of the liquid guide may occur again, so it is necessary to obtain the real-time resistance of the heating element and then compare the power control.

In step S530, the real-time resistance of the heating element is compared with a preset second protection resistance interval.

In step S540, when the real-time resistance of the heating element is less than the lower limit of the second protection resistance interval, the output power is adjusted to the first power.

Wherein, the second protection resistance interval is determined based on the second power from the preset protection resistance interval.

Recycle the heating control method of the atomization component, determine the corresponding second protection resistance interval according to the current output power, and judge the real-time resistance of the heating element according to the power adjustment scheme corresponding to the second protection resistance interval. The output power is adjusted so that the atomization component can be in a state of balance between atomization efficiency and liquid guiding efficiency as much as possible, so as to achieve the purpose of dry burning protection.

In step S550, when the real-time resistance of the heating element is greater than or equal to the upper limit of the second resistance interval, the atomizing assembly is controlled to stop heating.

If the real-time resistance value of the heating element reaches the upper limit, it may be difficult to eliminate the dry burning problem only by adjusting the output power. It is necessary to stop the heating in time to prevent the dry burning problem from getting worse.

In one of the embodiments, as shown in FIG. 5, the real-time resistance of the heating element is compared with the preset first protection resistance interval, and when the real-time resistance falls within the first protection resistance interval, the output power is adjusted The steps include:

Step S320: When the real-time resistance of the heating element is greater than or equal to the second target value of the first protection resistance interval and less than the first median value of the first protection resistance interval, the output power is adjusted to the third power, and The third power is less than the first power.

The first median value R ₁ divides the protection resistance interval formed by the first target value R _1H and the second target value R _1L into two cells. Each cell can correspond to a power value. When the heating element is When the real-time resistance value falls within the interval between the second target value and the first median value, the output power is reduced to a third power corresponding to the interval, so that the atomization assembly can regain a balance between atomization efficiency and liquid guiding efficiency.

In one of the embodiments, as shown in FIG. 6, the real-time resistance of the heating element is compared with the preset first protection resistance interval, and when the real-time resistance falls within the first protection resistance interval, the output power is adjusted The steps include:

Step S330, when the real-time resistance of the heating element is greater than or equal to the first median value of the first protection resistance interval and less than the first target value of the first protection resistance interval, the output power is adjusted to the fourth power; where , The fourth power is less than or equal to the third power.

When the real-time resistance value of the heating element falls within the interval formed by the first median value and the first target value, the output power is lowered to the fourth power corresponding to this interval, so that the atomization assembly can reach the atomization efficiency and liquid guide again The state of efficiency balance.

In one of the embodiments, as shown in FIG. 7, the heating control method of the atomization assembly further includes the following steps:

Step S610, controlling the atomizing assembly to use the preset third power as the output power for heating.

After the foregoing steps, the output power is adjusted to the third power for heating, so that the atomization assembly reaches a state where the atomization efficiency and the liquid guiding efficiency are balanced again.

In step S620, the real-time resistance value of the heating element of the atomization assembly is obtained.

After adjusting the power and heating for a period of time, the imbalance of the atomization of the liquid guide may occur again, so it is necessary to obtain the real-time resistance of the heating element and then compare and control the power.

Step S630, comparing the real-time resistance of the heating element with a preset third protection resistance interval;

Step S640: When the real-time resistance of the heating element is greater than or equal to the median of the third protection resistance interval and less than the upper limit of the third protection resistance interval, the output power is adjusted to the fourth power.

Wherein, the third protection resistance interval is determined based on the third power from the preset protection resistance interval.

Recycle the heating control method of the atomization component, determine the corresponding third protection resistance interval according to the current output power, and judge the real-time resistance of the heating element according to the power adjustment scheme corresponding to the third protection resistance interval, and then the corresponding The output power is adjusted so that the atomization component can be in a state of balance between atomization efficiency and liquid guiding efficiency as much as possible, so as to achieve the purpose of dry burning protection.

In step S650, when the real-time resistance of the heating element is less than the lower limit of the third protection resistance interval, the output power is adjusted to the first power.

When the real-time resistance of the heating element is less than the lower limit of the third protection resistance interval, that is, the atomization component reaches a state where the atomization efficiency and the efficiency of the liquid guide are balanced, no dry burning occurs, and the e-liquid content on the heating element is sufficient , The atomization efficiency is lower than the liquid guiding efficiency, and the output power can be restored to the first power for heating, and heating according to the normal working output power.

In step S660, when the real-time resistance of the heating element is greater than or equal to the upper limit of the third protection resistance interval, the atomization assembly is controlled to stop heating.

If the real-time resistance value of the heating element reaches the upper limit, it may be difficult to eliminate the dry burning problem only by adjusting the output power. It is necessary to stop the heating in time to prevent the dry burning problem from getting worse.

In one of the embodiments, as shown in FIG. 8, the heating control method of the atomization assembly further includes the following steps:

Step S710, controlling the atomizing assembly to use the preset fourth power as the output power for heating.

After the foregoing steps, the output power is adjusted to the fourth power for heating, so that the atomization assembly reaches a state where the atomization efficiency and the liquid guiding efficiency are in balance again.

In step S720, the real-time resistance value of the heating element of the atomization assembly is obtained.

After adjusting the power and heating for a period of time, the imbalance of the atomization of the liquid guide may occur again, so it is necessary to obtain the real-time resistance of the heating element before comparing and power control.

Step S730, comparing the real-time resistance of the heating element with a preset fourth protection resistance interval;

In step S740, when the real-time resistance of the heating element is greater than or equal to the upper limit of the fourth protection resistance interval, the atomization assembly is controlled to stop heating.

Wherein, the fourth protection resistance interval is determined based on the fourth power from the preset protection resistance interval.

Recycle the heating control method of the atomization component, determine the corresponding fourth protection resistance interval according to the current output power, and judge the real-time resistance of the heating element according to the power adjustment scheme corresponding to the fourth protection resistance interval. The output power is adjusted so that the atomization component can be in a state of balance between atomization efficiency and liquid guiding efficiency as much as possible, so as to achieve the purpose of dry burning protection.

Step S750: When the real-time resistance of the heating element is greater than or equal to the lower limit of the fourth protection resistance interval and less than the median of the fourth protection resistance interval, the output power is adjusted to the third power.

When the real-time resistance value of the heating element is greater than or equal to the lower limit of the fourth protection resistance value interval and less than the median value of the fourth protection resistance value interval, that is, the atomization efficiency of the atomization component does not match the liquid guiding efficiency. Light, the output power can be adjusted up to the third power for heating, to minimize the amount of smoke due to the power down adjustment, and the power adjustment judgment is made according to the third protection resistance interval corresponding to the third power.

In one of the embodiments, the sampling period for obtaining the real-time resistance value of the heating element of the atomization assembly ranges from 1 ms to 30 ms.

The shorter the sampling period, the more precise the adjustment of the dry-burn protection of the atomization component, but the greater the amount of data processing, and the higher the data processing capability of the electronic atomization device. Those skilled in the art can perform real-time adjustments according to specific product requirements. The sampling period of the resistance value is selected.

In one of the embodiments, as shown in FIG. 9, the heating control method of the atomization assembly further includes:

In step S340, the real-time resistance of the heating element is compared with the first protection resistance interval, and when the real-time resistance falls within the first protection resistance interval, prompt information is generated and fed back to the user.

When the real-time resistance value of the heating element falls within the first protection resistance value range, that is, the atomization efficiency of the atomization component and the liquid guiding efficiency are unbalanced, which may be due to the fact that there is less smoke oil in the liquid storage cavity or the liquid guiding member is blocked. This makes the e-liquid content on the heating element lower. In addition to adjusting the output power to avoid dry burning, it also generates prompt information to feed back to the user. The user can detect the e-liquid content in the liquid storage cavity and whether the liquid guide is blocked, and add e-liquid or It is to replace the internal parts to fundamentally solve the dry burning problem.

In one of the embodiments, the heating control method of the atomization assembly further includes:

The real-time resistance of the heating element is compared with the protection resistance interval corresponding to the current output power, and the output power is adjusted when the real-time resistance values collected in at least two sampling periods fall within the protection resistance interval.

The real-time resistance value collected multiple times is compared and then adjusted to avoid the real-time resistance value being unable to truly reflect the dry burning situation due to thermal inertia or other interference factors.

It should be understood that although the various steps in the flowcharts of FIGS. 1-9 are displayed in sequence as indicated by the arrows, these steps are not necessarily performed in sequence in the order indicated by the arrows. Unless there is a clear description in this article, there is no strict order for the execution of these steps, and these steps can be executed in other orders. Moreover, at least part of the steps in Figures 1-9 may include multiple sub-steps or multiple stages. These sub-steps or stages are not necessarily executed at the same time, but can be executed at different times. These sub-steps or stages The execution order of is not necessarily performed sequentially, but may be performed alternately or alternately with at least a part of other steps or sub-steps or stages of other steps. In one of the embodiments, an electronic atomization device is provided, and the application of this application provides any method for heating control of atomization components.

In one of the embodiments, as shown in FIG. 10, a heating control device for an atomization assembly is provided, which includes: a heating control module 910, a resistance value acquisition module 920, and an output power adjustment module 930, wherein:

The heating control module 910 is used to control the atomization assembly to use the preset first power as the output power for heating;

The resistance value obtaining module 920 is used to obtain the real-time resistance value of the heating element of the atomization component; and

The output power adjustment module 930 is configured to compare the real-time resistance of the heating element with a preset first protection resistance interval, and adjust the output power when the real-time resistance falls within the first protection resistance interval.

In one of the embodiments, as shown in FIG. 11, the heating control device of the atomization assembly further includes:

The heating stop control module 940 is configured to control the atomization component to stop heating when the real-time resistance of the heating element is greater than or equal to the first target value in the first protection resistance interval.

In one of the embodiments, the output power adjustment module 930 includes:

The first output power adjustment module is configured to adjust the output power to when the real-time resistance value of the heating element is greater than or equal to the second target value of the first protection resistance value interval and less than the first target value of the first protection resistance value interval The second power; where the second power is less than the first power.

For the specific definition of the heating control device of the atomization assembly, please refer to the above definition of the heating control method of the atomization assembly, which will not be repeated here. Each module in the heating control device for the atomization assembly can be implemented in whole or in part by software, hardware, and combinations thereof. The above-mentioned modules may be embedded in the form of hardware or independent of the processor in the computer equipment, or may be stored in the memory of the computer equipment in the form of software, so that the processor can call and execute the operations corresponding to the above-mentioned modules. In one of the embodiments, a computer device is provided. The computer device may be a terminal, and its internal structure diagram may be as shown in FIG. 12. The computer equipment includes a processor, a memory, a network interface, a display screen and an input device connected through a system bus. Among them, the processor of the computer device is used to provide calculation and control capabilities. The memory of the computer device includes a non-volatile storage medium and an internal memory. The non-volatile storage medium stores an operating system and computer readable instructions. The internal memory provides an environment for the operation of the operating system and computer-readable instructions in the non-volatile storage medium. The network interface of the computer device is used to communicate with an external terminal through a network connection. The computer-readable instruction is executed by the processor to realize a heating control method of the atomization assembly. The display screen of the computer equipment can be a liquid crystal display screen or an electronic ink display screen, and the input device of the computer equipment can be a touch layer covered on the display screen, or it can be a button, trackball or touchpad set on the housing of the computer equipment .

Those skilled in the art can understand that the structure shown in FIG. 12 is only a block diagram of a part of the structure related to the solution of the present application, and does not constitute a limitation on the computer device to which the solution of the present application is applied. The specific computer device may Including more or fewer parts than shown in the figure, or combining some parts, or having a different arrangement of parts.

A computer device includes a memory and one or more processors. The memory stores computer-readable instructions. When the computer-readable instructions are executed by the processor, the one or more processors perform the following steps:

Control the atomization component to use the preset first power as the output power for heating;

Obtain the real-time resistance value of the heating element of the atomization component; and

The real-time resistance of the heating element is compared with the preset first protection resistance interval, and when the real-time resistance falls within the first protection resistance interval, the output power is adjusted.

In one of the embodiments, the processor further implements the following steps when executing the computer-readable instructions:

When the real-time resistance of the heating element is greater than or equal to the first target value in the first protection resistance interval, the atomizing assembly is controlled to stop heating.

In one of the embodiments, the processor further implements the following steps when executing the computer-readable instructions:

When the real-time resistance of the heating element is greater than or equal to the second target value of the first protection resistance interval and less than the first target value of the first protection resistance interval, the output power is adjusted to the second power; The power is less than the first power.

In one of the embodiments, the processor further implements the following steps when executing the computer-readable instructions:

Control the atomization component to use the preset second power as the output power for heating;

Obtain the real-time resistance value of the heating element of the atomization component;

The real-time resistance of the heating element is compared with the preset second protection resistance interval, and when the real-time resistance of the heating element is less than the lower limit of the second protection resistance interval, the output power is adjusted to the first power;

When the real-time resistance of the heating element is greater than or equal to the upper limit of the second resistance interval, the atomizing assembly is controlled to stop heating.

In one of the embodiments, the processor further implements the following steps when executing the computer-readable instructions:

When the real-time resistance of the heating element is greater than or equal to the second target value of the first protection resistance interval and less than the first median value of the first protection resistance interval, the output power is adjusted to the third power, and the third power Less than the first power.

In one of the embodiments, the processor further implements the following steps when executing the computer-readable instructions:

When the real-time resistance value of the heating element is greater than or equal to the first median value of the first protection resistance value interval and less than the first target value of the first protection resistance value interval, the output power is adjusted to the fourth power; The power is less than or equal to the third power.

In one of the embodiments, the processor further implements the following steps when executing the computer-readable instructions:

Control the atomization component to use the preset third power as the output power for heating;

Obtain the real-time resistance value of the heating element of the atomization component;

Compare the real-time resistance of the heating element with the preset third protection resistance interval, when the real-time resistance of the heating element is greater than or equal to the median of the third protection resistance interval and less than the upper limit of the third protection resistance interval Value, the output power is adjusted to the fourth power;

When the real-time resistance of the heating element is less than the lower limit of the third protection resistance interval, the output power is adjusted to the first power;

When the real-time resistance of the heating element is greater than or equal to the upper limit of the third protection resistance interval, the atomization assembly is controlled to stop heating.

In one of the embodiments, the processor further implements the following steps when executing the computer-readable instructions:

Control the atomization component to use the preset fourth power as the output power for heating;

Obtain the real-time resistance value of the heating element of the atomization component;

The real-time resistance of the heating element is compared with the preset fourth protection resistance interval, and when the real-time resistance of the heating element is greater than or equal to the upper limit of the fourth protection resistance interval, the atomization component is controlled to stop heating;

When the real-time resistance of the heating element is greater than or equal to the lower limit of the fourth protection resistance interval and less than the middle value of the fourth protection resistance interval, the output power is adjusted to the third power.

In one of the embodiments, the processor further implements the following steps when executing the computer-readable instructions:

The real-time resistance value of the heating element is compared with the first protection resistance value interval, and when the real-time resistance value falls within the first protection resistance value interval, prompt information is generated and fed back to the user.

In one of the embodiments, the processor further implements the following steps when executing the computer-readable instructions:

The real-time resistance of the heating element is compared with the protection resistance interval corresponding to the current output power, and the output power is adjusted when the real-time resistance values collected in at least two sampling periods fall within the protection resistance interval.

One or more non-volatile storage media storing computer-readable instructions. When the computer-readable instructions are executed by one or more processors, the one or more processors perform the following steps:

Control the atomization component to use the preset first power as the output power for heating;

Obtain the real-time resistance value of the heating element of the atomization component; and

The real-time resistance of the heating element is compared with the preset first protection resistance interval, and when the real-time resistance falls within the first protection resistance interval, the output power is adjusted.

In one of the embodiments, when the computer-readable instructions are executed by the processor, the following steps are also implemented:

When the real-time resistance of the heating element is greater than or equal to the first target value in the first protection resistance interval, the atomization component is controlled to stop heating.

In one of the embodiments, when the computer-readable instructions are executed by the processor, the following steps are also implemented:

When the real-time resistance of the heating element is greater than or equal to the second target value of the first protection resistance interval and less than the first target value of the first protection resistance interval, the output power is adjusted to the second power; The power is less than the first power.

In one of the embodiments, when the computer-readable instructions are executed by the processor, the following steps are also implemented:

Control the atomization component to use the preset second power as the output power for heating;

Obtain the real-time resistance value of the heating element of the atomization component;

The real-time resistance of the heating element is compared with the preset second protection resistance interval, and when the real-time resistance of the heating element is less than the lower limit of the second protection resistance interval, the output power is adjusted to the first power;

When the real-time resistance of the heating element is greater than or equal to the upper limit of the second resistance interval, the atomizing assembly is controlled to stop heating.

In one of the embodiments, when the computer-readable instructions are executed by the processor, the following steps are also implemented:

When the real-time resistance of the heating element is greater than or equal to the second target value of the first protection resistance interval and less than the first median value of the first protection resistance interval, the output power is adjusted to the third power, and the third power Less than the first power.

In one of the embodiments, when the computer-readable instructions are executed by the processor, the following steps are also implemented:

When the real-time resistance value of the heating element is greater than or equal to the first median value of the first protection resistance value interval and less than the first target value of the first protection resistance value interval, the output power is adjusted to the fourth power; The power is less than or equal to the third power.

In one of the embodiments, when the computer-readable instructions are executed by the processor, the following steps are also implemented:

Control the atomization component to use the preset third power as the output power for heating;

Obtain the real-time resistance value of the heating element of the atomization component;

Compare the real-time resistance of the heating element with the preset third protection resistance interval, when the real-time resistance of the heating element is greater than or equal to the median of the third protection resistance interval and less than the upper limit of the third protection resistance interval Value, the output power is adjusted to the fourth power;

When the real-time resistance of the heating element is less than the lower limit of the third protection resistance interval, the output power is adjusted to the first power;

When the real-time resistance of the heating element is greater than or equal to the upper limit of the third protection resistance interval, the atomization assembly is controlled to stop heating.

In one of the embodiments, when the computer-readable instructions are executed by the processor, the following steps are also implemented:

Control the atomization component to use the preset fourth power as the output power for heating;

Obtain the real-time resistance value of the heating element of the atomization component;

The real-time resistance of the heating element is compared with the preset fourth protection resistance interval, and when the real-time resistance of the heating element is greater than or equal to the upper limit of the fourth protection resistance interval, the atomization component is controlled to stop heating;

When the real-time resistance of the heating element is greater than or equal to the lower limit of the fourth protection resistance interval and less than the middle value of the fourth protection resistance interval, the output power is adjusted to the third power.

In one of the embodiments, when the computer-readable instructions are executed by the processor, the following steps are also implemented:

The real-time resistance value of the heating element is compared with the first protection resistance value interval, and when the real-time resistance value falls within the first protection resistance value interval, prompt information is generated and fed back to the user.

In one of the embodiments, when the computer-readable instructions are executed by the processor, the following steps are also implemented:

The real-time resistance of the heating element is compared with the protection resistance interval corresponding to the current output power, and the output power is adjusted when the real-time resistance values collected in at least two sampling periods fall within the protection resistance interval.

A person of ordinary skill in the art can understand that all or part of the processes in the above-mentioned embodiment methods can be implemented by instructing relevant hardware through computer-readable instructions. The computer-readable instructions can be stored in a non-volatile computer. In a readable storage medium, when the computer-readable instructions are executed, they may include the processes of the above-mentioned method embodiments. Wherein, any reference to memory, storage, database or other media used in the embodiments provided in this application may include non-volatile and/or volatile memory. Non-volatile memory may include read only memory (ROM), programmable ROM (PROM), electrically programmable ROM (EPROM), electrically erasable programmable ROM (EEPROM), or flash memory. Volatile memory may include random access memory (RAM) or external cache memory. As an illustration and not a limitation, RAM is available in many forms, such as static RAM (SRAM), dynamic RAM (DRAM), synchronous DRAM (SDRAM), double data rate SDRAM (DDRSDRAM), enhanced SDRAM (ESDRAM), synchronous chain Channel (Synchlink) DRAM (SLDRAM), memory bus (Rambus) direct RAM (RDRAM), direct memory bus dynamic RAM (DRDRAM), and memory bus dynamic RAM (RDRAM), etc.

The technical features of the above embodiments can be combined arbitrarily. In order to make the description concise, all possible combinations of the technical features in the above embodiments are not described. However, as long as there is no contradiction between the combinations of these technical features, they should It is considered as the range described in this specification.

The above-mentioned embodiments only express several implementation manners of the present application, and their description is relatively specific and detailed, but they should not be understood as a limitation on the scope of the invention patent. It should be pointed out that for those of ordinary skill in the art, without departing from the concept of this application, several modifications and improvements can be made, and these all fall within the protection scope of this application. Therefore, the scope of protection of the patent of this application shall be subject to the appended claims.

Claims (20)

A heating control method of an atomization component includes: Controlling the atomization assembly to use the preset first power as the output power for heating; Obtaining the real-time resistance value of the heating element of the atomization assembly; and The real-time resistance of the heating element is compared with a preset first protection resistance interval, and when the real-time resistance falls within the first protection resistance interval, the output power is adjusted. The heating control method of the atomization assembly according to claim 1, wherein the first protection resistance interval includes at least a first target value and a second target value, wherein the first target value is the first The upper limit of a protection resistance interval, and the second target value is the lower limit of the first protection resistance interval. The heating control method of an atomization component according to claim 2, wherein the first protection resistance interval further comprises a first median value, and the first median value is the same as the first target value and the first median value. The median value between the two target values. The heating control method of the atomization component according to claim 3, wherein the first protection resistance value interval further includes a plurality of target values, and a subdivision interval is formed between every two adjacent target values, according to Adjust the output power to the power corresponding to the subdivision interval in which the real-time resistance value falls into the subdivision interval. The heating control method of the atomization assembly according to claim 2, wherein the method further comprises the following steps: When the real-time resistance of the heating element is greater than or equal to the first target value of the first protection resistance interval, the atomization assembly is controlled to stop heating. The heating control method of the atomization assembly according to claim 3, wherein the method further comprises the following steps: When the real-time resistance of the heating element is greater than or equal to the first target value of the first protection resistance interval, the atomization assembly is controlled to stop heating. The heating control method of the atomization assembly according to claim 2, wherein the real-time resistance value of the heating element is compared with a preset first protection resistance value interval, and when the real-time resistance value falls within the In the first protection resistance interval, the step of adjusting the output power includes: When the real-time resistance of the heating element is greater than or equal to the second target value of the first protection resistance interval and less than the first target value of the first protection resistance interval, the output power is adjusted to Second power; wherein the second power is less than the first power. The heating control method of the atomization assembly according to claim 7, wherein the method further comprises the following steps: Controlling the atomization assembly to use the preset second power as the output power for heating; Obtaining the real-time resistance value of the heating element of the atomization assembly; and The real-time resistance of the heating element is compared with a preset second protection resistance interval, and when the real-time resistance of the heating element is less than the lower limit of the second protection resistance interval, the The output power is adjusted to the first power; and When the real-time resistance of the heating element is greater than or equal to the upper limit of the second resistance interval, the atomization assembly is controlled to stop heating. The heating control method of the atomization assembly according to claim 3, wherein the real-time resistance value of the heating element is compared with a preset first protection resistance value interval, and when the real-time resistance value falls within In the first protection resistance interval, the step of adjusting the output power includes: When the real-time resistance of the heating element is greater than or equal to the second target value of the first protection resistance interval and less than the first median value of the first resistance interval, the output power is adjusted to the first Three powers, and the third power is less than the first power. The heating control method of the atomization assembly according to claim 3, wherein the real-time resistance value of the heating element is compared with a preset first protection resistance value interval, and when the real-time resistance value falls within In the first protection resistance interval, the step of adjusting the output power includes: When the real-time resistance value of the heating element is greater than or equal to the first median value of the first protection resistance value interval and less than the first target value of the first protection resistance value interval, the output power is adjusted to The fourth power; wherein the fourth power is less than or equal to the third power. The heating control method of the atomization assembly according to claim 9, wherein the method further comprises the following steps: Controlling the atomization assembly to use the preset third power as the output power for heating; Obtaining the real-time resistance value of the heating element of the atomization assembly; The real-time resistance value of the heating element is compared with a preset third protection resistance value interval, when the real-time resistance value of the heating element is greater than or equal to the median value of the third protection resistance value interval and less than the first When the upper limit value of the three protection resistance interval, the output power is adjusted to the fourth power; When the real-time resistance of the heating element is less than the lower limit of the third protection resistance interval, adjusting the output power to the first power; and When the real-time resistance of the heating element is greater than or equal to the upper limit of the third protection resistance interval, the atomization assembly is controlled to stop heating. The heating control method of the atomization assembly according to claim 10, wherein the method further comprises the following steps: Controlling the atomization assembly to use the preset fourth power as the output power for heating; Obtaining the real-time resistance value of the heating element of the atomization assembly; The real-time resistance of the heating element is compared with a preset fourth protection resistance interval, and when the real-time resistance of the heating element is greater than or equal to the upper limit of the fourth protection resistance interval, control The atomization component stops heating; and When the real-time resistance of the heating element is greater than or equal to the lower limit of the fourth protection resistance interval and less than the median value of the fourth protection resistance interval, the output power is adjusted to the third power . The heating control method of the atomization assembly according to claim 1, wherein the sampling period for obtaining the real-time resistance value of the heating element of the atomization assembly ranges from 1 ms to 30 ms. The heating control method of an atomization assembly according to claim 1, wherein the method further comprises: The real-time resistance value of the heating element is compared with the first protection resistance value interval, and when the real-time resistance value falls within the first protection resistance value interval, prompt information is generated and fed back to the user. The heating control method of the atomization assembly according to claim 13, wherein the method further comprises: The real-time resistance value of the heating element is compared with the protection resistance value interval corresponding to the current output power, and when the real-time resistance value collected in at least two sampling periods falls within the protection resistance value interval, adjust all The output power. A computer device includes a memory and one or more processors. The memory stores computer-readable instructions. When the computer-readable instructions are executed by the one or more processors, the one or more Each processor performs the following steps: Controlling the atomization assembly to use the preset first power as the output power for heating; Obtaining the real-time resistance value of the heating element of the atomization assembly; and The real-time resistance of the heating element is compared with a preset first protection resistance interval, and when the real-time resistance falls within the first protection resistance interval, the output power is adjusted. The computer device according to claim 16, wherein the processor further executes the following steps when executing the computer-readable instruction: When the real-time resistance of the heating element is greater than or equal to the first target value of the first protection resistance interval, the atomization assembly is controlled to stop heating. The computer device according to claim 16, wherein the processor further executes the following steps when executing the computer-readable instruction: When the real-time resistance of the heating element is greater than or equal to the second target value of the first protection resistance interval and less than the first target value of the first protection resistance interval, the output power is adjusted to Second power; wherein the second power is less than the first power. One or more non-volatile computer-readable storage media storing computer-readable instructions. When the computer-readable instructions are executed by one or more processors, the one or more processors perform the following steps: Controlling the atomization assembly to use the preset first power as the output power for heating; Obtaining the real-time resistance value of the heating element of the atomization assembly; and The real-time resistance of the heating element is compared with a preset first protection resistance interval, and when the real-time resistance falls within the first protection resistance interval, the output power is adjusted. The storage medium according to claim 19, wherein the following steps are further executed when the computer-readable instructions are executed by the processor: When the real-time resistance of the heating element is greater than or equal to the first target value of the first protection resistance interval, the atomization assembly is controlled to stop heating.

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