CN109007975B - Electronic cigarette control method and electronic cigarette - Google Patents

Abstract

The invention discloses an electronic cigarette control method and an electronic cigarette, and belongs to the technical field of electronic cigarettes. The method comprises the following steps: collecting body parameters of a user; the physical parameters are parameters for representing the physical health condition of the user; controlling the output power of the atomizer to generate smoke according to the body parameters; wherein the output power is in positive correlation with the amount of smoke generated by the atomizer. The problem of the fixed not intelligent enough of smog that produces of atomizer among the correlation technique is solved, reached and to have controlled the output of atomizer in real time according to user's physical parameter for electron cigarette is more intelligent effect.

Description

Electronic cigarette control method and electronic cigarette

Technical Field

The invention relates to the technical field of electronic cigarettes, in particular to an electronic cigarette control method and an electronic cigarette.

Background

The electronic cigarette is an electronic product simulating a cigarette, and has the same appearance as the cigarette. In addition, the electronic cigarette comprises an atomizer, and nicotine and the like are converted into steam by means of atomization of the atomizer and the like, so that the cigarette can generate smoke, taste and feeling as same as those of cigarettes.

In the related art, after a user turns on a switch in an electronic cigarette, an atomizer in the electronic cigarette starts to operate according to default output power, and then smoke is generated for the user to smoke.

In the above scheme, after the electronic cigarette is turned on, the amount of smoke generated in a unit time period when the atomizer operates at the default output power is fixed, so that the control mode of the electronic cigarette is not intelligent enough.

Disclosure of Invention

In order to solve the problems of the related art, the embodiment of the invention provides an electronic cigarette control method and an electronic cigarette. The technical scheme is as follows:

in a first aspect, there is provided an electronic cigarette control method, the method comprising:

collecting body parameters of a user; the physical parameters are parameters for representing the physical health condition of the user;

controlling the output power of the atomizer to generate smoke according to the body parameters; wherein the output power is in positive correlation with the amount of smoke generated by the atomizer.

Optionally, said controlling the output power of the nebulizer to produce smoke in accordance with the physical parameter comprises:

inquiring first output power corresponding to the body parameter according to the corresponding relation between the body parameter and the output power;

controlling the atomizer to generate smoke at the queried first output power.

Optionally, said controlling the output power of the nebulizer to produce smoke in accordance with the physical parameter comprises:

determining a health grade from the physical parameter;

inquiring a second output power corresponding to the determined health grade according to the corresponding relation between the health grade and the output power;

controlling the atomizer to generate smoke at the queried second output power.

Optionally, said controlling the output power of the nebulizer to produce smoke in accordance with the physical parameter comprises:

calculating the change rate of the body parameters in a unit time period according to the body parameters acquired in real time;

controlling the output power of the atomizer to generate smoke according to the change rate.

Optionally, said controlling the output power of the nebulizer to produce smoke in accordance with said rate of change comprises:

detecting whether the change rate reaches a first preset threshold value;

if the change rate reaches the first preset threshold, reducing the output power of the atomizer for generating smoke when the body parameter is smaller than a first boundary value or larger than a second boundary value; and when the body parameter is between the first boundary value and the second boundary value, increasing the output power of the atomizer for generating smoke, wherein the first boundary value and the second boundary value are boundary values of a healthy value range corresponding to the body parameter, and the first boundary value is smaller than the second boundary value.

Optionally, the method further comprises:

and when the physical parameter is smaller than a first threshold value or larger than a second threshold value, controlling the atomizer to stop working, wherein the first threshold value is not larger than a first boundary value, the second threshold value is not smaller than a second boundary value, the first boundary value and the second boundary value are boundary values of a health value range corresponding to the physical parameter, and the first boundary value is smaller than the second boundary value.

Optionally, the method further comprises:

in the process of controlling the output power, if the physical parameter is continuously decreased after being smaller than a first boundary value or continuously increased after being larger than a second boundary value within a preset time period, controlling the atomizer to stop working, wherein the first boundary value and the second boundary value are boundary values of a health value range corresponding to the physical parameter, and the first boundary value is smaller than the second boundary value.

Optionally, the method further comprises:

generating prompt information, wherein the prompt information carries the name of the tobacco tar currently used by the electronic cigarette and the body parameters acquired in the historical time period;

and sending the prompt information to a bound mobile terminal, wherein the mobile terminal is used for recommending tobacco tar for the user according to the prompt information.

Optionally, the method further comprises:

acquiring the physical parameter prior to the nebulizer generating smoke;

determining an initial output power of the nebulizer from the physical parameter;

controlling the atomizer to generate the smoke at the initial output power when the smoke is generated.

Optionally, the method further comprises:

continuing to acquire the physical parameters of the user after the nebulizer stops producing smoke;

if the acquired body parameters meet preset conditions, determining initial output power of the atomizer for generating smoke next time according to the acquired body parameters; or sending the acquired physical parameters to a mobile terminal, wherein the mobile terminal is used for recommending tobacco tar for the user according to the received physical parameters; the preset condition comprises that the change rate of the physical parameter in a preset time period reaches a second preset threshold value, or the physical parameter is smaller than a first boundary value, or the physical parameter is larger than a second boundary value; the first boundary value and the second boundary value are boundary values of a health value range corresponding to the body parameter, and the first boundary value is smaller than the second boundary value.

In a second aspect, there is provided an electronic cigarette comprising:

the acquisition module is used for acquiring body parameters of a user; the physical parameters are parameters for representing the physical health condition of the user;

the control module is used for controlling the output power of the atomizer to generate smoke according to the body parameters acquired by the acquisition module; wherein the output power is in positive correlation with the amount of smoke generated by the atomizer.

Optionally, the control module is further configured to:

inquiring first output power corresponding to the body parameter according to the corresponding relation between the body parameter and the output power; controlling the atomizer to generate smoke at the queried first output power.

Optionally, the control module is further configured to:

determining a health grade from the physical parameter; inquiring a second output power corresponding to the determined health grade according to the corresponding relation between the health grade and the output power; controlling the atomizer to generate smoke at the queried second output power.

Optionally, the control module includes:

the calculation unit is used for calculating the change rate of the body parameters in a unit time period according to the body parameters acquired in real time;

and the control unit is used for controlling the output power of the atomizer for generating smoke according to the change rate.

Optionally, the control unit is further configured to:

detecting whether the change rate reaches a first preset threshold value;

if the change rate reaches the first preset threshold, reducing the output power of the atomizer for generating smoke when the body parameter is smaller than a first boundary value or larger than a second boundary value; and when the body parameter is between the first boundary value and the second boundary value, increasing the output power of the atomizer for generating smoke, wherein the first boundary value and the second boundary value are boundary values of a healthy value range corresponding to the body parameter, and the first boundary value is smaller than the second boundary value.

Optionally, the control module is further configured to:

and when the physical parameter is smaller than a first threshold value or larger than a second threshold value, controlling the atomizer to stop working, wherein the first threshold value is not larger than a first boundary value, the second threshold value is not smaller than a second boundary value, the first boundary value and the second boundary value are boundary values of a health value range corresponding to the physical parameter, and the first boundary value is smaller than the second boundary value.

Optionally, the control module is further configured to, in the process of controlling the output power, control the atomizer to stop working if the physical parameter continuously decreases after being smaller than a first boundary value or continuously increases after being larger than a second boundary value within a preset time period, where the first boundary value and the second boundary value are boundary values of a health value range corresponding to the physical parameter, and the first boundary value is smaller than the second boundary value.

Optionally, the electronic cigarette further comprises:

the generating module is used for generating prompt information, and the prompt information carries the name of tobacco tar currently used by the electronic cigarette and the body parameters acquired in a historical time period;

and the sending module is used for sending the prompt information to the bound mobile terminal, and the mobile terminal is used for recommending tobacco tar for the user according to the prompt information.

Optionally, the collecting module is further configured to collect the body parameter before the nebulizer generates smoke;

the electronic cigarette further comprises:

a determination module for determining an initial output power of the nebulizer from the physical parameter;

the control module is further used for controlling the atomizer to generate smoke at the initial output power when the atomizer starts to generate smoke.

Optionally, the collecting module is further configured to continue to collect the body parameter of the user after the nebulizer stops generating smoke;

the control module is used for determining the initial output power of the atomizer when the body parameters collected by the collection module meet preset conditions according to the collected body parameters; or sending the collected physical parameters to a mobile terminal, wherein the mobile terminal is used for recommending tobacco tar for the user according to the received physical parameters; the preset condition comprises that the change rate of the physical parameter in a preset time period reaches a second preset threshold value, or the physical parameter is smaller than a first boundary value, or the physical parameter is larger than a second boundary value; the first boundary value and the second boundary value are boundary values of a health value range corresponding to the body parameter, and the first boundary value is smaller than the second boundary value.

The technical scheme provided by the embodiment of the invention has the following beneficial effects:

the body parameters of a user are collected in the process of generating smoke by the atomizer, and then the output power of the atomizer for generating the smoke is controlled according to the body parameters. Wherein, the output power is in positive correlation with the amount of the smoke generated by the atomizer; the problem of the fixed not intelligent enough of smog that produces of atomizer among the correlation technique is solved, reached and to have controlled the output of atomizer in real time according to user's physical parameter for electron cigarette is more intelligent effect. Meanwhile, as the output power of the atomizer is controlled according to the body parameters, the method also achieves the effect of providing the output power suitable for the current body state of the user for the user so as to improve the use experience of the user in using the electronic cigarette.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

Figure 1 is a schematic diagram of an implementation environment involved in a method for controlling an electronic cigarette according to various embodiments of the present invention;

fig. 2 is a schematic structural diagram of an electronic cigarette according to an embodiment of the present invention;

figure 3 is a schematic diagram of a sensor provided in an electronic cigarette provided by embodiments of the present invention;

figures 4, 5 and 6 are flow charts of methods of controlling an electronic cigarette according to embodiments of the present invention;

figure 7 is a method flow diagram of another electronic cigarette control method provided by embodiments of the present invention;

fig. 8 is a schematic structural diagram of an electronic cigarette according to an embodiment of the present invention.

Detailed Description

To make the objects, technical solutions and advantages of the present invention more apparent, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Referring to FIG. 1, a schematic diagram of an implementation environment in which various embodiments of the invention are implemented is shown. As shown in fig. 1, the implementation environment may include an e-cigarette 110 and a mobile terminal 120.

As shown in fig. 2, the electronic cigarette 110 may include an MCU (micro controller Unit), an atomizer, a power control Unit, a battery, a charging Unit, a parameter collecting Unit, a key, and a display Unit. Wherein:

the MCU is the control center of the e-cigarette 110, which is used to control other units in the e-cigarette 110.

The atomizer is used for atomizing tobacco tar, and then produces smog for the user's suction.

The power control unit is used for controlling the output power of the atomizer, and when the power control unit is actually implemented, the larger the output power of the atomizer is, the more the atomizer generates smoke in a unit time period.

A battery is used to power the e-cigarette 110, and optionally, the battery is typically a lithium battery.

The charging unit refers to a unit for charging a battery.

The parameter acquisition unit is a unit for acquiring a physical parameter of the user, and optionally, the parameter acquisition unit may be a sensor.

Since the physical parameters may include: at least one of blood oxygen content, blood oxygen saturation, blood pressure value, heart rate, lung capacity, step number, saliva pH value, oral cavity humidity, body temperature and oral cavity temperature, therefore, the type of the sensor is different according to different body parameters needing to be collected. For example, when the body parameter includes blood oxygen content, the electronic cigarette may acquire the parameter through a blood oxygen sensor; when the physical parameter comprises a heart rate, the electronic cigarette can acquire the parameter through a heart rate sensor; when the body parameter includes the sialic acid alkalinity, the electronic cigarette may acquire the parameter through a sialic acid alkalinity sensor, and so on, which is not described in detail herein.

In addition, the sensor may be located at different positions in the electronic cigarette 110 according to different principles of acquiring different body parameters. For example, when acquiring parameters such as blood oxygen content, blood oxygen saturation, or body temperature, the sensor may be in contact with the skin of the user, so that the corresponding sensor may be disposed at the holding position of the user's finger in the electronic cigarette 110, that is, at the position shown in fig. 31 in (1) of fig. 3. For another example, when acquiring parameters such as ph value of saliva, oral cavity temperature or oral cavity humidity, the sensor needs to enter the oral cavity of the user, so that the corresponding sensor may be disposed at the position of the mouthpiece in the electronic cigarette 110, that is, at the position shown as 32 in (2) of fig. 3. Of course, in actual implementation, the corresponding sensors may be disposed at other positions according to different principles of collecting different body parameters, which is not limited in this embodiment.

The button refers to a button in the electronic cigarette 110 for controlling the electronic cigarette 110 to be turned on or off. The button may also be a button for controlling the electronic cigarette 110 to start or end the operation of the atomizer, and may also be a button for setting the operation parameters of the electronic cigarette 110, such as time, operation mode, operation voltage, operation power, and the like. Optionally, the key may be an entity key, a virtual key such as a touch screen, a pressure key, a touch key, or the like, which is not limited in this embodiment.

The display unit refers to a unit for display. Alternatively, the display unit may be a display screen or the like. The MCU can transmit the content to be displayed to the display unit, such as the working mode, time and date of the electronic cigarette, so as to display the content.

Although not shown in the drawings, in actual implementation, the electronic cigarette may further include other units, for example, a communication unit for communicating with other terminals, such as a WiFi (Wireless Fidelity) unit, a bluetooth unit, an infrared unit, and the like, and for example, a container for holding tobacco tar may also be included, and details of this embodiment are not repeated herein. In addition, in practical implementation, two or more units in the electronic cigarette 110 may also be integrated into a whole, for example, the MCU, the power control unit, the battery, the charging unit, the parameter collecting unit, the key and the display unit may be integrated into a battery device, and the specific structure of the electronic cigarette is not limited in this embodiment.

The mobile terminal 120 may be a terminal such as a mobile phone, a tablet computer, or an e-reader. The mobile terminal 120 may be connected to the e-cigarette 110 through a wireless network. Optionally, an APP (Application) corresponding to the electronic cigarette 110 may be installed in the mobile terminal 120, and the mobile terminal 120 is bound to the electronic cigarette 110 through the APP.

It should be noted that fig. 1 is only illustrated by an implementation environment that includes both the electronic cigarette 110 and the mobile terminal 120, and optionally, the implementation environment may further include more or fewer terminals, for example, the implementation environment may also not include the mobile terminal 120, which is not limited in this embodiment.

In the implementation scenario described above, the electronic cigarette 110 may collect body parameters of the user, and control the output power of the nebulizer according to the collected body parameters. In practice, the e-cigarette 110 may collect the physical parameters of the user at least one of before, during and after the aerosol is generated by the nebulizer, and therefore, each of the three different embodiments will be described in detail below.

Referring to fig. 4, a flowchart of a method of controlling an electronic cigarette according to an embodiment of the present invention is shown, and the electronic cigarette control method is used in the electronic cigarette shown in fig. 1 to illustrate the embodiment. As shown in fig. 4, the electronic cigarette control method may include:

in step 401, physical parameters are collected before the nebulizer generates smoke.

The electronic cigarette may collect the user's physical parameters after the electronic cigarette is turned on and before the cigarette is lit. Alternatively, the e-cigarette may capture physical parameters of the user through sensors. The body parameter is a parameter for characterizing the physical health condition of the user, and the specific content thereof is as described in the foregoing embodiments, and is not described herein again.

For example, the body parameter includes blood oxygen content, and when the user places a finger at the position of the blood oxygen sensor in the electronic cigarette before smoking, the blood oxygen sensor can acquire the blood oxygen content of the user. For another example, the body parameter includes sialic acid alkalinity, and before the user smokes, the user may put a mouthpiece of the electronic cigarette into the mouth, and a sialic acid alkalinity sensor disposed at the mouthpiece may acquire the sialic acid alkalinity of the user.

The specific contents and specific collection modes of the body parameters are detailed in the foregoing parts of the embodiments, and are not described herein again.

Step 402, determining an initial output power of the electronic cigarette according to the body parameter.

Optionally, the electronic cigarette may query the output power corresponding to the acquired body parameter according to a corresponding relationship between the body parameter and the output power, where the queried output power is the initial output power of the atomizer after the cigarette is ignited. Optionally, in the above correspondence, the plurality of body parameters may correspond to one output power, for example, taking the body parameter as the blood oxygen content, please refer to the following table, which shows a possible correspondence, as shown in the following table, in which the output power corresponding to the blood oxygen content of 95% to 96% is 8W, and the output power corresponding to the blood oxygen content of 96% to 97% is 10W, which is not limited in this embodiment.

Blood oxygen content	Output power
		95％-96％	8W
96％-97％	10W

Optionally, the electronic cigarette may further determine a health level of the user according to the collected physical parameters, query an output power corresponding to the determined health level according to a correspondence between the health level and the output power, and the queried output power is an initial output power of the atomizer after ignition of the cigarette. Similar to the above, the higher the determined health level, the higher its corresponding output power may be, and vice versa, the smaller its corresponding output power, for the health of the user and the experience of the use of the e-cigarette. The electronic cigarette can inquire the health level corresponding to the body parameter according to the corresponding relation between the body parameter and the health level. Alternatively, one health level may correspond to a range of physical parameters. For example, taking the body parameter including the blood oxygen content as an example, please refer to the following table, which shows a possible body parameter and a health level and a possible corresponding relationship between the health level and the output power.

Physical parameters	Health grade	Output power
			>95％	Superior food	10W
85％～90％	Good wine	7W
			<85％	Difference (D)	6W

The above-mentioned corresponding relation between body parameter and the output power, the corresponding relation between health level and the output power and the corresponding relation between body parameter and the health level can be the acquiescent corresponding relation in the electron cigarette, also can be the user-defined corresponding relation in the electron cigarette, still can be the user through the APP in mobile terminal after self-defined to send the corresponding relation to the electron cigarette, this embodiment does not restrict this.

It should be noted that step 401 and step 402 are optional steps, and may or may not be executed in actual implementation, which is not limited in this embodiment.

And step 403, controlling the atomizer to generate the smoke at the initial output power when the smoke is generated.

After the electronic cigarette is lit, a nebulizer in the electronic cigarette may generate smoke at an initial output power.

When the electronic cigarette executes the steps 401 and 402, the initial output power is the output power determined in the step 402, and when the steps 401 and 402 are not executed, the initial output power may be the output power preset in the electronic cigarette, or may be the output power of the atomizer when the electronic cigarette is used last time, which is not limited in this embodiment.

In summary, in the electronic cigarette control method provided in this embodiment, the user parameters are collected before the atomizer starts to work, that is, before the user smokes the electronic cigarette, the initial output power of the atomizer when generating the smoke is determined according to the user parameters, and then the atomizer is controlled to generate the smoke with the initial output power when starting to generate the smoke; the problem of the fixed not intelligent enough of smog that produces of atomizer among the correlation technique is solved, reached and to have controlled the output of atomizer in real time according to user's physical parameter for electron cigarette is more intelligent effect. Meanwhile, when the atomizer starts to generate smoke, the smoke is generated according to the initial output power determined by the user parameters, so that the effect of providing the output power suitable for the current body state of the user for the user and further improving the use experience of the user in using the electronic cigarette is achieved.

Referring to fig. 5, a flowchart of a method of controlling an electronic cigarette according to an embodiment of the present invention is shown, and the electronic cigarette control method is used in the electronic cigarette shown in fig. 1 to illustrate the embodiment. As shown in fig. 5, the electronic cigarette control method may include:

step 501, collecting body parameters of a user in the process of generating smoke by the atomizer.

After the nebulizer begins to produce aerosol, the user may puff. At this time, the electronic cigarette may collect physical parameters of the user. In practice, the electronic cigarette may collect the body parameters in real time after the nebulizer starts producing smoke, or at predetermined time intervals. The manner of acquiring the body parameters of the electronic cigarette is similar to that in step 401, and this embodiment is not described herein again.

Optionally, an airflow sensor may be disposed in the electronic cigarette, and the electronic cigarette may detect whether the user is currently performing a smoking action through the airflow sensor (if the airflow sensor detects an airflow, the electronic cigarette may determine that the user is currently performing the smoking action, otherwise, if the airflow sensor does not detect an airflow, the electronic cigarette may determine that the user is not performing the smoking action), and then when the detection result is that the user is performing the smoking action, the electronic cigarette collects the physical parameters of the user. The electronic cigarette may detect whether the user performs the smoking action currently in real time, or detect whether the user performs the smoking action at predetermined time intervals, which is not limited herein. It should be noted that, the above is only an example of detecting the smoking behavior of the user through the airflow sensor, in practical implementation, the electronic cigarette may also detect through other technical means, for example, whether the airflow sensor detects the airflow and when the atomizer works at the same time, it is determined that the user performs smoking, which is not limited in this embodiment.

Step 502, controlling the output power of the atomizer to generate smoke according to the body parameters; wherein, the output power is in positive correlation with the amount of smoke generated by the electronic cigarette.

As a possible implementation manner, the electronic cigarette may query the first output power corresponding to the acquired body parameter according to the corresponding relationship between the body parameter and the output power, and control the atomizer to generate smoke with the queried first output power.

For example, assuming that the collected blood oxygen content is 97%, the first output power queried according to the corresponding relationship between the blood oxygen content and the output power is 12W, the electronic cigarette controls the atomizer to generate smoke with the output power of 12W.

As another possible implementation manner, the electronic cigarette may determine a health level according to the collected physical parameters, query a second output power corresponding to the determined health level according to a corresponding relationship between the health level and the output power, and control the atomizer to generate smoke with the queried second output power. The determining mode of the electronic cigarette for determining the health level corresponding to the physical parameter may include: the health level corresponding to the body parameter is queried according to the corresponding relationship between the body parameter and the health level, which is not described herein again in this embodiment.

For example, if the collected blood oxygen content is 97%, the current health level of the user may be found to be optimal according to the correspondence between the blood oxygen content and the health level, and the corresponding output power of the user is 10W when the health level is optimal according to the correspondence between the health level and the output power, at this time, the electronic cigarette will control the atomizer to generate smoke with the output power of 10W.

The above-mentioned corresponding relation between the body parameter and the output power and the corresponding relation between the health level and the output power may be a default corresponding relation in the electronic cigarette, may also be a user-defined corresponding relation in the electronic cigarette, and may also be a corresponding relation which is sent to the electronic cigarette after being defined by the APP in the mobile terminal for the user, which is not limited in this embodiment.

As another possible implementation manner, the step may include:

firstly, according to the body parameters collected in real time, the change rate of the body parameters in a unit time period is calculated.

The unit time period is a time period having a preset duration. For example, the unit time period is 2S, and for example, the unit time period is 5S, which is not limited thereto. In practical implementation, the unit time period may be a preset time period in the electronic cigarette, or a time period customized by the user, which is not limited to this. Optionally, the unit time period may be longer than a uniform breath when the body parameter includes blood oxygen content, for example, and not limited thereto, because some body parameters of the user may change with the respiration of the user, for example, the blood oxygen content in the body of the user is different when the user exhales and inhales.

Optionally, the rate of change = currently acquired physical parameter — physical parameter acquired a preset length of time ago.

Second, the output power of the atomizer to produce the aerosol is controlled according to the rate of change.

Optionally, this step may include:

(1) And detecting whether the change rate reaches a first preset threshold value.

The first preset threshold may be a default numerical value in the electronic cigarette, or may be a user-defined numerical value, which is not limited herein.

(2) If the change rate reaches a first preset threshold value, reducing the output power of the atomizer for generating smoke when the body parameter is smaller than a first boundary value or larger than a second boundary value; increasing the output power of the nebulizer to generate smoke when the body parameter is between the first boundary value and the second boundary value.

If the change rate reaches the first preset threshold value, it indicates that the body reaction of the user is obvious when the user sucks the electronic cigarette, and at this time, when the collected body parameter is smaller than the first boundary value or larger than the second boundary value, the electronic cigarette can reduce the output power of the atomizer, and the comfort level of the user for sucking the electronic cigarette is improved. For example, when the blood oxygen content is reduced by 2% in a unit time, the output power of the atomizer for generating smoke is reduced. Whereas the electronic cigarette may increase the output power of the nebulizer for generating the smoke in order to provide a better smoking experience for the user when the body parameter is between said first boundary value and said second boundary value. Optionally, since the electronic cigarette may collect the body parameter in real time, the electronic cigarette may judge, in real time, a relationship between the collected body parameter and the first boundary value and the second boundary value, and then control, in real time, the output power of the atomizer for generating the smoke according to a judgment result, which is not limited in this embodiment.

The above-mentioned reducing the output power of the atomizer generating smoke means reducing the output power by a first preset value, and the increasing the output power of the atomizer generating smoke means increasing the output power by a second preset value. The first preset value and the second preset value are default values in the electronic cigarette and also can be user-defined values, and the first preset value and the second preset value can be the same or different and are not limited. Optionally, when the output power of the atomizer for generating the smoke is reduced, if the body parameter is smaller than the first boundary value, the electronic cigarette may further obtain a first preset value corresponding to a difference between the body parameter and the first boundary value according to the difference, and if the body parameter is larger than the second boundary value, the electronic cigarette obtains a first preset value corresponding to the difference according to a difference between the body parameter and the second boundary value. The electronic cigarette can inquire the preset numerical value corresponding to the calculated difference value according to the corresponding relation between each difference value and each preset numerical value; the larger the difference in the corresponding relationship is, the larger the corresponding preset value may be, and in actual implementation, a plurality of differences may correspond to the same preset value, which is not limited in this embodiment. Similarly, when the output power of the smoke generated by the atomizer is increased, the electronic cigarette may calculate a difference between the body parameter and the average value, and obtain a second preset value corresponding to the difference, where the average value is an average value of the first boundary value and the second boundary value, and the electronic cigarette may query the determined second preset value corresponding to the difference according to a corresponding relationship between the difference and the preset value. When the output power of the atomizer is controlled, the difference value is obtained according to the current body parameters, and then the numerical value required to be reduced or increased is obtained according to the difference value, so that after the output power of the atomizer is adjusted, when the atomizer generates smoke with the adjusted output power, the amount of the generated smoke is more in line with the current body condition of a user, and the effect of providing the output power suitable for the current body state of the user for the user is achieved.

Optionally, the electronic cigarette may be provided with a maximum output power of the atomizer, and before the electronic cigarette increases the output power, the electronic cigarette may detect whether a sum of the current output power and a second preset value reaches the maximum output power, if not, increase the output power, and if so, increase the output power of the atomizer to the maximum output power.

In summary, in the electronic cigarette control method provided by this embodiment, the physical parameters of the user are collected during the process of generating smoke by the atomizer, and then the output power of the atomizer is controlled according to the physical parameters. Wherein, the output power is in positive correlation with the amount of the smoke generated by the atomizer; the problem of the fixed not intelligent enough of smog that produces of atomizer among the correlation technique is solved, reached and to have controlled the output of atomizer in real time according to user's physical parameter for electron cigarette is more intelligent effect. Meanwhile, as the output power of the atomizer is controlled according to the body parameters, the method also achieves the effect of providing the output power suitable for the current body state of the user for the user so as to improve the use experience of the user in using the electronic cigarette.

The first point to be supplemented is that, in the above embodiment, when the physical parameter acquired by the electronic cigarette in real time is smaller than the first threshold or larger than the second threshold, the electronic cigarette may control the nebulizer to stop operating. The first threshold is not greater than a first boundary value, the second threshold is not less than a second boundary value, the first boundary value and the second boundary value are boundary values of a health value range corresponding to the body parameter, and the first boundary value is less than the second boundary value. For example, taking the body parameter as the blood pressure value, the normal blood pressure range of the systolic pressure of the human body is: 90-139, the first boundary value is 90, the second boundary value is 139, the first threshold value may be a value not greater than 90, for example, the first threshold value may be 75, and the second threshold value may be a value not less than 139, for example, the second threshold value may be 150. In actual implementation, the specific values of the first threshold and the second threshold may be default values in the electronic cigarette, or may also be user-defined values, which is not limited in this embodiment.

In the above description, the atomizer is controlled to stop operating only when the physical parameter is smaller than the first threshold or larger than the second threshold, but in practice, the electronic cigarette may first send an alarm prompt message, for example, a prompt of "tic", and the user may control the atomizer to stop operating after triggering the stop.

The second point to be supplemented is that, in the above embodiment, the physical parameter acquired by the electronic cigarette continuously decreases after being less than the first boundary value or continuously increases after being greater than the second boundary value within the preset time period, which indicates that the content of nicotine in the tobacco tar currently used by the electronic cigarette may be too high and may not be suitable for the user, and at this time, the electronic cigarette may control the nebulizer to stop working. The preset time period may be a preset time period in the electronic cigarette, or a time period defined by a user, which is not limited in this embodiment. Optionally, when the body parameter collected by the electronic cigarette is continuously decreased after being smaller than the first boundary value or continuously increased after being larger than the second boundary value within a preset time period, the electronic cigarette may further generate a prompt message carrying a name of the tobacco tar currently used by the electronic cigarette and the body parameter collected within a historical time period, and send the generated prompt message to the mobile terminal. The historical time period is an average time period for which the user smokes the electronic cigarette once, for example, the historical time period is 3 minutes. And after receiving the prompt message, the mobile terminal recommends tobacco tar for the user according to big data analysis. Optionally, an APP corresponding to the electronic cigarette may be installed in the mobile terminal, personal information of a user using the electronic cigarette is set in the APP, the personal information includes at least one of gender, age, smoking frequency, cigarette age, and weight, and the mobile terminal may recommend tobacco tar to the user according to the prompt information and the personal information. For example, after the mobile terminal receives the prompt message, the nicotine content in the tobacco tar can be obtained from the server according to the name of the tobacco tar in the prompt message, and then the tobacco tar with the nicotine content suitable for the current physical condition of the user is selected for the user according to the physical parameters in the prompt message. Assuming that the obtained nicotine content is 18mg/ml, if the pumping frequency of the user is 5 persons per day, the age of the user is 60, and the blood oxygen content of the user is relatively low, at this time, the mobile terminal may recommend a tobacco tar with a lower nicotine content for the user, for example, a certain brand of tobacco tar with a recommended nicotine content of 12mg/ml, and this embodiment does not limit the specific implementation of determining the recommended tobacco tar by the mobile terminal.

In addition, for example, only the generated prompt information carries the name of the used tobacco tar and the body parameter collected in the historical time period at the same time, optionally, the prompt information may also only carry the body parameter collected in the historical time period, and at this time, after the mobile terminal receives the prompt information, the mobile terminal may recommend the tobacco tar for the user according to the body parameter in the prompt information and the name of the tobacco tar set in the APP by the user. Optionally, the mobile terminal may recommend the tobacco tar to the user according to the physical parameters, the name of the tobacco tar, and the personal information, which is not described herein again.

Referring to fig. 6, a flowchart of a method of controlling an electronic cigarette according to an embodiment of the present invention is shown, and the electronic cigarette control method is used in the electronic cigarette shown in fig. 1 to illustrate the embodiment. As shown in fig. 6, the electronic cigarette control method may include:

and 601, continuously acquiring the body parameters of the user after the atomizer stops generating the smoke.

This step is similar to step 401 in the above embodiment, and is not described herein again.

For example, the physical parameters of the user are acquired in real time during a target period of time later.

Step 602, when the collected body parameters meet preset conditions, determining initial output power of the atomizer for next smoke generation according to the collected body parameters; or sending the collected body parameters to a mobile terminal, wherein the mobile terminal is used for recommending tobacco tar for the user according to the received body parameters; the preset conditions comprise that the change rate of the body parameter in a preset time period reaches a second preset threshold value, or the body parameter is smaller than a first boundary value, or the body parameter is larger than a second boundary value; the first boundary value and the second boundary value are boundary values of a health value range corresponding to the body parameter, and the first boundary value is smaller than the second boundary value.

When the collected body parameters meet the preset conditions, in order to provide output power suitable for the body parameters of the user for the user when the user sucks the electronic cigarette next time and improve the comfort level of the user sucking the electronic cigarette, the electronic cigarette can determine the initial output power of the atomizer when the atomizer generates smoke next time according to the collected body parameters, optionally, the electronic cigarette can determine the initial output power in the determining mode in the step 402, and thus, the atomizer can generate smoke according to the determined initial output power when the user sucks the electronic cigarette again.

Alternatively, the first and second electrodes may be,

when the collected body parameters meet preset conditions, it is indicated that the currently used tobacco tar may not be suitable for the user, at this time, in order to recommend suitable tobacco tar to the user, the electronic cigarette may send the collected body parameters to the mobile terminal, and the mobile terminal recommends the tobacco tar for the user according to the received body parameters. The steps of recommending tobacco tar for the user by the mobile terminal are similar to the recommending method, and are not described again in this embodiment.

In summary, in the electronic cigarette control method provided in this embodiment, after the atomizer generates smoke, body parameters of the user are collected, and then when the body parameters meet preset conditions, initial output power for the next smoke generation is determined, or the body parameters are sent to the mobile terminal, so that the mobile terminal recommends tobacco tar for the user; the problem of the fixed not intelligent enough of smog that produces of atomizer among the correlation technique is solved, reached and to have controlled the output of atomizer in real time according to user's physical parameter for electron cigarette is more intelligent effect.

The above embodiments all use the electronic cigarette to collect the body parameters before, during or after the atomizer starts to work, and then control the output power of the atomizer as an example, during actual implementation, the body parameters can be collected simultaneously under any two or three conditions, and then the output power of the atomizer is controlled according to the collected body parameters, and this embodiment is not limited thereto.

In addition, the electronic cigarette can be provided with a plurality of working modes, for example, a default working mode and an intelligent working mode are set, and when the electronic cigarette is in the default working mode, the atomizer works according to default output power after the electronic cigarette is ignited; and in the intelligent operating mode, the electronic cigarette operates as described in any of the embodiments above. For example, taking the body parameter including blood oxygen content as an example, please refer to fig. 7, which shows a flowchart of a possible electronic cigarette control method.

Referring to fig. 8, which shows a schematic diagram of an electronic cigarette according to an embodiment of the present invention, as shown in fig. 8, the electronic cigarette may include: an acquisition module 810 and a control module 820;

an acquisition module 810 for acquiring a body parameter of a user; the physical parameters are parameters for representing the physical health condition of the user;

a control module 820, configured to control the output power of the atomizer for generating smoke according to the physical parameters collected by the collecting module 810; wherein the output power is in positive correlation with the amount of smoke generated by the atomizer.

In summary, the electronic cigarette provided by this embodiment collects the physical parameters of the user through the process of generating smoke by the atomizer, and then controls the output power of the atomizer for generating smoke according to the physical parameters. Wherein, the output power is in positive correlation with the amount of the smoke generated by the atomizer; the problem of the fixed not intelligent enough of smog that produces of atomizer among the correlation technique is solved, reached and to have controlled the output of atomizer in real time according to user's physical parameter for electron cigarette is more intelligent effect.

Based on the above embodiment, optionally, the control module 820 is further configured to:

inquiring first output power corresponding to the body parameter according to the corresponding relation between the body parameter and the output power; controlling the atomizer to generate smoke at the queried first output power.

Optionally, the control module 820 is further configured to: determining a health grade from the physical parameter; inquiring a second output power corresponding to the determined health grade according to the corresponding relation between the health grade and the output power; controlling the atomizer to generate smoke at the queried second output power.

Optionally, the control module 820 includes:

the calculation unit is used for calculating the change rate of the body parameters in a unit time period according to the body parameters acquired in real time;

and the control unit is used for controlling the output power of the atomizer for generating smoke according to the change rate.

Optionally, the control unit is further configured to:

detecting whether the change rate reaches a first preset threshold value;

if the change rate reaches the first preset threshold, reducing the output power of the atomizer for generating smoke when the body parameter is smaller than a first boundary value or larger than a second boundary value; and when the body parameter is between the first boundary value and the second boundary value, increasing the output power of the atomizer for generating smoke, wherein the first boundary value and the second boundary value are boundary values of a healthy value range corresponding to the body parameter, and the first boundary value is smaller than the second boundary value.

Optionally, the control module 820 is further configured to:

and when the physical parameter is smaller than a first threshold value or larger than a second threshold value, controlling the atomizer to stop working, wherein the first threshold value is not larger than a first boundary value, the second threshold value is not smaller than a second boundary value, the first boundary value and the second boundary value are boundary values of a health value range corresponding to the physical parameter, and the first boundary value is smaller than the second boundary value.

Optionally, the control module 820 is further configured to, in the process of controlling the output power, control the atomizer to stop working if the body parameter continuously decreases after being smaller than a first boundary value or continuously increases after being larger than a second boundary value within a preset time period, where the first boundary value and the second boundary value are boundary values of a healthy value range corresponding to the body parameter, and the first boundary value is smaller than the second boundary value.

Optionally, the electronic cigarette further comprises:

the generating module is used for generating prompt information, and the prompt information carries the name of the tobacco tar currently used by the electronic cigarette and the body parameters acquired in a historical time period;

and the sending module is used for sending the prompt information to the bound mobile terminal, and the mobile terminal is used for recommending tobacco tar for the user according to the prompt information.

Optionally, the acquiring module 810 is further configured to acquire the physical parameter before the nebulizer generates smoke;

the electronic cigarette further comprises:

a determination module for determining an initial output power of the electronic cigarette according to the physical parameter;

the control module is further used for controlling the atomizer to generate smoke at the initial output power when the atomizer starts to generate smoke.

The acquisition module is further used for continuously acquiring the body parameters of the user after the atomizer stops generating smoke;

the control module is used for determining the initial output power of the atomizer when the body parameters collected by the collection module meet preset conditions according to the collected body parameters; or sending the collected physical parameters to a mobile terminal, wherein the mobile terminal is used for recommending tobacco tar for the user according to the received physical parameters; the preset condition comprises that the change rate of the physical parameter in a preset time period reaches a second preset threshold value, or the physical parameter is smaller than a first boundary value, or the physical parameter is larger than a second boundary value; the first boundary value and the second boundary value are boundary values of a health value range corresponding to the body parameter, and the first boundary value is smaller than the second boundary value.

It should be noted that: the electronic cigarette control provided by the above embodiment is only exemplified by the division of the above functional modules, and in practical applications, the above functions may be distributed by different functional modules according to needs, that is, the internal structure of the server is divided into different functional modules to complete all or part of the above described functions. In addition, the electronic cigarette and the electronic cigarette control method provided by the above embodiment belong to the same concept, and the specific implementation process is described in detail in the method embodiment, which is not described again here.

In addition, in the embodiment of the present invention, the electronic cigarette may control the output power of the electronic cigarette by controlling the output voltage, the output current, the resistance of the heating element, and the like of the electronic cigarette, which is not limited in this embodiment.

It will be understood by those skilled in the art that all or part of the steps for implementing the above embodiments may be implemented by hardware, or may be implemented by a program instructing relevant hardware, where the program may be stored in a computer-readable storage medium, and the storage medium may be a read-only memory, a magnetic disk or an optical disk.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims (15)

1. An electronic cigarette control method, characterized in that the electronic cigarette comprises a parameter acquisition unit for acquiring physical parameters of a user, the method comprising:

in the process of generating smoke by an atomizer of an electronic cigarette, when detecting that a user is performing smoking behavior, acquiring physical parameters of the user in real time; the physical parameters are parameters for characterizing the physical health condition of the user, and the physical parameters comprise: at least one of blood oxygen content, blood oxygen saturation, blood pressure value, heart rate, lung capacity, step number, pH of saliva, oral humidity, body temperature, and oral temperature; wherein the detecting that the user is performing a pumping action comprises: determining that the user is performing a puff when an airflow sensor in the electronic cigarette detects airflow;

controlling the output power of the atomizer in real time according to the body parameters acquired in real time, comprising:

calculating a rate of change of the physical parameter over a unit time period;

when the rate of change reaches a first preset threshold and the physical parameter is less than a first boundary value or greater than a second boundary value, reducing the output power of the nebulizer currently producing smoke by a first preset value corresponding to the difference between the physical parameter and the first boundary value when the physical parameter is less than the first boundary value or the difference between the physical parameter and the second boundary value when the physical parameter is greater than the second boundary value;

increasing the output power of the nebulizer currently producing smoke by a second preset value when the rate of change reaches the first preset threshold and the physical parameter is between the first boundary value and the second boundary value, the second preset value corresponding to a difference between the physical parameter and a mean value, the mean value being an average of the first boundary value and the second boundary value;

when the change rate reaches a first preset threshold value, the user has an obvious body reaction when smoking the electronic cigarette, the first boundary value and the second boundary value are boundary values of a health value range corresponding to the body parameter, the first boundary value is smaller than the second boundary value, and the output power and the amount of the smoke generated by the atomizer are in a positive correlation relationship.

2. The method of claim 1, wherein controlling the output power of the nebulizer currently producing smoke to increase by a second preset value or decrease by a first preset value in accordance with the physical parameter comprises:

inquiring first output power corresponding to the body parameter according to the corresponding relation between the body parameter and the output power;

and controlling the atomizer to generate smoke at the inquired first output power, wherein the first output power is obtained by increasing the output power by a second preset value or reducing the output power by a first preset value.

3. The method of claim 1, wherein controlling the output power of the nebulizer currently producing smoke to increase by a second preset value or decrease by a first preset value in accordance with the physical parameter comprises:

determining a health grade from the physical parameter;

inquiring a second output power corresponding to the determined health grade according to the corresponding relation between the health grade and the output power;

and controlling the atomizer to generate smoke according to the inquired second output power, wherein the second output power is obtained by increasing the output power by a second preset value or decreasing the output power by a first preset value.

4. The method of any of claims 1 to 3, further comprising:

and when the physical parameter is smaller than a first threshold value or larger than a second threshold value, controlling the atomizer to stop working, wherein the first threshold value is not larger than a first boundary value, and the second threshold value is not smaller than a second boundary value.

5. A method according to any of claims 1 to 3, characterized in that the method further comprises:

in the process of controlling the output power, if the physical parameter continuously decreases after being smaller than a first boundary value or continuously increases after being larger than a second boundary value within a preset time period, the atomizer is controlled to stop working.

6. The method of claim 5, further comprising:

generating prompt information, wherein the prompt information carries the name of the tobacco tar currently used by the electronic cigarette and the body parameters acquired in the historical time period;

and sending the prompt information to a bound mobile terminal, wherein the mobile terminal is used for recommending tobacco tar for the user according to the prompt information.

7. The method of claim 1, further comprising:

continuing to acquire the physical parameters of the user after the nebulizer stops producing smoke;

if the collected body parameters meet preset conditions, determining initial output power of the atomizer when smoke is generated next time according to the collected body parameters; or sending the collected physical parameters to a mobile terminal, wherein the mobile terminal is used for recommending tobacco tar for the user according to the received physical parameters; the preset condition includes that the change rate of the physical parameter in a preset time period reaches a second preset threshold, or the physical parameter is smaller than a first boundary value, or the physical parameter is larger than a second boundary value.

8. An electronic cigarette, characterized in that the electronic cigarette comprises a parameter acquisition unit for acquiring a physical parameter of a user, and:

the acquisition module is used for acquiring the body parameters of the user in real time when detecting that the user performs smoking action in the process of generating smoke by the atomizer of the electronic cigarette; the physical parameters are parameters for characterizing the physical health condition of the user, and the physical parameters comprise: at least one of blood oxygen content, blood oxygen saturation, blood pressure value, heart rate, lung capacity, step number, pH of saliva, oral humidity, body temperature, and oral temperature; wherein the detecting that the user is performing a pumping action comprises: determining that the user is performing a puff when an airflow sensor in the electronic cigarette detects airflow;

the control module is used for controlling the output power of the atomizer in real time according to the body parameters acquired in real time; wherein the output power is in positive correlation with the amount of smoke generated by the atomizer;

the control module includes:

the calculation unit is used for calculating the change rate of the body parameters in a unit time period according to the body parameters acquired in real time;

the control unit is used for controlling the output power of the current generated smoke of the atomizer to increase a second preset value or decrease a first preset value according to the change rate;

the control unit is further configured to:

when the rate of change reaches a first preset threshold and the physical parameter is less than a first boundary value or greater than a second boundary value, reducing the output power of the nebulizer currently producing smoke by a first preset value corresponding to the difference between the physical parameter and the first boundary value when the physical parameter is less than the first boundary value or the difference between the physical parameter and the second boundary value when the physical parameter is greater than the second boundary value; and increasing the output power of the nebulizer currently producing smoke by a second preset value when the rate of change reaches the first preset threshold and the physical parameter is between the first boundary value and the second boundary value, the second preset value corresponding to a difference between the physical parameter and a mean value, the mean value being an average of the first boundary value and the second boundary value; when the change rate reaches a first preset threshold value, the user has obvious physical reaction when smoking the electronic cigarette, the first boundary value and the second boundary value are boundary values of a health value range corresponding to the physical parameters, and the first boundary value is smaller than the second boundary value.

9. The electronic cigarette of claim 8, wherein the control module is further configured to:

inquiring first output power corresponding to the body parameter according to the corresponding relation between the body parameter and the output power; and controlling the atomizer to generate smoke according to the inquired first output power, wherein the first output power is obtained by increasing the output power by a second preset value or decreasing the output power by a first preset value.

10. The electronic cigarette of claim 8, wherein the control module is further configured to:

determining a health grade from the physical parameter; inquiring a second output power corresponding to the determined health grade according to the corresponding relation between the health grade and the output power; and controlling the atomizer to generate smoke according to the inquired second output power, wherein the second output power is obtained by increasing the output power by a second preset value or decreasing the output power by a first preset value.

11. The electronic cigarette of any of claims 8-10, wherein the control module is further configured to:

and when the physical parameter is smaller than a first threshold value or larger than a second threshold value, controlling the atomizer to stop working, wherein the first threshold value is not larger than a first boundary value, and the second threshold value is not smaller than a second boundary value.

12. The electronic cigarette according to any one of claims 8 to 10,

the control module is further configured to, in the process of controlling the output power, control the atomizer to stop working if the physical parameter continuously decreases after being smaller than a first boundary value or continuously increases after being larger than a second boundary value within a preset time period.

13. The electronic cigarette of claim 12, further comprising:

the generating module is used for generating prompt information, and the prompt information carries the name of the tobacco tar currently used by the electronic cigarette and the body parameters acquired in a historical time period;

and the sending module is used for sending the prompt information to the bound mobile terminal, and the mobile terminal is used for recommending tobacco tar for the user according to the prompt information.

14. The electronic cigarette of claim 8,

the acquisition module is further used for continuously acquiring the body parameters of the user after the atomizer stops generating smoke;

the control module is used for determining the initial output power of the atomizer when the body parameters collected by the collection module meet preset conditions according to the collected body parameters; or sending the collected physical parameters to a mobile terminal, wherein the mobile terminal is used for recommending tobacco tar for the user according to the received physical parameters; the preset condition includes that the change rate of the physical parameter in a preset time period reaches a second preset threshold, or the physical parameter is smaller than a first boundary value, or the physical parameter is larger than a second boundary value.

15. A computer-readable storage medium storing at least one instruction which, when executed by a processor, implements the electronic cigarette control method of any of claims 1-7.

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