CN110522079B

CN110522079B - Method for determining output power of electronic cigarette, electronic cigarette and computer storage medium

Info

Publication number: CN110522079B
Application number: CN201810508730.0A
Authority: CN
Inventors: 不公告发明人
Original assignee: Changzhou Paiteng Electronic Technology Co Ltd
Current assignee: Changzhou Paiteng Electronic Technology Co Ltd
Priority date: 2018-05-24
Filing date: 2018-05-24
Publication date: 2021-07-02
Anticipated expiration: 2038-05-24
Also published as: CN110522079A; WO2019223531A1

Abstract

The invention provides a method for determining output power of an electronic cigarette, the electronic cigarette and a computer storage medium, wherein the method comprises the following steps: acquiring the resistance value of the heating element; determining a first output power range matched with the acquired resistance value; determining a second output power range according to the first output power range and the use parameters of the electronic cigarette, wherein the use parameters comprise at least one of the remaining capacity of the battery, the use duration of the battery and the use duration of the atomizing head; and determining the output power of the electronic cigarette according to the second output power range. The invention can match the output power of the electronic cigarette with the heating element and the using state of the electronic cigarette, so as to ensure the suction effect and the suction safety at the same time.

Description

Method for determining output power of electronic cigarette, electronic cigarette and computer storage medium

Technical Field

The present invention relates to the field of electronic cigarette technologies, and in particular, to a method for determining an output power of an electronic cigarette, and a computer storage medium.

Background

In current electron cigarette field, the atomising head resistance (also generate heat a resistance) size that different electron cigarette held slightly differs, and the atomising head of different resistances also can be matchd to same kind of electron cigarette, however, current electron cigarette is after the atomising head of the different resistances of replacement at every turn, still only continues output before, probably leads to output to mismatch and the phenomenon that the atomising head burns out appears, influences the safe handling of electron cigarette.

Disclosure of Invention

In view of the above, the present invention provides a method for determining an output power of an electronic cigarette, the electronic cigarette and a computer storage medium, which can match the output power of the electronic cigarette with a heating element currently installed in the electronic cigarette and a use state of the electronic cigarette, so as to ensure a smoking effect and smoking safety at the same time.

The invention provides a method for determining output power of an electronic cigarette, which comprises the following steps:

acquiring the resistance value of the heating element;

determining a first output power range matched with the acquired resistance value;

determining a second output power range according to the first output power range and the use parameters of the electronic cigarette, wherein the use parameters comprise at least one of the remaining capacity of a battery, the use duration of the battery and the use duration of an atomizing head;

and determining the output power of the electronic cigarette according to the second output power range.

Wherein the determining a second output power range from the first output power range and the usage parameters of the electronic cigarette comprises:

acquiring use parameters of the electronic cigarette;

determining output power ranges corresponding to the acquired use parameters according to the corresponding relation between the use parameters and the output power ranges;

and determining the second output power range according to the first output power range and the output power range corresponding to each use parameter.

Wherein the determining the second output power range according to the first output power range and the output power range corresponding to each use parameter includes:

if the output power ranges corresponding to the use parameters have intersection with the first output power range, selecting a power range with the minimum upper limit value from the obtained intersection as the second output power range;

if the output power range part corresponding to each use parameter has an intersection with the first output power range, selecting a power range with the minimum upper limit value from the output power range without the intersection with the first output power range and the obtained intersection as the second output power range;

and if the output power range corresponding to each use parameter does not have intersection with the first output power range, selecting a power range with the minimum upper limit value or the minimum lower limit value from the output power range corresponding to each use parameter and the first output power range as the second output power range.

if the output power ranges corresponding to the use parameters have intersection with the first output power range, selecting the minimum upper limit value of the upper limit values of all the intersection as the upper limit value of the second output power range, and selecting the maximum lower limit value of the lower limit values of all the intersection as the lower limit value of the second output power range;

and if the intersection between the output power range corresponding to each use parameter and the first output power range is not empty, taking the intersection between the output power range corresponding to each use parameter and the first output power range as the second output power range.

If the intersection between the output power range corresponding to each usage parameter and the first output power range is empty, after the intersection between the output power ranges with the intersection is calculated, a power range with the minimum upper limit value is selected from the obtained output power ranges without the intersection as the second output power range.

Wherein the determining the output power of the electronic cigarette according to the second output power range comprises:

displaying the second output power range, or displaying at least one recommended power determined according to the second output power range;

determining an output power of the electronic cigarette according to the operation information for the second output power range or the at least one recommended power.

Wherein the determining the output power of the electronic cigarette according to the operation information for the second output power range or the at least one recommended power comprises:

when the second output power range is displayed, receiving a power value input by a user, if the power value is within the second output power range, taking the power value as the output power of the electronic cigarette, and if the power value is not within the second output power range, outputting a message prompting that the power value input fails;

and when at least one recommended power determined according to the second output power range is displayed and operation information for confirming the recommended power is received, the confirmed recommended power is used as the output power of the electronic cigarette.

Wherein, the resistance of obtaining the heating member includes:

reading the resistance value or the model of the heating element stored in a storage chip of the atomizer or the atomizing head where the heating element is located, or receiving the resistance value or the model of the heating element input by a user;

and when the model of the heating piece is obtained, obtaining the resistance value of the heating piece according to the model of the heating piece.

Wherein, according to the model of the piece that generates heat obtains the resistance of the piece that generates heat, include:

sending a heating piece resistance value acquisition request to a server according to the type of the heating piece and receiving the heating piece resistance value returned by the server; or the like, or, alternatively,

and inquiring the resistance value of the heating member corresponding to the type of the heating member according to the locally stored corresponding relationship between the type and the resistance value of different heating members.

Wherein, the resistance of obtaining the heating member includes:

outputting a detection voltage to the heating member;

the resistance value of the heat generating member is calculated based on the detected value of the current.

Wherein the method further comprises:

when a mounting signal of the battery or the atomizing head is detected, outputting prompt information for confirming whether the battery or the atomizing head is unused;

if the battery or the atomizing head is not used, numbering the installed battery or the installed atomizing head and starting to accumulate the corresponding service time;

if the number is the used battery or the atomizing head, when the number corresponding to the installed battery or the atomizing head is obtained, the using time length is continuously accumulated on the original using time length corresponding to the obtained number;

if the number is the used battery or the atomizing head, the number is carried out on the mounted battery or the atomizing head and prompt information for inputting the use time is generated when the number corresponding to the mounted battery or the atomizing head is not acquired.

Wherein the method further comprises:

when a modification instruction of the use duration is received, the battery number or the atomizing head number selected by a user is confirmed;

acquiring the modified service life;

and storing the modified service life and the battery number or the atomizing head number selected by the user and continuously accumulating the service life on the modified service life.

The invention also provides an electronic cigarette, which is characterized by comprising a memory and a processor, wherein the memory stores at least one program instruction, and the processor is used for realizing the method for determining the output power of the electronic cigarette by loading and executing the at least one program instruction.

The present invention also provides a computer storage medium having computer program instructions stored thereon; the computer program instructions, when executed by a processor, implement a method of determining the output power of an electronic cigarette as described above.

According to the method for determining the output power of the electronic cigarette, the electronic cigarette and the computer storage medium, the first output power range matched with the resistance value of the installed heating element is determined, the second output power range is determined according to the first output power range and the use parameters of the electronic cigarette, the use parameters comprise at least one of the residual capacity of a battery, the use duration of the battery and the use duration of an atomizing head, and finally the output power of the electronic cigarette is determined according to the second output power range.

Drawings

Figure 1 is a schematic flow diagram of a method of determining the output power of an electronic cigarette in an exemplary embodiment of the invention.

Fig. 2 is a schematic structural diagram of an electronic cigarette in an exemplary embodiment of the invention.

Detailed Description

To further illustrate the technical means and effects of the present invention adopted to achieve the predetermined objects, the following detailed description of the embodiments, structures, features and effects of the present invention will be made with reference to the accompanying drawings and examples.

Figure 1 is a schematic flow diagram of a method of determining the output power of an electronic cigarette in an exemplary embodiment of the invention. As shown in fig. 1, the method for determining the output power of the electronic cigarette according to the embodiment includes the following steps:

and step 110, acquiring the resistance value of the heating element.

Wherein, the atomizer of electron cigarette includes atomising head and the stock solution subassembly that has the stock solution chamber, be equipped with in the atomising head and generate heat a and imbibition piece, imbibition piece absorbs the tobacco juice in order to heat the cigarette for the piece that generates heat in supplying to the stock solution chamber through inlet channel, can be equipped with a detection circuitry that generates heat in the electron cigarette, a detection circuitry that generates heat is connected with the atomizing circuit of electron cigarette, whether insert the piece that generates heat in being used for detecting the atomizing circuit, the atomizing circuit of electron cigarette sets up in the battery device of electron cigarette and communicates with the battery device, the piece that generates heat is installed in the slot on the atomizer earlier usually, when the atomizer is connected with the battery device of electron cigarette, the piece that generates heat inserts the atomizing circuit, will produce the electric current pulse signal because of the sudden change of resistance in the circuit when inserting the piece that generates heat in the atomizing circuit, when detecting this electric current pulse signal, can confirm that inserts the piece that, The atomizing head or the atomizer to further acquire the resistance value of the heating member. In actual implementation, the current pulse signal only needs to be detected, and the specific current value does not need to be determined.

In one embodiment, the process of obtaining the resistance value of the heat generating member may specifically include:

reading the resistance value or the model of the heating element stored in a storage chip in the atomizer or the atomizing head where the heating element is located, or receiving the resistance value or the model of the heating element input by a user;

and when the model of the heating member is obtained, the resistance value of the heating member is obtained according to the model of the heating member.

Wherein, the process of obtaining the resistance value of the heating member according to the type of the heating member may specifically include:

sending a heating piece resistance value acquisition request to the server according to the type of the heating piece and receiving the heating piece resistance value returned by the server; or the like, or, alternatively,

and inquiring the resistance value of the heating member corresponding to the acquired type of the heating member according to the locally stored corresponding relationship between the type and the resistance value of different heating members.

In practical implementation, as an implementation manner, when the heating element, the atomizing head or the atomizer is inserted into the electronic cigarette, the resistance or the model of the heating element stored in the storage chip of the atomizing head or the atomizer can be read out through the data transmission pin on the electronic cigarette, wherein, after the user replaces the heating element in the atomizing head or the atomizer, the atomizing head or the atomizer can be connected to an external control device, for example, on a mobile phone or a computer, the resistance of the heating element stored in the storage chip is modified through the operation of the mobile phone or the computer, so that when the atomizing head or the atomizer which has replaced the heating element is installed on a battery device, the resistance or the model of the heating element stored in the storage chip of the atomizer can also be read out through the data transmission pin on the electronic cigarette. As another embodiment, when the heating element detection circuit detects that the heating element is connected to the heating element circuit, a resistance input interface or a model input interface is displayed on the touch display screen, and a user can input a resistance or a model on the input interface, so that the electronic cigarette obtains the resistance or the model of the heating element after the user determines that the input is completed.

When the model of the heating element is acquired, the corresponding resistance value of the heating element can be searched locally or by a server according to the model of the heating element. If the resistance value of the corresponding heating piece is searched for by the server, the Wireless communication module on the electronic cigarette sends a resistance value acquisition request to the server and receives the resistance value of the heating piece returned by the server, the Wireless communication unit is, for example, a Wireless Fidelity (WIFI) module, a 2G/3G/4G network communication module and the like, which can realize Wireless communication, the embodiment is not limited to this, the resistance values of the heating pieces of various types can be stored in the server, when a user inputs the type of the heating piece through the touch display screen, the server is connected through a Wireless communication mode to inquire the resistance value of the corresponding heating piece, and the mode is particularly suitable for replacing the heating piece or the atomizer of different manufacturers. If the corresponding parameters of the heating parts are searched locally, the resistance values of the heating parts corresponding to the received models can be inquired according to the corresponding relationship between the locally stored models and the resistance values of the different heating parts, and the method is particularly suitable for the condition of replacing the heating parts or the atomizers of the same manufacturer.

In another embodiment, the process of obtaining the resistance value of the heat generating member may specifically include:

outputting a detection voltage to the heating member;

Wherein, when detecting to insert in the atomizing circuit and generate heat when piece, detect voltage, for example for 1V, can calculate the resistance that generates heat through the electric current that detects the correspondence to the both ends output that generates heat piece through the resistance detection circuit of integrated inside the electron cigarette. By the mode, even if the model or the resistance value of the heating wire cannot be found, and the user cannot know the resistance value or the model of the heating piece, the resistance value of the heating piece can be automatically detected by the electronic cigarette.

And step 120, determining a first output power range matched with the acquired resistance value.

The first output power range is a power range with a better smoke amount under the resistance value determined according to the resistance value of the heating element, and can be determined according to an empirical value and the rated maximum power of the electronic cigarette. In practical implementation, as an implementation manner, a corresponding relationship between the resistance value of the heating element and the first output power range is stored in a memory chip of the electronic cigarette, wherein when the output voltage of the electronic cigarette is not changed, the resistance value of the heating element and the output power generally have a negative correlation, that is, the larger the resistance value of the heating element is, the smaller the matched output power is, the upper limit value of the first output power range should be lower than the rated maximum power of the electronic cigarette, and after the resistance value of the heating element is obtained, the matched first output power range can be determined according to the corresponding relationship between the resistance value of the heating element and the first output power range. As another embodiment, the optimal output power of the smoke amount may be calculated according to a preset calculation formula and the obtained resistance value, and the first output power range may be obtained by performing the fluctuation of the set wattage up and down on the basis of the calculated output power, for example, the optimal output power of the smoke amount may be calculated to be 6W, and then, the fluctuation of the set wattage up and down on the basis of 6W, for example, the fluctuation of 2W up and down may be performed, and finally, the first output power range may be 4-8W.

And step 130, determining a second output power range according to the first output power range and the use parameters of the electronic cigarette, wherein the use parameters comprise at least one of the remaining capacity of the battery, the use duration of the battery and the use duration of the atomizing head.

In an embodiment, determining the second output power range according to the first output power range and the usage parameter of the electronic cigarette may specifically include:

acquiring use parameters of the electronic cigarette;

and determining a second output power range according to the first output power range and the output power range corresponding to each use parameter.

Besides the storage chip in the atomizer, another storage chip can be arranged in the cigarette body of the electronic cigarette, and the storage chip is used for storing relevant parameters of the electronic cigarette, including but not limited to storing usage parameters of the electronic cigarette, and the usage parameters of the electronic cigarette can reflect whether the current usage state of the electronic cigarette is good, such as whether the electricity is about to be exhausted, whether the battery life or the life of the atomizing head reaches a limit, and the like, wherein the remaining electricity of the battery can be directly detected, the usage duration of the battery is the duration accumulated from the first use of the battery, since the battery generally used by the electronic cigarette is a rechargeable battery, the battery can be repeatedly charged and used, so the usage duration of the battery is irrelevant to the charging times of the battery, of course, the usage parameters of the electronic cigarette can also include the charging times of the battery, and the usage duration of the atomizing head is the duration accumulated from the first use of the atomizing, since the heat generating member is an important component of the atomizing head, the length of time that the atomizing head is used is generally considered to be equal to the length of time that the heat generating member is used.

In this embodiment, the storage chip of the electronic cigarette stores a corresponding relationship between the usage parameter and the output power range, or stores a corresponding relationship between the usage parameter range and the output power range. The residual capacity of the battery is in positive correlation with the output power, namely the more the residual capacity is, the larger the upper limit value of the output power is, the negative correlation is formed between the service life of the battery and the service life of the atomizing head and the output power, namely the longer the service life is, the smaller the output power is, and therefore the safe use of the electronic cigarette is guaranteed. When the corresponding relation between the use parameters and the output power range is determined, the output power range corresponding to the residual electric quantity is a power range which enables the electronic cigarette to perform energy-saving output and can output smoke under the residual electric quantity, exceeding the power range may cause the electronic cigarette to consume too fast, seriously affects the use time of the electronic cigarette, or too low power to atomize smoke liquid, the output power range corresponding to the use time of the battery is a safe power range which cannot cause the battery damage under the use time, exceeding the power range may cause the battery damage to cause safety problems, the output power range corresponding to the use time of the atomizing head is a safe power range which cannot cause the atomizing head damage under the use time, and exceeding the power range may cause the atomizing head to burn out.

After the usage parameters of the electronic cigarette are acquired, the output power range corresponding to the current usage parameters can be determined according to the corresponding relationship between the usage parameters and the output power range, and then a second output power range is determined according to the first output power range and the output power range corresponding to the usage parameters. It should be understood that when the second output power ranges are obtained by intersection, they may be a value range or a specific value, the intersection relationship between the power ranges refers to the intersection condition between the power ranges and the power value magnitude relationship between the power ranges obtained by intersection between the power ranges, and the power value magnitude relationship between the power ranges refers to the magnitude relationship obtained by comparing the power value included in one power range with the power value included in another power range, and when actually implemented, the power value magnitude relationship between the power ranges may be obtained by comparing the magnitude of the upper limit value of the power ranges, for example, the upper limit value 5W of the power range 2-5W is smaller than the upper limit value 7W of the power range 0-7W, and the power range 2-5W is considered smaller than the power range 0-7W, and for example, the upper limit value 5W of the power range 2-5W is smaller than the upper limit value 7W of the power range 3-7W W, the power range 2-5W is considered to be smaller than the power range 3-7W, and for example, the upper limit value 4W of the power range 2-4W is smaller than the upper limit value 7W of the power range 5-7W, the power range 2-4W is considered to be smaller than the power range 5-7W. It should be noted that, comparing the upper limit value of the power range merely determines the relationship between the power values of the power ranges, and when finally determining the second output power range, in addition to comparing the upper limit value of the power range, the relationship between the lower limit value of the power range may also be considered at the same time.

In one embodiment, determining the second output power range according to the first output power range and the output power range corresponding to each use parameter includes:

if the output power ranges corresponding to the use parameters have intersection with the first output power range, selecting a power range with the minimum upper limit value from the obtained intersection as a second output power range;

if the output power range part corresponding to each use parameter has intersection with the first output power range, selecting a power range with the minimum upper limit value from the output power range without intersection with the first output power range and the obtained intersection as a second output power range;

and if the output power range corresponding to each use parameter does not have intersection with the first output power range, selecting a power range with the minimum upper limit value or the minimum lower limit value from the output power range corresponding to each use parameter and the first output power range as a second output power range.

After the output power range corresponding to the current use parameter is determined, a plurality of output power ranges including the first output power range and the output power range corresponding to each use parameter can be obtained, and the second output power range is determined by combining the intersection relation between the output power ranges and the power value size relation between the power ranges, so that the second output power range and the heating element and the use state which are currently installed in the electronic cigarette can reach a better matching state. During actual implementation, the intersection condition of the output power range corresponding to each use parameter and the first output power range includes that the intersection, part of the output power range have the intersection or the intersection does not exist, and the second output power range corresponding to different intersection conditions can be determined by combining the principle that the output power selects smaller values to ensure safe use of the electronic cigarette.

When the output power range corresponding to each use parameter has an intersection with the first output power range, the power range with the minimum upper limit value in the intersection is selected as the second output power range, and the second output power range can enable the electronic cigarette to have a good smoking effect and high safety. For example, the output power range corresponding to the remaining capacity of the battery is 1-3W, the output power range corresponding to the service life of the battery is 2-6W, the output power range corresponding to the service life of the atomizing head is 3-5W, and the output power range corresponding to the first output power range is 2-4W, the intersections of the output power range corresponding to each service parameter and the first output power range are 2-3W, 2-4W, and 3-4W, respectively, and at this time, the power range 2-3W with the minimum upper limit value in 2-3W, 2-4W, and 3-4W is selected as the second output power range. When the output power range part corresponding to each use parameter has intersection with the first output power range, the power range with the minimum upper limit value is selected from the output power range without intersection with the first output power range and the obtained intersection as a second output power range, and the second output power range has better suction effect on the premise of safe use of the electronic cigarette. For example, the output power range corresponding to the remaining capacity of the battery is 1-3W, the output power range corresponding to the service life of the battery is 5-7W, the output power range corresponding to the service life of the atomizing head is 3-5W, and the output power range corresponding to the first output power range is 2-4W, there is no intersection between the output power range corresponding to the service life of the battery and the output power range corresponding to the first output power range, the intersections between the remaining capacity of the battery and the service life of the atomizing head and the first output power range are 2-3W and 3-4W, respectively, and at this time, the smallest power range 2-3W among the upper limit values of 5-7W, 2-3W and 3-4W is selected as the second output power range. And if the output power range corresponding to each use parameter does not have intersection with the first output power range, selecting a power range with the minimum upper limit value from the output power range corresponding to each use parameter and the first output power range as a second output power range, wherein the second output power range may be one of the first output power range or the output power range corresponding to each use parameter, so that the electronic cigarette has a better suction effect on the premise of safe use. For example, the output power range corresponding to the remaining capacity of the battery is 5-6W, the output power range corresponding to the service life of the battery is 5-7W, the output power range corresponding to the service life of the atomizing head is 6-8W, and the output power range corresponding to the first output power range is 2-4W, so that the output power ranges corresponding to the service parameters do not have an intersection with the first output power range, and at this time, the power range 2-4W with the minimum upper limit value in 5-6W, 5-7W, 6-8W, and 2-4W is selected as the second output power range. In addition, since the output power ranges corresponding to the respective use parameters do not intersect with the first output power range, the lower limit value of the power range with the minimum upper limit value is also the minimum, and thus, the power range 2-4W with the minimum lower limit value among 5-6W, 5-7W, 6-8W, and 2-4W may also be selected as the second output power range by comparing the lower limit values.

In one embodiment, determining the second output power range according to the output power range corresponding to each usage parameter and the first output power range includes:

and if the intersection between the output power range corresponding to each use parameter and the first output power range is not empty, taking the intersection between the output power range corresponding to each use parameter and the first output power range as a second output power range.

If the intersection between the output power range corresponding to each use parameter and the first output power range is empty, after the intersection between the output power ranges with the intersection is calculated, the power range with the minimum upper limit value is selected from the obtained output power ranges without the intersection as the second output power range.

And if the intersection between the output power range corresponding to each use parameter and the first output power range is not empty, taking the intersection between the output power range corresponding to each use parameter and the first output power range as a second output power range. For example, the output power range corresponding to the remaining capacity of the battery is 1-4W, the output power range corresponding to the service life of the battery is 2-6W, the output power range corresponding to the service life of the atomizing head is 3-5W, the output power range corresponding to the first output power range is 2-4W, the intersection between the output power range corresponding to each service parameter and the intersection of the first output power ranges is 3-4W, the intersection is not empty, and at this time, 3-4W is taken as the second output power range, so that the size of the upper limit value and the lower limit value is considered in the determination process of the power range, and the suction effect can be better while the safe use is met.

If the intersection between the output power range corresponding to each use parameter and the first output power range is empty, after the intersection between the output power ranges with the intersection is calculated, the power range with the minimum upper limit value is selected from the obtained output power ranges without the intersection as the second output power range. For example, the output power range corresponding to the remaining capacity of the battery is 5-6W, the output power range corresponding to the service life of the battery is 5-7W, the output power range corresponding to the service life of the atomizing head is 6-8W, and the output power range corresponding to the first output power range is 2-4W, wherein the intersection of 5-6W, 5-7W, and 6-8W is 6W, and the calculated intersection 6W and 2-4W are output power ranges without intersection, so that the intersection between the output power range corresponding to each service parameter and the first output power range is empty, and at this time, the output power range 2-4W with the minimum upper limit value is selected from the obtained output power ranges 6W without intersection and 2-4W as the second output power range. For another example, the output power range corresponding to the remaining capacity of the battery is 5-6W, the output power range corresponding to the service life of the battery is 7-8W, the output power range corresponding to the service life of the atomizing head is 9-10W, the output power range corresponding to the first output power range is 2-4W, the intersection of 5-6W, 7-8W, 9-10W and 2-4W is an empty set, the empty set does not contain any element, the finally obtained output power range without intersection is 5-6W, 7-8W, 9-10W and 2-4W, and at this time, the power range 2-4W with the smallest upper limit value is selected from 5-6W, 7-8W, 9-10W and 2-4W as the second output power range. In both cases, the determination process of the second output power range takes the magnitude of the upper limit value and the magnitude of the lower limit value into consideration, so that the pumping effect is better while the safe use is satisfied.

It will be appreciated that the manner in which the second output power range is determined from the first output power range and the usage parameters of the e-cigarette is not limited thereto, for example, the determination method may be a method of determining a correction coefficient for the first output range based on the usage parameter of the electronic cigarette, correcting the upper limit value and the lower limit value of the first output range by using the correction coefficient to obtain the second output range, wherein, the correction coefficient is in negative correlation with the residual capacity of the battery, namely the correction coefficient is lower when the residual capacity is more, the correction coefficient is in positive correlation with the battery and the service life of the atomizing head, namely the correction coefficient is higher when the service life is longer, after obtaining the correction coefficients corresponding to the use parameters, the maximum value of all the correction coefficients is taken to correct the first output power range, the determined second output power range has a better smoking effect on the premise of safe use of the electronic cigarette. In addition, the first output power range may be corrected only when the remaining capacity is lower than the threshold value and the usage time of the battery or the atomizing head exceeds the threshold value, that is, when the remaining capacity, the usage time of the battery or the atomizing head still satisfies the condition for safe usage of the electronic cigarette, the first output power range is not corrected.

And step 140, determining the output power of the electronic cigarette according to the second output power range.

In one embodiment, determining the output power of the electronic cigarette according to the second output power range comprises:

and determining the output power of the electronic cigarette according to the operation information aiming at the second output power range or at least one recommended power.

In one embodiment, determining the output power of the electronic cigarette according to the operation information for the second output power range or the at least one recommended power comprises:

when the second output power range is displayed, receiving a power value input by a user, if the power value is within the second output power range, taking the power value as the output power of the electronic cigarette, and if the power value is not within the second output power range, outputting a message for prompting the failure of power value input;

and when at least one recommended power determined according to the second output power range is displayed and the operation information for confirming the recommended power is received, the confirmed recommended power is used as the output power of the electronic cigarette.

After the second output power range is determined, the second output power range can be directly displayed on a display screen of the electronic cigarette or a display screen of an intelligent terminal in communication connection with the electronic cigarette, a user inputs a certain value in the range by himself, if the input value is in the range, the value input by the user is used as the output power of the electronic cigarette, and if the input value exceeds the range, prompt information of input failure is displayed. In addition, after the second output power range is determined, at least one power can be randomly selected from the second output power range to be displayed through the display screen to be recommended to the user, if the user selects one of the powers through operating the electronic cigarette, the power selected and confirmed by the user is used as the output power of the electronic cigarette, if the user is not satisfied with the recommended power, the power can be automatically modified from the second output power range, and the power value modified by the user is used as the output power of the electronic cigarette. As another embodiment, after the second output power range is determined, the electronic cigarette may also randomly select an output power directly from the second output power range as the output power of the electronic cigarette without operation confirmation by the user.

In one embodiment, the method for determining the output power of the electronic cigarette further comprises the following steps:

When a user installs a battery or an atomizing head, the electronic cigarette inquires whether the user is a new (namely unused) battery or atomizing head, if so, the battery or the atomizing head is numbered, the respective use time length is recorded, and if not, the stored battery number or the stored atomizing head number can be displayed, so that the user can select and continue to record on the original record corresponding to the number after selecting the battery number or the atomizing head number. As another embodiment, the electronic cigarette may further read out the serial number and the usage duration stored in the battery or the memory chip of the atomizing head/atomizer through the data transmission pin, and further continue to accumulate the usage duration. For the used battery or the atomizing head, when the electronic cigarette cannot read the number corresponding to the battery or the atomizing head or the number corresponding to the installed battery or the atomizing head is not stored in the electronic cigarette, a new number can be established for the installed battery or the atomizing head, the user is prompted to input the use duration, and then the use duration is continuously accumulated on the use duration input by the user. It should be understood that when the user installs the atomizing head or the atomizer, the process of saving the usage time of the atomizing head may be performed simultaneously with the process of acquiring the usage parameters of the electronic cigarette in step 130, or may be performed before the process of acquiring the usage parameters of the electronic cigarette in step 130.

acquiring the modified service life;

When a user uses the electronic cigarette, if the accumulated using time of the electronic cigarette is found to be wrong, the using time of the battery or the atomizing head can be automatically corrected, at the moment, the user can operate the electronic cigarette to display a modification interface of the using time, select the serial number to trigger a modification instruction of the using time, then input and store the modified using time, and the electronic cigarette stores the modified using time and the corresponding serial number and continues to accumulate the using time on the modified using time.

The method for determining the output power of the electronic cigarette comprises the steps of determining a first output power range matched with the resistance value of the installed heating element, determining a second output power range according to the first output power range and the use parameters of the electronic cigarette, wherein the use parameters comprise at least one of the remaining capacity of a battery, the use duration of the battery and the use duration of an atomizing head, and finally determining the output power of the electronic cigarette according to the second output power range.

Fig. 2 is a schematic structural diagram of an electronic cigarette in an exemplary embodiment of the invention. As shown in fig. 2, the present invention further provides an electronic cigarette, which includes a memory 210 and a processor 220, wherein the memory 210 stores at least one program instruction, and the processor 220 implements the method for determining the output power of the electronic cigarette by loading and executing the at least one program instruction.

For the specific steps implemented when the processor 220 executes in this embodiment, please refer to the description of the embodiment shown in fig. 1, which is not repeated herein.

The present invention also provides a computer storage medium having computer program instructions stored thereon; the computer program instructions, when executed by the processor, implement the method of determining the output power of an electronic cigarette as described above.

The foregoing storage medium includes: various media capable of storing program codes, such as a usb disk, a removable hard disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk, an optical disk, or a cloud.

Please refer to the description of the embodiment shown in fig. 1 for a specific flow of steps that is implemented when computer program instructions stored in the computer storage medium of this embodiment are executed by the processor, which is not described herein again.

Although the present invention has been described with reference to a preferred embodiment, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims

1. A method of determining an electronic cigarette output power, comprising:

acquiring the resistance value of the heating element;

2. The method of determining an electronic cigarette output power of claim 1, wherein determining a second output power range based on the first output power range and a usage parameter of the electronic cigarette comprises:

acquiring use parameters of the electronic cigarette;

3. The method of determining an output power of an electronic cigarette according to claim 2, wherein determining the second output power range from the first output power range and the output power range corresponding to each usage parameter comprises:

4. A method of determining an output power of an electronic cigarette according to any of claims 1 to 3, wherein determining the output power of the electronic cigarette from the second output power range comprises:

5. The method of determining an output power of an electronic cigarette according to the operating information for the second output power range or the at least one recommended power of claim 4, comprising:

6. The method for determining the output power of the electronic cigarette according to claim 1, wherein the obtaining the resistance value of the heating element comprises:

7. The method for determining the output power of the electronic cigarette according to claim 6, wherein the obtaining the resistance value of the heat generating member according to the model of the heat generating member comprises:

8. The method for determining the output power of the electronic cigarette according to claim 1, wherein the obtaining the resistance value of the heating element comprises:

outputting a detection voltage to the heating member;

9. The method of determining electronic cigarette output power of claim 1, further comprising:

10. The method of determining electronic cigarette output power of claim 9, further comprising:

acquiring the modified service life;

11. An electronic cigarette, comprising a memory storing at least one program instruction and a processor implementing the method of determining electronic cigarette output power of any one of claims 1 to 10 by loading and executing the at least one program instruction.

12. A computer storage medium having computer program instructions stored thereon; the computer program instructions when executed by a processor implement a method of determining electronic cigarette output power as claimed in any of claims 1 to 10.