CN107427066A - Electronic cigarette control circuit and electronic cigarette control method - Google Patents

Abstract

An electronic cigarette control circuit and an electronic cigarette atomization control method are provided, wherein the electronic cigarette control circuit comprises a battery (102), a smoking trigger unit (103), a microprocessor (101), a switch unit (105), a signal detection unit (104) and an atomization unit (106); the microprocessor (101) is used for generating a first control signal and outputting the first control signal to the switch unit (105), and the microprocessor (101) is also used for generating a second control signal and outputting the second control signal to the switch unit (105) when a first preset condition is met. If the amount of the smoke which the user wants to suck is changed, only one second trigger operation needs to be input, the microprocessor (101) can generate the second control signal, and when the first preset condition is met, the microprocessor (101) can control the atomization power of the atomization unit (106) to be increased or decreased gradually each time, so that the service life of the electronic cigarette control circuit is effectively guaranteed.

Description

Electronic cigarette control circuit and electronic cigarette control method technical field

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

Background technique

The electronic cigarette in the prior art adjusts the atomization power of the electronic cigarette through the sliding rheostat, such as the electronic cigarette disclosed by the patent No. CN201220422812. Part of the power consumption of this electronic cigarette is on the sliding rheostat, so the service life of the electronic cigarette is short . Another electronic cigarette provided by the prior art is to control the atomization power of the electronic cigarette by continuously triggering the controller by pressing the button. However, pressing the button at a high frequency will easily fatigue the button, resulting in poor contact between the button and the controller. , resulting in a short service life of the electronic cigarette, and the electronic cigarette is not easy to adjust, so it is inconvenient to use.

Contents of the invention

The invention provides an electronic cigarette control circuit and an electronic cigarette control method;

An electronic cigarette control circuit, which includes a battery, a smoking trigger unit, a microprocessor, a switch unit, a signal detection unit and an atomization unit;

The smoking trigger unit is electrically connected to the battery and the microprocessor respectively, and the smoking trigger unit is used to receive a first trigger operation input by a user;

The switch unit is electrically connected to the microprocessor and the atomization unit respectively, and the microprocessor is used to generate a first control signal, and the microprocessor outputs the first control signal to the switch unit, and the switch unit is used to conduct the connection between the atomization unit and the battery according to the first control signal The circuit path between them, so that the atomization unit can atomize the e-liquid to form smoke;

The signal detection unit is electrically connected to the battery and the microprocessor respectively, the signal detection unit is used to receive the second trigger operation input by the user, and the microprocessor is also used to meet the first preset condition Next, generate a second control signal, and output the second control signal to the switch unit, so that the switch unit conducts the circuit between the atomization unit and the battery according to the second control signal channel, the microprocessor is used to increase or decrease the atomization power of the atomization unit through the second control signal, and the first preset condition is that the microprocessor determines the smoking trigger The unit receives the first trigger operation again.

preferred,

The smoking trigger unit is an airflow sensor, the first triggering operation is the user's puffing operation, and the airflow sensor is used to generate a trigger signal when receiving the first triggering operation, so that the airflow sensor will The generated trigger signal is sent to the microprocessor, and the microprocessor is used to generate the first control signal or the second control signal according to the trigger signal;

or,

The smoking trigger unit is a first key switch, the first trigger operation is a press operation, and the first key switch is used to conduct the microprocessor and the battery when receiving the first trigger operation The circuit path between, so that the microprocessor generates the first control signal or the second control signal.

Preferably, the switch unit includes a first resistor and a first transistor, one end of the first resistor is electrically connected to the microprocessor, and the other end of the first resistor is connected to the first transistor One end of the first triode is electrically connected with the atomizing unit at the other end.

Preferably, the signal detection unit is a second key switch and a second resistor, one end of the second resistor is electrically connected to the microprocessor, and the other end of the second resistor is electrically connected to the battery, so One end of the second key switch is electrically connected to the microprocessor, and the other end of the second key switch is electrically connected to the battery;

The microprocessor is also used to determine the preset increment, so that when the signal detection unit has received the second trigger operation input by the user and the first preset condition is satisfied, the microprocessor is used to determine the second trigger operation. A target control signal, the first target control signal is the control signal sent by the microprocessor to the switch unit last time, wherein the control signal sent by the microprocessor to the switch unit last time is the The first control signal or the second control signal, the microprocessor is also used to determine whether the duty cycle of the first target control signal is greater than or equal to a first preset value, when the first target control When the duty ratio of the signal is greater than or equal to the first preset value, the atomization unit atomizes the e-liquid with a power greater than or equal to the first preset power; when the duty ratio of the first target control signal is smaller than the preset value When the first preset value is mentioned, the atomization unit atomizes the e-liquid with less than the first preset power, wherein the first preset power is the maximum atomization power of the atomization unit; if not , then the microprocessor increases the preset increment on the duty cycle of the first target control signal to generate the second control signal; A second control signal for the atomization unit to atomize with a second preset power, where the second preset power is the minimum atomization power of the atomization unit.

Preferably, the signal detection unit is a second key switch and a second resistor, one end of the second resistor is electrically connected to the microprocessor, and the other end of the second resistor is electrically connected to the battery, so One end of the second key switch is electrically connected to the microprocessor, and the other end of the second key switch is electrically connected to the battery;

The microprocessor is also used to determine the preset decrement, so that when the signal detection unit has received the second trigger operation input by the user and the first preset condition is met, the microprocessor is used to determine the second trigger operation. Two target control signals, the second target control signal is the control signal sent by the microprocessor to the switch unit last time, wherein the control signal sent by the microprocessor to the switch unit last time is the The first control signal or the second control signal; the microprocessor is also used to determine whether the duty cycle of the second target control signal is greater than a second preset value, when the second target control signal When the duty cycle is greater than the second preset value, the atomization unit atomizes the e-liquid with a power greater than the second preset value; when the duty cycle of the second target control signal is less than or equal to the second preset value When setting the value, the atomization unit atomizes the e-liquid with less than or equal to the second preset power, wherein the second preset power is the minimum atomization power of the atomization unit; if so, the The microprocessor reduces the preset decrement on the duty cycle of the second target control signal to generate the second control signal; if not, the microprocessor generates A second control signal for the unit to atomize with a first preset power, where the first preset power is the maximum atomization power of the atomization unit.

Preferably, the signal detection unit includes a first detection subunit and a second detection subunit arranged in parallel, the first detection subunit includes a third key switch and a third resistor, and the second detection subunit includes a first Four key switch and fourth resistor;

One end of the third resistor is electrically connected to the microprocessor, the other end of the third resistor is electrically connected to the battery, one end of the third key switch is electrically connected to the microprocessor, the The other end of the third key switch is electrically connected to the battery, the third key switch is used to receive the pressing operation input by the user, and the microprocessor is used to determine if the third key switch receives the pressing operation, Then the microprocessor determines that the signal detection unit has received the second trigger operation input by the user, and the microprocessor is also used to determine that if the third key switch does not receive the press operation, the The microprocessor determines that the signal detection unit has not received the second trigger operation input by the user;

One end of the fourth resistor is electrically connected to the battery, the other end of the fourth resistor is electrically connected to the microprocessor, one end of the fourth key switch is electrically connected to the battery, and the fourth The other end of the key switch is electrically connected to the microprocessor, and the fourth switch is used to receive the pressing input by the user operation, the microprocessor is used to determine that when the fourth switch receives the pressing operation, it is determined that the second preset condition is met, and the microprocessor is also used to determine that the second preset condition is satisfied Three target control signals, the third target control signal is the second control signal sent by the microprocessor to the switch unit last time; if the microprocessor determines that the first preset condition is met, the The microprocessor outputs the third target control signal to the switch unit, so that the switch unit conducts the circuit path between the atomization unit and the battery according to the third target control signal.

Preferably, the atomization unit includes a plurality of heating wires arranged in parallel, and the number of the switching units is equal to the number of the heating wires, so that each of the heating wires corresponds to each of the switching units;

One end of each heating wire is electrically connected to the microprocessor, and the other end of each heating wire is electrically connected to the microprocessor through the switch unit;

The microprocessor is also used to determine a first preset corresponding relationship, the first preset corresponding relationship includes the corresponding relationship between each control signal generated by the microprocessor and each switch unit. The generated control signal is the first control signal or the second control signal, so that the microprocessor determines the target switch unit corresponding to the generated control signal according to the first preset correspondence, making the microprocessor conduct the circuit path between the heating wire corresponding to the target switch unit and the battery.

Preferably, the electronic cigarette control circuit further includes a prompting module, the prompting module is electrically connected to the microprocessor, and the prompting module is used to correspondingly generate a prompting state according to the prompting signal sent by the microprocessor, and Different prompt signals correspond to different prompt states;

The microprocessor is also used to generate a second preset correspondence, the second preset correspondence includes the correspondence between each control signal and each prompt signal generated by the microprocessor, and the microprocessor generates The generated control signal is the first control signal or the second control signal, so that the microprocessor determines the target prompt signal corresponding to the generated control signal according to the generated control signal, so that The prompt module correspondingly generates a prompt state through the target prompt signal to prompt the user.

Preferably, the prompt module is a light module and/or a voice module.

A method for controlling electronic smog, including:

The microprocessor determines whether the smoking trigger unit has received the first trigger operation input by the user, and the smoking trigger unit is electrically connected to the battery and the microprocessor respectively;

If so, the microprocessor determines whether the signal detection unit receives a second trigger operation input by the user, and the signal detection unit is electrically connected to the battery and the microprocessor respectively;

if not, the microprocessor generates a first control signal;

The microprocessor outputs the first control signal to the switch unit, and the switch unit is electrically connected to the microprocessor and the atomization unit respectively, so that the switch unit turns on all the atomizers according to the first control signal. The circuit path between the atomization unit and the battery, so that the atomization unit can atomize the e-liquid to form smoke;

If so, the microprocessor generates a second control signal when a first preset condition is met, and the first preset condition is that the microprocessor determines that the smoking trigger unit receives the first trigger operation again ;

The microprocessor outputs the second control signal to the switch unit, so that the switch unit conducts the circuit path between the atomization unit and the battery according to the second control signal, so as to The microprocessor is made to change the atomization power of the atomization unit in an increasing or decreasing manner through the second control signal.

Preferably, before the microprocessor generates the second control signal when the first preset condition is met, the method includes:

When the microprocessor determines to change the atomization power of the atomization unit in an incremental manner, the microprocessor determines a preset increment;

The generating of the second control signal by the microprocessor under the first preset condition includes:

When the first preset condition is satisfied, the microprocessor determines a first target control signal, and the first target control signal is the control signal sent by the microprocessor to the switch unit last time, wherein, The control signal sent by the microprocessor to the switch unit last time is the first control signal or the second control signal;

The microprocessor determines whether the duty cycle of the first target control signal is greater than or equal to a first preset value, when the duty cycle of the first target control signal is greater than or equal to the first preset value , then make the atomization unit atomize the e-liquid with greater than or equal to the first preset power, and when the duty cycle of the first target control signal is smaller than the first preset value, then make the atomization The unit atomizes the e-liquid with less than the first preset power, wherein the first preset power is the maximum atomization power of the atomization unit;

If not, the microprocessor increases the duty cycle of the first target control signal by the preset increment to generate the second control signal;

If so, the microprocessor generates a second control signal for making the atomization unit atomize with a second preset power, and the second preset power is the minimum atomization power of the atomization unit .

Preferably, before the microprocessor generates the second control signal when the first preset condition is met, the method includes:

When the microprocessor determines to change the atomization power of the atomization unit in a decreasing manner, the microprocessor determines a preset decrement;

The generating of the second control signal by the microprocessor under the first preset condition includes:

When the first preset condition is satisfied, the microprocessor determines a second target control signal, and the second target control signal is the control signal sent by the microprocessor to the switch unit last time, wherein, The control signal sent by the microprocessor to the switch unit last time is the first control signal or the second control signal;

The microprocessor determines whether the duty cycle of the second target control signal is greater than a second preset value, and when the duty cycle of the second target control signal is greater than the second preset value, the The atomization unit atomizes the e-liquid with a power greater than the second preset power, and when the duty ratio of the second target control signal is less than or equal to the second preset value, the atomization unit is made to Equal to the second preset power atomized e-liquid, wherein the second preset power is the minimum atomization power of the atomization unit;

if yes, the microprocessor reduces the duty cycle of the second target control signal by the preset decrement to generate the second control signal;

If not, the microprocessor generates a second control signal for making the atomization unit atomize with a first preset power, and the first preset power is the maximum atomization of the atomization unit power.

preferred,

The smoking trigger unit is an airflow sensor, and the smoking trigger unit is electrically connected to the battery and the microprocessor respectively, and the microprocessor determines whether the smoking trigger unit receives the first trigger operation input by the user include:

The microprocessor determines whether a trigger signal is received, the trigger signal is generated by the airflow sensor when the first trigger operation is received, and the first trigger operation is an operation of pumping by the user;

If so, the microprocessor determines that the smoking trigger unit has received the first trigger operation input by the user;

If not, the microprocessor determines that the smoking trigger unit has not received the first trigger operation input by the user;

or,

The smoking trigger unit is a first key switch, and the smoking trigger unit is connected to the battery respectively is electrically connected to the microprocessor, and the microprocessor determines whether the first trigger operation of the smoking trigger unit receiving user input includes:

The microprocessor determines whether the circuit between the microprocessor and the battery is conductive, the first trigger operation is a press operation, and the first key switch is used to receive the first trigger operation turn on the circuit path between the microprocessor and the battery;

If so, the microprocessor determines that the smoking trigger unit has received a first trigger operation input by the user;

If not, the microprocessor determines that the smoking trigger unit has not received the first trigger operation input by the user.

Preferably, after the microprocessor outputs the second control signal to the switch unit, the method further includes:

The microprocessor determines the third target control signal when a second preset condition is met, and the second preset condition is that the microprocessor determines that the signal detection unit receives the second trigger operation again, so The third target control signal is the second control signal sent by the microprocessor to the switch unit last time;

If the microprocessor determines that the first preset condition is satisfied, the microprocessor outputs the third target control signal to the switch unit, so that the switch unit is controlled according to the third target The signal conducts the circuit path between the atomization unit and the battery.

Preferably, the signal detection unit includes a first detection subunit and a second detection subunit arranged in parallel;

The second trigger operation for the microprocessor to determine whether the signal detection unit receives user input includes:

When the microprocessor determines that the first detection subunit has received a user-input pressing operation, then the microprocessor determines that the signal detection unit has received a user-input second trigger operation;

When the microprocessor determines that the first detection subunit has not received a user-input pressing operation, the microprocessor determines that the signal detection unit has not received a user-input second trigger operation;

After the microprocessor outputs the second control signal to the switch unit, the method further includes:

The microprocessor determines a third target control signal when a second preset condition is met, and the second preset It is assumed that the microprocessor determines that the second detection subunit has received a pressing operation input by the user, and the third target control signal is the second control signal sent by the microprocessor to the switch unit last time ;

If the microprocessor determines that the first preset condition is satisfied, the microprocessor outputs the third target control signal to the switch unit, so that the switch unit is controlled according to the third target The signal conducts the circuit path between the atomization unit and the battery.

Preferably, the atomization unit includes a plurality of heating wires arranged in parallel, and the number of the switching units is equal to the number of the heating wires, so that each of the heating wires corresponds to each of the switching units, and each of the switching units One end of the heating wire is electrically connected to the microprocessor, and the other end of each heating wire is electrically connected to the microprocessor through the switch unit;

The method also includes:

The microprocessor determines a first preset correspondence, and the first preset correspondence includes a correspondence between each control signal generated by the microprocessor and each switch unit;

The microprocessor outputting the first control signal to the switch unit includes:

The microprocessor determines a first target switch unit corresponding to the first control signal according to the first preset correspondence;

The microprocessor outputs the first control signal to the first target switch unit, so that the first target switch unit turns on the switch corresponding to the first target switch unit according to the first control signal. The circuit path between the atomization unit and the battery;

The microprocessor outputting the second control signal to the switch unit includes:

The microprocessor determines a second target switch unit corresponding to the second control signal according to the first preset correspondence, so that the second target switch unit is turned on and connected to the second target switch unit according to the second control signal. The circuit path between the atomization unit corresponding to the second target switch unit and the battery.

Preferably, the method also includes:

The microprocessor generates a second preset corresponding relationship, the second preset corresponding relationship includes the corresponding relationship between each control signal generated by the microprocessor and each prompt signal, and the control signal generated by the microprocessor The signal is the first control signal or the second control signal;

The microprocessor determines a target prompt signal corresponding to the generated control signal according to the generated control signal;

The microprocessor sends the target prompt signal to a prompt module, and the prompt module communicates with the The microprocessor is electrically connected, and the prompting module is used to correspondingly generate a prompting state according to the prompting signal sent by the microprocessor, and different prompting signals correspond to different prompting states, so that the prompting module prompts according to the target The signal corresponds to generating an alert state to alert the user.

The present invention provides an electronic cigarette control circuit and an electronic smoke control method. The electronic cigarette control circuit includes a battery, a smoking trigger unit, a microprocessor, a switch unit, a signal detection unit, and an atomization unit; the microprocessor is used for If it is determined that the smoking trigger unit receives a first trigger operation, the microprocessor generates a first control signal, and the microprocessor outputs the first control signal to the switch unit, and the switch unit It is used to conduct the circuit path between the atomization unit and the battery according to the first control signal, so that the atomization unit can atomize e-liquid to form smoke; the microprocessor is also used to Generate a second control signal when the first preset condition is met, and output the second control signal to the switch unit, so that the switch unit turns on the atomization unit and the atomizer according to the second control signal In the circuit path between the batteries, the microprocessor is used to increase or decrease the atomization power of the atomization unit through the second control signal. If the user wishes to suck smoke with a changed amount of smoke, he only needs to input the second trigger operation once, and the microprocessor can generate a second trigger operation according to the second trigger operation input by the user. control signal, and whenever the first preset condition is met, the microprocessor can control the atomization power of the atomization unit to increase or decrease with the same amplitude every time through the second control signal, without the need for the user The signal detection unit is operated multiple times, thereby effectively avoiding poor contact between the signal detection unit and the microprocessor due to multiple triggers of the signal detection unit, and effectively ensuring the service life of the electronic cigarette control circuit.

Description of drawings

Fig. 1 is a schematic diagram of a circuit connection structure of an electronic cigarette control circuit provided by the present invention;

Fig. 2 is a schematic diagram of another circuit connection structure of an electronic cigarette control circuit provided by the present invention;

Fig. 3 is a schematic diagram of another circuit connection structure of the electronic cigarette control circuit provided by the present invention;

Fig. 4 is a schematic diagram of another circuit connection structure of the electronic cigarette control circuit provided by the present invention;

Fig. 5 is a schematic diagram of another circuit connection structure of the electronic cigarette control circuit provided by the present invention;

6 is a schematic diagram of another circuit connection structure of the electronic cigarette control circuit provided by the present invention;

Fig. 7 is a schematic diagram of another circuit connection structure of the electronic cigarette control circuit provided by the present invention;

Fig. 8 is a flow chart of steps in a preferred embodiment of the method for controlling electronic vaping provided by the present invention picture;

Fig. 9 is a flow chart of steps in another preferred embodiment of the method for controlling electronic vaping provided by the present invention;

Fig. 10 is a flow chart of steps in another preferred embodiment of the method for controlling electronic vaping provided by the present invention;

Fig. 11 is a flow chart of steps in another preferred embodiment of the method for controlling vaping provided by the present invention;

Fig. 12 is a flow chart of steps in another preferred embodiment of the method for controlling vaping provided by the present invention;

Fig. 13 is a flow chart of steps in another preferred embodiment of the method for controlling electronic cigarette generation provided by the present invention.

detailed description

Embodiment 1. This embodiment provides an electronic cigarette control circuit, so that the electronic cigarette control circuit provided by this embodiment can change the atomization power of the electronic cigarette without pressing the button at a high frequency, effectively improving the electronic cigarette. the service life of the smoke;

As shown in Figure 1, the electronic cigarette control circuit provided by this embodiment includes: a battery 102, a smoking trigger unit 103, a microprocessor 101, a switch unit 105, a signal detection unit 104, and an atomization unit 106;

Specifically, the smoking trigger unit 103 is electrically connected to the battery 102 and the microprocessor 101 respectively, and the smoking trigger unit 103 is configured to receive a first trigger operation input by a user;

More specifically, in this embodiment, the specific structure of the smoking trigger unit 103 is not limited, as long as the user wishes to smoke smoke, the first trigger operation can be input through the smoking trigger unit 103 to suck smoke, for example, The first triggering operation may be an action of sucking the smoking trigger unit 103 , and for example, the first triggering operation may be an action of pressing the smoking trigger unit 103 ;

The switch unit 105 is electrically connected to the microprocessor 101 and the atomization unit 106 respectively, and the microprocessor 101 is configured to, if it is determined that the smoking trigger unit 103 receives the first trigger operation, then The microprocessor 101 generates a first control signal, and the microprocessor 101 outputs the first control signal to the switch unit 105, and the switch unit 105 is used to conduct according to the first control signal A circuit path between the atomization unit 106 and the battery 102, so that the atomization unit 106 can atomize e-liquid to form smoke;

Wherein, this embodiment does not limit the specific structure of the atomization unit 106, as long as the atomization unit 106 can atomize E-liquid can be used to form smoke.

This embodiment does not limit the specific structure of the switch unit 105, as long as the switch unit 105 can conduct the circuit path between the atomization unit 106 and the battery 102 according to the first control signal. .

In order to achieve the purpose that the electronic cigarette control circuit shown in this embodiment can change the atomization power of the atomization unit 106, the signal detection unit 104 is electrically connected to the battery 102 and the microprocessor 101 respectively ;

The signal detection unit 104 is configured to receive a second trigger operation input by a user;

This embodiment does not limit the second trigger operation, for example, the second trigger operation is a press operation;

The microprocessor 101 is further configured to generate a second control signal when the first preset condition is satisfied;

Wherein, the first preset condition is that the microprocessor 101 determines that the smoking trigger unit 103 receives the first trigger operation again;

Specifically, when the user wishes to change the atomization power of the atomization unit 106, the second trigger operation is input through the signal detection unit 104, and the user wishes to inhale the atomization power of the atomization unit 106 again. When the power of the smoke has changed, the user inputs the first trigger operation again through the smoking trigger unit 103, so that the user can inhale the smoke whose amount of smoke has increased or decreased compared with the last time ;

More specifically, the microprocessor 101 outputs the second control signal generated under the first preset condition to the switch unit 105, so that the switch unit 105 according to the second control The signal conducts the circuit path between the atomization unit 106 and the battery 102, and the microprocessor 101 is used to change the atomization of the atomization unit 106 in an incremental or decremental manner through the second control signal. Transformation power;

For example, when the user inputs the second trigger operation through the signal detection unit 104, each time the user inputs the first trigger operation through the smoking trigger unit 103, the microprocessor 101 generates the second The control signal controls the atomization power of the atomization unit 106 to increase each time with an equal or unequal range;

Preferably, in this embodiment, the second control signal generated by the microprocessor 101 is used to control the The atomization power of the atomization unit 106 is incremented each time with an equal range, so that after the user inputs the first trigger operation each time, the amount of smoke can be increased and compared with the last time the user smokes. Take the smoke volume with a constant increase in the received smoke volume as an example;

Also for example, when the user inputs the second trigger operation through the signal detection unit 104, each time the user inputs the first trigger operation through the smoking trigger unit 103, the microprocessor 101 generates the first trigger operation through the generated first trigger operation. The second control signal controls the atomization power of the atomization unit 106 to decrease each time with equal or unequal amplitude;

Preferably, in this embodiment, the second control signal generated by the microprocessor 101 is used to control the atomization power of the atomization unit 106 to decrease each time with an equal range, so that the user can input the value each time. After the above-mentioned first trigger operation, the amount of smoke that can be sucked is reduced and the amount of smoke reduced compared with the amount of smoke drawn last time is taken as an example.

In this embodiment, there is no limitation on whether the atomization power of the atomization unit 106 controlled by the microprocessor 101 is increased in an increasing manner or decreased in a decreasing manner through the generated second control signal;

It can be seen that, by using the electronic cigarette control circuit shown in this embodiment, when the user wishes to inhale smoke with a changed amount of smoke, he only needs to input the second trigger operation once, and the microprocessor 101 That is, a second control signal can be generated according to the second trigger operation input by the user, and whenever the first preset condition is met, the microprocessor 101 can control the atomization through the second control signal The atomization power of the unit 106 is increased or decreased with the same amplitude every time, and the user does not need to operate the signal detection unit 104 for many times, thereby effectively avoiding the signal detection unit 104 being triggered by the signal detection unit 104 for many times. The poor contact between the microprocessors 101 effectively guarantees the service life of the control circuit of the electronic cigarette.

Embodiment 2, this embodiment describes in detail the specific circuit connection structure of the electronic cigarette control circuit:

First please refer to FIG. 2, the smoking trigger unit is an airflow sensor 201;

Specifically, the first trigger operation is an operation in which the user sucks the airflow sensor 201, and the airflow sensor 201 is used to generate a trigger signal when receiving the first trigger operation, so that the airflow sensor 201 201 sending the generated trigger signal to the microprocessor 101, where the microprocessor 101 is configured to generate the first control signal or the second control signal according to the trigger signal;

It should be clear that this embodiment is described by taking the smoking trigger unit as an example of the airflow sensor 201, and there is no limitation, as long as the smoking trigger unit can receive the first trigger operation inputted by the user. For example, the smoking trigger unit is a first button switch, the first trigger operation is a press operation, and the first button switch is used to turn on the micro switch when receiving the first trigger operation. The circuit path between the processor 101 and the battery 102 enables the microprocessor 101 to generate the first control signal or the second control signal.

More specifically, if the user has never input the second trigger operation through the signal detection unit 104, it means that the user has no desire to change the atomization power of the atomization unit 106, and the microprocessor 101 uses generating the first control signal according to the trigger signal;

If the user has input the second trigger operation through the signal detection unit 104, it means that the user wants to change the atomization power of the atomization unit 106, and the microprocessor 101 is used to signal to generate said second control signal;

The specific circuit structure of the switch unit 105 will be described in detail below in conjunction with FIG. 2 :

Wherein, as shown in Figure 2, the model of the microprocessor 101 is SN8P2711B. It should be clear that the specific model of the microprocessor 101 is not limited in this embodiment for illustration, as long as the microprocessor It is sufficient that 101 can realize the functions shown in this embodiment.

The switch unit 105 includes a first resistor R1 and a first transistor Q1;

One end of the first resistor R1 is electrically connected to the microprocessor 101, the other end of the first resistor R1 is electrically connected to one end of the first transistor Q1, and the first transistor Q1 The other end is electrically connected to the atomizing unit 106 .

That is, when the first control signal or the second control signal generated by the microprocessor 101 flows through the first triode Q1, the first triode Q1 The control signal or the second control signal is closed to make the circuit between the atomization unit 106 and the battery 102 conduct, that is, whether it is the first control signal or the second control signal, it will The first triode Q1 is made to conduct the circuit path between the atomization unit 106 and the battery 102 .

The specific circuit structure of the signal detection unit 104 will be described in detail below in conjunction with FIG. 2 :

Specifically, the following describes in detail how the microprocessor 101 changes the atomization power of the atomization unit 106 in an incremental manner through the signal detection unit 104;

The signal detection unit 104 is a second key switch K2 and a second resistor R2;

Specifically, one end of the second resistor R2 is electrically connected to the microprocessor 101, the other end of the second resistor R2 is electrically connected to the battery 102, and one end of the second key switch K2 is electrically connected to the The microprocessor 101 is electrically connected, and the other end of the second key switch K2 is electrically connected to the battery 102;

The microprocessor 101 is also used to determine a preset increment;

This embodiment does not limit the specific value of the preset increment, which may be predetermined by the microprocessor 101 according to needs, or set correspondingly according to an instruction input by the user, which is not specifically limited in this embodiment.

When the signal detection unit 104 has received the second trigger operation input by the user and satisfies the first preset condition, that is, when the user wishes to inhale smoke again after inputting the second trigger operation, then input the When the first trigger operation is mentioned above;

The microprocessor 101 is used to determine a first target control signal, the first target control signal is the control signal sent by the microprocessor 101 to the switch unit 105 last time, wherein the microprocessor 101 The control signal sent to the switch unit 105 last time is the first control signal or the second control signal;

That is, if the microprocessor 101 determines that the signal detection unit 104 has never received the second trigger operation, the first target control signal is the first control signal;

If the microprocessor 101 determines that the signal detection unit 104 has received the second trigger operation, and the microprocessor 101 determines that the first preset condition was met last time (that is, the user passed the When the smoking trigger unit inputs the first trigger operation), the second control signal sent by the microprocessor 101 to the switch unit 105 is the first target control signal;

Preferably, in this embodiment, in order to avoid the potential safety hazard caused by the continuous increase of the atomization power of the atomization unit 106 after reaching the maximum atomization power, the atomization unit 106 is prevented from In the case of burning, after the microprocessor 101 has determined the first target control signal, it does not change the atomization power of the atomization unit 106, but the microprocessor 101 determines the first target control signal. Whether the duty cycle of the first target control signal is greater than or equal to the first preset value; wherein, it can be understood that the maximum atomization power is an atomization power value set to avoid potential safety hazards and burning.

In this embodiment, the size of the first preset value is not limited, and it may be set by the microprocessor 101 according to the specific working parameters of the atomization unit 106 .

Wherein, when the duty ratio of the first target control signal is greater than or equal to the first preset value, the atomization unit 106 atomizes the e-liquid with greater than or equal to the first preset power, and the first The preset power is the maximum atomization power of the atomization unit 106;

When the duty cycle of the first target control signal is less than the first preset value, the atomization unit 106 atomizes the e-liquid with less than the first preset power;

If the microprocessor 101 determines that the duty cycle of the first target control signal is less than the first preset value, the microprocessor 101 increases the duty cycle of the first target control signal the preset increment to generate the second control signal;

Specifically, if the microprocessor 101 determines that the duty cycle of the first target control signal is smaller than the first preset value, it means that the last atomization power of the atomization unit 106 is still within a safe range. (that is, the atomization power of the atomization unit 106 when atomizing e-liquid last time is less than the maximum atomization power of the atomization unit 106), the microprocessor 101 can increasing the preset increment to generate the second control signal;

Wherein, after generating the second control signal that the duty cycle has increased by the preset increment, if the microprocessor 101 determines that the first preset condition is met again, then the duty cycle has been increased by the If the second control signal with the preset increment is determined as the first target control signal, it is necessary to determine again whether the duty cycle of the first target control signal is greater than or equal to the first preset value;

If the duty cycle of the first target control signal is greater than or equal to the first preset value, then the microprocessor 101 generates a signal for making the atomization unit 106 atomize with the second preset power. The second control signal, the second preset power is the minimum atomization power of the atomization unit 106 .

That is, if the microprocessor 101 determines that the duty cycle of the first target control signal is greater than or equal to the first preset value, it means that the last atomization power of the atomization unit 106 is not within a safe range. (that is, the atomization power of the atomization unit 106 when atomizing e-liquid last time is greater than or equal to the maximum atomization power of the atomization unit 106), then the microprocessor 101 cannot continue to change the The atomization power of the atomization unit 106 is cyclic, that is, the microprocessor 101 uses the second control signal to make the atomization unit 106 atomize the e-liquid with the minimum atomization power to form smoke , that is, the atomization unit 106 returns to the initial atomization power through the second control signal.

In this embodiment, the minimum atomization power of the atomization unit 106 is not limited. For example, when the signal detection unit has not received the second trigger operation, the microprocessor 101 determines that the first atomization power is satisfied. Under a preset condition, the atomization power of the atomization unit 106 is the minimum atomization power of the atomization unit 106 .

It can be seen from the above description that after the microprocessor 101 receives the second trigger operation input by the user through the signal detection unit 104, it receives When the user inputs the first trigger operation, it is necessary to determine whether the duty cycle of the first target control signal sent by the microprocessor 101 to the switch unit 105 last time is greater than or equal to the first preset value, so as to determining whether to continue to increase the duty cycle of the first target control signal in an incremental manner, so that the atomization power of the atomization unit 106 continues to increase, or to cycle back to the minimum atomization power of the atomization unit 106, It can be seen that the use of the above circuit structure can effectively prevent the atomization unit 106 from exceeding the safety of the atomization unit 106, and avoid the situation of burning the atomization unit 106 when the atomization power exceeds the safety of the atomization unit 106, and avoid The burning of the atomizing unit 106 will reduce the service life of the electronic cigarette.

The above has explained how the electronic cigarette control circuit shown in Figure 2 realizes changing the atomization power of the atomization unit 106 in an incremental manner. Way to change the atomization power of the atomization unit 106;

The specific structure of the electronic cigarette control circuit when the atomization power of the atomization unit 106 is changed in a decreasing manner and the specific structure of the electronic cigarette control circuit when the atomization power of the atomization unit 106 is changed in an incremental manner The structure is the same and will not be repeated here;

The microprocessor 101 is used to determine a preset decrement;

This embodiment does not limit the specific value of the preset decrement, which may be predetermined by the microprocessor 101 according to needs, or set correspondingly according to an instruction input by the user, and is not specifically limited in this embodiment.

When the signal detection unit 104 has received the second trigger operation input by the user and satisfies the first preset condition, that is, when the user wishes to inhale smoke again after inputting the second trigger operation, then input the When the first trigger operation is mentioned above;

The microprocessor 101 is used to determine a second target control signal, the second target control signal is the control signal sent by the microprocessor 101 to the switch unit 105 last time, wherein the microprocessor 101 The control signal sent to the switch unit 105 last time is the first control signal or the second control signal;

That is, if the microprocessor 101 determines that the signal detection unit 104 has never received the second trigger operation, the second target control signal is the first control signal;

If the microprocessor 101 determines that the signal detection unit 104 has received the second trigger operation, and the microprocessor 101 determines that the first preset condition was met last time (that is, the user passed the When the smoking trigger unit inputs the first trigger operation), the second control signal sent by the microprocessor 101 to the switch unit 105 is the second target control signal;

Preferably, in this embodiment, in order to avoid the atomization power of the atomization unit 106 reaching the minimum atomization power, when the atomization power of the atomization unit 106 is continuously reduced, the mist If the concentration of smoke generated by the atomization unit 106 is not enough to meet the needs of the user, the microprocessor 101 will not change the atomization power of the atomization unit 106 after the second target control signal has been determined, but The microprocessor 101 first determines whether the duty cycle of the second target control signal is greater than a second preset value;

In this embodiment, the size of the second preset value is not limited, and it may be set by the microprocessor 101 according to the specific working parameters of the atomization unit 106 .

Wherein, when the duty cycle of the second target control signal is greater than the second preset value, the atomization unit 106 atomizes the e-liquid with a power greater than the second preset power, and the second preset power is The minimum atomization power of the atomization unit 106;

When the duty ratio of the second target control signal is less than or equal to the second preset value, the atomization unit 106 atomizes the e-liquid with less than or equal to the second preset power, and the second The preset power is the minimum atomization power of the atomization unit 106;

If the duty cycle of the second target control signal is greater than a second preset value, the microprocessor 101 reduces the duty cycle of the second target control signal by the preset decrement to generate the the second control signal;

Specifically, if the microprocessor 101 determines that the duty cycle of the second target control signal is smaller than the second preset value, it means that the last atomization power of the atomization unit 106 can atomize a certain concentration. smoke, and there is no case where the atomized smoke concentration is too low (that is, the atomization power of the atomization unit 106 was greater than the minimum atomization power of the atomization unit 106 when atomizing the e-liquid last time), then the The microprocessor 101 may reduce the preset decrement on the duty cycle of the second target control signal to generate the second control signal;

Wherein, after generating the second control signal that the duty cycle has been reduced by the preset decrement, if the microprocessor 101 determines that the first preset condition is met again, then the duty cycle has been reduced by the If the second control signal of the preset decrement is determined as the second target control signal, it is necessary to determine again whether the duty cycle of the second target control signal is greater than the second preset value;

If the duty cycle of the second target control signal is less than or equal to the second preset value, then the microprocessor 101 generates The second control signal, the first preset power is the maximum atomization power of the atomization unit 106 .

That is, if the microprocessor 101 determines that the duty cycle of the second target control signal is smaller than the second preset value, it means that the last atomization power of the atomization unit 106 is too small, and the atomized If the smoke concentration cannot meet the needs of the user, the microprocessor 101 cannot continue to change the atomization power of the atomization unit 106 in a decreasing manner, but in a cyclic manner, that is, the microprocessor 101 passes the The second control signal makes the atomization unit 106 atomize the e-liquid with the maximum atomization power to form smoke, that is, the atomization unit 106 returns to the initial atomization power through the second control signal.

It can be seen from the above description that after the microprocessor 101 receives the second trigger operation input by the user through the signal detection unit 104, it receives the first trigger operation input by the user through the smoking trigger unit 103 every time thereafter. At any time, it is necessary to determine whether the duty cycle of the second target control signal sent by the microprocessor 101 to the switch unit 105 last time is greater than the second preset value, so as to determine whether to continue reducing the Whether the duty cycle of the second target control signal is used so that the atomization power of the atomization unit 106 continues to decrease, or the maximum atomization power that is circulated back to the atomization unit 106, it can be seen that the above circuit structure can effectively Inconvenience to the user caused by continuously reducing the atomization power of the atomization unit 106 when the concentration of the atomized smoke by the atomization unit 106 cannot meet the user's requirements is prevented.

It should be clear that, when the atomization power of the atomization unit 106 satisfies certain conditions (see the above for details), the atomization power of the atomization unit 106 is adjusted in an increasing or decreasing manner. is a preferred example, without limitation, for example, the atomization power of the atomization unit 106 may also be randomly adjusted.

When the electronic cigarette adopts the electronic cigarette control circuit provided in this embodiment, if the concentration of the smoke atomized by the atomization unit 106 last time is more suitable for the taste of the user, when the user wants to smoke smoke in the future, he can Continuing to smoke with the smoke concentration drawn last time, the following describes in detail how the electronic cigarette control circuit provided in this embodiment realizes fixing the atomization power of the atomization unit 106;

This embodiment provides two ways of fixing the atomization power of the atomization unit 106:

The first type: the microprocessor 101 determines the third target control signal when the second preset condition is satisfied, wherein the second preset condition is that the microprocessor 101 determines that the signal detection unit 104 receives again to the second trigger operation;

The third target control signal is the second control signal sent by the microprocessor 101 to the switch unit 105 last time;

That is, if the user determines that the concentration of the smoke drawn last time is more appropriate, the second trigger operation is input again through the signal detection unit 104, and the microprocessor 101 detects that the signal detection unit 104 receives the signal detection unit 104 again. The second trigger operation can determine that the second control signal sent by the microprocessor 101 to the switch unit 105 last time is the third target control signal;

In the subsequent use process, if the microprocessor 101 determines that the first preset condition is met (that is, when the user needs to inhale smoke and inputs the first trigger operation), the microprocessor 101 will The three-target control signal is output to the switch unit 105, so that the switch unit 105 conducts the circuit path between the atomization unit 106 and the battery 102 according to the third target control signal.

The second type: please refer to Figure 3, wherein Figure 3 is a schematic diagram of another circuit connection structure of an electronic cigarette control circuit provided by the present invention;

The signal detection unit 104 includes a first detection subunit 301 and a second detection subunit 302 arranged in parallel;

The first detection subunit 301 includes a third key switch K3 and a third resistor R3, and the second detection subunit 302 includes a fourth key switch K4 and a fourth resistor R4;

As shown in Figure 3, one end of the third resistor R3 is electrically connected to the microprocessor 101, the other end of the third resistor R3 is electrically connected to the battery 102, and one end of the third key switch K3 It is electrically connected to the microprocessor 101, and the other end of the third key switch K3 is electrically connected to the battery 102;

Wherein, the third key switch K3 is used to receive the pressing operation input by the user, and the microprocessor 101 is used to determine that if the third key switch K3 receives the pressing operation, the microprocessor 101 determines The signal detection unit 104 receives the second trigger operation input by the user;

The microprocessor 101 is further configured to determine that if the third key switch K3 does not receive the pressing operation, the microprocessor 101 determines that the signal detection unit 104 does not receive the second key input by the user. trigger action;

One end of the fourth resistor R4 is electrically connected to the battery 102, the other end of the fourth resistor R4 is electrically connected to the microprocessor 101, and one end of the fourth key switch K4 is electrically connected to the battery 102. connected, the other end of the fourth key switch K4 is electrically connected to the microprocessor 101,

Specifically, the fourth key switch K4 is used to receive a pressing operation input by the user, and the microprocessor 101 is used to determine that when the fourth switch K4 receives the pressing operation, it is determined that the second preset is satisfied. condition;

The microprocessor 101 is further configured to determine a third target control signal when the second preset condition is met, and the third target control signal is the second target signal sent by the microprocessor 101 to the switch unit 105 last time. control signal;

If the microprocessor 101 determines that the first preset condition is satisfied (that is, when the user needs to inhale smoke again), the microprocessor 101 outputs the third target control signal to the switch unit 105, To make the switch unit 105 conduct the circuit path between the atomization unit 106 and the battery 102 according to the third target control signal.

It can be seen that, using the above description, when the user inputs the second trigger operation through the signal detection unit for the first time, the user wishes to change the atomization power of the atomization unit 106 in an incremental or decremental manner, so as to change smoke concentration, when the user inputs the second trigger operation through the signal detection unit 104 again, it means that the user feels that the current smoke concentration is more appropriate, and then the microprocessor 101 determines that the user inputs the second trigger operation. When the second trigger operation is performed, the second control signal sent to the switching power supply 105 last time is determined as the third target control signal, then when the microprocessor 101 determines that the user inputs the first When the operation is triggered, the determined third target control signal is sent to the switch unit 105, so that the atomization unit 106 performs the action of atomizing e-liquid according to the third target control signal, and the atomization The conversion power does not change.

Embodiment 3, this embodiment describes another way of changing the smoke concentration by the electronic cigarette control circuit as shown in FIG. 4 ;

Embodiment 2 illustrates changing the duty cycle of the second control signal so that the microprocessor 101 can adjust the atomization power of the atomization unit 106 in an increasing or decreasing manner, as shown in FIG. 2 As shown in FIG. 3 , the number of heating wires included in the atomization unit 106 is one, and this embodiment explains the adjustment of the atomization power by conducting the circuit paths between different numbers of heating wires and the battery 102 ;

As shown in Figure 4, the atomization unit 106 includes a plurality of heating wires 401 arranged in parallel, and the number of the switching unit 105 is equal to the number of the heating wires 401, so that each heating wire 401 is connected to each heating wire 401 Corresponding to the switch unit 105;

Please refer to Fig. 5 for the specific circuit connection structure, wherein Fig. 5 takes two heating wires 401 as an example for illustration, without limitation;

That is, one end of each heating wire 401 is electrically connected to the microprocessor 101, and the other end of each heating wire 401 is electrically connected to the microprocessor through the switch unit 105;

Wherein, the specific structure and function of each of the switch units 105 can be found in the above-mentioned embodiments, and will not be repeated in this embodiment.

The microprocessor 101 is also used to determine a first preset correspondence, the first preset correspondence includes the correspondence between each control signal generated by the microprocessor 101 and each switch unit 105, the microprocessor The control signal generated by the processor 101 is the first control signal or the second control signal, so that the microprocessor 101 determines to correspond to the generated control signal according to the first preset correspondence. The target switch unit, so that the microprocessor 101 conducts the circuit path between the heating wire 401 corresponding to the target switch unit and the battery 102 .

For example, when the user only inputs the first trigger operation, the microprocessor 101 determines the target switch unit according to the first preset correspondence relationship. Taking the number of the target switch unit as one example, the microprocessor 101 The processor 101 conducts the circuit path between the heating wire 401 corresponding to the target switch unit and the battery 102, so as to make one of the heating wires 401 work;

When the signal detection unit 104 receives the second trigger operation input by the user, the microprocessor 101 is further configured to generate a second control signal when the first preset condition is met, so that the the corresponding target switch unit;

Take the example shown in FIG. 5 , that is, when the microprocessor 101 determines to receive the first trigger operation, one of the heating wires 401 can be made to work, and when the microprocessor 101 determines to receive the a second trigger operation, and when the first preset condition is met, make the two heating wires 401 work;

Of course, the number of the heating wires 401 is not limited to two, as long as the microprocessor 101 determines that the greater the atomization power, the more heating wires 401 work to atomize the e-liquid.

In order to remind the user of the current working status of the electronic cigarette control circuit, as shown in FIG. 6 , the electronic cigarette control circuit further includes a prompt module 701, and the prompt module 701 is electrically connected to the microprocessor 101;

The prompting module 701 is used for correspondingly generating a prompting state according to the prompting signal sent by the microprocessor 101, and different prompting signals correspond to different prompting states;

The microprocessor 101 is also used to generate a second preset correspondence, the second preset correspondence includes the correspondence between each control signal generated by the microprocessor 101 and each prompt signal, and the microprocessor 101 The control signal generated by the controller 101 is the first control signal or the second control signal, so that the microprocessor 101 determines the target corresponding to the generated control signal according to the generated control signal The prompt signal enables the prompt module 701 to generate a prompt state corresponding to the target prompt signal to prompt the user.

This embodiment does not limit the specific structure of the prompt module 701, as long as the user can be given different prompts according to the prompt signal, so that the user can determine the current atomization unit 106 according to different prompt states The level of the atomization power is enough;

The following is described by taking the example shown in FIG. 7 as an example. It should be clear that the example shown in FIG. 7 is an illustration of this embodiment and is not limited;

Taking FIG. 7 as an example, the prompt module 701 can be a voice module 601 and a light module 602, and both the voice module 601 and the light module 602 are electrically connected to the microprocessor 101;

In a specific application scenario, the microprocessor 101 generates different prompt signals according to the atomization power of the atomization unit 106, so that the voice module 601 emits different sounds and the light module 602 emits different sounds. The lighting effect is not specifically limited in this embodiment.

Embodiment 4, this embodiment provides a method for controlling the generation of electronic cigarettes, so that the atomization power of the electronic cigarette can be changed without pressing buttons frequently through the method for controlling the generation of electronic cigarettes provided by this embodiment, effectively improving the Extended the service life of electronic cigarettes;

The specific steps of the method for controlling vaping provided by this embodiment will be described in detail below in conjunction with FIG. 8 :

It should be clarified that the electronic cigarette control method shown in this embodiment is based on the electronic cigarette control circuit shown in Embodiment 1. For the specific circuit connection structure of the electronic cigarette control circuit, please refer to the above-mentioned embodiment. , and will not be described in this embodiment.

801. The microprocessor determines whether the smoking trigger unit has received the first trigger operation input by the user, and if so, proceed to step 802;

If the microprocessor 101 determines that the smoking trigger unit 103 receives the first trigger operation, it means that the user wishes to inhale smoke; if the microprocessor 101 determines that the first trigger operation is not received, Then continue to detect whether the smoking trigger unit 103 receives the first trigger operation;

Wherein, the smoking trigger unit 103 is electrically connected to the battery 102 and the microprocessor 101 respectively;

More specifically, in this embodiment, the specific structure of the smoking trigger unit 103 is not limited, as long as the user wishes to smoke smoke, the first trigger operation can be input through the smoking trigger unit 103 to suck smoke, for example, The first triggering operation may be an action of sucking the smoking trigger unit 103 , and for example, the first triggering operation may be an action of pressing the smoking trigger unit 103 ;

802. The microprocessor determines whether the signal detection unit receives a second trigger operation input by the user. If not, proceed to step 803, if yes, proceed to step 805;

Wherein, the signal detection unit 104 is electrically connected to the battery 102 and the microprocessor 101 respectively;

The signal detection unit 104 is configured to receive a second trigger operation input by a user;

This embodiment does not limit the second trigger operation, for example, the second trigger operation is a press operation;

803. The microprocessor generates a first control signal;

It means that there is no need to change the atomization power of the atomization unit 106, and it is sufficient to generate the first control signal that does not change the atomization power of the atomization unit 106;

804. The microprocessor outputs the first control signal to a switch unit, and the switch unit is electrically connected to the microprocessor and the atomization unit respectively;

The switch unit 105 conducts the circuit path between the atomization unit 106 and the battery 102 according to the first control signal, so that the atomization unit 106 can atomize e-liquid to form smoke;

805. The microprocessor generates a second control signal when the first preset condition is met;

Wherein, the first preset condition is that the microprocessor 101 determines that the smoking trigger unit 103 receives the first trigger operation again, that is, when the user needs to inhale smoke again after inputting the second trigger operation, Then input the first trigger operation;

806. The microprocessor outputs the second control signal to the switch unit, so that the switch unit conducts the circuit path between the atomization unit and the battery according to the second control signal ;

The microprocessor 101 increases or decreases the atomization power of the atomization unit 106 through the second control signal.

For the specific implementation process, please refer to Embodiment 1, which will not be repeated in this embodiment;

Optionally, after step 804 or step 806 is performed, step 807 may also be performed, wherein the microprocessor generates a second preset correspondence;

The second preset corresponding relationship includes the corresponding relationship between each control signal generated by the microprocessor 101 and each prompt signal, and the control signal generated by the microprocessor is the first control signal or the second 2. Control signals;

For the specific circuit structure and implementation principle, please refer to the above-mentioned embodiments, which will not be repeated here;

808. The microprocessor determines the generated control signal according to the generated control signal The target prompt signal corresponding to the signal;

809. The microprocessor sends the target prompt signal to a prompt module.

The prompting module is electrically connected to the microprocessor, and the prompting module is used to correspondingly generate prompting states according to the prompting signals sent by the microprocessor, and different prompting signals correspond to different prompting states, so that the The prompting module correspondingly generates a prompting state according to the target prompting signal to prompt the user.

It can be seen that, by adopting the electronic cigarization control method shown in this embodiment, when the user wishes to inhale smoke with a changed amount of smoke, he only needs to input the second trigger operation once, and the microprocessor will 101 can generate a second control signal according to the second trigger operation input by the user, and whenever the first preset condition is met, the microprocessor 101 can control the mist through the second control signal The atomization power of the atomization unit 106 is incremented or decremented each time with the same amplitude, and the user does not need to operate the signal detection unit 104 for many times, thus effectively avoiding the signal detection unit 104 being triggered by the signal detection unit 104 multiple times. Poor contact with the microprocessor 101 effectively guarantees the service life of the electronic cigarette control circuit.

Embodiment 5, this embodiment explains in detail how the electronic atomization control method realizes changing the atomization power of the atomization unit 106;

First of all, as shown in FIG. 9 , how the electronic atomization control method provided in this embodiment realizes the adjustment of the atomization power in an incremental manner will be described in detail:

901. The microprocessor determines whether the smoking trigger unit receives the first trigger operation input by the user, and if so, proceed to step 902;

902. The microprocessor determines whether the signal detection unit has received the second trigger operation input by the user, if not, proceed to step 903, and if yes, proceed to step 905;

903. The microprocessor generates a first control signal;

904. The microprocessor outputs the first control signal to a switch unit, and the switch unit is electrically connected to the microprocessor and the atomization unit respectively;

Wherein, for the specific process of step 901 to step 904, please refer to step 801 to step 804 shown in FIG. 8 for details, and details will not be described in this embodiment;

905. When the microprocessor determines to change the atomization power of the atomization unit in an incremental manner, the microprocessor determines a preset increment;

In this embodiment, there is no limitation on how the microprocessor determines to change the atomization power of the atomization unit in an incremental manner;

906. When the first preset condition is met, the microprocessor determines a first target control signal;

Wherein, the first target control signal is the control signal sent by the microprocessor 101 to the switch unit 105 last time;

The control signal sent by the microprocessor 101 to the switch unit 105 last time is the first control signal or the second control signal;

For details, please refer to the above-mentioned embodiments, which will not be repeated here;

907. The microprocessor determines whether the duty cycle of the first target control signal is greater than or equal to a first preset value, if not, proceed to step 908, and if yes, proceed to step 909;

Wherein, when the duty cycle of the first target control signal is greater than or equal to the first preset value, the atomization unit 106 is made to atomize the e-liquid with a power greater than or equal to the first preset value. When the duty cycle of the first target control signal is less than the first preset value, the atomization unit 106 is made to atomize the e-liquid with less than the first preset power;

The first preset power is the maximum atomization power of the atomization unit;

908. The microprocessor adds the preset increment to the duty cycle of the first target control signal to generate the second control signal;

909. The microprocessor generates a second control signal for enabling the atomization unit to atomize with a second preset power, where the second preset power is the minimum atomization power of the atomization unit;

After the completion of the first target control signal as determined by step 908 or step 909, proceed to step 910, the microprocessor outputs the second control signal to the switch unit, so that the switch unit The second control signal conducts the circuit path between the atomization unit and the battery;

In the following, as shown in FIG. 10 , a detailed description will be given of how the electronic atomization control method provided in this embodiment realizes the adjustment of the atomization power in a decreasing manner:

1001. The microprocessor determines whether the smoking trigger unit has received the first trigger operation input by the user, and if so, proceed to step 1002;

1002. The microprocessor determines whether the signal detection unit has received the second trigger operation input by the user, if not, proceed to step 1003, and if yes, proceed to step 1005;

1003. The microprocessor generates a first control signal;

1004. The microprocessor outputs the first control signal to a switch unit, and the switch unit is electrically connected to the microprocessor and the atomization unit respectively;

Wherein, for the specific process from step 1001 to step 1004, please refer to step 901 to step 9 shown in FIG. As shown in step 904, details are not described in this embodiment;

1005. When the microprocessor determines to change the atomization power of the atomization unit in a decreasing manner, the microprocessor determines a preset decrement;

In this embodiment, there is no limitation on how the microprocessor determines to change the atomization power of the atomization unit in a decreasing manner;

1006. When the first preset condition is met, the microprocessor determines a second target control signal;

The second target control signal is the control signal sent by the microprocessor to the switch unit last time, wherein the control signal sent by the microprocessor to the switch unit last time is the first control signal or the second control signal;

1007. The microprocessor determines whether the duty cycle of the second target control signal is greater than a second preset value, if yes, proceed to step 1008, and if not, proceed to step 1009;

When the duty cycle of the second target control signal is greater than the second preset value, the atomization unit 106 is made to atomize the e-liquid with a power greater than the second preset value;

When the duty cycle of the second target control signal is less than or equal to the second preset value, the atomization unit 106 is made to atomize the e-liquid with less than or equal to the second preset power;

Wherein, the second preset power is the minimum atomization power of the atomization unit;

1008. The microprocessor reduces the preset decrement on the duty cycle of the second target control signal to generate the second control signal;

1009. The microprocessor generates a second control signal for enabling the atomization unit to atomize with a first preset power, where the first preset power is the maximum atomization power of the atomization unit.

After completing the second target control signal determined by step 1008 or step 1009, proceed to step 1010, the microprocessor outputs the second control signal to the switch unit, so that the switch unit The second control signal conducts the circuit path between the atomization unit and the battery;

If the concentration of the smoke atomized by the atomization unit 106 last time is more suitable for the taste of the user, and the user wishes to continue to smoke at the concentration of the smoke drawn last time when the user wishes to smoke smoke in the future, the present embodiment will be described below A detailed description of how the provided electronic atomization control method realizes fixing the atomization power of the atomization unit 106;

This embodiment provides two methods, the first one is shown in Figure 11, and the specific circuit structure is shown in Embodiment 1 to Embodiment 2, and this embodiment will not repeat them;

1101. The microprocessor determines whether the smoking trigger unit has received the first trigger operation input by the user, and if so, proceed to step 1102;

1102. The microprocessor determines whether the signal detection unit has received the second trigger operation input by the user, if not, proceed to step 1103, and if yes, proceed to step 1105;

1103. The microprocessor generates a first control signal;

1104. The microprocessor outputs the first control signal to a switch unit, and the switch unit is electrically connected to the microprocessor and the atomization unit respectively;

1105. The microprocessor generates a second control signal when the first preset condition is met;

1106. The microprocessor outputs the second control signal to the switch unit, so that the switch unit conducts the circuit path between the atomization unit and the battery according to the second control signal ;

For the specific implementation process of step 1101 to step 1106 in this embodiment, please refer to step 801 to step 806, and details will not be repeated here;

1107. The microprocessor determines a third target control signal when the second preset condition is met;

The second preset condition is that the microprocessor 101 determines that the signal detection unit 104 receives the second trigger operation again;

The third target control signal is the second control signal sent by the microprocessor 101 to the switch unit 105 last time;

1108. If the microprocessor determines that the first preset condition is met, the microprocessor outputs the third target control signal to the switch unit, so that the switch unit The target control signal conducts the circuit path between the atomization unit and the battery.

The first kind is shown in Figure 12, and the specific circuit structure is shown in Embodiment 1 to Embodiment 2, and will not be repeated in this embodiment;

1201. The microprocessor determines whether the smoking trigger unit has received the first trigger operation input by the user, and if so, proceed to step 1202;

1202. The microprocessor determines whether the signal detection unit has received the second trigger operation input by the user, if not, proceed to step 1203, and if yes, proceed to step 1205;

Wherein, the signal detection unit 104 shown in this embodiment includes a first detection subunit and a second detection subunit arranged in parallel;

Specifically, the microprocessor 101 determines that the first detection subunit has received the button input by the user. When the press operation is performed, the microprocessor 101 determines that the signal detection unit 104 has received a second trigger operation input by the user;

When the microprocessor 101 determines that the first detection subunit does not receive a user-input pressing operation, then the microprocessor 101 determines that the signal detection unit 104 does not receive a user-input second trigger operation;

1203. The microprocessor generates a first control signal;

1204. The microprocessor outputs the first control signal to a switch unit, and the switch unit is electrically connected to the microprocessor and the atomization unit;

1205. The microprocessor generates a second control signal when the first preset condition is met;

1206. The microprocessor outputs the second control signal to the switch unit, so that the switch unit conducts the circuit path between the atomization unit and the battery according to the second control signal ;

For the specific implementation process of steps 1201 to 1206 in this embodiment, please refer to steps 1101 to 1106, and details will not be repeated here;

1207. The microprocessor determines a third target control signal when a second preset condition is met, and the second preset condition is that the microprocessor determines that the second detection subunit receives a user-input press operation ;

The third target control signal is the second control signal sent by the microprocessor 101 to the switch unit last time;

1208. If the microprocessor determines that the first preset condition is met, the microprocessor outputs the third target control signal to the switch unit, so that the switch unit The target control signal conducts the circuit path between the atomization unit and the battery.

Embodiment 6, this embodiment In this embodiment, in conjunction with what is shown in FIG. 13 , another way of changing the smoke concentration in the electronic vaping control method is described;

Its circuit structure can be seen in Embodiment 3 in detail, and will not be described in detail in this embodiment;

1301. The microprocessor determines a first preset correspondence relationship;

The first preset correspondence includes the correspondence between each control signal generated by the microprocessor 101 and each switch unit;

1302. The microprocessor determines whether the smoking trigger unit has received the first trigger operation input by the user, and if so, proceed to step 1303;

Further, there are two ways to implement step 1301. For the specific circuit connection structure, please refer to Embodiment 2, and details will not be repeated here;

The first type: the smoking trigger unit is an airflow sensor, and the smoking trigger unit is electrically connected to the battery and the microprocessor respectively, then the microprocessor determines whether the smoking trigger unit has received a user input First trigger actions include:

The microprocessor determines whether a trigger signal is received, the trigger signal is generated by the airflow sensor when the first trigger operation is received, and the first trigger operation is an operation of pumping by the user;

If so, the microprocessor determines that the smoking trigger unit has received the first trigger operation input by the user;

If not, the microprocessor determines that the smoking trigger unit has not received the first trigger operation input by the user;

The second type: the smoking trigger unit is a first button switch, and the smoking trigger unit is electrically connected to the battery and the microprocessor respectively, then the microprocessor determines whether the smoking trigger unit receives user input The first trigger actions include:

The microprocessor determines whether the circuit between the microprocessor and the battery is conductive, the first trigger operation is a press operation, and the first key switch is used to receive the first trigger operation turn on the circuit path between the microprocessor and the battery;

If so, the microprocessor determines that the smoking trigger unit has received a first trigger operation input by the user;

If not, the microprocessor determines that the smoking trigger unit has not received the first trigger operation input by the user.

More specifically, the atomization unit includes a plurality of electric heating wires arranged in parallel, and the number of the switching units is equal to the number of the electric heating wires, so that each of the electric heating wires corresponds to each of the switching units, and each of the switching units One end of the heating wire is electrically connected to the microprocessor, and the other end of each heating wire is electrically connected to the microprocessor through the switch unit;

1303. The microprocessor determines whether the signal detection unit has received the second trigger operation input by the user, if not, proceed to step 1304, and if yes, proceed to step 1307;

1304. The microprocessor generates a first control signal;

1305. The microprocessor determines a first target switch unit corresponding to the first control signal according to the first preset correspondence;

1306. The microprocessor outputs the first control signal to the first target switch unit, so that the first target switch unit is turned on with the first target switch unit according to the first control signal The circuit path between the corresponding atomization unit and the battery;

1307. The microprocessor generates a second control signal when the first preset condition is met;

1308. The microprocessor determines a second target switch unit corresponding to the second control signal according to the first preset correspondence, so that the second target switch unit is turned on according to the second control signal A circuit path between the atomization unit corresponding to the second target switch unit and the battery.

Those skilled in the art can clearly understand that for the convenience and brevity of the description, the specific working process of the above-described system, device and unit can refer to the corresponding process in the foregoing method embodiment, which will not be repeated here.

The above embodiments are only used to illustrate the technical solutions of the present invention, rather than to limit them; although the present invention has been described in detail with reference to the foregoing embodiments, those of ordinary skill in the art should understand that: it can still be described in the foregoing embodiments Modifications are made to the recorded technical solutions, or equivalent replacements are made to some of the technical features; and these modifications or replacements do not make the essence of the corresponding technical solutions deviate from the spirit and scope of the technical solutions of the embodiments of the present invention.

Claims (17)

1. A kind of electronic cigarette control circuit, which is characterized in that including battery, smoking trigger unit, microprocessor, switch unit, detecting signal unit and atomization unit；

   The smoking trigger unit is electrically connected with the battery and the microprocessor respectively, and the smoking trigger unit is used to receive the first trigger action of user's input；

   The switch unit is electrically connected with the microprocessor and the atomization unit respectively, and the microprocessor is used for if it is determined that the smoking trigger unit receives first trigger action, then the microprocessor generates first control signal, and the microprocessor exports the first control signal to the switch unit, the switch unit is used to according to the first control signal circuit pathways between the atomization unit and the battery be connected so that the atomization unit can atomization smoke oil to form smog；

   The detecting signal unit is electrically connected with the battery and the microprocessor respectively, the detecting signal unit is used to receive the second trigger action of user's input, the microprocessor is also used to generate second control signal in the case where meeting the first preset condition, and the second control signal is exported to the switch unit, so that the circuit pathways between the atomization unit and the battery are connected according to the second control signal for the switch unit, the microprocessor is used to change the atomization power of the atomization unit in a manner of increasing or decreasing the second control signal, first preset condition is that the microprocessor determines that the smoking trigger unit receives first trigger action again.
2. Electronic cigarette control circuit according to claim 1, which is characterized in that

   The smoking trigger unit is air flow sensor, first trigger action is the operation of user's suction, the air flow sensor is for generating trigger signal when receiving first trigger action, so that the generated trigger signal is sent to the microprocessor by the air flow sensor, the microprocessor is used to generate the first control signal or the second control signal according to the trigger signal；

   Or,

   The smoking trigger unit is the first key switch, first trigger action is pressing operation, first key switch is used to that the circuit pathways between the microprocessor and the battery to be connected when receiving first trigger action, so that the microprocessor generates the first control signal or the second control signal.
3. Electronic cigarette control circuit according to claim 1, it is characterized in that, the switch unit includes first resistor and the first triode, one end of the first resistor is electrically connected with the microprocessor, the other end of the first resistor is electrically connected with one end of first triode, first triode it is another End is electrically connected with the atomization unit.
4. Electronic cigarette control circuit according to claim 1, it is characterized in that, the detecting signal unit is the second key switch and second resistance, one end of the second resistance is electrically connected with the microprocessor, the other end of the second resistance is electrically connected with the battery, one end of second key switch is electrically connected with the microprocessor, and the other end of second key switch is electrically connected with the battery；

   The microprocessor is also used to determine preset increments, when so that the detecting signal unit having received the second trigger action of user's input and meets first preset condition, the microprocessor is for determining that first object controls signal, the first object control signal is the control signal for the microprocessor last time being sent to the switch unit, wherein, the control signal that the microprocessor last time is sent to the switch unit is the first control signal or the second control signal, the microprocessor is also used to determine whether the duty ratio of the first object control signal is greater than or equal to the first preset value, when the duty ratio of first object control signal is greater than or equal to first preset value, the atomization unit is to be greater than or equal to the first predetermined power atomization smoke oil, when the duty ratio of first object control signal When less than first preset value, the atomization unit is to be less than the first predetermined power atomization smoke oil, wherein first predetermined power is the maximum atomization power of the atomization unit；If it is not, then the microprocessor increases the preset increments in the duty ratio of first object control signal to generate the second control signal；It is used for if so, the microprocessor generates so that the second control signal that the atomization unit is atomized with the second predetermined power, second predetermined power are the minimum atomization power of the atomization unit.
5. Electronic cigarette control circuit according to claim 1, it is characterized in that, the detecting signal unit is the second key switch and second resistance, one end of the second resistance is electrically connected with the microprocessor, the other end of the second resistance is electrically connected with the battery, one end of second key switch is electrically connected with the microprocessor, and the other end of second key switch is electrically connected with the battery；

   The microprocessor is also used to determine default decrement, when so that the detecting signal unit having received the second trigger action of user's input and meets first preset condition, the microprocessor is for determining the second target control signal, second target control signal is the control signal for the microprocessor last time being sent to the switch unit, wherein, it is the first control signal or the second control signal that the microprocessor last time, which is sent to the control signal of the switch unit,；The microprocessor is also used to determine whether the duty ratio of second target control signal is greater than the second preset value, when the duty ratio of second target control signal is greater than second preset value, the atomization unit is to be greater than the second predetermined power atomization smoke oil, when the duty ratio of second target control signal is less than or equal to second preset value, the atomization unit is to be less than Or it is equal to the second predetermined power atomization smoke oil, wherein second predetermined power is the minimum atomization power of the atomization unit；If so, the microprocessor reduces the default decrement in the duty ratio of second target control signal to generate the second control signal；If it is not, then the microprocessor is generated for so that the second control signal that the atomization unit is atomized with the first predetermined power, first predetermined power are the maximum atomization power of the atomization unit.
6. Electronic cigarette control circuit according to claim 1, it is characterized in that, the detecting signal unit includes the first detection sub-unit and the second detection sub-unit being arranged in parallel, first detection sub-unit includes third key switch and 3rd resistor, and second detection sub-unit includes the 4th key switch and the 4th resistance；

   One end of the 3rd resistor is electrically connected with the microprocessor, the other end of the 3rd resistor is electrically connected with the battery, one end of the third key switch is electrically connected with the microprocessor, the other end of the third key switch is electrically connected with the battery, the third key switch is used to receive the pressing operation of user's input, if the microprocessor is for determining that the third key switch receives the pressing operation, then the microprocessor determines that the detecting signal unit receives second trigger action of user's input, if the microprocessor is also used to determine that the third key switch is not received by the pressing operation, then the microprocessor determines that the detecting signal unit is not received by second trigger action of user's input；

   One end of 4th resistance is electrically connected with the battery, the other end of 4th resistance is electrically connected with the microprocessor, one end of 4th key switch is electrically connected with the battery, the other end of 4th key switch is electrically connected with the microprocessor, and the 4th switch is for receiving the pressing operation of user's input, the microprocessor is for determining when the 4th switch receives the pressing operation, it then determines and meets the second preset condition, the microprocessor is also used to determine third target control signal in the case where meeting the second preset condition, the third target control signal is the second control signal for the microprocessor last time being sent to the switch unit；If the microprocessor determination meets first preset condition, then the microprocessor exports the third target control signal to the switch unit, so that the circuit pathways between the atomization unit and the battery are connected according to the third target control signal for the switch unit.
7. Electronic cigarette control circuit according to claim 1, it is characterized in that, the atomization unit includes multiple heating wire being arranged in parallel, and the number of the switch unit is equal with the number of the heating wire, so that each heating wire is corresponding with each switch unit；

   One end of each heating wire is electrically connected with the microprocessor, and the other end of each heating wire is electrically connected by the switch unit with the microprocessor；

   The microprocessor is also used to determine the first default corresponding relationship, the first default corresponding relationship includes the corresponding relationship of the microprocessor each control signal and each switch unit generated, the microprocessor control signal generated is the first control signal or the second control signal, so that the microprocessor is according to the determining target switch unit corresponding with the generated control signal of the described first default corresponding relationship, so that the circuit pathways between microprocessor conducting heating wire corresponding with the target switch unit and the battery.
8. Electronic cigarette control circuit according to claim 1, it is characterized in that, the electronic cigarette control circuit further includes cue module, the cue module is electrically connected with the microprocessor, the cue module is for the corresponding generation prompt state of the standby signal according to transmitted by the microprocessor, and different standby signals corresponds to different prompt states；

   The microprocessor is also used to generate the second default corresponding relationship, the second default corresponding relationship includes the corresponding relationship of the microprocessor each control signal and each standby signal generated, the microprocessor control signal generated is the first control signal or the second control signal, so that the microprocessor is according to the determining target prompting signal corresponding with the generated control signal of the generated control signal, so that the cue module is by target prompting signal correspondence generation prompt state to prompt user.
9. Electronic cigarette control circuit according to claim 8, which is characterized in that the cue module is light modules and/or voice module.
10. A kind of electronic cigarette atomizing control method characterized by comprising

    Microprocessor determines whether smoking trigger unit receives the first trigger action of user's input, and the smoking trigger unit is electrically connected with battery and the microprocessor respectively；

    If so, the microprocessor determines whether detecting signal unit receives the second trigger action of user's input, the detecting signal unit is electrically connected with the battery and the microprocessor respectively；

    If it is not, then the microprocessor generates first control signal；

    The microprocessor exports the first control signal to switch unit, the switch unit is electrically connected with the microprocessor and atomization unit respectively, so that the circuit pathways between the atomization unit and battery are connected according to the first control signal for the switch unit so that the atomization unit can atomization smoke oil to form smog；

    If so, the microprocessor generates second control signal in the case where meeting the first preset condition, first preset condition is that the microprocessor determines that the smoking trigger unit receives first trigger action again；

    The microprocessor exports the second control signal to the switch unit, so that the circuit pathways between the atomization unit and the battery are connected according to the second control signal for the switch unit, to make the microprocessor change by the second control signal atomization power of the atomization unit in a manner of increasing or decreasing.
11. Electronic cigarette atomizing control method according to claim 10, which is characterized in that the microprocessor is generated in the case where meeting the first preset condition before second control signal, which comprises

    When the microprocessor, which determines, incrementally changes the atomization power of the atomization unit, the microprocessor determines preset increments；

    The microprocessor generates second control signal in the case where meeting the first preset condition

    When meeting first preset condition, the microprocessor determines that first object controls signal, the first object control signal is the control signal for the microprocessor last time being sent to the switch unit, wherein, it is the first control signal or the second control signal that the microprocessor last time, which is sent to the control signal of the switch unit,；

    The microprocessor determines whether the duty ratio of the first object control signal is greater than or equal to the first preset value, when the duty ratio of first object control signal is greater than or equal to first preset value, make the atomization unit then to be greater than or equal to the first predetermined power atomization smoke oil, when the duty ratio of first object control signal is less than first preset value, make the atomization unit then to be less than the first predetermined power atomization smoke oil, wherein, first predetermined power is the maximum atomization power of the atomization unit；

    If it is not, then the microprocessor increases the preset increments in the duty ratio of first object control signal to generate the second control signal；

    It is used for if so, the microprocessor generates so that the second control signal that the atomization unit is atomized with the second predetermined power, second predetermined power are the minimum atomization power of the atomization unit.
12. Electronic cigarette atomizing control method according to claim 10, which is characterized in that the microprocessor is generated in the case where meeting the first preset condition before second control signal, which comprises

    When the microprocessor determines the atomization power for changing the atomization unit with decreasing fashion, the microprocessor determines default decrement；

    The microprocessor generates second control signal in the case where meeting the first preset condition

    When meeting first preset condition, the microprocessor determines the second target control signal, second target control signal is the control signal for the microprocessor last time being sent to the switch unit, wherein, the microprocessor last time be sent to the switch unit control signal be the first control signal or The second control signal；

    The microprocessor determines whether the duty ratio of second target control signal is greater than the second preset value, when the duty ratio of second target control signal is greater than second preset value, make the atomization unit then to be greater than the second predetermined power atomization smoke oil, when the duty ratio of second target control signal is less than or equal to second preset value, make the atomization unit then to be less than or equal to the second predetermined power atomization smoke oil, wherein, second predetermined power is the minimum atomization power of the atomization unit；

    If so, the microprocessor reduces the default decrement in the duty ratio of second target control signal to generate the second control signal；

    If it is not, then the microprocessor is generated for so that the second control signal that the atomization unit is atomized with the first predetermined power, first predetermined power are the maximum atomization power of the atomization unit.
13. Electronic cigarette atomizing control method according to claim 10, which is characterized in that

    The smoking trigger unit is air flow sensor, and the smoking trigger unit is electrically connected with the battery and the microprocessor respectively, then the microprocessor determines whether smoking trigger unit receives the first trigger action that user inputs and include:

    The microprocessor determines whether to receive trigger signal, trigger signal generation when receiving first trigger action by the air flow sensor, the operation that first trigger action aspirates for user；

    If so, the microprocessor determines that the smoking trigger unit receives first trigger action of user's input；

    If it is not, then the microprocessor determines that the smoking trigger unit is not received by first trigger action of user's input；

    Or,

    The smoking trigger unit is the first key switch, and the smoking trigger unit is electrically connected with the battery and the microprocessor respectively, then the microprocessor determines whether smoking trigger unit receives the first trigger action that user inputs and include:

    The microprocessor determines whether the circuit between the microprocessor and the battery is connected, first trigger action is pressing operation, and first key switch is used to that the circuit pathways between the microprocessor and the battery to be connected when receiving first trigger action；

    If so, the microprocessor determines that the smoking trigger unit receives the first trigger action of user's input；

    If it is not, then the microprocessor determines that the smoking trigger unit is not received by the first of user's input Trigger action.
14. Electronic cigarette atomizing control method according to claim 10, which is characterized in that the microprocessor exports the second control signal to after the switch unit, the method also includes:

    The microprocessor determines third target control signal in the case where meeting the second preset condition, second preset condition is that the microprocessor determines that the detecting signal unit receives second trigger action again, and the third target control signal is the second control signal for the microprocessor last time being sent to the switch unit；

    If the microprocessor determination meets first preset condition, then the microprocessor exports the third target control signal to the switch unit, so that the circuit pathways between the atomization unit and the battery are connected according to the third target control signal for the switch unit.
15. Electronic cigarette atomizing control method according to claim 10, which is characterized in that the detecting signal unit includes the first detection sub-unit and the second detection sub-unit being arranged in parallel；

    The microprocessor determines whether detecting signal unit receives the second trigger action that user inputs and include:

    When the microprocessor determines that first detection sub-unit receives the pressing operation of user's input, then the microprocessor determines that the detecting signal unit receives the second trigger action of user's input；

    When the microprocessor determines that first detection sub-unit is not received by the pressing operation of user's input, then the microprocessor determines that the detecting signal unit is not received by the second trigger action of user's input；

    The microprocessor exports the second control signal to after the switch unit, the method also includes:

    The microprocessor determines third target control signal in the case where meeting the second preset condition, second preset condition is that the microprocessor determines that second detection sub-unit receives the pressing operation of user's input, and the third target control signal is the second control signal for the microprocessor last time being sent to the switch unit；

    If the microprocessor determination meets first preset condition, then the microprocessor exports the third target control signal to the switch unit, so that the circuit pathways between the atomization unit and the battery are connected according to the third target control signal for the switch unit.
16. Electronic cigarette atomizing control method according to claim 10, which is characterized in that the atomization unit includes multiple heating wire being arranged in parallel, and the number of the number of the switch unit and the heating wire Mesh is equal, so that each heating wire is corresponding with each switch unit, one end of each heating wire is electrically connected with the microprocessor, and the other end of each heating wire is electrically connected by the switch unit with the microprocessor；

    The method also includes:

    The microprocessor determines that the first default corresponding relationship, the first default corresponding relationship include the corresponding relationship of the microprocessor each control signal and each switch unit generated；

    The microprocessor exports the first control signal

    The microprocessor determines first object switch unit corresponding with the first control signal according to the described first default corresponding relationship；

    The microprocessor exports the first control signal to the first object switch unit, so that the circuit pathways between atomization unit corresponding with the first object switch unit and battery are connected according to the first control signal for the first object switch unit；

    The microprocessor exports the second control signal

    The microprocessor determines the second target switch unit corresponding with the second control signal according to the described first default corresponding relationship, so that the circuit pathways between atomization unit corresponding with the second target switch unit and battery are connected according to the second control signal for the second target switch unit.
17. Electronic cigarette atomizing control method according to claim 10, which is characterized in that the method also includes:

    The microprocessor generates the second default corresponding relationship, the second default corresponding relationship includes the corresponding relationship of the microprocessor each control signal and each standby signal generated, and the microprocessor control signal generated is the first control signal or the second control signal；

    The microprocessor is according to the determining target prompting signal corresponding with the generated control signal of the generated control signal；

    The target prompting signal is sent to cue module by the microprocessor, the cue module is electrically connected with the microprocessor, the cue module is for the corresponding generation prompt state of the standby signal according to transmitted by the microprocessor, and different standby signals corresponds to different prompt states, so that the cue module is according to the corresponding prompt state that generates of the target prompting signal to prompt user.