CN110839963A - Starting method of control module of intelligent atomization device - Google Patents

Abstract

The invention discloses a starting method of a control module of an intelligent atomization device, which belongs to the field of atomization devices, wherein the intelligent atomization device comprises a Bluetooth controller and an acceleration sensing module, the Bluetooth controller is electrically connected with the acceleration sensing module to acquire acceleration data fed back by the acceleration sensing module, the Bluetooth controller comprises a dormant state and a working state, the dormant state only monitors signals of the acceleration sensing module, and the working state starts all functional modules; the acceleration sensing module judges whether the acquired acceleration data exceeds a set threshold value, and if so, the Bluetooth controller is started to enter a working state from a dormant state. The invention can effectively shorten the response time of the atomization device Bluetooth controller, improve the working efficiency of the atomization device Bluetooth controller and reduce the power consumption of the Bluetooth controller.

Description

Starting method of control module of intelligent atomization device

Technical Field

The invention relates to the field of atomization devices, in particular to a starting method of a control module of an intelligent atomization device.

Background

The basic working principle of the atomization device is that heat is generated by power supply of a battery, and smoke is generated by atomizing smoke oil of the atomization device. The atomization device consists of a main control chip, a battery, a key, an LED breathing lamp and an atomizer. The scheme that the traditional MCU is used for externally hanging a motor, an LED indicator light, an OLED screen, a microphone, a heating rod, a heating wire and other peripheral circuits according to different product requirements to form the whole control circuit becomes the conventional idea of the control circuit of the atomization device. The atomization device product can be added with additional functions of geographic position positioning, user identity authentication, automatic circuit disconnection, communication establishment with a smart phone and the like. Accordingly, it is desirable to add bluetooth, gravity sensors, positioners, and device locking modules to existing atomization device products.

Add multiple functional module in the atomizing device product, undoubtedly greatly increased the power consumption of atomizing device in the use, atomizing device originally will consume completely soon just not enough electric quantity. In addition to bringing the inconvenience of charging for many times for the user, the atomization effect of the atomizer part of the atomization device on the tobacco tar can be influenced, and even the safety problem of unstable voltage of the atomization device is generated. Therefore, how to effectively start the bluetooth controller of the atomization device, shorten the response time of the bluetooth controller, and reduce the power consumption of the bluetooth controller becomes a technical problem to be solved urgently in the field of atomization devices.

Disclosure of Invention

The invention provides a starting method of an intelligent atomization device control module, which can effectively shorten the response time of an atomization device Bluetooth controller, improve the working efficiency of the atomization device Bluetooth controller and reduce the power consumption of the Bluetooth controller.

The technical scheme of the invention is realized as follows:

a starting method of an intelligent atomization device control module is realized based on an intelligent atomization device, the intelligent atomization device comprises a Bluetooth controller and an acceleration sensing module, the Bluetooth controller is electrically connected with the acceleration sensing module to acquire acceleration data fed back by the acceleration sensing module, the Bluetooth controller comprises a dormant state and a working state, the dormant state only monitors signals of the acceleration sensing module, and the working state starts all functional modules; the method specifically comprises the following steps:

s1, the acceleration sensing module acquires acceleration data of the intelligent atomization device;

s2, judging whether the acquired acceleration data exceed the set threshold, if yes, executing the next step, otherwise, returning to the step S1;

and S3, starting the Bluetooth controller to enable the Bluetooth controller to enter the working state from the dormant state.

As a preferred starting method of the intelligent atomization device control module in the present invention, step S2 specifically includes the following steps:

s21, judging whether the acquired acceleration data exceed the set threshold, if yes, executing the next step, otherwise, returning to the step S1;

s22, the acceleration sensing module starts to record the change mode of the acceleration of the atomization device, wherein the change mode of the acceleration of the atomization device comprises but is not limited to the acceleration, the direction and the frequency;

and S23, judging whether the obtained acceleration change mode is consistent with the preset change mode, if so, executing a step S3, otherwise, keeping the Bluetooth controller in a dormant state.

As a preferred starting method of the control module of the intelligent atomization device, the Bluetooth controller is respectively connected with a controllable switch combined module and a current detection module, the output end of the controllable switch combined module is connected with an atomizer interface, and the current detection module detects the current value of the output end of the controllable switch combined module and feeds the current value back to the Bluetooth controller.

As a preferred starting method of the control module of the intelligent atomization device, the controllable switch combination module comprises a switch Q1 and a MOS tube Q2, an input pin of the switch Q1 is connected with the positive electrode of a power supply, a gate of the MOS tube Q2 is connected with the bluetooth controller through a resistor R19, a drain of the MOS tube Q2 is connected with a control pin of the switch Q1, a source of the MOS tube Q2 is grounded, and an electron R14 is connected between the input pin and the control pin of the switch Q1.

As a preferred starting method of the control module of the intelligent atomization device, the current detection module comprises a resistor R11 and a current detection chip, the resistor R11 is connected in series with the positive electrode output end of the controllable switch combination module, and the current detection chip detects the value of current flowing through the resistor R11.

As a preferred starting method of the control module of the intelligent atomization device, a heating wire for supplying heat to the atomizer is fixed at the interface of the atomizer.

As the preferable starting method of the intelligent atomization device control module, the Bluetooth controller is further connected with an RGB lamp.

As a preferred starting method of the control module of the intelligent atomization device, the bluetooth controller is further connected with a voltage stabilizer, and the acceleration sensing module is electrically connected with the voltage stabilizer.

As a preferable starting method of the intelligent atomization device control module, the Bluetooth controller is further connected with an atomization device air pressure sensor.

The invention has the beneficial effects that: the response time of the atomization device Bluetooth controller can be effectively shortened, the working efficiency of the atomization device Bluetooth controller is improved, and the power consumption of the Bluetooth controller is reduced.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a flowchart of an embodiment of a method for starting an intelligent electronic cigarette control module according to the present invention;

figure 2 is a flow chart of another embodiment of a method for starting an intelligent electronic cigarette control module according to the present invention;

figure 3 is a functional block diagram of an intelligent electronic cigarette;

figure 4 is a schematic circuit diagram of an intelligent electronic cigarette;

fig. 5 is a flowchart illustrating an exemplary method of activating the control module of the intelligent air humidifier according to the present invention;

fig. 6 is a flowchart illustrating another exemplary method of activating the control module of the intelligent air humidifier according to the present invention;

fig. 7 is a functional block diagram of an intelligent air humidifier;

fig. 8 is a schematic circuit diagram of an intelligent air humidifier;

FIG. 9 is a flowchart illustrating an exemplary method for activating a control module of an intelligent aerosol treatment apparatus;

FIG. 10 is a flowchart illustrating another exemplary method for activating the control module of the intelligent aerosol treatment apparatus;

FIG. 11 is a schematic block diagram of an intelligent aerosol treatment apparatus;

fig. 12 is a schematic circuit diagram of the intelligent atomization therapeutic apparatus.

In the figure, 1-bluetooth controller; 2-a controllable switch combined module; 3-a current detection module; 4-atomizer interface; 5-RGB lamp; 6-an acceleration sensing module; 7-voltage stabilizer.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it should also be noted that, unless otherwise explicitly specified or limited, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

The invention provides a starting method of an intelligent atomization device control module, which is realized based on an intelligent atomization device, wherein the atomization device can be equipment for realizing atomization functions of an electronic cigarette, an air humidifier, an atomization therapeutic apparatus and the like, the intelligent atomization device comprises a Bluetooth controller and an acceleration sensing module, the Bluetooth controller is electrically connected with the acceleration sensing module to acquire acceleration data fed back by the acceleration sensing module, the Bluetooth controller comprises a dormant state and a working state, the dormant state only monitors signals of the acceleration sensing module, and the working state starts all functional modules; compared with the prior art, the technical scheme disclosed in the application realizes the high-efficient start-up of atomizing device bluetooth module, has improved atomizing device bluetooth module's work efficiency to atomizing device bluetooth module's power consumption has been saved. Meanwhile, the method can be applied to the scene of identity authentication of the user of the atomization device, and the atomization device product is effectively prevented from being used by specific people such as children.

Example one

As shown in fig. 1 and 2, the invention provides a method for starting an intelligent electronic cigarette control module, which is implemented based on an intelligent electronic cigarette, wherein the intelligent electronic cigarette comprises a bluetooth controller and an acceleration sensing module, the bluetooth controller is electrically connected with the acceleration sensing module to acquire acceleration data fed back by the acceleration sensing module, the bluetooth controller comprises a sleep state and a working state, the sleep state only monitors signals of the acceleration sensing module, and the working state starts all functional modules; the method specifically comprises the following steps:

s1, the acceleration sensing module acquires acceleration data of the intelligent electronic cigarette;

s2, judging whether the acquired acceleration data exceed the set threshold, if yes, executing the next step, otherwise, returning to the step S1;

and S3, starting the Bluetooth controller to enable the Bluetooth controller to enter the working state from the dormant state.

In order to effectively utilize the bluetooth controller of the electronic cigarette to realize the identity authentication of the electronic cigarette user, the invention also provides a preferable starting method of the intelligent electronic cigarette control module, and the step S2 specifically comprises the following steps:

s21, judging whether the acquired acceleration data exceed the set threshold, if yes, executing the next step, otherwise, returning to the step S1;

s22, the acceleration sensing module starts to record the change mode of the acceleration of the electronic cigarette, wherein the change mode of the acceleration of the electronic cigarette comprises but is not limited to the acceleration size, direction and frequency;

and S23, judging whether the obtained acceleration change mode is consistent with the preset change mode, if so, executing a step S3, otherwise, keeping the Bluetooth controller in a dormant state.

After the electronic cigarette user purchases a related electronic cigarette, the built-in Bluetooth controller of the electronic cigarette is started according to the process, and meanwhile, a corresponding application program (APP) is installed on a target terminal such as a smart phone. And then, the electronic cigarette and the target terminal are communicated through Bluetooth. The user sets an 'electronic cigarette acceleration change mode' on the terminal, for example, shaking three times or more from top to bottom; alternatively, from bottom to top, shake five times or more. After the setting is finished, the obtained preset mode is sent to a built-in single chip microcomputer of the electronic cigarette and stored.

When the user needs to start the built-in Bluetooth controller of the electronic cigarette next time, the set 'acceleration change mode of the electronic cigarette' must be operated repeatedly. Thus, others, especially children, cannot activate their bluetooth controller even if they take the electronic cigarette.

Further, the user may set that the use of the e-cigarette is to be restricted when the bluetooth controller is not activated. For example, the number of the sucked openings of the electronic cigarette can be only within 3; or, the electronic cigarette cannot start ignition, namely, one mouth cannot suck. Therefore, the electronic cigarette can be effectively prevented from being abused by people such as children who are not suitable for using the electronic cigarette.

As shown in fig. 3-4, thebluetooth controller 1 is connected with a controllable switch combination module 2 and acurrent detection module 3 respectively, the output end of the controllable switch combination module 2 is connected with anatomizer interface 4, and thecurrent detection module 3 detects the current value of the output end of the controllable switch combination module 2 and feeds back the current value to thebluetooth controller 1. Controllable switch composite module 2 opens or closes under the control ofbluetooth controller 1, foratomizer interface 4 power supply after opening, no longer supplies power after closing.Current detection module 3 monitors the current value of 2 outputs of controllable switch composite module, feeds back tobluetooth controller 1, andbluetooth controller 1 can accurately calculateatomizer interface 4's heater resistance according to received current value, and controllable switch composite module 2 andcurrent detection module 3's power consumption is less, reaches the low-power consumption, saves the effect of electron cigarette power consumption, guarantees that other functional modules of electron cigarette have sufficient electric quantity.

Controllable switch composite module 2 includes switch Q1 and MOS pipe Q2, and switch Q1's input pin is connected with the power positive pole, and the gate of MOS pipe Q2 connectsbluetooth controller 1 through resistance R19, and MOS pipe Q2's drain electrode is connected with switch Q1's control pin, and MOS pipe Q2's source ground connection is connected with electron R14 between switch Q1's input pin and the control pin. Specifically, a resistor R12 and a resistor R16 which are connected in series are arranged between the positive electrode and the negative electrode of the power supply, the common end of the resistor R12 and the common end of the resistor R16 are connected with theBluetooth controller 1, a proper voltage value is provided for theBluetooth controller 1, and the function of monitoring whether the voltage of the power supply is abnormal or not can be achieved.

Thecurrent detection module 3 comprises a resistor R11 and a current detection chip, the resistor R11 is connected in series with the anode output end of the controllable switch combination module 2, and the current detection chip detects the current value flowing through the resistor R11. The required time of current detection chip in the testing process is short, and the formula thatbluetooth controller 1 calculated the heater resistance is simple, has realized from this that the accuracy of electron cigarette heater resistance is detected in the very short time to having improved the work efficiency of atomizing core, having saved electron cigarette power consumption, reduced the number of times that charges of electron cigarette.

And a heating wire for supplying heat to the atomizer is welded at theatomizer interface 4.

Thebluetooth controller 1 is also connected with anRGB lamp 5. TheRGB lamp 5 is a breathing lamp, and by utilizing the PWM output function of theBluetooth controller 1, in the process that theRGB lamp 5 is turned off to be brightest, under the condition that the PWM period is fixed, the PWM starts from a low level, and a positive wide frequency is increased by every 3ms until the PWM output is a high level. In contrast, in the process from the maximum on to the off of theRGB lamp 5, the PWM is increased by a negative wide frequency every 6ms from the high level until the PWM outputs the low level, thereby realizing the control of the breathing lamp. When the voltage of the battery is under-voltage, the gradual change speed time of the breathing lamp can be changed into 1/3 of normal operation, so as to remind a user of charging in time.

Bluetooth controller 1 still is connected withacceleration response module 6 and stabiliser 7,acceleration response module 6 and stabiliser 7 electric connection.Acceleration sensing module 6 can be used to detect the motion condition of electron cigarette, feeds back tobluetooth controller 1, and stabiliser 7 provides required regulated voltage foracceleration sensing module 6 andbluetooth controller 1.

TheBluetooth controller 1 is also connected with an electronic cigarette pressure sensor. The electron cigarette pressure sensor can be used to detect the inside atmospheric pressure data of electron cigarette to feed back tobluetooth controller 1, if unusual,bluetooth controller 1 can in time report to the police.

Example two

As shown in fig. 5 and 6, the invention provides a starting method of an intelligent air humidifier control module, which is implemented based on an intelligent air humidifier, the intelligent air humidifier comprises a bluetooth controller and an acceleration sensing module, the bluetooth controller is electrically connected with the acceleration sensing module to acquire acceleration data fed back by the acceleration sensing module, the bluetooth controller comprises a sleep state and a working state, the sleep state only monitors signals of the acceleration sensing module, and the working state starts all functional modules; the method specifically comprises the following steps:

s1, the acceleration sensing module acquires acceleration data of the intelligent air humidifier;

s2, judging whether the acquired acceleration data exceed the set threshold, if yes, executing the next step, otherwise, returning to the step S1;

and S3, starting the Bluetooth controller to enable the Bluetooth controller to enter the working state from the dormant state.

In order to effectively utilize the bluetooth controller of the air humidifier to realize the identity authentication of the user of the air humidifier, the invention further provides a preferred starting method of the intelligent air humidifier control module, and the step S2 specifically includes the following steps:

s21, judging whether the acquired acceleration data exceed the set threshold, if yes, executing the next step, otherwise, returning to the step S1;

s22, the acceleration sensing module starts to record the change mode of the air humidifier acceleration, wherein the change mode of the air humidifier acceleration includes but is not limited to the acceleration size, direction and frequency;

and S23, judging whether the obtained acceleration change mode is consistent with the preset change mode, if so, executing a step S3, otherwise, keeping the Bluetooth controller in a dormant state.

After purchasing a related air humidifier, a user of the air humidifier starts a built-in Bluetooth controller of the air humidifier according to a flow, and installs a corresponding application program (APP) on a target terminal such as a smart phone. Then, the air humidifier and the target terminal are communicated through Bluetooth. The user sets an 'air humidifier acceleration change mode' on the terminal, for example, shaking three times or more from top to bottom; alternatively, from bottom to top, shake five times or more. After the setting is finished, the obtained preset mode is sent to the built-in single chip microcomputer of the air humidifier and stored.

When the user needs to start the built-in Bluetooth controller of the air humidifier next time, the set 'acceleration change mode of the air humidifier' must be repeatedly operated. Thus, others, especially children, cannot activate their bluetooth controller even if they take the air humidifier. Further, the user may set that, at the same time, when the bluetooth controller is not activated, the use of the air humidifier will be restricted.

As shown in fig. 7-8, thebluetooth controller 1 is connected with a controllable switch combination module 2 and acurrent detection module 3 respectively, the output end of the controllable switch combination module 2 is connected with anatomizer interface 4, and thecurrent detection module 3 detects the current value of the output end of the controllable switch combination module 2 and feeds back the current value to thebluetooth controller 1. Controllable switch composite module 2 opens or closes under the control ofbluetooth controller 1, foratomizer interface 4 power supply after opening, no longer supplies power after closing.Current detection module 3 monitors the current value of 2 outputs of controllable switch composite module, feeds back tobluetooth controller 1, andbluetooth controller 1 can accurately calculateatomizer interface 4's heater resistance according to received current value, and controllable switch composite module 2 andcurrent detection module 3's power consumption is less, reaches low-power consumption, saves air humidifier power consumption's effect, guarantees that other functional modules of air humidifier have sufficient electric quantity.

Controllable switch composite module 2 includes switch Q1 and MOS pipe Q2, and switch Q1's input pin is connected with the power positive pole, and the gate of MOS pipe Q2 connectsbluetooth controller 1 through resistance R19, and MOS pipe Q2's drain electrode is connected with switch Q1's control pin, and MOS pipe Q2's source ground connection is connected with electron R14 between switch Q1's input pin and the control pin. Specifically, a resistor R12 and a resistor R16 which are connected in series are arranged between the positive electrode and the negative electrode of the power supply, the common end of the resistor R12 and the common end of the resistor R16 are connected with theBluetooth controller 1, a proper voltage value is provided for theBluetooth controller 1, and the function of monitoring whether the voltage of the power supply is abnormal or not can be achieved.

Thecurrent detection module 3 comprises a resistor R11 and a current detection chip, the resistor R11 is connected in series with the anode output end of the controllable switch combination module 2, and the current detection chip detects the current value flowing through the resistor R11. The time that the current detection chip is required in the testing process is short, and the formula thatbluetooth controller 1 calculated the heater resistance is simple, has realized from this that the accuracy of air humidifier heater resistance is detected in the very short time to improve the work efficiency of atomizing core, saved air humidifier power consumption, reduced air humidifier's the number of times of charging.

And a heating wire for supplying heat to the atomizer is welded at theatomizer interface 4.

Thebluetooth controller 1 is also connected with anRGB lamp 5. TheRGB lamp 5 is an RGB lamp, and by utilizing the PWM output function of theBluetooth controller 1, in the process that theRGB lamp 5 is turned off to be brightest, under the condition that the PWM period is fixed, the PWM is increased by one positive wide frequency from low level every 3ms until the PWM output is high level. In contrast, in the process from the maximum on to the off of theRGB lamp 5, the PWM is increased by a negative wide frequency every 6ms from the high level until the PWM outputs the low level, thereby controlling the RGB lamp. When the voltage of the battery is under-voltage, the gradual change speed time of the RGB lamp can be changed into 1/3 of normal operation, so as to remind the user of charging in time.

Bluetooth controller 1 still is connected withacceleration response module 6 and stabiliser 7,acceleration response module 6 and stabiliser 7 electric connection. Theacceleration sensing module 6 can be used for detecting the motion condition of the air humidifier and feeding back the motion condition to theBluetooth controller 1, and the voltage stabilizer 7 provides required stable voltage for theacceleration sensing module 6 and theBluetooth controller 1.

TheBluetooth controller 1 is also connected with an air humidifier pressure sensor. The air humidifier air pressure sensor can be used for detecting air pressure data inside the air humidifier and feeding back the air pressure data to theBluetooth controller 1, and if abnormity occurs, theBluetooth controller 1 can give an alarm in time.

EXAMPLE III

As shown in fig. 9 and 10, the invention provides a method for starting a control module of an intelligent atomization therapeutic apparatus, which is implemented based on the intelligent atomization therapeutic apparatus, the intelligent atomization therapeutic apparatus comprises a bluetooth controller and an acceleration sensing module, the bluetooth controller is electrically connected with the acceleration sensing module to acquire acceleration data fed back by the acceleration sensing module, the bluetooth controller comprises a sleep state and a working state, the sleep state only monitors signals of the acceleration sensing module, and the working state starts all functional modules; the method specifically comprises the following steps:

s1, the acceleration sensing module acquires acceleration data of the intelligent atomization therapeutic apparatus;

s2, judging whether the acquired acceleration data exceed the set threshold, if yes, executing the next step, otherwise, returning to the step S1;

and S3, starting the Bluetooth controller to enable the Bluetooth controller to enter the working state from the dormant state.

In order to effectively utilize the bluetooth controller of the therapeutic aerosol treatment device to realize the identity authentication of the user of the therapeutic aerosol treatment device, the invention also provides a preferable starting method of the control module of the intelligent therapeutic aerosol treatment device, and the step S2 specifically comprises the following steps:

s21, judging whether the acquired acceleration data exceed the set threshold, if yes, executing the next step, otherwise, returning to the step S1;

s22, the acceleration sensing module starts to record the change mode of the acceleration of the atomization therapeutic apparatus, wherein the change mode of the acceleration of the atomization therapeutic apparatus comprises but is not limited to the acceleration, the direction and the frequency;

and S23, judging whether the obtained acceleration change mode is consistent with the preset change mode, if so, executing a step S3, otherwise, keeping the Bluetooth controller in a dormant state.

After the user of the atomization therapeutic apparatus purchases the relevant atomization therapeutic apparatus, the built-in Bluetooth controller of the atomization therapeutic apparatus is started according to the flow, and meanwhile, a corresponding application program (APP) is installed on a target terminal such as a smart phone. Then, the atomization therapeutic apparatus and the target terminal are communicated through Bluetooth. The user sets an acceleration change mode of the aerosol therapeutic apparatus on the terminal, for example, shaking the aerosol therapeutic apparatus three times or more from top to bottom; alternatively, from bottom to top, shake five times or more. After the setting is finished, the obtained preset mode is sent to a built-in single chip microcomputer of the atomization therapeutic apparatus and stored.

When the user needs to start the built-in Bluetooth controller of the atomization therapeutic apparatus next time, the set acceleration change mode of the atomization therapeutic apparatus needs to be operated repeatedly. Thus, others, especially children, cannot activate their bluetooth controller even if they take the aerosol therapy device. Further, the user may set that, at the same time, when the bluetooth controller is not enabled, the use of the aerosol therapy device is restricted.

As shown in fig. 11-12, thebluetooth controller 1 is connected with a controllable switch combination module 2 and acurrent detection module 3 respectively, the output end of the controllable switch combination module 2 is connected with anatomizer interface 4, and thecurrent detection module 3 detects the current value of the output end of the controllable switch combination module 2 and feeds back the current value to thebluetooth controller 1. Controllable switch composite module 2 opens or closes under the control ofbluetooth controller 1, foratomizer interface 4 power supply after opening, no longer supplies power after closing.Current detection module 3 monitors the current value of 2 outputs of controllable switch composite module, feeds back tobluetooth controller 1, andbluetooth controller 1 can accurately calculateatomizer interface 4's heater resistance according to the current value received, and controllable switch composite module 2 andcurrent detection module 3's power consumption is less, reaches the low-power consumption, saves the effect of atomizing therapeutic instrument power consumption, guarantees that other functional modules of atomizing therapeutic instrument have sufficient electric quantity.

Controllable switch composite module 2 includes switch Q1 and MOS pipe Q2, and switch Q1's input pin is connected with the power positive pole, and the gate of MOS pipe Q2 connectsbluetooth controller 1 through resistance R19, and MOS pipe Q2's drain electrode is connected with switch Q1's control pin, and MOS pipe Q2's source ground connection is connected with electron R14 between switch Q1's input pin and the control pin. Specifically, a resistor R12 and a resistor R16 which are connected in series are arranged between the positive electrode and the negative electrode of the power supply, the common end of the resistor R12 and the common end of the resistor R16 are connected with theBluetooth controller 1, a proper voltage value is provided for theBluetooth controller 1, and the function of monitoring whether the voltage of the power supply is abnormal or not can be achieved.

Thecurrent detection module 3 comprises a resistor R11 and a current detection chip, the resistor R11 is connected in series with the anode output end of the controllable switch combination module 2, and the current detection chip detects the current value flowing through the resistor R11. The required time of current detection chip in the testing process is short, and the formula thatbluetooth controller 1 calculated the heater resistance is simple, has realized from this that the accuracy of atomizing therapeutic instrument heater resistance detects in the very short time to having improved the work efficiency of atomizing core, having saved atomizing therapeutic instrument power consumption, reduced atomizing therapeutic instrument's the number of times that charges.

And a heating wire for supplying heat to the atomizer is welded at theatomizer interface 4.

Thebluetooth controller 1 is also connected with anRGB lamp 5. TheRGB lamp 5 is a breathing lamp, and by utilizing the PWM output function of theBluetooth controller 1, in the process that theRGB lamp 5 is turned off to be brightest, under the condition that the PWM period is fixed, the PWM starts from a low level, and a positive wide frequency is increased by every 3ms until the PWM output is a high level. In contrast, in the process from the maximum on to the off of theRGB lamp 5, the PWM is increased by a negative wide frequency every 6ms from the high level until the PWM outputs the low level, thereby realizing the control of the breathing lamp. When the voltage of the battery is under-voltage, the gradual change speed time of the breathing lamp can be changed into 1/3 of normal operation, so as to remind a user of charging in time.

Bluetooth controller 1 still is connected withacceleration response module 6 and stabiliser 7,acceleration response module 6 and stabiliser 7 electric connection.Acceleration sensing module 6 can be used to detect atomizing therapeutic instrument's motion condition, feeds back tobluetooth controller 1, and stabiliser 7 provides required regulated voltage foracceleration sensing module 6 andbluetooth controller 1.

TheBluetooth controller 1 is also connected with an aerosol therapeutic apparatus pressure sensor. The pressure sensor of the atomization therapeutic apparatus can be used for detecting the pressure data inside the atomization therapeutic apparatus and feeding back the pressure data to theBluetooth controller 1, and if abnormity occurs, theBluetooth controller 1 can give an alarm in time.

The present invention is not limited to the above preferred embodiments, and any modifications, equivalent substitutions, improvements, etc. within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (9)

1. A starting method of an intelligent atomization device control module is realized based on an intelligent atomization device, the intelligent atomization device comprises a Bluetooth controller and an acceleration sensing module, the Bluetooth controller is electrically connected with the acceleration sensing module to acquire acceleration data fed back by the acceleration sensing module, the Bluetooth controller comprises a dormant state and a working state, the dormant state only monitors signals of the acceleration sensing module, and the working state starts all functional modules; the method is characterized by comprising the following steps:

s1, the acceleration sensing module acquires acceleration data of the intelligent atomization device;

s2, judging whether the acquired acceleration data exceed the set threshold, if yes, executing the next step, otherwise, returning to the step S1;

and S3, starting the Bluetooth controller to enable the Bluetooth controller to enter the working state from the dormant state.

2. The method for starting the control module of the intelligent atomization device according to claim 1, wherein the step S2 specifically comprises the following steps:

s21, judging whether the acquired acceleration data exceed the set threshold, if yes, executing the next step, otherwise, returning to the step S1;

s22, the acceleration sensing module starts to record the change mode of the acceleration of the atomization device, wherein the change mode of the acceleration of the atomization device comprises but is not limited to the acceleration, the direction and the frequency;

and S23, judging whether the obtained acceleration change mode is consistent with the preset change mode, if so, executing a step S3, otherwise, keeping the Bluetooth controller in a dormant state.

3. The method for starting the control module of the intelligent atomization device according to claim 1, wherein the Bluetooth controller is connected with a controllable switch combination module and a current detection module respectively, the output end of the controllable switch combination module is connected with an atomizer interface, and the current detection module detects the current value of the output end of the controllable switch combination module and feeds the current value back to the Bluetooth controller.

4. The starting method of the intelligent atomization device control module according to claim 3, characterized in that: controllable switch composite module includes switch Q1 and MOS pipe Q2, switch Q1's input pin is connected with the power positive pole, MOS pipe Q2's grid is connected through resistance R19 the bluetooth controller, MOS pipe Q2's drain electrode with switch Q1's control pin is connected, MOS pipe Q2's source ground connection, be connected with electron R14 between switch Q1's input pin and the control pin.

5. The starting method of the intelligent atomization device control module according to claim 3 or 4, characterized in that: the current detection module comprises a resistor R11 and a current detection chip, the resistor R11 is connected in series with the anode output end of the controllable switch combination module, and the current detection chip detects the current value flowing through the resistor R11.

6. The starting method of the intelligent atomization device control module according to claim 3, characterized in that: and a heating wire for supplying heat to the atomizer is fixed at the interface of the atomizer.

7. The starting method of the intelligent atomization device control module according to claim 1 or 3, which is characterized in that: the Bluetooth controller is also connected with an RGB lamp.

8. The starting method of the intelligent atomization device control module according to claim 1 or 3, which is characterized in that: the bluetooth controller still is connected with the stabiliser, acceleration response module with stabiliser electric connection.

9. The starting method of the intelligent atomization device control module according to claim 1 or 3, which is characterized in that: the bluetooth controller is also connected with an atomization device air pressure sensor.

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