CN112545060A - Battery rod, electronic atomization device, detection equipment and working method of detection equipment - Google Patents

Abstract

The invention provides a battery pole, an electronic atomization device, detection equipment and a working method thereof, wherein the battery pole comprises: the control chip is used for driving the atomizer electrically connected with the battery rod to acquire parameter information of the atomizer and/or other elements in the battery rod and converting the parameter information into parameter signals with different frequencies; and the driving circuit is connected with the control chip and the light-emitting unit and used for acquiring the parameter signal, driving the light-emitting unit to emit light by utilizing the parameter signal so as to generate an optical signal, and further sending the parameter signal out through the optical signal. Therefore, the transmission of the parameter information of the electronic atomization device is realized, the use is convenient, and the cost is saved.

Description

Battery rod, electronic atomization device, detection equipment and working method of detection equipment

Technical Field

The invention relates to the field of electronic atomization devices, in particular to a battery rod, an electronic atomization device, detection equipment and a working method of the detection equipment.

Background

When the electronic atomization device is produced, some basic parameters need to be tested to ensure the product quality, such as cell voltage, atomizer resistance, output power and other parameters. In the prior art, in order to obtain parameter information of an electronic atomization device, such as test parameters, pumping parameters, and the like, an additional communication module, such as a bluetooth module, is added to an electronic atomization apparatus to transmit the parameter information, and the additional communication module increases the cost and volume of the electronic atomization device; the other method is to use an external test instrument such as a multimeter to perform a test through the test fixture to obtain parameter information, but the operation is complicated and the use is inconvenient.

Disclosure of Invention

The invention provides a battery rod, an electronic atomization device and detection equipment, which are used for acquiring parameter information of the electronic atomization device, are convenient to use and save cost.

In order to solve the above technical problems, a first technical solution provided by the present invention is: provided is a battery pole including: the control chip is used for driving the atomizer electrically connected with the battery rod to acquire parameter information of the atomizer and/or other elements in the battery rod and converting the parameter information into parameter signals with different frequencies; and the driving circuit is connected with the control chip and the light-emitting unit and used for acquiring the parameter signal, driving the light-emitting unit to emit light by utilizing the parameter signal so as to generate an optical signal, and further sending the parameter signal out through the optical signal.

Wherein, the control chip includes: an encoding unit configured to encode the parameter information to generate encoded data; and the first timer is connected with the coding unit and used for generating parameter signals with different frequencies according to the coded data.

Wherein the parameter signals of different frequencies generated by the first timer also have different duty cycles.

Wherein, the control chip further comprises: the acquisition unit is used for acquiring the parameter information of the atomizer and/or other elements in the battery rod and sending the parameter information to the coding unit; the modulation unit is connected with the first timer and used for outputting the parameter signals with different frequencies to the driving circuit; wherein the encoding unit is connected with the acquiring unit.

Wherein the frequency of the parameter signal with different frequencies is more than 50 HZ.

Wherein the parameter signals of different frequencies at least comprise parameter signals of two frequencies; or the parameter signal comprises at least three frequencies of parameter signals.

In order to solve the above technical problems, a second technical solution provided by the present invention is: provided is an electronic atomization device including: a battery rod and an atomizer; the battery rod is the battery rod of any one of the above items and is used for driving the atomizer; the atomizer includes a heating element, and the parameter information acquired by the battery lever includes a heating parameter of the heating element.

In order to solve the above technical problems, a third technical solution provided by the present invention is: the working method of the electronic atomization device is provided, and the method is carried out based on the electronic atomization device, and comprises the following steps: acquiring parameter information of the atomizer and/or other elements in the battery rod; converting the parameter information into parameter signals with different frequencies; and driving a light-emitting unit to emit light by using the parameter signal so as to generate an optical signal, and then sending the parameter signal out by using the optical signal.

In order to solve the above technical problems, a fourth technical solution provided by the present invention is: there is provided a detection apparatus comprising: the optical sensor is used for acquiring an optical signal generated by a battery rod of the electronic atomization device; and the control unit is connected with the optical sensor and used for converting the optical signal into a digital signal, identifying the frequency of the digital signal and further decoding and acquiring the parameter information of the electronic atomization device according to the identified frequency.

Wherein the control unit includes: a second timer for identifying a frequency of the digital signal; and the decoding unit is connected with the second timer and used for decoding and acquiring the parameter information of the atomizer according to the identified frequency.

The second timer is started at a first level signal of the digital signal and stopped at the next first level signal, so that the frequency of the digital signal is identified.

Wherein the control unit further comprises: the receiving unit is connected with the optical sensor and is used for converting the optical signal into a digital signal; the display unit is connected with the decoding unit and used for displaying the parameter information; wherein the second timer is connected to the receiving unit.

In order to solve the above technical problems, a fifth technical solution provided by the present invention is: the working method of the detection device is provided, and the method is carried out based on the detection device of any one of the above parts, and comprises the following steps: acquiring an optical signal generated by a battery rod of the electronic atomization device; converting the optical signal into a digital signal; and identifying the frequency of the digital signal, and then decoding according to the identified frequency to acquire the parameter information of the electronic atomization device.

The battery rod provided by the invention has the beneficial effects that the battery rod is different from the situation of the prior art, and the battery rod provided by the invention comprises a control chip, wherein the control chip is used for acquiring parameter information of the atomizer and/or other elements in the battery rod and converting the parameter information into parameter signals with different frequencies; the driving circuit obtains the parameter signal, drives the light-emitting unit to emit light by utilizing the parameter signal so as to generate an optical signal, and then sends the parameter signal out through the optical signal. Therefore, the transmission of the parameter information of the electronic atomization device is realized, the use is convenient, and the cost is saved.

Drawings

FIG. 1 is a schematic structural view of one embodiment of a battery pole of the present invention;

FIG. 2 is a schematic diagram of one embodiment of the battery pole of FIG. 1;

FIG. 3 is a schematic structural view of another embodiment of the battery pole of FIG. 1;

FIG. 4a is a schematic waveform diagram of parameter signals with different frequencies;

FIG. 4b is a waveform diagram of an embodiment of parameter signals with different frequencies;

FIG. 5 is a waveform diagram of an optical signal of the light emitting unit;

FIG. 6 is a schematic structural diagram of an electronic atomizer according to an embodiment of the present invention;

FIG. 7 is a schematic flow chart illustrating a method of operating an electronic atomizer according to an embodiment of the present invention;

FIG. 8 is a schematic structural diagram of an embodiment of the detecting apparatus of the present invention;

FIG. 9 is a schematic structural diagram of an embodiment of the detecting apparatus shown in FIG. 8;

fig. 10 is a schematic flow chart of another embodiment of the working method of the detection device of the present invention.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, 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 application.

Referring to fig. 1, a schematic structural diagram of a battery pole according to a first embodiment of the invention is shown, specifically, the battery pole includes a control chip 11, a driving circuit 12 and a light emitting unit 13. The control chip 11 drives the atomizer inserted into the battery rod to acquire parameter information of the atomizer and/or other elements in the battery rod, and converts the parameter information into parameter signals with different frequencies; the driving circuit 12 is connected to the control chip 11 and the light emitting unit 13, and is configured to obtain the parameter signal, drive the light emitting unit 13 to emit light by using the parameter signal to generate an optical signal, and further send the parameter signal out through the optical signal.

Specifically, the control chip 11 may be an MCU chip or the like. When the atomizer is inserted into the battery rod for operation, the control chip 11 obtains parameter information of the electronic atomization device, where the parameter information includes test parameters and/or pumping parameters, where the test parameters may be, for example, cell temperature, cell voltage, atomizer resistance, output power, and the like, and the pumping parameters may be, for example, the number of pumping ports, pumping time, and the like.

Further, referring to fig. 2, the control chip 11 includes: an encoding unit 111 and a first timer 112, the encoding unit 111 being configured to encode the parameter information to generate encoded data; the first timer 112 is connected to the encoding unit 111, and is used for generating parameter signals of different frequencies according to the encoded data. Specifically, the first timer 112 may generate two different frequency parameter signals, such as a parameter signal with a frequency f0 and a parameter signal with a frequency f1, and in another embodiment, the different frequency parameter signals generated by the first timer 112 also have different duty ratios. Referring to fig. 4a, the first timer 112 may generate a parameter signal with a frequency f0 and different duty cycles and a parameter signal with a frequency f1 and different duty cycles. Wherein, A represents a parameter signal with frequency f0 and different duty ratio, and B represents a parameter signal with frequency f1 and different duty ratio. In another embodiment, the first timer 112 may further generate a parameter signal with a frequency f2 and different duty ratios, as shown in fig. 4a, where C represents a parameter signal with a frequency f2 and different duty ratios, the duty ratios are used for controlling the light emitting brightness of the light emitting unit 13, and the larger the duty ratio, i.e., the longer the high level lasts, the higher the brightness of the light emitting unit 13.

In one embodiment, the frequency of the parameter signal of different frequencies is greater than 50 HZ. In particular, the frequencies f0, f1, f2 are greater than 50HZ to prevent human eyes from being able to detect flicker. Wherein, the parameter signal of the frequency f0 may indicate transmission of data 0, the parameter signal of the frequency f1 indicates transmission of data 1, and the parameter signal of the frequency f2 may indicate no data transmission. In one embodiment, the frequencies f0, f1, f2 may be 70HZ, 100HZ, 120HZ, respectively, for example.

Further, referring to fig. 3, the difference from the embodiment shown in fig. 2 is that in this embodiment, the control chip 11 further includes: acquisition section 113 and modulation section 114. The obtaining unit 113 is configured to obtain the parameter information of the nebulizer and/or other components in the battery rod, and send the parameter information to the encoding unit 111, and the modulating unit 114 is connected to the first timer 112 and configured to output parameter signals with different frequencies to the driving circuit 12. In this embodiment, the encoding unit 111 is connected to the obtaining unit 113, the obtaining unit 113 obtains the pumping parameters from the atomizer, obtains parameter information such as test parameters from the battery rod, and sends the parameter information to the encoding unit 111, the encoding unit 111 encodes the parameter information to generate encoded data, the first timer 112 generates parameter signals with different frequencies or different duty ratios according to the encoded data, for example, as shown in fig. 4a, the modulation unit 114 sends the parameter signals to the driving circuit 12, and the driving circuit 12 controls the light emitting unit 13 to emit light by using the parameter signals, so as to transmit the parameter information of the electronic atomization apparatus. Specifically, if the parameter information is the cell voltage, for example, 3.2V, and the encoded data is 11111100, the parameter information is converted into parameter signals with different frequencies, the parameter signal with the frequency f0 represents data 0, and the parameter signal with the frequency f1 represents data 1, so as to generate a waveform diagram of the parameter signals with different frequencies, as shown in fig. 4 b.

Further, the battery pole still includes connection control chip 11's electric core, miaow head, heating circuit, detection circuitry etc. and wherein electric core connection control chip 11 for the atomizer power supply, the miaow head is used for detecting user's suction action, carries out work in order to start electron atomizing device, and is concrete, when the miaow head detects the air current change, starts electron atomizing device promptly and carries out work. The heating circuit is used for controlling a heating element (heating wire) of the atomizer to generate heat according to the PWM signal so as to atomize the atomized matrix, and the detection circuit is used for detecting the electric parameters of the heating wire during working and transmitting the electric parameters to the control chip 11. Specifically, the control chip 11 outputs a PWM signal to the heating circuit to control the heating element in the atomizer to generate heat when the microphone detects a change in the airflow.

Specifically, the light emitting unit 13 may be an LED lamp, and may be changed when the light emitting unit 13 emits light, for example, may go through the processes of gradually turning on, gradually turning off, and turning off, as shown in fig. 5. In the fade-in phase, the parameter signal with the frequency f0 may indicate transmission of data 0, the parameter signal with the frequency f1 indicates transmission of data 1, the parameter signal with the frequency f2 may indicate no data transmission, and the duty ratio is gradually increased. In the long bright phase, the parameter signal with the frequency f0 may indicate the transmission of data 0, the parameter signal with the frequency f1 indicates the transmission of data 1, and the parameter signal with the frequency f2 may indicate no data transmission, and the duty ratio is the same, wherein the larger the duty ratio is, the brighter the light emitting unit is. During the extinguishing process, the parameter signal with the frequency f0 may indicate the transmission of data 0, the parameter signal with the frequency f1 indicates the transmission of data 1, the parameter signal with the frequency f2 may indicate no data transmission, and the duty ratio is gradually reduced. And in an extinguishing stage, outputting constant level. The parameter information of the electronic atomization device is sent out through the light signal sent by the light-emitting unit 13.

Fig. 6 is a schematic structural diagram of an electronic atomizing device according to an embodiment of the present invention. The electronic atomization device comprises a battery rod 61 and an atomizer 62, wherein the battery rod 61 is the battery rod and is used for driving the atomizer 62; the atomizer 62 includes a heating element 621, and the parameter information acquired by the battery lever 61 includes a heating parameter of the heating element 621.

Referring to fig. 7, a schematic flow chart of a working method of an electronic atomization device according to a first embodiment of the present invention is shown, where the method includes:

step S71: parameter information is obtained for the atomizer and/or other components within the battery rod.

Specifically, when the electronic atomization device is used, parameter information of the atomizer and/or other elements in the battery rod is acquired, and the parameter information includes: the method comprises the steps of testing parameters and/or pumping parameters, wherein the testing parameters can be cell temperature, cell voltage, atomizer resistance value, output power and the like, and the pumping parameters can be pumping port number, pumping time and the like.

Step S72: and converting the parameter information into parameter signals with different frequencies.

The parameter information is converted into parameter signals with different frequencies, specifically, in an embodiment, the parameter signals with different frequencies may also have different duty ratios. For example, the parameter information may be converted into a parameter signal with a frequency f0 and a different duty ratio and a parameter signal with a frequency f1 and a different duty ratio, or may also be converted into a parameter signal with a frequency f2 and a different duty ratio, which is not limited in particular. It should be noted that the frequency of the parameter signal with different frequencies is greater than 50 HZ. In particular, the frequencies f0, f1, f2 are greater than 50HZ to prevent human eyes from being able to detect flicker.

Step S73: and driving a light-emitting unit to emit light by using the parameter signal so as to generate an optical signal, and then sending the parameter signal out by using the optical signal.

The parameter signals with different frequencies and/or different duty ratios are used for driving the light-emitting unit to emit light so as to generate light signals, and then the parameter signals are sent out by the light signals. Specifically, the light emitting unit may be an LED lamp, and may be changed when the light emitting unit emits light, for example, the light emitting unit may be turned on gradually, turned on for a long time, turned off gradually, turned off and the like. In the fade-in phase, the parameter signal with the frequency f0 may indicate transmission of data 0, the parameter signal with the frequency f1 indicates transmission of data 1, the parameter signal with the frequency f2 may indicate no data transmission, and the duty ratio is gradually increased. In the long bright phase, the parameter signal with the frequency f0 may indicate the transmission of data 0, the parameter signal with the frequency f1 indicates the transmission of data 1, and the parameter signal with the frequency f2 may indicate no data transmission, and the duty ratio is the same, wherein the larger the duty ratio is, the brighter the light emitting unit is. During the extinguishing process, the parameter signal with the frequency f0 may indicate the transmission of data 0, the parameter signal with the frequency f1 indicates the transmission of data 1, the parameter signal with the frequency f2 may indicate no data transmission, and the duty ratio is gradually reduced. And in an extinguishing stage, outputting constant level. The parameter information of the electronic atomization device is sent out through the light signal sent by the light-emitting unit.

Referring to fig. 8, a schematic structural diagram of an embodiment of the detection apparatus of the present invention is shown, specifically, the detection apparatus includes: an optical sensor 71 and a control unit 72, wherein the optical sensor 71 acquires an optical signal generated by a battery rod of the atomization device; specifically, the optical sensor is used for acquiring a light signal generated by a light-emitting unit in the battery pole. The control unit 72 is connected to the optical sensor 71, and is configured to convert the optical signal into a digital signal, identify the frequency of the digital signal, and decode and acquire parameter information of the electronic atomization device according to the identified frequency.

Specifically, please refer to fig. 9, wherein the control unit 72 specifically includes: a second timer 724 and a decoding unit 723. The second timer 724 is used for identifying the frequency of the digital signal; the decoding unit 723 is connected to the second timer 724 and configured to decode and acquire parameter information of the nebulizer according to the identified frequency.

Specifically, the second timer 724 starts at a first level signal of the digital signal and stops at the next first level signal, thereby identifying the frequency of the digital signal. Specifically, the second timer 724 starts when the digital signal is at a high level and stops when the digital signal is at a next high level, so as to detect the frequency of the identification digital signal. That is, the second timer 724 only needs to consider the frequency to derive the parameter information, which does not need to pay attention to the duty ratio in the frequency.

Further, the control unit 72 further includes: a receiving unit 722, and a display unit 721. The receiving unit 722 is connected to the optical sensor 71, and is configured to convert the optical signal into a digital signal; the display unit 721 is connected to the decoding unit 723 for displaying the parameter information.

Specifically, the receiving unit 722 is connected to the optical sensor 71, acquires an optical signal from the optical sensor 71, and converts the optical signal into a digital signal; the second timer 724 is connected to the receiving unit 722, identifies the frequency of the digital signal, and the decoding unit 723 decodes the identified frequency to obtain the parameter information of the nebulizer and displays the parameter information by using the display unit 721. Specifically, if the frequency f0 is recognized, it indicates that data 0 is received, if the frequency f1 is recognized, it indicates that data 1 is received, and if the frequency f2 is recognized, it indicates that no data is present.

In an embodiment, the detection device may be a test device. When the method is applied to the field of automatic testing, the function of acquiring the parameter information can be realized only by superposing a section of testing program in the original application program, so that the quality of the electronic atomization device is judged according to the parameter information. Furthermore, because the optical signal generated by the electronic atomization device cannot be recognized by human eyes, the software on which the test program is superimposed can be the software of the electronic atomization device which is finally delivered from the factory, i.e. a set of test software does not need to be written additionally, and the procedures of the production link can also be reduced.

It can be understood that the testing device may also be other electronic devices such as a mobile terminal, for example, a mobile phone, a television, a computer, a home monitoring system, and the like of the user, so that in the process of using the electronic atomization device, the parameter information is directly displayed on the display screen of the mobile terminal, and further the smoking parameters can be processed to realize functions such as identifying the smoking habit of the user.

Referring to fig. 10, a schematic flow chart of an embodiment of a working method of a test device according to the present invention is shown, which specifically includes:

step S101: and acquiring an optical signal generated by a battery rod of the electronic atomization device.

Specifically, the testing device comprises an optical sensor, and the optical sensor is used for acquiring an optical signal generated by a battery rod of the electronic atomization device.

Step S102: and converting the optical signal into a digital signal.

The optical signal is converted into a digital signal.

Step S103: and identifying the frequency of the digital signal, and then decoding according to the identified frequency to acquire the parameter information of the electronic atomization device.

And identifying the frequency of the digital signal, and then decoding according to the identified frequency to acquire the parameter information of the electronic atomization device. Specifically, if the frequency f0 is recognized, it indicates that data 0 is received, if the frequency f1 is recognized, it indicates that data 1 is received, and if the frequency f2 is recognized, it indicates that no data is present.

According to the electronic atomization device and the detection equipment provided by the application, specifically, software of a test program is superposed on the electronic atomization device; parameter information of the atomizer and/or other elements in the battery rod is obtained through software with a test program, the parameter information is converted into parameter signals with different frequencies, the parameter signals are used for driving the light-emitting unit to emit light to generate light signals, and then the parameter signals are sent out through the light signals. The detection equipment acquires the optical signal, converts the optical signal into a digital signal, identifies the frequency of the digital signal and then decodes according to the identified frequency to acquire the parameter information of the electronic atomization device. The method does not need to increase the hardware cost of the electronic atomization device, and is simple to operate. Especially when being applied to the test field, can realize automatic test, the test is simple and the degree of accuracy is high.

Specifically, the battery rod of the electronic atomization device provided by the application is in a suction state, and the light-emitting unit 13 is turned on in the suction process, wherein the display state of the light-emitting unit 13 is controlled by the control chip 11 according to the suction state of the electronic atomization device, and parameter signals with different frequencies and different duty ratios can be transmitted in the normal display process of the light-emitting unit 13. In the present application, the modulation frequency of light is required to be greater than 50Hz, which does not affect the user's use, that is, the light signal with the parameter signal and the light signal without the parameter signal have no difference in user experience, but the signal can be found to have a difference when performing signal testing, the light signal with the parameter signal can measure a plurality of frequencies, and the light signal without the parameter signal has only one frequency. In other application scenarios, as long as the light-emitting unit 13 emits light during the normal operation of the electronic atomization device, the electronic atomization device can superimpose the parameter signals to transmit the parameter information.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (13)

1. A battery pole, comprising:

the control chip is used for driving the atomizer electrically connected with the battery rod to acquire parameter information of the atomizer and/or other elements in the battery rod and converting the parameter information into parameter signals with different frequencies;

and the driving circuit is connected with the control chip and the light-emitting unit and used for acquiring the parameter signal, driving the light-emitting unit to emit light by utilizing the parameter signal so as to generate an optical signal, and further sending the parameter signal out through the optical signal.

2. The battery pole of claim 1, wherein the control chip comprises:

an encoding unit configured to encode the parameter information to generate encoded data;

and the first timer is connected with the coding unit and used for generating parameter signals with different frequencies according to the coded data.

3. The battery pole of claim 2, wherein the different frequency parameter signals generated by the first timer also have different duty cycles.

4. The battery pole of claim 2, wherein the control chip further comprises:

the acquisition unit is used for acquiring the parameter information of the atomizer and/or other elements in the battery rod and sending the parameter information to the coding unit;

the modulation unit is connected with the first timer and used for outputting the parameter signals with different frequencies to the driving circuit;

wherein the encoding unit is connected with the acquiring unit.

5. The battery pole of claim 1, wherein the frequency of the parameter signal of different frequency is greater than 50 HZ.

6. The battery pole as claimed in claim 1, wherein the parameter signals of different frequencies comprise at least two frequencies of parameter signals; or

The parameter signal includes at least three frequencies of parameter signals.

7. An electronic atomization device, comprising: a battery rod and an atomizer;

the battery rod is the battery rod of any one of the preceding claims 1 to 6, used for driving the atomizer;

the atomizer includes a heating element, and the parameter information acquired by the battery lever includes a heating parameter of the heating element.

8. A method for operating an electronic atomizer, wherein the method is performed based on the electronic atomizer of claim 7, and the method comprises:

acquiring parameter information of the atomizer and/or other elements in the battery rod;

converting the parameter information into parameter signals with different frequencies;

and driving a light-emitting unit to emit light by using the parameter signal so as to generate an optical signal, and then sending the parameter signal out by using the optical signal.

9. A detection apparatus, comprising:

the optical sensor is used for acquiring an optical signal generated by a battery rod of the electronic atomization device;

and the control unit is connected with the optical sensor and used for converting the optical signal into a digital signal, identifying the frequency of the digital signal and further decoding and acquiring the parameter information of the electronic atomization device according to the identified frequency.

10. The detection apparatus according to claim 9, wherein the control unit includes:

a second timer for identifying a frequency of the digital signal;

and the decoding unit is connected with the second timer and used for decoding and acquiring the parameter information of the atomizer according to the identified frequency.

11. The apparatus of claim 10, wherein the second timer is started at a first level of the digital signal and stopped at a next first level of the digital signal to identify a frequency of the digital signal.

12. The detection apparatus according to claim 10, wherein the control unit further comprises:

the receiving unit is connected with the optical sensor and is used for converting the optical signal into a digital signal;

the display unit is connected with the decoding unit and used for displaying the parameter information;

wherein the second timer is connected to the receiving unit.

13. A method for operating a test device, the method being performed on the basis of a test device according to any one of claims 9 to 12, the method comprising:

acquiring an optical signal generated by a battery rod of the electronic atomization device;

converting the optical signal into a digital signal;

and identifying the frequency of the digital signal, and then decoding according to the identified frequency to acquire the parameter information of the electronic atomization device.

Images