CN117039625A - Method and device for controlling rhythms of charged particles - Google Patents

Abstract

The invention discloses a method and a device for controlling the rhythm of charged particles, belongs to the technical field of charged particle generation, and is used for solving the technical problem that the conventional charged particle generation device cannot control and adjust parameters of emitted charged particles according to actual action effects. The method comprises the following steps: the main control module generates an initial control signal and sends the initial control signal to the rhythm control module; the rhythm control module generates a corresponding initial rhythm signal according to the initial control signal; the charged particle generation module generates charged particle waves with corresponding rhythms according to the initial rhythms and transmits the charged particle waves into a space; the data feedback module feeds back the acquired real-time effect data to the main control module; and the main control module generates an adjusting control signal according to the real-time effect data, and adjusts the charged particle wave rhythm parameters emitted by the charged particle generation module through the adjusting control signal.

Description

Method and device for controlling rhythms of charged particles

Technical Field

The invention relates to the technical field of charged particle generation, in particular to a method and a device for controlling the rhythm of charged particles.

Background

The charged particles are particles with various forms of charges, have certain energy, certain conversion frequency and movement direction, can produce health care effect and disinfection effect, and can be widely applied to the fields of human health, physiotherapy health care, air disinfection and the like.

Air anions are one type of charged particles, and are widely applied, and are usually generated by ionizing air by negative high pressure or strong rays. However, the existing charged particle generation system or device can not be used for completing tasks by transmitting the charged particles, and after the charged particles are transmitted, the device can not be used for obtaining the specific action effect of the charged particles, judging whether the currently transmitted charged particles meet the actual requirements or not, accurately controlling and adjusting the transmission of the charged particles, easily causing the problem of insufficient or excessive transmission force and reducing the service efficiency of the charged particle generation device.

Disclosure of Invention

The embodiment of the invention provides a method and a device for controlling the rhythm of charged particles, which are used for solving the following technical problems: the existing charged particle generation device cannot control and adjust parameters of the emitted charged particles according to actual action effects.

The embodiment of the invention adopts the following technical scheme:

in one aspect, an embodiment of the present invention provides a method for controlling a rhythm of charged particles, where the method includes:

the main control module generates an initial control signal and sends the initial control signal to the rhythm control module;

the rhythm control module generates a corresponding initial rhythm signal according to the initial control signal;

the charged particle generation module generates charged particle waves with corresponding rhythms according to the initial rhythms and transmits the charged particle waves into a space;

the data feedback module feeds back the acquired real-time effect data to the main control module;

and the main control module generates an adjusting control signal according to the real-time effect data, and adjusts the charged particle wave rhythm parameters emitted by the charged particle generation module through the adjusting control signal.

In a possible implementation manner, the main control module generates an initial control signal, which specifically includes:

after the main control module is started, reading pre-stored initial control parameters, and generating the initial control signals according to the initial control parameters; the initial control parameters at least comprise an initial waveform frequency, an initial waveform amplitude and an initial transmitting time.

In a possible implementation manner, the rhythm control module generates a corresponding initial rhythm signal according to the initial control signal, and specifically includes:

after receiving the initial control signal, the rhythm control module reads initial control parameters contained in the initial control signal;

the rhythm control module generates an initial rhythm signal corresponding to the initial control parameter through a programmable waveform generator;

the rhythm control module amplifies the initial rhythm signal through a double operational amplifier and sends the initial rhythm signal to the charged particle generation module.

In a possible implementation manner, the charged particle generation module generates a charged particle wave with a corresponding rhythm according to the initial rhythm signal and emits the charged particle wave into space, and specifically includes:

the charged particle generation module inputs the initial rhythm signal into a negative high voltage generation circuit;

the negative high voltage generating circuit generates initial voltage at high level, and stably boosts the initial voltage through the piezoelectric ceramic transformer to output negative high voltage with corresponding rhythm to the charged particle emitter;

the charged particle emitter ionizes air under the action of negative high pressure to generate charged particle waves with corresponding rhythms, and emits the charged particle waves into space.

In a possible implementation manner, the data feedback module feeds back the collected real-time effect data to the main control module, and specifically includes:

the data feedback module acquires real-time effect data of the charged particle wave action object through data acquisition equipment; wherein the real-time effect data at least comprises one of human body sign data and air quality data;

the data feedback module feeds the real-time effect data back to the main control module through a lead connected with the main control module.

In a possible implementation manner, the main control module generates an adjustment control signal according to the real-time effect data, and specifically includes:

the main control module compares the real-time effect data with corresponding preset thresholds of all levels, and determines a threshold interval to which the real-time effect data belongs;

determining an actual action grade corresponding to the real-time effect data according to the threshold interval, and calculating a grade difference between the actual action grade and a designated action grade;

converting the level difference into a waveform frequency difference;

and generating the adjusting control signal according to the waveform frequency difference, and sending the adjusting control signal to a rhythm control module.

In a possible implementation manner, the adjusting control signal adjusts the charged particle wave rhythm parameter emitted by the charged particle generating module, which specifically includes:

the rhythm control module generates a final rhythm signal corresponding to the regulation control signal through a programmable waveform generator;

the rhythm control module amplifies the final rhythm signal through a double operational amplifier and sends the final rhythm signal to the charged particle generation module;

the charged particle generation module inputs the final rhythm signal into a negative high voltage generation circuit so that the negative high voltage generation circuit outputs negative high voltage with the same frequency as the final rhythm signal;

the charged particle emitter ionizes air under the action of the negative high pressure, generates charged particle waves with the same frequency as the final rhythm signal, and emits the charged particle waves into space.

On the other hand, the embodiment of the invention also provides a device for controlling the rhythm of the charged particles, which comprises: the device comprises a main control module, a rhythm control module, a charged particle generation module and a data feedback module;

the main control module is used for generating an initial control signal and sending the initial control signal to the rhythm control module; generating an adjusting control signal according to the real-time effect data, and adjusting the charged particle wave rhythm parameters emitted by the charged particle generating module through the adjusting control signal;

the rhythm control module is used for generating a corresponding initial rhythm signal according to the initial control signal;

the charged particle generation module is used for generating charged particle waves with corresponding rhythms according to the initial rhythmic signals and transmitting the charged particle waves into a space;

the data feedback module is used for feeding back the acquired real-time effect data to the main control module.

In one possible embodiment, the rhythm control module includes a rhythm generation circuit and a signal amplification circuit;

the rhythm generation circuit comprises a programmable waveform generator, wherein the programmable waveform generator is used for generating corresponding rhythm signals according to digital signals sent by the main control module; the rhythm signal at least comprises waveform frequency and waveform amplitude;

the signal amplifying circuit comprises a double operational amplifier which is used for amplifying the rhythm signal and transmitting the rhythm signal to the charged particle generating module.

In one possible embodiment, the charged particle generation module includes a negative high voltage generation circuit and a charged particle emitter;

the negative high voltage generating circuit comprises a piezoelectric ceramic transformer and is used for generating negative high voltage with corresponding rhythm according to the rhythm signal;

the charged particle emitter is used for receiving the negative high voltage with the corresponding rhythm, generating charged particles with the corresponding rhythm and emitting the charged particles into the space.

The method and the device for controlling the rhythm of the charged particles can control the generation frequency of the charged particles so as to obtain the charged particle wave with a specific rhythm, and can adjust the frequency of the emitted charged particles in real time according to the obtained actual effect data so as to form a benign feedback mechanism, which is rarely adopted in the application field of the charged particle wave at present, realize the accurate control and adjustment of the emission of the charged particles, avoid the problem of insufficient or excessive emission force of the charged particles, and improve the use efficiency of the charged particle generating device. In the actual use process, the released charged particles are easy to be in an excessive state, so that the method provided by the invention can simultaneously play a role in saving energy consumption.

Drawings

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

FIG. 1 is a flow chart of a method for controlling the rhythm of charged particles according to an embodiment of the present invention;

fig. 2 is a circuit diagram of a master control module according to an embodiment of the present invention;

FIG. 3 is a circuit diagram of a rhythm control module according to an embodiment of the present invention;

FIG. 4 is a circuit diagram of a charged particle generation module according to an embodiment of the present invention;

fig. 5 is a schematic structural diagram of a charged particle rhythm control device according to an embodiment of the present invention.

Detailed Description

In order to make the technical solution of the present invention better understood by those skilled in the art, the technical solution of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, which can be made by one of ordinary skill in the art based on the embodiments herein without making any inventive effort, shall fall within the scope of the present invention.

The embodiment of the invention provides a method for controlling the rhythm of charged particles, which is shown in figure 1 and specifically comprises the following steps of S101-S105:

s101, the main control module generates an initial control signal and sends the initial control signal to the rhythm control module.

Specifically, after the main control module is started, reading pre-stored initial control parameters, and generating the initial control signals according to the initial control parameters; the initial control parameters at least comprise an initial waveform frequency, an initial waveform amplitude and an initial transmitting time.

As a possible implementation manner, fig. 2 is a circuit diagram of a main control module provided by the embodiment of the present invention, as shown in fig. 2, the main control circuit includes a 32-bit ARM microcontroller U4A, the model is STM32F051K8U6, and the ARM microcontroller is used for storing a program, and generating a digital signal and a driving signal according to the stored program. The main control circuit also comprises a power management chip PI, a resistor R6, a resistor R7 and a capacitor C15. The 23 pin of the ARM microcontroller U4A is connected with the 3 pin of the power management chip PI; the 24 pin of the ARM microcontroller U4A is connected with the 4 pin of the power management chip PI; the 1 pin of the power management chip PI is connected with a 3.3V power supply, and the 2 pin is grounded. The 31 pin of the ARM microcontroller U4A is connected with the resistor R6 and grounded; the 4 pin of the ARM microcontroller U4A is connected with a resistor R7, and the resistor R7 is connected with a 3.3V power supply; the 4 pin of ARM microcontroller U4A is also connected to capacitor C15 and to ground.

S102, the rhythm control module generates a corresponding initial rhythm signal according to the initial control signal.

Specifically, after receiving the initial control signal, the rhythm control module reads initial control parameters contained in the initial control signal; the rhythm control module then generates an initial rhythm signal corresponding to the initial control parameter via a programmable waveform generator.

Further, the rhythm control module amplifies the initial rhythm signal through a double operational amplifier and sends the initial rhythm signal to the charged particle generation module.

As a possible implementation manner, fig. 3 is a circuit diagram of a rhythm control module provided by an embodiment of the present invention, where, as shown in fig. 3, a rhythm generating circuit includes a programmable waveform generator U1, where the programmable waveform generator U1 is configured to generate a corresponding rhythm signal according to a digital signal sent by a main control module 120; the rhythm signal includes at least a waveform frequency and a waveform amplitude. The signal amplifying circuit includes a dual operational amplifier U5, and the dual operational amplifier U5 is used for amplifying the rhythm signal and transmitting to the charged particle generating module 140. The rhythm generation circuit further includes: crystal oscillator X1, capacitor C4, capacitor C5, and capacitor C6. The 3 pin of the crystal oscillator X1 is an output pin and is connected with the 5 pin of the programmable waveform generator U1; the 4 pin of the crystal oscillator X1 is connected with a 3.3V power supply, the 2 pin is grounded, and the 1 pin is suspended. The 1 pin of the programmable waveform generator U1 is connected with one end of a capacitor C4, and the other end of the capacitor C4 is grounded; the 2 pin of the programmable waveform generator U1 is connected with a 3.3V power supply. The 3 pin of the programmable waveform generator U1 is connected with one end of the capacitor C6, and the 4 pin is connected with the other end of the capacitor C6. The pin 3 of the programmable waveform generator U1 is connected with the positive electrode of the capacitor C5, and the pin 4 is connected with the negative electrode of the capacitor C5; the capacitor C5 is a polar capacitor; the capacitor C5 is connected with the capacitor C6 in parallel; the 10 pin of the programmable waveform generator U1 is connected with the signal amplifying circuit, and the 1 pin is connected with the capacitor C1 and grounded.

The signal amplifying circuit further includes: resistor R4, resistor R1, resistor R2, resistor R5, transistor Q1, diode D2, and polarized electrolytic capacitor CE3. The 3 pin of the double operational amplifier U5 is connected with one end of a resistor R4, and the other end of the resistor R4 is connected with a rhythm generating circuit; a resistor R1 is connected between the 1 pin and the 2 pin of the double operational amplifier U5; the 1 pin is also connected with a resistor R2; the other end of the resistor R2 is connected with the base electrode of the triode Q1; the collector of the triode Q1 is connected with a 15V power supply, and the emitter is connected with the charged particle generation module. The emitter of the triode Q1 is connected with a resistor R5 and grounded; the emitter is also connected with the cathode of the diode D2, and the anode of the diode D2 is grounded; the emitter is also connected with the positive electrode of the polar electrolytic capacitor CE3, and the negative electrode of the polar electrolytic capacitor CE4 is grounded.

S103, the charged particle generation module generates charged particle waves with corresponding rhythms according to the initial rhythms and transmits the charged particle waves into a space.

Specifically, the charged particle generation module inputs the initial rhythm signal to a negative high voltage generation circuit;

the negative high voltage generating circuit generates initial voltage at high level, and stably boosts the initial voltage through the piezoelectric ceramic transformer to output negative high voltage with corresponding rhythm to the charged particle emitter;

the charged particle emitter ionizes air under the action of negative high pressure to generate charged particle waves with corresponding rhythms, and emits the charged particle waves into space.

As a possible implementation manner, fig. 4 is a circuit diagram of a charged particle generation module according to an embodiment of the present invention, where, as shown in fig. 4, the negative high voltage generation circuit at least includes a piezoelectric ceramic transformer, a triode Q4, a triode Q2, a triode Q3, a resistor R9, a resistor R8, and a capacitor C16; the sheet piezoelectric ceramic transformer is arranged in an HX electrolytic capacitor, and the two poles of the HX electrolytic capacitor are the input ends of the piezoelectric ceramic transformer. The model of the HX electrolytic capacitor is HX3005. The triode Q4 and the triode Q2 are NPN type triodes, and the triode Q3 is a PNP type triode. One end of a resistor R9 is connected with a 40KHz PWM controller, and the other end is connected with the base electrode of a triode Q4; the PWM controller is used for pulse modulation. The collector of the triode Q4 is connected with one end of a resistor R8, and the emitter is grounded; the other end of the resistor R8 is connected with a 15V power supply. The collector of transistor Q2 is connected to a rhythm control module 110. The triode Q2 is connected in parallel with the triode Q3, and is connected with one pole of the HX electrolytic capacitor through the capacitor C16, and the other pole of the HX electrolytic capacitor is grounded.

The output end of the piezoelectric ceramic transformer is connected with a circuit formed by connecting four diodes in parallel, and the other three branches except the first branch are respectively connected with a capacitor. The output end of the parallel circuit is connected with the charged particle emitter.

And S104, the data feedback module feeds back the acquired real-time effect data to the main control module.

Specifically, the data feedback module collects real-time effect data of the charged particle wave action object through data collection equipment; the real-time effect data at least comprises one of human body sign data and air quality data.

Further, the data feedback module feeds back the real-time effect data to the main control module through a wire connected with the main control module.

As a possible implementation manner, the data feedback module in the present invention is a facility matched with an application scenario, and if the application scenario is a human health treatment, the data feedback module may be a human body sign data acquisition device, such as a heart rate monitoring device, a blood oxygen monitoring device, etc. If the application scenario is air disinfection, the data feedback module may be an air quality monitoring device. The data feedback module in the invention is not particularly limited, and can be any instrument for feeding back real-time state data of the charged particle acting object, and the invention only protects the functions of the instrument and the specific functions achieved by cooperation with the previous modules.

And S105, the main control module generates an adjusting control signal according to the real-time effect data, and adjusts the charged particle wave rhythm parameters emitted by the charged particle generation module through the adjusting control signal.

Specifically, the main control module compares the real-time effect data with corresponding preset thresholds of all levels, and determines a threshold interval to which the real-time effect data belongs; determining an actual action grade corresponding to the real-time effect data according to the threshold interval, and calculating a grade difference between the actual action grade and a designated action grade;

converting the level difference into a waveform frequency difference; and generating the adjusting control signal according to the waveform frequency difference, and sending the adjusting control signal to a rhythm control module.

As a possible implementation mode, effect data thresholds of a plurality of levels are set in the main control module in advance, then the two thresholds between which the real-time effect data are located are determined through comparison, and intervals between the two thresholds can be set to different action levels, so that which action level the real-time effect data are actually located is determined. If the actual action level is lower than the action level designated by the user, calculating a difference between the two levels, multiplying the difference by the current frequency, and finally generating an adjustment control signal according to the calculated frequency.

Further, the rhythm control module generates a final rhythm signal corresponding to the adjustment control signal through a programmable waveform generator; the rhythm control module amplifies the final rhythm signal through a double operational amplifier and sends the final rhythm signal to the charged particle generation module; the charged particle generation module inputs the final rhythm signal into a negative high voltage generation circuit so that the negative high voltage generation circuit outputs negative high voltage with the same frequency as the final rhythm signal; the charged particle emitter ionizes air under the action of the negative high pressure, generates charged particle waves with the same frequency as the final rhythm signal, and emits the charged particle waves into space.

In addition, an embodiment of the present invention further provides a device for controlling a rhythm of a charged particle, as shown in fig. 5, a device 500 for controlling a rhythm of a charged particle includes: a master control module 510, a rhythm control module 520, a charged particle generation module 530, and a data feedback module 540;

the main control module 510 is configured to generate an initial control signal, and send the initial control signal to the rhythm control module 520; generating an adjusting control signal according to the real-time effect data, and adjusting the charged particle wave rhythm parameters emitted by the charged particle generating module through the adjusting control signal;

the rhythm control module 520 is configured to generate a corresponding initial rhythm signal according to the initial control signal;

the charged particle generation module 530 is configured to generate a charged particle wave having a corresponding rhythm according to the initial rhythm signal, and transmit the charged particle wave into space;

the data feedback module 540 is configured to feed back the collected real-time effect data to the main control module 510.

Further, the rhythm control module 520 includes a rhythm generation circuit and a signal amplification circuit;

the rhythm generation circuit comprises a programmable waveform generator, wherein the programmable waveform generator is used for generating corresponding rhythm signals according to digital signals sent by the main control module; the rhythm signal at least comprises waveform frequency and waveform amplitude;

the signal amplifying circuit comprises a double operational amplifier which is used for amplifying the rhythm signal and transmitting the rhythm signal to the charged particle generating module.

Further, the charged particle generation module 530 includes a negative high voltage generation circuit and a charged particle emitter;

the negative high voltage generating circuit comprises a piezoelectric ceramic transformer and is used for generating negative high voltage with corresponding rhythm according to the rhythm signal;

the charged particle emitter is used for receiving the negative high voltage with the corresponding rhythm, generating charged particles with the corresponding rhythm and emitting the charged particles into the space.

The method and the device for controlling the rhythm of the charged particles can control the generation frequency of the charged particles so as to obtain the charged particle wave with a specific rhythm, and can adjust the frequency of the emitted charged particles in real time according to the obtained actual effect data so as to form a benign feedback mechanism, which is rarely adopted in the application field of the charged particle wave at present, realize the accurate control and adjustment of the emission of the charged particles, avoid the problem of insufficient or excessive emission force of the charged particles, and improve the use efficiency of the charged particle generating device. In the actual use process, the released charged particles are easy to be in an excessive state, so that the method provided by the invention can simultaneously play a role in saving energy consumption.

The embodiments of the present invention are described in a progressive manner, and the same and similar parts of the embodiments are all referred to each other, and each embodiment is mainly described in the differences from the other embodiments. In particular, for the device embodiments, since they are substantially similar to the method embodiments, the description is relatively simple, and reference is made to the description of the method embodiments in part.

The foregoing describes certain embodiments of the present invention. In addition, the processes depicted in the accompanying figures do not necessarily require the particular order shown, or sequential order, to achieve desirable results. In some embodiments, multitasking and parallel processing are also possible or may be advantageous.

The foregoing is merely exemplary of the present invention and is not intended to limit the present invention. Various modifications and changes may be made to the embodiments of the invention by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the embodiments of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. A method of controlling the rhythm of charged particles, the method comprising:

the main control module generates an initial control signal and sends the initial control signal to the rhythm control module;

the rhythm control module generates a corresponding initial rhythm signal according to the initial control signal;

the charged particle generation module generates charged particle waves with corresponding rhythms according to the initial rhythms and transmits the charged particle waves into a space;

the data feedback module feeds back the acquired real-time effect data to the main control module;

and the main control module generates an adjusting control signal according to the real-time effect data, and adjusts the charged particle wave rhythm parameters emitted by the charged particle generation module through the adjusting control signal.

2. The method for controlling the rhythm of charged particles according to claim 1, wherein the main control module generates an initial control signal, specifically comprising:

after the main control module is started, reading pre-stored initial control parameters, and generating the initial control signals according to the initial control parameters; the initial control parameters at least comprise an initial waveform frequency, an initial waveform amplitude and an initial transmitting time.

3. The method according to claim 1, wherein the rhythm control module generates a corresponding initial rhythm signal according to the initial control signal, and the method specifically comprises:

after receiving the initial control signal, the rhythm control module reads initial control parameters contained in the initial control signal;

the rhythm control module generates an initial rhythm signal corresponding to the initial control parameter through a programmable waveform generator;

the rhythm control module amplifies the initial rhythm signal through a double operational amplifier and sends the initial rhythm signal to the charged particle generation module.

4. The method according to claim 1, wherein the charged particle generation module generates charged particle waves having a corresponding rhythm according to the initial rhythm signal, and emits the charged particle waves into a space, and the method comprises:

the charged particle generation module inputs the initial rhythm signal into a negative high voltage generation circuit;

the negative high voltage generating circuit generates initial voltage at high level, and stably boosts the initial voltage through the piezoelectric ceramic transformer to output negative high voltage with corresponding rhythm to the charged particle emitter;

the charged particle emitter ionizes air under the action of negative high pressure to generate charged particle waves with corresponding rhythms, and emits the charged particle waves into space.

5. The method for controlling the rhythm of charged particles according to claim 1, wherein the data feedback module feeds back the collected real-time effect data to the main control module, and specifically comprises:

the data feedback module acquires real-time effect data of the charged particle wave action object through data acquisition equipment; wherein the real-time effect data at least comprises one of human body sign data and air quality data;

the data feedback module feeds the real-time effect data back to the main control module through a lead connected with the main control module.

6. The method for controlling the rhythm of charged particles according to claim 1, wherein said main control module generates an adjustment control signal according to said real-time effect data, specifically comprising:

the main control module compares the real-time effect data with corresponding preset thresholds of all levels, and determines a threshold interval to which the real-time effect data belongs;

determining an actual action grade corresponding to the real-time effect data according to the threshold interval, and calculating a grade difference between the actual action grade and a designated action grade;

converting the level difference into a waveform frequency difference;

and generating the adjusting control signal according to the waveform frequency difference, and sending the adjusting control signal to a rhythm control module.

7. The method according to claim 6, wherein the adjusting the charged particle waveform rhythm parameter emitted by the charged particle generating module by the adjusting control signal specifically comprises:

the rhythm control module generates a final rhythm signal corresponding to the regulation control signal through a programmable waveform generator;

the rhythm control module amplifies the final rhythm signal through a double operational amplifier and sends the final rhythm signal to the charged particle generation module;

the charged particle generation module inputs the final rhythm signal into a negative high voltage generation circuit so that the negative high voltage generation circuit outputs negative high voltage with the same frequency as the final rhythm signal;

the charged particle emitter ionizes air under the action of the negative high pressure, generates charged particle waves with the same frequency as the final rhythm signal, and emits the charged particle waves into space.

8. A charged particle rhythm control device, said device comprising: the device comprises a main control module, a rhythm control module, a charged particle generation module and a data feedback module;

the main control module is used for generating an initial control signal and sending the initial control signal to the rhythm control module; generating an adjusting control signal according to the real-time effect data, and adjusting the charged particle wave rhythm parameters emitted by the charged particle generating module through the adjusting control signal;

the rhythm control module is used for generating a corresponding initial rhythm signal according to the initial control signal;

the charged particle generation module is used for generating charged particle waves with corresponding rhythms according to the initial rhythmic signals and transmitting the charged particle waves into a space;

the data feedback module is used for feeding back the acquired real-time effect data to the main control module.

9. The charged-particle rhythm control device of claim 8, wherein said rhythm control module comprises a rhythm generation circuit and a signal amplification circuit;

the rhythm generation circuit comprises a programmable waveform generator, wherein the programmable waveform generator is used for generating corresponding rhythm signals according to digital signals sent by the main control module; the rhythm signal at least comprises waveform frequency and waveform amplitude;

the signal amplifying circuit comprises a double operational amplifier which is used for amplifying the rhythm signal and transmitting the rhythm signal to the charged particle generating module.

10. The charged-particle rhythm control device of claim 8, wherein said charged-particle generation module comprises a negative high-voltage generation circuit and a charged-particle emitter;

the negative high voltage generating circuit comprises a piezoelectric ceramic transformer and is used for generating negative high voltage with corresponding rhythm according to the rhythm signal;

the charged particle emitter is used for receiving the negative high voltage with the corresponding rhythm, generating charged particles with the corresponding rhythm and emitting the charged particles into the space.