CN110543128A - Control circuit of beautiful carving appearance - Google Patents

Abstract

the invention discloses a control circuit of a beautiful carving instrument, which comprises a power supply circuit, a processing module connected with the power supply circuit, a non-body-control micro-electric control structure in signal connection with the processing module, and a body-control micro-electric control structure in signal connection with the processing module, wherein the processing module is connected with an ultrasonic wave emitting head through an ultrasonic wave control circuit, and is also in signal connection with an adsorption control structure; the processing module is further in signal connection with a heating structure for respectively heating the non-body-control micro-electric control structure, the body-control micro-electric control structure and the adsorption control structure, and is further in signal connection with a temperature detection structure for respectively carrying out temperature detection on the non-body-control micro-electric control structure, the body-control micro-electric control structure and the adsorption control structure so as to respectively form a heating non-body-control system, a heating body control system and a heating adsorption system. The invention can effectively provide the physiotherapy with smooth fluctuation and comfortable change, improve the use effect and enlarge the physiotherapy range and the diversity of operation.

Description

Control circuit of beautiful carving appearance

Technical Field

The invention belongs to the field of control of a beautiful carving instrument, and particularly relates to a control circuit of a beautiful carving instrument.

Background

The beautifying carving instrument is a biological micro-electrical physical therapy for beautifying people by using physical, electronic and optical methods. The electrotherapy is to use the special electrotherapeutic instrument to output electric energy, and after the electrotherapeutic instrument is adjusted by a specially trained electrotherapeutic operator, various manipulations are used to quickly get through the channels and collaterals of pathological changes, so that the qi and blood of the human body are unblocked, the pathological structure is changed, and the purpose of treating multiple diseases of the whole body is achieved. Traditional this kind of biological little electricity physiotherapy in market needs two people's interoperation to carry out the physiotherapy, and physiotherapy equipment adjusts little electricity physiotherapy through the frequency amplitude of controlling a plurality of continuous sudden change electric pulse spike signals and dredge channels and collaterals mode and effect, and traditional biological little electricity physiotherapy can produce spike burr signal in the electric pulse spike signal change of sudden change in the twinkling of an eye and have one kind like ant acupuncture and sting the sense, thereby make the user use feel poor, influence the use mood and the confidence of reusing, thereby influence the result of use.

disclosure of Invention

The invention aims to provide a control circuit of a beautiful carving instrument, which can effectively provide a physiotherapy with smooth fluctuation and comfortable change and improve the use effect.

In order to achieve the purpose, the invention provides a control circuit of a beauty carving instrument, which comprises a power supply circuit, a processing module, a non-body-control micro-electric control structure and a body-control micro-electric control structure, wherein the processing module is connected with the power supply circuit and used for generating a sine envelope wave signal and receiving signal processing, the non-body-control micro-electric control structure is in signal connection with the processing module and used for single-person operation, the body-control micro-electric control structure is in signal connection with the processing module and used for two-person cooperative operation, the processing module is connected with an ultrasonic emitting head through an ultrasonic control circuit used for ultrasonic atomization control, and the processing module is also in signal connection with an adsorption control structure used for five-row collateral communication, scraping; the processing module is further in signal connection with a heating structure, the heating structure is used for heating the non-body-control micro-electric control structure, the body-control micro-electric control structure and the adsorption control structure respectively, the processing module is further in signal connection with a temperature detection structure, the temperature detection structure is used for detecting the temperature of the non-body-control micro-electric control structure, the body-control micro-electric control structure and the adsorption control structure respectively, so that the heating non-body-control system, the heating body control system and the heating adsorption system are formed respectively, and the processing module is in signal connection with the display through a communication circuit.

preferably, the frequency of the sinusoidal envelope wave generated by the processing module is 1.5KHz-2.5 KHz.

preferably, the non-body-control micro-electric control structure comprises a first digital potentiometer, a first power amplifier, a first voltage device and a first electrode plate connector, wherein the first digital potentiometer is respectively connected with the processing module and the power supply circuit, the first power amplifier is connected with the first digital potentiometer and the power supply circuit, the first voltage device is connected with the first power amplifier and the power supply circuit, the first electrode plate connector is connected with the first voltage device and is used for connecting the first electrode plate, the heating structure and the temperature detection structure are arranged in the first electrode plate, and the processing module is connected with the first electrode plate through the first digital potentiometer, the first power amplifier, the first voltage device and the first electrode plate connector in sequence to form the bidirectional pulse micro-electric control and heating structure.

preferably, the processing module is connected with the body-controlled micro-electric control structure through an operational amplifier, and is connected with the scraping micro-electric control structure, the privacy-position-adjusting micro-electric control structure, the micro-electric sun-supporting conditioning micro-electric control structure and the five-element network-connecting-conditioning micro-electric control structure through the operational amplifier, and the circuit structure of the scraping micro-electric control structure, the circuit structure of the privacy-position-adjusting micro-electric control structure, the circuit structure of the micro-electric sun-supporting conditioning micro-electric control structure and the circuit structure of the five-element network-connecting-network-connecting-conditioning micro-electric control structure are respectively the same as those of the body-controlled.

preferably, the body-controlled micro-electrical control structure comprises a second digital potentiometer, a second power amplifier, a second voltage transformer and a second electrode plate connector, wherein the second digital potentiometer, the second power amplifier, the second voltage transformer and the second electrode plate connector are respectively connected with the operational amplifier, the processing module and the power supply circuit, the second voltage transformer is connected with the second power amplifier and the power supply circuit, the second electrode plate connector is connected with the second voltage transformer and is used for being connected with a second electrode plate, and the heating structure and the temperature detection structure are arranged in the second electrode plate, and the processing module is connected with the second electrode plate through the operational amplifier, the second digital potentiometer, the second power amplifier, the second voltage transformer and the second electrode.

Preferably, the adsorption control structure includes an air pump control circuit for controlling the operation of the air pump, an adsorption control circuit for controlling the adsorption of the negative pressure suction head by controlling the operation of the adsorption solenoid valve, and an excretion control circuit for controlling the operation of the excretion solenoid valve to stop the adsorption of the negative pressure suction head by controlling the operation of the adsorption solenoid valve, wherein the air pump control circuit, the adsorption solenoid valve and the excretion solenoid valve are respectively connected with a processing module through signals, the adsorption solenoid valve is arranged on a connecting pipeline between the air pump and the negative pressure suction head, and the excretion solenoid valve is arranged on the negative pressure suction head.

preferably, the ultrasonic control circuit is detachably connected with the ultrasonic emitting head by arranging an ultrasonic output connector, one end of the ultrasonic output connector is connected with the power supply circuit through a second inductor and is connected with the ground wire through a twenty-seventh capacitor, one end of the second inductor, which is connected with the power supply circuit, is connected with the ground wire through a twenty-ninth capacitor and the other end of the second inductor, is connected with the ground wire through a vibrating tube and a fourth inductor, the other end of the ultrasonic output connector is connected with the ground wire through a thirty-third capacitor and a first-to-third capacitor in sequence, the connecting end of the thirty-third capacitor and the first-to-third capacitor is connected with the vibrating tube through a fifty-sixteenth resistor, the connecting end of the thirty-third capacitor and the first-to-third capacitor is connected with the collector of a thirty-first triode, the emitter of the thirty-first triode is connected with the ground, a collector of the thirty-first triode is connected with an emitter of the twenty-ninth triode sequentially through a sixteenth resistor and a fifty-seventh resistor, the collector of the thirty-first triode is further connected with the emitter of the twenty-ninth triode through a fifteenth resistor, the collector of the twenty-ninth triode is connected with the power supply circuit, a base of the twenty-ninth triode is connected with the processing module through a fifty-first resistor, the base of the twenty-ninth triode is connected with the power supply circuit through a fifty-first resistor and a fifty-third resistor respectively, and fifty-fourth resistors are further connected in parallel at two ends of the fifty-third resistor.

Preferably, the heating structure is provided with a heating control circuit connected with the power supply circuit and the processing module and a heating device connected with the heating control circuit, and the heating structure is provided with seven paths with the same structure corresponding to each electrode plate and the suction head.

Preferably, the temperature detection structure is provided with a temperature detection circuit connected with the power supply circuit and the processing module and a temperature detection device connected with the temperature detection circuit, and the temperature detection structure is provided with seven paths with the same structure corresponding to each electrode plate and the suction head.

preferably, the power supply circuit outputs direct current 24V, direct current 12V, direct current 5V and direct current 3V, respectively.

Compared with the prior art, the invention has the beneficial effects that:

According to the invention, the processing module generates a sine envelope wave signal to control the non-body-control micro-electric control structure and the body-control micro-electric control structure to carry out micro-electric physical therapy, and the heating non-body-control system and the heating body-control system are formed by combining heating control, and meanwhile, the heating adsorption system for five-element collateral dredging, scraping and toxin expelling, privacy treatment and micro-electric sun-supporting is formed by the adsorption control structure, so that the physiotherapy with smooth and fluctuating comfortable change can be effectively provided, the use effect is improved, and the physiotherapy range and the operation diversity are enlarged. According to the invention, the processing module controls the ultrasonic control circuit to form a multi-gear ultrasonic waveform, so that the moisturizing effect can be effectively improved. The non-body-control micro-electric control structure and the body-control micro-electric control structure are arranged, so that single or double cooperative operation can be performed according to the environment, the use requirement is met, and the effect and the safety of physical therapy are ensured.

drawings

FIG. 1 is a block diagram of a control architecture of the present invention;

FIG. 2 is a schematic diagram of a circuit configuration of a processing module according to the present invention;

FIG. 3 is a schematic circuit diagram of a non-body-controlled micro-electrical control structure according to the present invention;

FIG. 4 is a schematic circuit diagram of an operational amplifier according to the present invention;

FIG. 5 is a schematic circuit diagram of the integrated micro-electrical control structure according to the present invention;

fig. 6 is a schematic circuit diagram of a five-element collateral-dredging conditioning micro-electrical control structure according to the present invention;

FIG. 7 is a schematic circuit diagram of a scraping micro-control structure according to the present invention;

FIG. 8 is a schematic circuit diagram of a privacy-adjusting micro-control structure according to the present invention;

FIG. 9 is a schematic circuit diagram of a micro-electric control structure for micro-electric sun-supporting conditioning according to the present invention;

FIG. 10 is a schematic circuit diagram of an ultrasonic control circuit according to the present invention;

FIG. 11 is a schematic diagram of a circuit configuration of an air pump control circuit according to the present invention;

FIG. 12 is a schematic diagram of a circuit configuration of the adsorption control circuit of the present invention;

FIG. 13 is a schematic diagram of a circuit configuration of a drain control circuit according to the present invention;

FIG. 14 is a schematic circuit diagram of a heating control circuit for a non-body-controlled micro-electrical control structure according to the present invention;

FIG. 15 is a schematic circuit diagram of a temperature detection circuit for a non-body-controlled micro-electrical control structure according to the present invention;

FIG. 16 is a schematic diagram showing the circuit configuration of a pressure detecting circuit for a negative pressure pipette tip of the present invention;

FIG. 17 is a schematic diagram of the circuit configuration of the alarm circuit of the present invention;

FIG. 18 is a schematic circuit diagram of a 5V power supply circuit of the present invention;

FIG. 19 is a schematic circuit diagram of a 3.3V power supply circuit of the present invention;

FIG. 20 is a schematic circuit diagram of a 24V power supply circuit according to the present invention;

FIG. 21 is a schematic circuit diagram of a download circuit according to the present invention;

FIGS. 22-27 are waveforms of the output waveforms of the five-element collateral-dredging conditioning micro-electric control structure of the present invention with the voltage intensity gradually increasing at constant temperature;

FIG. 28 is a waveform diagram of the output of the five-element collateral-dredging conditioning micro-electrical control structure at a voltage intensity of 25V;

FIG. 29 is a waveform diagram of the output of the five-element collateral-dredging conditioning micro-electrical control structure under a voltage of 50V;

FIG. 30 is a waveform diagram of the output of the five-element collateral-dredging conditioning micro-electrical control structure at a voltage intensity of 70V;

FIG. 31 is a waveform diagram of the output of the five-element collateral-dredging conditioning micro-electrical control structure at a voltage of 80V;

Detailed Description

The technical solutions of the present invention are further described in detail below with reference to the accompanying drawings, but the scope of the present invention is not limited to the following.

As shown in fig. 1-21, the present invention provides a control circuit of a carving beauty apparatus, which comprises a power supply circuit, a processing module 1 connected with the power supply circuit for generating sinusoidal envelope wave signals and receiving signal processing, a non-body-control micro-electric control structure 100 connected with the processing module 1 for single-person operation, and a body-control micro-electric control structure 200 connected with the processing module 1 for two-person cooperative operation, wherein the processing module 1 is connected with an ultrasonic emitter 91 through an ultrasonic control circuit 9 for ultrasonic atomization control, and the processing module 1 is further connected with an adsorption control structure 300 for five-row communication, scraping and toxin expelling, private processing, and micro-electric sun support; the processing module 1 is further in signal connection with a heating structure 500 for heating the non-body-control micro-electrical control structure 100, the body-control micro-electrical control structure 200 and the adsorption control structure 300 respectively, and the processing module 1 is further in signal connection with a temperature detection structure 600 for detecting the temperature of the non-body-control micro-electrical control structure 100, the body-control micro-electrical control structure 200 and the adsorption control structure 300 respectively to form a heating non-body-control system, a heating body-control system and a heating adsorption system respectively, and the processing module 1 is in signal connection with the display 81 through a communication circuit 8.

the frequency of the sinusoidal envelope wave generated by the processing module 1 is 1.5KHz or 1.8KHz or 1.9KHz or 2KHz or 2.1KHz or 2.2KHz or 2.3KHz or 2.5 KHz. The power supply circuit respectively outputs direct current 24V, direct current 5V and direct current 3V. In this embodiment, the processing module 1 is an MCU and is connected to the download circuit through a seventeenth connector P37, and the processing module 1 is further connected to an indicator light circuit for work indication, a fan for air cooling, and a sterilization switch circuit for on-off control through an optical coupler. The communication circuit 8 is a 232 communication circuit. The power supply circuit is connected with external direct current 12V and direct current 36V power supplies through connectors, and voltage reduction is carried out through the voltage stabilizing chip U1 and the voltage stabilizing chip U5.

the heating structure 500 is provided with a heating control circuit 5 connected with the power supply circuit and the processing module 1 and a heating device 51 connected with the heating control circuit 5, and seven paths with the same structure are arranged on the heating structure 500 corresponding to each electrode plate and the suction head. The temperature detection structure 600 is provided with a temperature detection circuit 6 connected with the power supply circuit and the processing module 1 and a temperature detection device 61 connected with the temperature detection circuit 6, and seven paths with the same structure are arranged on the temperature detection structure 600 corresponding to each electrode plate and the suction head. In the present embodiment, the heating device 51 is a resistance heater, and the temperature detecting device 61 is a thermistor.

The non-body-control micro-electrical control structure 100 comprises a first digital potentiometer U18 connected with the processing module 1 and a power supply circuit, a first power amplifier U17 connected with the first digital potentiometer U18 and the power supply circuit, a first voltage transformer T6 connected with the first power amplifier U17 and the power supply circuit, and a first electrode plate joint P40 connected with the first voltage transformer T6 and used for connecting a first electrode plate, wherein the heating structure 500 and the temperature detection structure 600 are arranged in the first electrode plate, and the processing module 1 is connected with the first electrode plate through the first digital potentiometer U18, the first power amplifier U17, the first voltage transformer T6 and the first electrode plate joint P40 in sequence to form a bidirectional pulse micro-electrical control and heating structure. In the present embodiment, the first transformer T6 is an audio transformer. When carrying out non-body control and declining, 2 KHz's sinusoidal envelope wave is sent out by processing module 1 and loops through first digital potentiometer U18, first power amplifier U17, first voltage ware T6 output and carry out two-way pulse microelectro physiotherapy, simultaneously through controllable heating, improve the effect of physiotherapy for single convenient operation safety increases human cell vigor, promotes human metabolism, makes human qi and blood unblocked, and the quick recovery is healthy, reaches the purpose that prevents diseases, treats diseases. The non-body-control micro-electric physical therapy temperature is 30-60 ℃, the micro-electric intensity is 0-99V, the physical therapy time is set to be 30-60min, and five gears are set for adjustment.

the processing module 1 is connected with the body-controlled micro-electric control structure 200 through an operational amplifier U9, and the processing module 1 is connected with the scraping micro-electric control structure, the privacy-adjusting micro-electric control structure, the micro-electric yang-supporting conditioning micro-electric control structure and the five-row communication-network conditioning micro-electric control structure through an operational amplifier U9, and the circuit structure of the scraping micro-electric control structure, the circuit structure of the privacy-adjusting micro-electric control structure, the circuit structure of the micro-electric yang-supporting conditioning micro-electric control structure and the circuit structure of the five-row communication-network conditioning micro-electric control structure are respectively the same as the circuit structure of the body-controlled micro-electric control structure 200. In this embodiment, as shown in fig. 22 to 27, it can be seen that when the temperature of the five-element collateral-dredging micro-electric control structure is 30 degrees, the voltage intensity is in a changing waveform diagram that is continuously increased in an interval of lower than 25V, it can be seen that the waveform changes regularly, there is no distortion, and the amplitude is obviously increased along with the increase of the voltage intensity. As shown in fig. 28-31, the waveforms of several key value points at 30 degrees temperature, it can be seen that the voltage intensity is 25V, and the output envelope waveform has no distortion; the voltage intensity is within 30V to 70V and within 50V, the envelope waveform of the waveform changes from a regular waveform to a flat-top square wave waveform, and the flat-top wave of the waveform is obvious when the voltage intensity is 70V; when the voltage intensity is 80V, the waveform almost evolves into flat-top square waves, so that the output waveform can be seen to be regular and flat, the human body feeling effect is comfortable, smooth and flat when physical therapy is carried out, and the use comfort is improved.

the body-controlled micro-electrical control structure 200 comprises a second digital potentiometer U15, a second power amplifier U14, a second voltage transformer T5 and a second electrode plate connector P38, wherein the second digital potentiometer U15, the second power amplifier U14, the second power amplifier U15 and the power supply circuit are respectively connected with the operational amplifier U9, the processing module 1 and the power supply circuit, the second voltage transformer T5 is connected with the second power amplifier U14 and the power supply circuit, the second electrode plate connector P38 is connected with the second voltage transformer T5 and is used for connecting a second electrode plate, the heating structure 500 and the temperature detection structure 600 are arranged in the second electrode plate, and the processing module 1 is connected with the second electrode plate through the operational amplifier U9, the second digital potentiometer U15, the second power amplifier U14, the second voltage transformer T5 and the second electrode plate connector P38 in sequence to form. The output of the operational amplifier U9 is connected to the third port of the second power amplifier U14 in this example. The second transformer T5 is an audio transformer.

In this embodiment, when carrying out the body accuse electricity, 2 KHz's sinusoidal envelope wave is sent by processing module 1 and is passed through operational amplifier U9 and amplify in proper order, then pass through second digital potentiometer U15 in proper order, second power amplifier U14, second voltage ware T5 output 47V, 2KHZ intermediate frequency sinusoidal envelope wave signal carries out the physiotherapy, through controllable heating, the effect of improvement physiotherapy, human cell vitality is increased, promote human metabolism, make human qi and blood unblocked, recover healthy fast, reach and prevent diseases, the purpose of treating the disease, simultaneously can carry out the cooperation regulation use by two people as required, improve the security and guarantee physiotherapy effect. The temperature of the body-controlled micro-electric physiotherapy is 30-60 ℃, the micro-electric intensity is 0-99V, the physiotherapy time is set to be 30-60min, and five gears are set for adjustment. Meanwhile, the operation is the same when the scraping micro physiotherapy, the private part regulation micro physiotherapy, the micro yang-strengthening regulation micro physiotherapy and the five-element collateral dredging regulation micro physiotherapy are carried out.

the adsorption control structure 300 comprises an air pump control circuit 2 connected with an air pump 21 for controlling the work of the air pump 21, an adsorption control circuit 3 connected with an adsorption solenoid valve 31 for controlling the work of the adsorption solenoid valve 31 to control the adsorption of the negative pressure suction head 7, and an excretion control circuit 4 connected with an excretion solenoid valve 41 for controlling the work of the excretion solenoid valve 41 to control the stop of the adsorption of the negative pressure suction head 7, the air pump control circuit 2, the adsorption solenoid valve 31 and the excretion solenoid valve 41 are respectively in signal connection with the processing module 1, the adsorption solenoid valve 31 is arranged on a connection pipeline between the air pump 21 and the negative pressure suction head 7, and the excretion solenoid valve 41 is arranged on the negative. In the present embodiment, the air pump 21 is a vacuum negative pressure air pump. The vacuum adsorption can be effectively matched with scraping micro-electric physiotherapy, private part micro-electric physiotherapy, micro-electric yang-strengthening micro-electric physiotherapy and five-element collateral dredging micro-electric physiotherapy to carry out cooperative physiotherapy, the temperature of each physiotherapy is set to be 30-60 ℃, the micro-electric intensity is 0-99V, the physiotherapy adsorption time is set to be 30-60min, and five grades are set to be adjustable. Chest conditioning can also be performed by vacuum adsorption, with a working time of 30-60min, an inspiratory time of 0-99 (units of N × 90Ms), and an expiratory time of 1-99 (units of N × 90 Ms).

the ultrasonic control circuit 9 is detachably connected with the ultrasonic emitting head 91 by arranging an ultrasonic output connector P32, one end of the ultrasonic output connector P32 is connected with the power supply circuit through a second inductor L2 and is connected with the ground wire through a twenty-seventh capacitor C27, one end of the second inductor L2 connected with the power supply circuit is connected with the ground wire through a twenty-ninth capacitor C29 and the other end is connected with the ground wire through an oscillating tube Q47 and a fourth inductor L4 in sequence, the other end of the ultrasonic output connector P32 is connected with the ground wire through a thirtieth capacitor C30 and a first one-to-one third capacitor C113 in sequence, the connecting end of the thirtieth capacitor C30 and the first one-to-one third capacitor C113 is connected with an oscillating tube Q47 through a fiftieth resistor R57, the connecting end of the thirtieth capacitor C30 and the first one-to-third capacitor C113 is connected with the collector of a thirty triode Q31, the emitter of the thirty triode Q31 is connected with the ground wire, a collector of the thirty-first triode Q31 is connected with an emitter of the twenty-ninth triode Q29 through a sixteenth resistor R62 and a fifty-seventh resistor R57 in sequence, a collector of the thirty-first triode Q31 is further connected with an emitter of the twenty-ninth triode Q29 through a fifteenth resistor R55, a collector of the twenty-ninth triode Q29 is connected with the power supply circuit, a base of the twenty-ninth triode Q29 is connected with the processing module 1 through a fifty-first resistor R51, a base of the twenty-ninth triode Q29 is connected with the power supply circuit through a fifty-first resistor R50 and a fifty-third resistor R53, and fifty-fourth resistors R54 are further connected in parallel with two ends of the fifty-third resistor R53.

in this embodiment, the ultrasonic atomization function is controlled by the ultrasonic control circuit 9, so that the humidification effect is effectively improved. The working time of the ultrasonic wave is set to be 30-60min, the working frequency of the ultrasonic wave is 1MHZ, the working voltage is 36V, and the maximum output is 100V; the ultrasonic waveform is set to 10 grades, the fundamental wave H is 800us, the L is 300us, and the period is 1.1 ms. 1, gear 1: 4 fundamental waves with the interval time of 6.7 milliseconds; 2, gear: 4 fundamental waves with the interval time of 6.2 milliseconds; 3, gear 3: 5 fundamental waves with the interval of 5.7 milliseconds; 4, gear 4: 5 fundamental waves with the interval of 5.2 milliseconds; 5, gear: 6 fundamental waves with the interval time of 4.7 milliseconds; 6, gear 6: 6 fundamental waves with the interval time of 4.2 milliseconds; 7, gear: 7 fundamental waves with the interval time of 3.7 milliseconds; and 8, gear: 7 fundamental waves with the interval time of 3.2 milliseconds; 9, gear: 8 fundamental waves with the interval time of 2.5 milliseconds; 10 gear: 9 fundamental waves with a time interval of 1.7 milliseconds. The effectiveness and the effect of ultrasonic atomization can be effectively improved through the arrangement.

the foregoing is merely a preferred embodiment of the invention, it is to be understood that the invention is not limited to the forms disclosed herein, but is not intended to be exhaustive or to limit the invention to other embodiments, and to various other combinations, modifications, and environments and may be modified within the scope of the inventive concept as expressed herein, by the teachings or the skill or knowledge of the relevant art. And that modifications and variations may be effected by those skilled in the art without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (10)

1. A control circuit of a carving instrument for beauty comprises a power supply circuit and is characterized by further comprising a processing module (1) which is connected with the power supply circuit and used for generating sinusoidal envelope wave signals and receiving signal processing, a non-body-control micro-electric control structure (100) which is in signal connection with the processing module (1) and used for single-person operation, and a body-control micro-electric control structure (200) which is in signal connection with the processing module (1) and used for cooperative operation of two persons, wherein the processing module (1) is connected with an ultrasonic emission head (91) through an ultrasonic control circuit (9) used for ultrasonic atomization control, and the processing module (1) is further in signal connection with an adsorption control structure (300) used for five-row communication, scraping and toxin expelling, private processing and micro-electric sun support; the processing module (1) is further in signal connection with a heating structure (500) which is used for heating the non-body-control micro-control structure (100), the body-control micro-control structure (200) and the adsorption control structure (300) respectively, and the processing module (1) is further in signal connection with a temperature detection structure (600) which is used for detecting the temperature of the non-body-control micro-control structure (100), the body-control micro-control structure (200) and the adsorption control structure (300) respectively to form a heating non-body-control system, a heating body-control system and a heating adsorption system respectively, and the processing module (1) is in signal connection with the display (81) through a communication circuit (8).

2. The control circuit of the carving instrument of claim 1, characterized in that the frequency of the sinusoidal envelope wave generated by the processing module (1) is 1.5KHz-2.5 KHz.

3. The carving instrument control circuit according to claim 1 or 2, characterized in that the non-body-control micro-control structure (100) comprises a first digital potentiometer (U18) connected to the processing module (1) and the power supply circuit, a first power amplifier (U17) connected to the first digital potentiometer (U18) and the power supply circuit, a first voltage transformer (T6) connected to the first power amplifier (U17) and the power supply circuit, and a first electrode tab connector (P40) connected to the first voltage transformer (T6) for connecting to a first electrode tab, the heating structure (500) and the temperature detection structure (600) are arranged in the first electrode plate, and the processing module (1) is connected with the first electrode plate sequentially through the first digital potentiometer (U18), the first power amplifier (U17), the first voltage device (T6) and the first electrode plate joint (P40) to form a bidirectional pulse micro-control and heating structure.

4. the control circuit of the carving beauty apparatus according to claim 1, wherein the processing module (1) is connected with the body-controlled micro-electrical control structure (200) through an operational amplifier (U9), and the processing module (1) is connected with the scraping micro-electrical control structure, the privacy-position micro-electrical control structure, the micro-electric sun-supporting conditioning micro-electrical control structure and the five-row network-communication conditioning micro-electrical control structure through an operational amplifier (U9), and the circuit structure of the scraping micro-electrical control structure, the circuit structure of the privacy-position micro-electrical control structure, the circuit structure of the micro-electric sun-supporting conditioning micro-electrical control structure and the circuit structure of the five-row network-communication conditioning micro-electrical control structure are respectively the same as the circuit structure of the body-controlled micro-electrical control structure (200).

5. The carving instrument control circuit according to claim 1 or 4, characterized in that the body-controlled micro-control structure (200) comprises a second digital potentiometer (U15) connected to the operational amplifier (U9), the processing module (1) and the power supply circuit, a second power amplifier (U14) connected to the second digital potentiometer (U15) and the power supply circuit, a second voltage transformer (T5) connected to the second power amplifier (U14) and the power supply circuit, and a second electrode tab connector (P38) connected to the second voltage transformer (T5) for connecting to a second electrode tab, the heating structure (500) and the temperature detection structure (600) are arranged in the second electrode plate, and the processing module (1) is connected with the second electrode plate through the operational amplifier (U9), the second digital potentiometer (U15), the second power amplifier (U14), the second voltage device (T5) and the second electrode plate connector (P38) in sequence to form a PWM sine wave micro-control and heating structure.

6. The control circuit of the carving beauty apparatus according to claim 1, characterized in that the adsorption control structure (300) comprises an air pump control circuit (2) for connecting with an air pump (21) to control the operation of the air pump (21), an adsorption control circuit (3) for connecting with an adsorption solenoid valve (31) to control the operation of the adsorption solenoid valve (31) to control the adsorption of the negative pressure suction head (7), and a drainage control circuit (4) for connecting with a drainage solenoid valve (41) to control the operation of the negative pressure suction head (7) to stop the adsorption, the air pump control circuit (2), the adsorption electromagnetic valve (31) and the drainage electromagnetic valve (41) are respectively in signal connection with the processing module (1), the adsorption electromagnetic valve (31) is arranged on a connecting pipeline between the air pump (21) and the negative pressure suction head (7), and the drainage electromagnetic valve (41) is arranged on the negative pressure suction head (7).

7. The carving instrument control circuit according to claim 1, characterized in that, the ultrasonic control circuit (9) and through setting up the ultrasonic output joint (P32) and ultrasonic emission head (91) detachable connection, the ultrasonic output joint (P32) one end through second inductance (L2) with supply circuit connection and through twenty seventh electric capacity (C27) with ground connection, the second inductance (L2) with supply circuit connection one end through twenty ninth electric capacity (C29) with ground connection and another end through oscillating tube (Q47) and fourth inductance (L4) with ground connection, the ultrasonic output joint (P32) another end through thirty electric capacity (C30) and first three electric capacity (C113) with ground connection, the thirty electric capacity (C30) and first three electric capacity (C113) connection end through fifth electric capacity (R57) with oscillating tube (Q47), the connecting end of the thirty-third capacitor (C30) and the first one-to-three capacitor (C113) is connected with the collector of a thirty-first triode (Q31), the emitter of a thirty-first triode (Q31) is connected with the ground wire, the base of the thirty-first triode (Q31) is connected with the processing module (1) through a sixteenth resistor (R66), the collector of the thirty-first triode (Q31) is connected with the emitter of a twenty-ninth triode (Q29) through a sixteenth resistor (R62) and a fifty-seventh resistor (R57) in sequence, the collector of the thirty-first triode (Q31) is further connected with the emitter of a twenty-ninth triode (Q29) through a fifteenth resistor (R55), the collector of the twenty-ninth triode (Q29) is connected with the power supply circuit, the base of the twenty-ninth triode (Q29) is connected with the processing module (1) through a fifty-first resistor (R51), the base electrodes of the twenty-ninth triode (Q29) are respectively connected with the power supply circuit through a fifty-third resistor (R50) and a fifty-third resistor (R53), and a fifty-fourth resistor (R54) is further connected in parallel at two ends of the fifty-third resistor (R53).

8. the carving instrument control circuit according to claim 1, characterized in that the heating structure (500) is provided with a heating control circuit (5) connected with the power supply circuit and the processing module (1) and a heating device (51) connected with the heating control circuit (5), and the heating structure (500) is provided with seven structurally identical paths corresponding to the electrode plates and the suction heads.

9. the carving instrument control circuit according to claim 1 or 8, characterized in that the temperature detection structure (600) is provided with a temperature detection circuit (6) connected with the power supply circuit and the processing module (1) and a temperature detection device (61) connected with the temperature detection circuit (6), and the temperature detection structure (600) is provided with seven same structures corresponding to each electrode plate and the suction head.

10. The control circuit of the carving instrument as claimed in claim 1, wherein the power supply circuit outputs 24V dc, 5V dc and 3V dc respectively.