CN103657852B - High-pressure electrostatic air cleaner - Google Patents

Abstract

The invention discloses a kind of high-pressure electrostatic air cleaner, comprise shell, be provided with fan, active carbon filter core, common filter core, electrostatic cleaning position, ion generator and main control circuit in the enclosure; Fan is positioned at the upper left side of shell, and active carbon filter core is positioned at the below of fan, and ion generator is positioned at the right side of fan; Common filter core is positioned at the lower left of shell, and electrostatic cleaning position is between active carbon filter core and common filter core; Main control circuit is positioned at the right side of electrostatic cleaning position.High-pressure electrostatic air cleaner of the present invention, has and effectively can remove indoor niff, improve air quality, improve clean-up effect, guarantee the advantages such as the security reliability of air purifier work.

Description

High-pressure electrostatic air cleaner

Technical field

The present invention relates to a kind of high-pressure electrostatic air cleaner.

Background technology

Air is that the mankind are resistance to the necessary condition of existence, is also pathophorous important medium.The quality of air quality is directly related with our health.Due to air quality more and more cause the concern of people+, air purifier market a slice in worldwide is had an optimistic view of.Air purifier is a kind of Domestic electrical equipment, it has detects smog, elimination dust, function such as elimination peculiar smell and pernicious gas etc. automatically, it is made up of systems such as circuit for producing high voltage, anion generator, gentle breeze fan, air cleaners usually, mainly contain following three types: one is filter absorbent-type, two is electrostatic precipitation types, and three is compound.Wherein, compound simultaneously utilization is filtered and electrostatic precipitation mode, and clean-up effect is best.

The present invention is based on the research to air purifier current situation, utilize compound mode, and combine anion generator popular at present, even better compared with conventional air cleaners on clean-up effect.

Summary of the invention

The present invention is for avoiding the weak point that exists in above-mentioned prior art, providing a kind of high-pressure electrostatic air cleaner, to improve clean-up effect, to guarantee the security reliability of air purifier work.

The invention provides a kind of high-pressure electrostatic air cleaner.

High-pressure electrostatic air cleaner, its design feature comprises shell, is provided with fan, active carbon filter core, common filter core, electrostatic cleaning position, ion generator and main control circuit in described shell; Described fan is positioned at the upper left side of described shell, and described active carbon filter core is positioned at the below of described fan, and described ion generator is positioned at the right side of described fan; Described common filter core is positioned at the lower left of shell, and described electrostatic cleaning position is between described active carbon filter core and described common filter core; Described main control circuit is positioned at the right side of described electrostatic cleaning position; The front plate of described shell is provided with guidance panel, and described main control circuit is positioned at the rear of described guidance panel.

The feature of high-pressure electrostatic air cleaner of the present invention is also:

Described main control circuit comprises microprocessor AVR, ion generator control circuit, power circuit, fan control circuitry, audible alarm circuit, key circuit and indicating lamp control circuit; Described ion generator control circuit, power circuit, fan control circuitry, audible alarm circuit, key circuit and indicating lamp control circuit are all connected with described microprocessor AVR.

Described ion generator control circuit comprises ion generator power plug interface IONIZER, high voltage package interface HIV1, resistance R1, resistance R10, resistance R27, transformer L1, relay R ELAY, triode TR2, triode TR3, electric capacity C2, diode D6; Described triode TR2 is connected with microprocessor AVR by resistance R10, and described triode TR3 is connected with microprocessor AVR by resistance R27.

Described power circuit comprises voltage stabilizing chip IC 1, the rectifier bridge be made up of diode D1 ~ D4, power supply output interface T2, resistance R2, electric capacity C1, electric capacity C3 ~ C5, electric capacity C12 and electric capacity C17; Described resistance R2, electric capacity C1, electric capacity C3 ~ C5, electric capacity C12 and electric capacity C17 are all connected with described voltage stabilizing chip IC 1, and described rectifier bridge is connected with described voltage stabilizing chip IC 1, and power supply exports interface T2 and is connected with described rectifier bridge.

Described fan control circuitry comprises power plug interface T1, fan connects interface CN1, resistance R14 ~ R16, resistance R20, resistance R24 ~ R26, resistance R31, optocoupler IC2 ~ IC4, bidirectional thyristor Q1 ~ Q3, resistance RES1 and electric capacity C10; Described optocoupler IC2 ~ IC4 is connected with described microprocessor AVR respectively by resistance R14 ~ R16.

Described audible alarm circuit comprises resistance R30, triode TR1 and buzzer U1; One end of described resistance R30 is connected with described microprocessor AVR, the other end of described resistance R30 is connected with the base stage of described triode TR1, the emitter stage of described triode TR1 connects power supply VCC, and the colelctor electrode of described triode TR1 is connected with described buzzer U1.

Described key circuit comprises resistance R19, resistance R28 ~ R29, button K1 ~ K3; Described button K1 is connected with described microprocessor AVR by resistance R28, and described button K2 is connected with described microprocessor AVR by resistance R19, and described button K3 is connected with described microprocessor AVR by resistance R29.

Described indicating lamp control circuit comprises resistance R4, resistance R5 ~ R6, resistance R11 ~ R13, LED 1 ~ LED3, LED 5 ~ LED7; Described LED 1 is connected with described microprocessor AVR by resistance R4, described LED 2 is connected with described microprocessor AVR by resistance R7, described LED 3 is connected with described microprocessor AVR by resistance R6, described LED 5 is connected with described microprocessor AVR by resistance R11, described LED 6 is connected with described microprocessor AVR by resistance R13, and described LED 7 is connected with described microprocessor AVR by resistance R12.

Compared with the prior art, beneficial effect of the present invention is embodied in:

High-pressure electrostatic air cleaner of the present invention, the control circuit of the air purifier also researched and developed on this basis for kernel control chip with ATmega16L microprocessor.The key control unit of native system have employed the Atmega16L single-chip microcomputer of atmel corp, utilize high voltage electrostatic technique, impurity absorption is destroyed in cleaning position, coordinate ion generator simultaneously, merge the suspension grain that can reduce 99% of the interior space that singlechip technology, embedded technology etc. form, pet hair scurf and other may cause irritated asthma reaction anaphylactogen, remove niff, effectively improve the air purifier product of air quality.

High-pressure electrostatic air cleaner of the present invention, can be applicable to the different occasions such as office, family, leisure, greatly can improve air quality, improve surrounding environment.

High-pressure electrostatic air cleaner of the present invention, has and effectively can remove indoor niff, improve air quality, improve clean-up effect, guarantee the advantages such as the security reliability of air purifier work.

Accompanying drawing explanation

Fig. 1 is the structural representation of high-pressure electrostatic air cleaner of the present invention.

Fig. 2 is the structured flowchart of the main control circuit of high-pressure electrostatic air cleaner of the present invention.

Fig. 3 is the microprocessor AVR of high-pressure electrostatic air cleaner of the present invention and the circuit diagram of key circuit.

Fig. 4 is the circuit diagram of the ion generator control circuit of high-pressure electrostatic air cleaner of the present invention.

Fig. 5 is the circuit diagram of the power circuit of high-pressure electrostatic air cleaner of the present invention.

Fig. 6 is the circuit diagram of the fan control circuitry of high-pressure electrostatic air cleaner of the present invention.

Fig. 7 is the circuit diagram of the audible alarm circuit of high-pressure electrostatic air cleaner of the present invention.

Fig. 8 is the circuit diagram of the indicating lamp control circuit of high-pressure electrostatic air cleaner of the present invention.

Fig. 9 is the circuit diagram of the peculiar smell absorbing curtain sensor circuit of high-pressure electrostatic air cleaner of the present invention.

Figure 10 is the circuit diagram of the luminous lamp control circuit of high-pressure electrostatic air cleaner of the present invention.

Figure 11 is the circuit diagram of the high voltage package feedback circuit of high-pressure electrostatic air cleaner of the present invention.

Label in accompanying drawing 1: 1 shell, 2 fans, 3 active carbon filter cores, 4 common filter cores, 5 electrostatic cleaning positions, 6 ion generators, 7 guidance panels.

Below by way of detailed description of the invention, and the invention will be further described by reference to the accompanying drawings.

Detailed description of the invention

See Fig. 1 ~ 11, high-pressure electrostatic air cleaner, it comprises shell 1, is provided with fan 2, active carbon filter core 3, common filter core 4, electrostatic cleaning position 5, ion generator 6 and main control circuit in described shell 1; Described fan 2 is positioned at the upper left side of described shell 1, and described active carbon filter core 3 is positioned at the below of described fan 2, and described ion generator 6 is positioned at the right side of described fan 2; Described common filter core 4 is positioned at the lower left of shell 1, and described electrostatic cleaning position 5 is between described active carbon filter core 3 and described common filter core 4; Described main control circuit is positioned at the right side of described electrostatic cleaning position 5; The front plate of described shell is provided with guidance panel 7, and described main control circuit is positioned at the rear of described guidance panel 7.

Described guidance panel is provided with the indicator lamp of button and running status.Raw gas, under the drive of electric motor fan, enters housing from air intake vent, first filters for the first time through plain gauze, particulate larger for volume in gas is isolated in outside filter core, enters cleaning position afterwards, under the effect of high-pressure electrostatic, make electric charge on fine particles band, be attached on pole plate; Purified gas carries out the purification of third time again by active carbon filter core, ensure the completeness of purification.In this process, the effect of ion generator releases a large amount of oxygen of electronics with air in be combined, and generation negative aeroion, enlivens air molecule, makes the air of going out from air outlet more pure and fresh.

Described main control circuit comprises microprocessor AVR, ion generator control circuit, power circuit, fan control circuitry, audible alarm circuit, key circuit and indicating lamp control circuit; Described ion generator control circuit, power circuit, fan control circuitry, audible alarm circuit, key circuit and indicating lamp control circuit are all connected with described microprocessor AVR.

If Fig. 2 is the structured flowchart of main control circuit.Fig. 3 is the circuit diagram of microprocessor AVR and key circuit.The preferred ATmega16 of described microprocessor AVR.ATmega16 is low-power consumption 8 the CMOS microcontrollers based on the AVRRISC structure strengthened.Due to instruction set and single clock cycle time for each instruction of its advanced person, the data throughput of ATmega16, thus can the contradiction of relieving system between power consumption and processing speed up to 1MIPS/MHz.User is entered the operating instructions by key circuit, operational order is transferred to microprocessor AVR by key circuit, then control instruction is issued ion generator control circuit by microprocessor AVR respectively, fan control circuitry, the circuit modules such as audible alarm circuit and indicating lamp control circuit, by each circuit module respectively to ion generator, fan, alarm buzzer and LED light etc. control, realize the control of these equipment, thus realize the control of whole high-pressure electrostatic air cleaner, and can filter core continuous operation 1 year, electrostatic cleaning position continuous operation two weeks or the too many alarm of dust, user is reminded to note safeguarding air purifier, improve the safe and reliable property of air purifier.

Described ion generator control circuit comprises ion generator power plug interface IONIZER, high voltage package interface HIV1, resistance R1, resistance R10, resistance R27, transformer L1, relay R ELAY, triode TR2, triode TR3, electric capacity C2, diode D6; The base stage of described triode TR2 is connected with microprocessor AVR by resistance R10, and the colelctor electrode of triode TR2 is connected with the terminal 1 of ion generator power plug interface IONIZER, the grounded emitter of triode TR2; Described resistance R1 is connected the terminal 2 of ion generator power plug interface IONIZER with the one end after described electric capacity C2 connection parallel with one another, the emitter stage of the other end connecting triode TR2 after resistance R1 and described electric capacity C2 connection parallel with one another ground connection; The negative pole of described diode D6 connects the terminal 2 of relay R ELAY and connects the terminal 2 of ion generator power plug interface IONIZER, the colelctor electrode of the positive pole connecting triode TR3 of diode D6; The base stage of described triode TR3 is connected with microprocessor AVR by resistance R27, the grounded emitter of triode TR3; One end of the primary winding of transformer L1 connects civil power live wire L, and the other end connects the terminal 1 of high voltage package interface HIV1; One end of the secondary coil of transformer L1 connects civil power zero line N, and the other end connects terminal 1 and the terminal 4 of relay R ELAY; The terminal 6 of the terminal 2 contact relay RELAY of high voltage package interface HIV1; The terminal 5 of relay R ELAY connects the positive pole of diode D6.

As the circuit diagram that Fig. 4 is ion generator control circuit, the annexation between each circuit components is shown in Fig. 4.Utilize relay J 1 to control the energising of high voltage package, provide high pressure to ion generator.The negative oxygen ion generator of air purifier adopts XJ2600-P49 ion generator.That the electrostatic precipitator of air purifier adopts is the electrostatic cleaning position TrumanCell that Oreck company of the U.S. produces.The power supply of described air purifier adopts DC speed-reducing.Utilize high-tension transformer to be boosted to by power-frequency voltage must voltage method produce anion, be discharged in ambient air, purify air.With relay as high voltage package power switch, high voltage package provides high pressure to electrostatic cleaning position, carries out receiving the dust of catching in flue gas with electrostatic depuration method.Its purification work mainly relies on discharge electrode and these two systems of receiving electrode.Produce anions and canons when two interpolar input high voltage direct currents at electrode space, and act on the particle surface by electrostatic field, move to its opposite polarity electrode under the effect of electric field force, and be deposited on electrode, reach object of gathering dust.In figure, diode D6 shields, and the electric current that when preventing relay coil from disconnecting, inverse electromotive force produces punctures triode TR3.

Described power circuit comprises voltage stabilizing chip IC 1, the rectifier bridge be made up of diode D1 ~ D4, power supply output interface T2, resistance R2, electric capacity C1, electric capacity C3 ~ C5, electric capacity C12 and electric capacity C17; Described resistance R2, electric capacity C1, electric capacity C3 ~ C5, electric capacity C12 and electric capacity C17 are all connected with described voltage stabilizing chip IC 1, and described rectifier bridge is connected with described voltage stabilizing chip IC 1, and power supply exports interface T2 and is connected with described rectifier bridge.

If Fig. 5 is the circuit diagram of power circuit, the annexation between each circuit components is shown in Fig. 5.Voltage stabilizing chip U2 is three proper power supply stabilization circuit L7805.L7805 is one piece three and rectifies power supply integrated regulator.The built-in short-circuit protection of this circuit and thermal protection circuit, have the advantages that output voltage is fixing, be widely used in doing power supply voltage stabilizing in the equipment such as various television set, radio cassette player, electronic instrument.L7805 adopts the packing forms encapsulation of three lead-in wire band fin plastics TO-220.

Each module of high-pressure electrostatic air cleaner of the present invention has needed several voltage, and the first is the 5V voltage needed for microcontroller chip Atmega16L, and the second is the 12V voltage needed for ion generator, and the third is the input 110V voltage of high voltage package.110V supply voltage is by transformer pressure-reducing, and then by obtaining 12V DC voltage after bridge rectifier rectification, capacitor filtering, this voltage supply ion generator is as the input voltage of ion generator; 12V DC voltage continues to input to 7805 mu balanced circuits backward, reduces the voltage to the 5V voltage that single-chip microcomputer is suitable for, powers to single-chip microcomputer.

Described fan control circuitry comprises power plug interface T1, fan connects interface CN1, resistance R14 ~ R16, resistance R20, resistance R24 ~ R26, resistance R31, optocoupler IC2 ~ IC4, bidirectional thyristor Q1 ~ Q3, resistance RES1 and electric capacity C10; Described optocoupler IC2 ~ IC4 is connected with described microprocessor AVR respectively by resistance R14 ~ R16.

The negative pole end of the light emitting diode of described optocoupler IC2 is connected with described microprocessor AVR by resistance R14, the upper terminal of the light-receiving device of optocoupler IC2 is connected the terminal 4 of interface CN1 with fan by the Anodic of resistance R26 connection bidirectional thyristor Q3, the lower terminal of the light-receiving device of IC2 connects the control pole of bidirectional thyristor Q3, the lower anode of bidirectional thyristor Q1, the lower anode of bidirectional thyristor Q2 and the lower anode of bidirectional thyristor Q3 are interconnected, the lower anode of bidirectional thyristor Q3 also connects the terminal 5 of fan connection interface CN1 by resistance RES1, the lower anode of bidirectional thyristor Q3 is also connected the terminal 1 of power plug interface T1 with resistance R31 by resistance RES1, between the terminal 1 that two ends after electric capacity C10 and resistance R20 is parallel with one another are connected to power plug interface T1 and terminal 2,

The negative pole end of the light emitting diode of described optocoupler IC3 is connected with described microprocessor AVR by resistance R15, the upper terminal of the light-receiving device of optocoupler IC3 is connected the control pole of the lower terminal connection bidirectional thyristor Q2 of the light-receiving device of the terminal 3, IC2 of interface CN1 with fan by the Anodic of resistance R25 connection bidirectional thyristor Q2;

The negative pole end of the light emitting diode of described optocoupler IC4 is connected with described microprocessor AVR by resistance R16, the upper terminal of the light-receiving device of optocoupler IC4 is connected the terminal 2 of interface CN1 with fan by the Anodic of resistance R24 connection bidirectional thyristor Q1, the lower terminal of the light-receiving device of IC4 connects the control pole of bidirectional thyristor Q1, and the lower anode of bidirectional thyristor Q1 also directly connects the terminal 1 of fan connection interface CN1.

If Fig. 6 is the circuit diagram of fan control circuitry, the annexation between each circuit components is shown in Fig. 6.In this control system, have employed the core component of DC speed-reducing as controlled wind speed.As shown in Figure 6, three road IGCT supply fans are utilized, the wind speed of control system.Three MOC3023 photoelectricity coupling IC2 ~ IC4 are connected with PA0, PA1, PA2 of single-chip microcomputer respectively, when this three I/O mouths difference output low levels, the light emitting diode triggered in connected MOC3023 is sent the light of certain wavelength, make output conducting, thus control the rotating speed of motor.

Described audible alarm circuit comprises resistance R30, triode TR1 and buzzer U1; One end of described resistance R30 is connected with described microprocessor AVR, the other end of described resistance R30 is connected with the base stage of described triode TR1, the emitter stage of described triode TR1 connects power supply VCC, and the colelctor electrode of described triode TR1 is connected with described buzzer U1.

As the circuit diagram that Fig. 7 is audible alarm circuit, the annexation between each circuit components is shown in Fig. 7.As Fig. 7, when needs are reported to the police, sent out by alarm command by microprocessor AVR, the level provided by the pin of microprocessor AVR makes triode TR1 conducting, thus provides driving power VCC, warning of sounding for buzzer U1.Filter core continuous operation 1 year, electrostatic cleaning position continuous operation two weeks or dust is too many time all report to the police.

Described key circuit comprises resistance R19, resistance R28 ~ R29, button K1 ~ K3; Described button K1 is connected with described microprocessor AVR by resistance R28, and described button K2 is connected with described microprocessor AVR by resistance R19, and described button K3 is connected with described microprocessor AVR by resistance R29.

As the circuit diagram that Fig. 3 is microprocessor AVR and key circuit.Key device, for adjusting wind speed and various state.Microprocessor AVR comprises peripheral circuit, and peripheral circuit comprises clock circuit, reset circuit and resistance R18.Power supply VCC is connected with microprocessor AVR by described resistance R18.Described reset circuit comprises resistance R17, electric capacity C9.Described clock circuit comprises electric capacity C6 and C7, crystal oscillator Y1.Annexation between each circuit components is shown in Fig. 2.

Described indicating lamp control circuit comprises resistance R4, resistance R5 ~ R6, resistance R11 ~ R13, LED 1 ~ LED3, LED 5 ~ LED7; Described LED 1 is connected with described microprocessor AVR by resistance R4, described LED 2 is connected with described microprocessor AVR by resistance R7, described LED 3 is connected with described microprocessor AVR by resistance R6, described LED 5 is connected with described microprocessor AVR by resistance R11, described LED 6 is connected with described microprocessor AVR by resistance R13, and described LED 7 is connected with described microprocessor AVR by resistance R12.

If Fig. 8 is the circuit diagram of indicating lamp control circuit, the annexation between each circuit components is shown in Fig. 8.

Six light emitting diodes are connected with six I/O mouths of the PB of microprocessor AVR respectively, and the current-limiting resistance of 470 Ω that connect respectively, shows for various state.K1, K2, K3 tri-buttons are connected with PD2, PB2, PD3 tri-I/O mouths respectively, for controlling six light emitting diodes.Concrete control mode is: the rotating speed of K1 key control motor, obtains different wind speed with this.LED5, LED6, LED7 tri-light emitting diodes represent high, medium and low third gear wind speed respectively, and first time presses K1 key, and motor is in fast state, press a K1 key again, motor is transformed into moderate rotation, and third time presses K1 key, motor is transformed into lower-speed state, circulates with this.K2 key is used for controlling luminous lamp, facilitates use night.K3 key controls LED2, LED3.LED2, LED3 are respectively electrostatic cleaning position, filter screen indicator lamp, all report to the police when considering net continuous operation 1 year, electrostatic cleaning position continuous operation two weeks or dust is too many, corresponding indicator lamp is bright, buzzer rings, now we need electrostatic cleaning position to remove to clean, change filter screen, press K3 key afterwards, corresponding indicator lamp is extinguished.

Microprocessor AVR is also connected with peculiar smell absorbing curtain sensor circuit, luminous lamp control circuit and high voltage package feedback circuit.

As the circuit diagram that Fig. 9 is peculiar smell absorbing curtain sensor circuit.Described peculiar smell absorbing curtain sensor circuit comprises resistance R3, electric capacity C18 and peculiar smell absorbing curtain and takes out inductive switch K4; The splicing ear 1 that described resistance R3, electric capacity C18 all take out inductive switch K4 with described peculiar smell absorbing curtain is connected; Described splicing ear 1 is also connected with described microprocessor AVR.Annexation between each circuit components is shown in Fig. 9.

As the circuit diagram that Figure 10 is luminous lamp control circuit.Luminous lamp control circuit comprises luminous lamp and connects interface CN1, resistance R8 and resistance R9; The splicing ear 1 that luminous lamp connects interface CN1 is connected with microprocessor AVR with resistance R9 respectively by resistance R8 with splicing ear 2.Annexation between each circuit components is shown in Figure 10.

As the circuit diagram that Figure 11 is high voltage package feedback circuit.High voltage package feedback circuit comprises resistance R21 ~ R23, electric capacity C11, electric capacity C8, diode D5, optocoupler IC5 and high voltage package feedback interface HIV2.Annexation between each circuit components is shown in Figure 11.

High-pressure electrostatic air cleaner of the present invention, the control circuit of the air purifier also researched and developed on this basis for kernel control chip with ATmega16L microprocessor.The key control unit of native system have employed the Atmega16L single-chip microcomputer of atmel corp, utilize high voltage electrostatic technique, impurity absorption is destroyed in cleaning position, coordinate ion generator simultaneously, merge the suspension grain that can reduce 99% of the interior space that singlechip technology, embedded technology etc. form, pet hair scurf and other may cause irritated asthma reaction anaphylactogen, remove niff, effectively improve the air purifier product of air quality.

High-pressure electrostatic air cleaner of the present invention, can be applicable to the different occasions such as office, family, leisure, greatly can improve air quality, improve surrounding environment, have and effectively can remove indoor niff, improve air quality, improve clean-up effect, guarantee the advantages such as the security reliability of air purifier work.

Claims (6)

1. high-pressure electrostatic air cleaner, it is characterized in that, comprise shell (1), in described shell (1), be provided with fan (2), active carbon filter core (3), common filter core (4), electrostatic cleaning position (5), ion generator (6) and main control circuit; Described fan (2) is positioned at the upper left side of described shell (1), described active carbon filter core (3) is positioned at the below of described fan (2), and described ion generator (6) is positioned at the right side of described fan (2); Described common filter core (4) is positioned at the lower left of shell (1), and described electrostatic cleaning position (5) is positioned between described active carbon filter core (3) and described common filter core (4); Described main control circuit is positioned at the right side of described electrostatic cleaning position (5); The front plate of described shell is provided with guidance panel (7), and described main control circuit is positioned at the rear of described guidance panel (7);

Described control circuit comprises microprocessor AVR, ion generator control circuit, power circuit, fan control circuitry, audible alarm circuit, key circuit and indicating lamp control circuit; Described ion generator control circuit, power circuit, fan control circuitry, audible alarm circuit, key circuit and indicating lamp control circuit are all connected with described microprocessor AVR;

Described ion generator control circuit comprises ion generator power plug interface IONIZER, high voltage package interface HIV1, resistance R1, resistance R10, resistance R27, transformer L1, relay R ELAY, triode TR2, triode TR3, electric capacity C2, diode D6; The base stage of described triode TR2 is connected with microprocessor AVR by resistance R10, and the colelctor electrode of triode TR2 is connected with the terminal 1 of ion generator power plug interface IONIZER, the grounded emitter of triode TR2; Described resistance R1 is connected the terminal 2 of ion generator power plug interface IONIZER with the one end after described electric capacity C2 connection parallel with one another, the emitter stage of the other end connecting triode TR2 after resistance R1 and described electric capacity C2 connection parallel with one another ground connection; The negative pole of described diode D6 connects the terminal 2 of relay R ELAY and connects the terminal 2 of ion generator power plug interface IONIZER, the colelctor electrode of the positive pole connecting triode TR3 of diode D6; The base stage of described triode TR3 is connected with microprocessor AVR by resistance R27, the grounded emitter of triode TR3; One end of the primary winding of transformer L1 connects civil power live wire L, and the other end connects the terminal 1 of high voltage package interface HIV1; One end of the secondary coil of transformer L1 connects civil power zero line N, and the other end connects terminal 1 and the terminal 4 of relay R ELAY; The terminal 6 of the terminal 2 contact relay RELAY of high voltage package interface HIV1; The terminal 5 of relay R ELAY connects the positive pole of diode D6.

2. high-pressure electrostatic air cleaner according to claim 1, it is characterized in that, described power circuit comprises voltage stabilizing chip IC 1, the rectifier bridge be made up of diode D1 ~ D4, power supply output interface T2, resistance R2, electric capacity C1, electric capacity C3 ~ C5, electric capacity C12 and electric capacity C17; Described resistance R2, electric capacity C1, electric capacity C3 ~ C5, electric capacity C12 and electric capacity C17 are all connected with described voltage stabilizing chip IC 1, and described rectifier bridge is connected with described voltage stabilizing chip IC 1, and power supply exports interface T2 and is connected with described rectifier bridge.

3. high-pressure electrostatic air cleaner according to claim 1, it is characterized in that, described fan control circuitry comprises power plug interface T1, fan connects interface CN1, resistance R14 ~ R16, resistance R20, resistance R24 ~ R26, resistance R31, optocoupler IC2 ~ IC4, bidirectional thyristor Q1 ~ Q3, resistance RES1 and electric capacity C10; Described optocoupler IC2 ~ IC4 is connected with described microprocessor AVR respectively by resistance R14 ~ R16;

The negative pole end of the light emitting diode of described optocoupler IC2 is connected with described microprocessor AVR by resistance R14, the upper terminal of the light-receiving device of optocoupler IC2 is connected the terminal 4 of interface CN1 with fan by the Anodic of resistance R26 connection bidirectional thyristor Q3, the lower terminal of the light-receiving device of IC2 connects the control pole of bidirectional thyristor Q3, the lower anode of bidirectional thyristor Q1, the lower anode of bidirectional thyristor Q2 and the lower anode of bidirectional thyristor Q3 are interconnected, the lower anode of bidirectional thyristor Q3 also connects the terminal 5 of fan connection interface CN1 by resistance RES1, the lower anode of bidirectional thyristor Q3 is also connected the terminal 1 of power plug interface T1 with resistance R31 by resistance RES1, between the terminal 1 that two ends after electric capacity C10 and resistance R20 is parallel with one another are connected to power plug interface T1 and terminal 2,

The negative pole end of the light emitting diode of described optocoupler IC3 is connected with described microprocessor AVR by resistance R15, the upper terminal of the light-receiving device of optocoupler IC3 is connected the control pole of the lower terminal connection bidirectional thyristor Q2 of the light-receiving device of the terminal 3, IC2 of interface CN1 with fan by the Anodic of resistance R25 connection bidirectional thyristor Q2;

The negative pole end of the light emitting diode of described optocoupler IC4 is connected with described microprocessor AVR by resistance R16, the upper terminal of the light-receiving device of optocoupler IC4 is connected the terminal 2 of interface CN1 with fan by the Anodic of resistance R24 connection bidirectional thyristor Q1, the lower terminal of the light-receiving device of IC4 connects the control pole of bidirectional thyristor Q1, and the lower anode of bidirectional thyristor Q1 also directly connects the terminal 1 of fan connection interface CN1.

4. high-pressure electrostatic air cleaner according to claim 1, is characterized in that, described audible alarm circuit comprises resistance R30, triode TR1 and buzzer U1; One end of described resistance R30 is connected with described microprocessor AVR, the other end of described resistance R30 is connected with the base stage of described triode TR1, the emitter stage of described triode TR1 connects power supply VCC, and the colelctor electrode of described triode TR1 is connected with described buzzer U1.

5. high-pressure electrostatic air cleaner according to claim 1, is characterized in that, described key circuit comprises resistance R19, resistance R28 ~ R29, button K1 ~ K3; Described button K1 is connected with described microprocessor AVR by resistance R28, and described button K2 is connected with described microprocessor AVR by resistance R19, and described button K3 is connected with described microprocessor AVR by resistance R29.

6. high-pressure electrostatic air cleaner according to claim 1, is characterized in that, described indicating lamp control circuit comprises resistance R4, resistance R5 ~ R6, resistance R11 ~ R13, LED 1 ~ LED3, LED 5 ~ LED7; Described LED 1 is connected with described microprocessor AVR by resistance R4, described LED 2 is connected with described microprocessor AVR by resistance R7, described LED 3 is connected with described microprocessor AVR by resistance R6, described LED 5 is connected with described microprocessor AVR by resistance R11, described LED 6 is connected with described microprocessor AVR by resistance R13, and described LED 7 is connected with described microprocessor AVR by resistance R12.