CN203896196U - Inverter type arc spraying power supply based on phase shifted full bridge - Google Patents

Abstract

The utility model relates to an inverter type arc spraying power supply based on a phase shifted full bridge. The inverter type arc spraying power supply comprises a first rectifying circuit, a first filtering circuit, a full bridge circuit, a high-frequency transformer T, a second rectifying circuit and a second filtering circuit which are sequentially connected. The first rectifying circuit is connected to three-phase AC input, and the second filtering circuit is connected to an electric arc spray gun. The inverter type arc spraying power supply of the utility model also comprises an auxiliary control module used for controlling the full bridge circuit to work. According to the inverter type arc spraying power supply of the utility model, the phase shifted full bridge control is utilized to realize the soft switch of a switch tube, the switch loss of the power supply is greatly reduced by the soft switch technology, the overall efficiency is raised, and the electric energy is saved.

Description

Contravariant electrical arc spraying power source based on phase-shifting full-bridge

Technical field

The utility model relates to Surface Engineering field of thermal spray, particularly a kind of contravariant electrical arc spraying power source based on phase-shifting full-bridge.

Background technology

Arc spraying technology is a kind of economy, applied widely, flexible, the high efficiency heat spraying method of constructing, and is a kind of process for modifying surface in industrial circle extensive use.Along with updating of electric arc spraying equipment, spraying coating process is improved, and arc spraying technology has welcome new development.

The basic principle of electric arc spraying is thereby that electrical arc spraying power source is added between two wires of sending to continuously and forms electric arc, and the heat of electric arc, by metal molten, utilizes compressed air that molten metal is atomized into micro-molten drop, sprays at a high speed surface of the work and forms coating.This coating is not changing on the basis of workpiece substrate material property, and significantly lifting workpieces combination property is as wear-resisting, anticorrosion, anti-oxidant, heat insulation etc.

Conventional arc spraying source adopts Industrial Frequency Transformer step-down, the galvanic topology of rectification output constant voltage, advantage is simple in structure, but the more problems of its existence, mainly contain following some: 1. because transformer is operated in power frequency state, power volume is large, quality weight, be unfavorable for the construction under on-the-spot especially complex working condition, restricted the application of arc spraying technology.2. complete machine adopts without the open loop of feedback and controls, and cannot follow the tracks of controls to output current, during reality use current fluctuation very large, seriously reduced the quality of arc spraying coating.3. the adjusting of output voltage realizes by transformer tapping, conventionally divides several gears, is not electrodeless adjusting, for different sprayed on material, cannot export accurately optimum spray voltage, has affected coating quality.

Summary of the invention

Technical problem to be solved in the utility model is to overcome the deficiencies in the prior art, a kind of contravariant electrical arc spraying power source based on phase-shifting full-bridge is provided, from structure and control mode solved conventional spray paint body long-pending large, quality is heavy, without FEEDBACK CONTROL, cannot accurately control the shortcomings such as output voltage, dwindling on the basis of complete machine size, improve performance, optimized coating quality.

For solving above technical problem, the utility model adopts following technical scheme:

A contravariant electrical arc spraying power source based on phase-shifting full-bridge, comprises the first rectification circuit, the first filter circuit, full-bridge circuit, high frequency transformer T, the second rectification circuit and the second filter circuit that connect successively, wherein:

Described the first rectification circuit is connected to three-phase alternating current input;

Described the second filter circuit is connected to arc pistol;

Described the first filter circuit comprises inductance L and the capacitor C that is connected in series in described the first rectification circuit two ends;

Described full-bridge circuit comprises the first switching tube Q ₁, second switch pipe Q ₂, the 3rd switching tube Q ₃, the 4th switching tube Q ₄, described the first switching tube Q ₁with described the 3rd switching tube Q ₃after series connection, be connected in described capacitor C two ends in parallel, described second switch pipe Q ₂with described the 4th switching tube Q ₄after series connection, be also connected in described capacitor C two ends in parallel;

Described contravariant electrical arc spraying power source also comprises auxiliary control module, for controlling described full-bridge circuit work;

Described auxiliary control module comprises output sample circuit, PI regulating circuit, the PWM controller connecting successively,

Described output sample circuit is connected to described arc pistol, for gathering output voltage and the output current of described arc pistol;

Described PI regulating circuit is for will carry out PI computing after Voltage Feedback value and predeterminated voltage reference value, output signal, and wherein, described Voltage Feedback value is the output voltage of the described arc pistol that collects of described output sample circuit;

Described PWM controller is for comparing the modulation wave signal of the signal of described PI regulating circuit output and the generation of described PWM controller, change the width of described PWM controller output pulse signal, output pulse signal, described pulse signal is used for controlling described full-bridge circuit work.

Described full-bridge circuit also comprises diode D ₁, diode D ₂, capacitor C ₁and capacitor C ₃, described diode D ₁be connected in parallel on described the first switching tube Q ₁two ends; Described capacitor C ₁also be connected in parallel on described the first switching tube Q ₁two ends; Described diode D ₂be connected in parallel on described the 3rd switching tube Q ₃two ends; Described capacitor C ₃also be connected in parallel on described the 3rd switching tube Q ₃two ends.

Described the first switching tube Q ₁with described the 3rd switching tube Q ₃be insulated gate bipolar transistor.

Described second switch pipe Q ₂with described the 4th switching tube Q ₄be inverse-impedance type insulated gate bipolar transistor.

Full-bridge circuit of the present utility model, based on phase shifting control, realizes zero-voltage and zero-current switch (ZVZCS).

Described contravariant electrical arc spraying power source of the present utility model also comprises auxiliary protection module, for the protection of the safety of described contravariant electrical arc spraying power source;

Described auxiliary protection module comprises testing circuit and Single-chip Controlling and the protection module connecting successively, wherein:

Described testing circuit is connected to described arc pistol, for detection of the operating state of described contravariant electrical arc spraying power source, output signal;

Described Single-chip Controlling and protection module are connected to described full-bridge circuit, for the signal of described testing circuit output is analyzed, processed, in time fault are processed, and protect the safety of described contravariant electrical arc spraying power source.

Described the first rectification circuit of the present utility model is three-phase commutation bridge.

The basic functional principle of contravariant electrical arc spraying power source of the present utility model is: the three-phase alternating current 380V of input becomes the direct current of 540V left and right through the first rectification circuit and the first filter circuit, via full-bridge circuit, carry out inversion again, become high frequency square wave alternating current, by high frequency transformer, transfer energy to the second rectification circuit of secondary, by its rectification, be direct current, by the required galvanic current of the final output of the second filter circuit.

Due to the enforcement of technique scheme, the utility model compared with prior art tool has the following advantages:

Contravariant electrical arc spraying power source of the present utility model adopts phase shifting control to realize the soft switch of switching tube, and soft switch technique greatly reduces the switching loss of power supply, has improved overall efficiency, has saved electric energy.Reducing on the basis of heat radiation in addition, greatly reducing equally the volume of radiator.

Energy in contravariant electrical arc spraying power source of the present utility model transmits by high frequency transformer, conventionally can accomplish 20KHz, greatly reduces volume and the quality of complete machine.

Contravariant electrical arc spraying power source of the present utility model, by the sampling of output voltage, electric current is carried out to closed-loop control, coincide output valve and preset reference value, and output waveform quality is high, effectively improves coating quality.

Contravariant electrical arc spraying power source of the present utility model, by changing preset reference value, can be realized the output of free voltage within the scope of change in voltage.

Accompanying drawing explanation

Fig. 1 is the structured flowchart of the contravariant electrical arc spraying power source based on phase-shifting full-bridge of the present utility model;

Fig. 2 is the circuit theory diagrams of the contravariant electrical arc spraying power source based on phase-shifting full-bridge of the present utility model;

Key waveforms figure when Fig. 3 is the full-bridge circuit work in Fig. 2.

Embodiment

Below in conjunction with Figure of description, the utility model is further described, obviously, described embodiment is only the utility model part, does not limit the scope of utility model.

Existing electrical arc spraying power source adopts Industrial Frequency Transformer step-down more, the galvanic topology of rectification output constant voltage, and in spraying source, the volume and weight of magnetic elements is large.Other contravariant electrical arc spraying power sources adopt hard switching technology more, and switching loss is large, and efficiency is low.Contravariant electrical arc spraying power source based on phase-shifting full-bridge of the present utility model, can accurately control output voltage, electric current, adopts soft switch technique; reduce switching loss; improve the efficiency of spraying source, and can carry out real-time monitoring to spraying source, automatically realize protection.

As shown in Figure 1 and 2, contravariant electrical arc spraying power source based on phase-shifting full-bridge of the present utility model, comprise the first rectification circuit 2, the first filter circuit 3, full-bridge circuit 3, high frequency transformer 5, the second rectification circuit 6 and the second filter circuit 7 that connect successively, wherein: the first rectification circuit 2 is connected to three-phase alternating current input 1; The second filter circuit 3 is connected to arc pistol 8.

Particularly, the first rectification circuit 2 of the present utility model is three-phase commutation bridge.

The first filter circuit 3 comprises inductance L and the capacitor C that is connected in series in the first rectification circuit 2 two ends.

Full-bridge circuit 4 comprises the first switching tube Q ₁, second switch pipe Q ₂, the 3rd switching tube Q ₃, the 4th switching tube Q ₄, the first switching tube Q ₁with the 3rd switching tube Q ₃after series connection, be connected in capacitor C two ends in parallel, second switch pipe Q ₂with the 4th switching tube Q ₄after series connection, be also connected in capacitor C two ends in parallel, and the first switching tube Q ₁with second switch pipe Q ₂all be connected with the first end of capacitor C, the 3rd switching tube Q ₃with the 4th switching tube Q ₄all be connected with the second end of capacitor C.Full-bridge circuit 4 of the present utility model also comprises diode D ₁, diode D ₂, capacitor C ₁and capacitor C ₃, diode D ₁be connected in parallel on the first switching tube Q ₁two ends; Capacitor C ₁also be connected in parallel on the first switching tube Q ₁two ends; Diode D ₂be connected in parallel on the 3rd switching tube Q ₃two ends; Capacitor C ₃also be connected in parallel on the 3rd switching tube Q ₃two ends.

The first switching tube Q ₁with the 3rd switching tube Q ₃be insulated gate bipolar transistor (IGBT).

Second switch pipe Q ₂with the 4th switching tube Q ₄be inverse-impedance type insulated gate bipolar transistor (IGBT).

Full-bridge circuit 4 of the present utility model, based on phase shifting control, realizes zero-voltage and zero-current switch (ZVZCS).

In the utility model, the second filter circuit 7 comprises the inductance L being connected in series _fand capacitor C _f, arc pistol 8 is connected in capacitor C in parallel _ftwo ends.

The first end of the former limit winding of high frequency transformer T is connected to the first switching tube Q by leakage inductance Lr ₁with the 3rd switching tube Q ₃between node, the second end of former limit winding be connected to second switch pipe Q ₂with the 4th switching tube Q ₄between node, the first end of the first secondary winding of high frequency transformer T is by diode D ₃be connected to inductance L _finput, the second end of the first secondary winding be connected to capacitor C _foutput, the first end of the second secondary winding of high frequency transformer T is connected with first secondary winding the second end, the second end of the second secondary winding of high frequency transformer T is by diode D ₄be connected to diode D ₃and inductance L _fbetween node.

The second rectification circuit 6 is full-wave rectifying circuit, comprises diode D ₃with diode D ₄.

At the first switching tube Q ₁with the 3rd switching tube Q ₃between node, inductance L _fbetween be connected with capacitance C _b.

Contravariant electrical arc spraying power source of the present utility model also comprises auxiliary control module, for controlling full-bridge circuit 4 work.

Auxiliary control module comprises output sample circuit 9, PI regulating circuit 10, the PWM controller 11 connecting successively,

Output sample circuit 9 is connected to arc pistol 8, for gathering output voltage and the output current of arc pistol 8;

PI regulating circuit 10 is for carrying out PI computing after Voltage Feedback value and predeterminated voltage reference value, output signal, wherein, the output voltage of the arc pistol 8 that Voltage Feedback value collects for output sample circuit 9;

PWM controller 11, for the modulation wave signal of the signal of PI regulating circuit 10 outputs and 11 generations of PWM controller is compared, changes the width of PWM controller 11 output pulse signals, output pulse signal, and pulse signal is used for controlling full-bridge circuit 4 work.Between PWM controller 11 and full-bridge circuit 4, be connected with drive circuit, the pulse signal of PWM controller output is sent to drive circuit, controls to the first switching tube Q of full-bridge circuit 4 by drive circuit ₁, second switch pipe Q ₂, the 3rd switching tube Q ₃, the 4th switching tube Q ₄.

Contravariant electrical arc spraying power source of the present utility model also comprises auxiliary protection module, for the protection of the safety of this contravariant electrical arc spraying power source;

Auxiliary protection module comprises connection detection circuit 12, Single-chip Controlling and protection module 13 successively, wherein:

Testing circuit 12 is voltage, electric current, temperature sensing circuit, and it is connected to arc pistol 8, for detection of the operating state of contravariant electrical arc spraying power source, output signal;

Single-chip Controlling and protection module 13 are connected to full-bridge circuit 4; for the signal of testing circuit 12 outputs is analyzed, is processed; in time fault is processed; quit work; the safety of protection contravariant electrical arc spraying power source, above-mentioned said fault comprises the faults such as open circuit, short circuit, low-voltage, overvoltage.

Contravariant electrical arc spraying power source of the present utility model also comprises wire feeder 15, the wire feed rate sampling module 14 connecting successively; wire feeder 15 is connected to arc pistol 8; wire feed rate sampling module 14 is connected to Single-chip Controlling and protection module 13; single-chip microcomputer in Single-chip Controlling and protection module 13 is exported to wire feeder 15 by corresponding wire feed signal, controls the work of wire feeder 15.In spraying, output current and preset reference value are compared, if output current value specific output electric current preset reference value is high, reduce wire feed rate, reduce output current; If output current value specific output electric current preset reference value is low, accelerate wire feed rate, increase output current, finally make outputting current steadily in output current preset reference value.

The single-chip microcomputer DA mouth of the preset reference value of output voltage of the present utility model, output current in Single-chip Controlling and protection module 13 exported.

The voltage that contravariant electrical arc spraying power source of the present utility model is inputted three-phase alternating current 380V becomes the direct current of 540V left and right through the first rectification circuit 2 and the first filter circuit 3, via full-bridge circuit, carry out inversion again, become high frequency square wave alternating current, HF switch frequency is elected 20KHz as herein, (clinodiagonal two switching tubes, as the first switching tube Q for two switching tubes of full-bridge circuit 4 each brachium pontis ₁with the 4th switching tube Q ₄or second switch pipe Q ₂with the 3rd switching tube Q ₃) the complementary conducting of 180 degree, between the conducting of two brachium pontis, differ a phase shifting angle.By regulating the size of phase shifting angle, carry out regulation output voltage pulse width, thereby reach the object that regulates corresponding output voltage.By high frequency transformer, transferring energy to the second rectification circuit of secondary, is direct current by its rectification, by the required galvanic current of the final output of the second filter circuit.

In spraying process, by voltage-current sensor, the output voltage of arc pistol and output current are sampled, output voltage and predeterminated voltage reference value are compared and carry out PI computing at chip internal, if output voltage values specific output voltage preset reference value is high, reduce the duty ratio of pulse-width signal (PWM), reduce IGBT ON time, reduce output voltage; If output voltage values specific output voltage preset reference value is low, increase the duty ratio of pulse-width signal (PWM), increased IGBT ON time, increase output voltage, finally make output voltage stabilization on default output voltage values.

Full-bridge circuit 4 of the present utility model has adopted phase shifting full bridge soft switch technology, and resonant transformation technology and common PWM converter technique are combined, and can make switching device under lower voltage, current stress, realize soft switch.Soft switch ZVS refer to switching tube in conducting or before turn-offing tube voltage drop be zero, thereby realize conduction loss and turn-off power loss is zero.

Key waveforms figure while working below in conjunction with the full-bridge circuit shown in Fig. 3 is elaborated to the operating state of the full-bridge circuit of contravariant electrical arc spraying power source of the present utility model: in Fig. 3, for convenience of explanation, by switching tube (Q ₁, Q ₂, Q ₃, Q ₄) drive waveforms, transformer primary side current i _pvariation, full-bridge output end voltage V _aBvariation, transformer secondary output diode both end voltage V _dvariation be drawn in same figure.

(1) mode 1(t ₁₂~ t ₀)

T ₁₂~ t ₀: Q ₁and Q ₄conducting, high frequency transformer T primary current i _pgive capacitance C _bcharging, capacitance C _bon voltage linear rise.T ₀constantly, Q ₁turn-off, enter switch mode 2.

(2) mode 2(t ₀~ t ₁)

T ₀constantly, Q ₁turn-off, electric current is to Q ₁, Q ₃junction capacitance C ₁, C ₃shift C ₁charging, C ₃electric discharge, switching tube Q ₁the voltage linear at two ends rises, C ₁, C ₃limited Q ₁the climbing of both end voltage, Q ₁realized ZVS shutoff.T ₁constantly, C ₃on voltage drop to zero, D subsequently ₃conducting enters switch mode 3.

(3) mode 3(t ₁~ t ₂)

T ₁constantly, C ₃on voltage drop to zero, Q subsequently ₃two ends reverse parallel connection diode D ₃conducting, plays afterflow effect, Q ₃the voltage at two ends is zero, now Q ₃conducting, Q ₃realize no-voltage conducting.Q ₃full-bridge output both end voltage V after conducting _aBbe clamped to zero, capacitance C _bon voltage be added to leakage inductance L _rupper, transformer primary side current i _plinear decline.Leakage inductance L _rin energy be added to capacitance C _b, two rectifier diode D of transformer secondary ₃, D ₄the powering load of conducting simultaneously.

(4) mode 4(t ₂~ t ₃)

T ₂constantly, primary current i _pdrop to zero, because the existence of inductance can stop the variation of electric current, primary current i _poppositely afterflow.But due to lagging leg Q ₂and Q ₄that adopt is reverse blocking IGBT, has deadened negative current, so primary current i _pbe maintained zero.In the meantime, capacitance C _bvoltage remain unchanged, Q ₄still conducting, but do not have electric current to flow through.T ₃constantly, Q ₄zero-current switching.Transformer secondary diode D ₃, D ₄conducting simultaneously, bears the load current of half separately.

(5) mode 5(t ₃~ t ₄)

Q ₄after zero-current switching, primary current i _pbe still zero, load current is along D ₃, D ₄afterflow.

(6) mode 6(t ₄~ t ₅)

T ₄constantly, Q ₂conducting, due to leakage inductance L _rexistence, primary current i _pcannot suddenly change, so Q ₂conducting time electric current be zero zero current turning-on.Q ₂after conducting, primary current i _plinear increasing, output current is through D ₄flow to load.

(7) mode 7(t ₅~ t ₆)

Q ₂, Q ₃conducting simultaneously, powering load.

As can be seen from Figure 3, circuit topology of the present utility model is by phase shifting control, Q ₁, Q ₃realized zero voltage switch, Q ₂, Q ₄realize Zero Current Switch, greatly reduced switching loss, greatly improved overall efficiency.Reducing on the basis of heat radiation in addition, greatly reducing equally the volume of radiator.

Above the utility model is described in detail; its object is to allow the personage who is familiar with this art can understand content of the present utility model and be implemented; can not limit protection range of the present utility model with this; all equivalences of doing according to Spirit Essence of the present utility model change or modify, and all should be encompassed in protection range of the present utility model.

Claims (6)

1. the contravariant electrical arc spraying power source based on phase-shifting full-bridge, comprises the first rectification circuit, the first filter circuit, full-bridge circuit, high frequency transformer T, the second rectification circuit and the second filter circuit that connect successively, wherein:

Described the first rectification circuit is connected to three-phase alternating current input;

Described the second filter circuit is connected to arc pistol;

Described the first filter circuit comprises inductance L and the capacitor C that is connected in series in described the first rectification circuit two ends;

Described full-bridge circuit comprises the first switching tube Q ₁, second switch pipe Q ₂, the 3rd switching tube Q ₃, the 4th switching tube Q ₄, described the first switching tube Q ₁with described the 3rd switching tube Q ₃after series connection, be connected in described capacitor C two ends in parallel, described second switch pipe Q ₂with described the 4th switching tube Q ₄after series connection, be also connected in described capacitor C two ends in parallel;

It is characterized in that:

Described contravariant electrical arc spraying power source also comprises auxiliary control module, for controlling described full-bridge circuit work;

Described auxiliary control module comprises output sample circuit, PI regulating circuit, the PWM controller connecting successively,

Described output sample circuit is connected to described arc pistol, for gathering output voltage and the output current of described arc pistol;

Described PI regulating circuit is for will carry out PI computing after Voltage Feedback value and predeterminated voltage reference value, output signal, and wherein, described Voltage Feedback value is the output voltage of the described arc pistol that collects of described output sample circuit;

Described PWM controller is for comparing the modulation wave signal of the signal of described PI regulating circuit output and the generation of described PWM controller, change the width of described PWM controller output pulse signal, output pulse signal, described pulse signal is used for controlling described full-bridge circuit work.

2. contravariant electrical arc spraying power source according to claim 1, is characterized in that, described full-bridge circuit also comprises diode D ₁, diode D ₂, capacitor C ₁and capacitor C ₃, described diode D ₁be connected in parallel on described the first switching tube Q ₁two ends; Described capacitor C ₁also be connected in parallel on described the first switching tube Q ₁two ends; Described diode D ₂be connected in parallel on described the 3rd switching tube Q ₃two ends; Described capacitor C ₃also be connected in parallel on described the 3rd switching tube Q ₃two ends.

3. contravariant electrical arc spraying power source according to claim 1 and 2, is characterized in that, described the first switching tube Q ₁with described the 3rd switching tube Q ₃be insulated gate bipolar transistor.

4. contravariant electrical arc spraying power source according to claim 1, is characterized in that, described second switch pipe Q ₂with described the 4th switching tube Q ₄be inverse-impedance type insulated gate bipolar transistor.

5. contravariant electrical arc spraying power source according to claim 1, is characterized in that, described contravariant electrical arc spraying power source also comprises auxiliary protection module, for the protection of the safety of described contravariant electrical arc spraying power source;

Described auxiliary protection module comprises testing circuit and Single-chip Controlling and the protection module connecting successively, wherein:

Described testing circuit is connected to described arc pistol, for detection of the operating state of described contravariant electrical arc spraying power source, output signal;

Described Single-chip Controlling and protection module are connected to described full-bridge circuit, for the signal of described testing circuit output is analyzed, processed, in time fault are processed, and protect the safety of described contravariant electrical arc spraying power source.

6. contravariant electrical arc spraying power source according to claim 1, is characterized in that, described the first rectification circuit is three-phase commutation bridge.