CN1308407A - Single-phase power factor correcting step-up converter - Google Patents
Single-phase power factor correcting step-up converter Download PDFInfo
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Abstract
A single-phase power factor correcting boost converter includes single phase input and output ends, single phase rectification circuit, voltage loop and current loop. One output signal of current loop is fed back to the output end of the current sampling circuit through feed back resistor. Its other output signal is connected to the positive input end of the follower which has one output signal fed back to its negative input end and an other output signal is connected to the positive input end of pulse width modulation circuit. The input power range of harmonic wave in IEC 1000-3-2A standard may be increased greatly, provided the circuit parameters satisfy certain conditions.
Description
The present invention relates to a kind of single-phase rectifier converter that has circuit of power factor correction, particularly adopt (Boost) converter that boosts of discontinuous mode (DCM), it is commonly referred to as single-phase DCM Boost converter.
Single-phase DCM Boost converter is [referring to L.liu and Y.liu, " Current waveformdistortion in power factor correction circuits employing discontinuousmode boost converters ", Conf.Rec.of PESC 1989, pp.825-829] be a kind of approximate circuit of power factor correction (abbreviating PFC as).With other Single-phase PFC circuit relatively, it have simple in structure, control is convenient, the Boost diode does not have advantages such as reverse-recovery problems.Adopt the fixed frequency of tradition to decide this pfc circuit of duty ratio, the maximal input that satisfies IEC-1000-3-2A level harmonic standard approximately is 1.2kW.Thereby,, can reach IEC-1000-3-2A level harmonic standard again for keeping this pfc circuit advantage of simple structure for the power supply module for communication of bigger input power, best approach is revised control strategy, the modulation duty cycle function exactly.
In recent years, more existing improved controlling schemes propose in succession, they be the CCM/DCM boundary Control [referring to Motorola Linear/Interface Ics Devices Data; " Power Factor Controllers-MC34262 "; pp3-399---3-413]; 2 subharmonic inject control [referring to DaFeng Weng; S.Yuvarajan; " Constant-Switching-FrequencyAC-DC Converter Using Second-Harmonic-Injected PWM "; IEEETransactions on Power Electronics, Vol.11, No.1, January, 1996.], the 2n subharmonic injects control [referring to S.Yuvarajan, DaFeng Weng, " Input-CurrentHarmonic Reduction in AC-DC Converters Using Rectified-VoltagePWM ", in Proc.HFPC ' 97] etc.After adopting these improved control strategies, can reduce 3 times, 5 times, 7 inferior harmonic contents greatly, thereby guarantee under the constant situation of main circuit structure, to increase the maximal input that satisfies the IEC-1000-3-2 standard.Although these control strategies can both be realized reducing of current harmonic content effectively, shortcoming is arranged respectively.Wherein the CCM/DCM boundary Control is a kind of variable frequency control scheme, and its switching frequency on a large scale changes makes that the design of input electromagnetic interface filter is comparatively difficult; The realization of 2 subharmonic injection method sample circuits is comparatively complicated; Though the 2n subharmonic injects the control method bigger improvement is arranged, it realizes still more complicated.
The somebody proposed employing Current-Clamped (current clamp) [referring to R.Rdel, B.P.Erisman, " Low-Cost Power-Factor Correction/Line-Harmonics Reduction with Current-Clamped Boost converter; " HFPC ' 95, pp261-269. and R.Rdel, A.S.Kislovski, B.P.Erisman, " Input-Current-Clamping:An Inexpensive Novel Control; Technique to AchieveCompliance with Harmonic Regulations " .IEEE APEC ' 96, pp145-151] control CCM single phase boost pfc circuit, it adopts traditional average current type current control and two kinds of technology of peak electricity flow pattern control, has realized that quite simply 1KW is with the interior single-phase high power factor correction requirement of satisfying IEC1000-3-2A level harmonic standard.But it still can not realize described alignment requirements in more high-power scope.
Purpose of the present invention is exactly in order to overcome the above problems, and a kind of single-phase power factor correcting step-up converter is provided, and can improve Harmonics of Input, makes it still can satisfy the IEC-1000-3-2 standard in more powerful application scenario, makes circuit simpler again.
The present invention realizes that the scheme of above-mentioned purpose is: a kind of single-phase power factor correcting step-up converter, comprise single-phase input, output, single phase rectifier circuit, Voltage loop, electric current loop, described single-phase input order cross streams power supply, output is output as direct current, at the positive output end of rectification circuit through the negative output terminal of an electronic switch of an inductance cross-over connection (S) to rectification circuit, the control end of this electronic switch links to each other with the output of a pulse-width modulation circuit, and the inverting input of this pulse-width modulation circuit links to each other with outside input triangular signal; The normal phase input end of described electric current loop connects the output of Voltage loop, and inverting input connects the output of current sampling circuit; It is characterized in that: the output signal of described electric current loop is leaded up to feedback resistance and is fed back to the output of current sampling circuit, and another road is connected to the normal phase input end of pulse-width modulation circuit.
Owing to adopted above scheme, compare with conventional method, have more a processing procedure: the input that the output of electric current loop is fed back to once again electric current loop, output after synthetic connects the normal phase input end of pulse-width modulation circuit, relatively produce required duty cycle of switching with the external subcarrier signal again, (experiment parameter of 1.5KW Boost pfc circuit is the Control Parameter of adjusting electric current loop: Rf=22K, R1=10K, R2=10K, C2=470pF) can make this account for the control ratio and just in time produce the desired control ratio that accounts for of pure input sinusoidal current waveform of high-quality (near unity power factor), thereby improve the input power range that satisfies IEC 1000-3-2A level harmonic standard greatly for DCM BOOST converter.Experiment has proved this point.
Fig. 1 is the available technology adopting principle schematic of the single-phase DCM Boost converter of frequency control surely.
Fig. 2 is the single-phase DCM BOOST of a kind of modified model of a prior art pfc circuit schematic diagram.
Fig. 3 is the single-phase DCM BOOST of the another kind of modified model of a prior art pfc circuit schematic diagram.
Fig. 4 is traditional Average Current Control technology circuit schematic diagram.
Fig. 5 is the single-phase DCM BOOST of the modified model pfc circuit schematic diagram that the present invention proposes.
Fig. 6 is the schematic diagram (M=1.4) of Fig. 1 PFC input phase current.
Fig. 7 is the schematic diagram (M=1.4) of Fig. 3 PFC input phase current.
Fig. 8 is schematic diagram (M=1.4) schematic diagram of Fig. 5 PFC input phase current.
Also the present invention is described in further detail in conjunction with the accompanying drawings below by specific embodiment.
Fig. 1 is that prior art adopts the fixed single-phase DCM Boost converter block diagram of control frequently, it is a traditional voltage-type control, as the bandwidth of design voltage ring well below the frequency of electrical network (<10Hz), then duty cycle of switching electrical network in the cycle (100Hz) can regard constant as, the maximum power that the simplest this Single-phase PFC technology can satisfy the IEC-1000-3-2A harmonic standard is 1.2 KW.
Fig. 2 is a kind of modified model Single-phase PFC of prior art block diagram, it by 2 times of an input of the output superposition of Voltage loop phase voltage or 2n rd harmonic signal with the modulation switch duty ratio, making it at electrical network is not that constant---the effect of modulation is near the phase voltage peak value in the cycle, suitably reduces duty ratio; And near 60 degree and 120 degree, suitably increase duty ratio, make the input phase current more near sinusoidal, thereby increase the maximum power that satisfies the IEC-1000-3-2A harmonic standard.But all to produce harmonic wave with complicated testing circuit and inject signal.
Fig. 3 is the another kind of modified model Single-phase PFC of a prior art block diagram, and it is the single-phase DCM BOOST PFC that a kind of peak current injects control.Detection and control are very simple, and because of being peak current control, make circuit have automatic current limiting function and superior dynamic property.
Fig. 4 is traditional Average Current Control technology, this circuit comprises single-phase input (Vin), output (Vo), single phase rectifier circuit, Voltage loop (1), electric current loop (2), described single-phase input (Vin) order cross streams power supply, output (Vo) is output as direct current, at the positive output end of rectification circuit through the negative output terminal of an inductance (L) electronic switch of cross-over connection (S) to rectification circuit, the control end of this electronic switch (S) links to each other with the output of a pulse-width modulation circuit (PWM), and the inverting input of this pulse-width modulation circuit (PWM) links to each other with outside input triangular signal; The normal phase input end of described electric current loop (2) connects the output of Voltage loop (1), and inverting input connects the output of current sampling circuit (K).In this scheme, (bandwidth far below net frequently, general<10Hz) output is the benchmark of electric current loop (2) (fast ring, bandwidth is general>1/10fs, fs is a switching frequency) to Voltage loop (1).The result of control forces inductive current to become direct current, thereby can make the input phase current be approximately square wave, actual because maximum restriction that accounts for the control ratio and circuit imperfect, its input current waveform will be for trapezoidal, so also can increase the maximum power that satisfies the IEC-1000-3-2A harmonic standard, but the degree that increases is limited.
Fig. 5 is a kind of single-phase DCM BOOST PFC block diagram that the present invention proposes, it is the improvement of Fig. 4, the output signal that it is characterized in that described electric current loop (2) is leaded up to feedback resistance (Rf) and is fed back to the output of current sampling circuit (K), and the normal phase input end of (or through voltage follower (3)) pulse-width modulation circuit (PWM) is received on another road.The input that is not both and the output of electric current loop (2) is fed back to once again electric current loop (2) with Fig. 4, output (or through a voltage follower (3)) after synthetic relatively produces required duty cycle of switching with the external subcarrier signal again, Control Parameter such as adjusting electric current loop 2 can make this account for control and control ratio than just in time accounting for for the pure input sinusoidal current waveform of DCM BOOST converter generation high-quality (near unity power factor) is desired, thereby (experiment parameter of 1.5KW Boost pfc circuit is: Rf=22K to have improved the input power range that satisfies IEC 1000-3-2A level harmonic standard greatly, R1=10K, R2=10K, C2=470pF can realize that power factor is approximately 1).The control circuit technology of invention is not only similar but also different with traditional average current type current control technology, and it is a kind of non-linear Average Current Control technology.
Fig. 5 is a schematic diagram of the present invention; realize the single-phase DCMBOOST PFC of Average Current Control with this principle, both can adopt resolution element also can adopt integrated circuit (IC), wherein current detection circuit also can have multiple; as instrument transformer, sampling resistor etc., they all belong to the protection range of this patent.
Be that example is introduced operation principle of the present invention only below with the block diagram of Fig. 5.The input current normalization waveform of traditional single phase DCM Boost converter as shown in Figure 6.Adopt Fig. 2, the modified model Single-phase PFC of Fig. 3, its input current waveform is as shown in Figure 7.As seen can reduce the each harmonic content of input current greatly.
Satisfy condition at the circuit parameter that guarantees Fig. 5: the electric current of (1) inductance is DCM (a discontinuous current pattern); (2) the Voltage loop bandwidth very low (<10Hz), promptly at electrical network in the cycle, Voltage loop output can be approximately constant; (3) reasonably electric current loop design, its input current waveform will be as shown in Figure 8 so, and it is a simple sinusoidal current waveform.Can match in excellence or beauty with the BOOST PFC (adopting chip UC3854 and MC33368 control) of the mode of following, and circuit structure is simple many.
Emphasis of the present invention is that the Average Current Control of Current Clamped has been generalized in the single-phase DCM BOOST converter first, and has done modification, detects and control has realized quite stable and high-quality Single-phase PFC with very simple.It is by detecting the inductor current signal of single-phase DCM Boost converter, constitute an electric current loop (interior ring) amplifier with the output of Voltage loop (outer shroud), again the output of electric current loop is fed back to once again simultaneously the input of electric current loop, output (or through a voltage follower) after synthetic relatively produces required duty cycle of switching with the external subcarrier signal again, this accounts for the pure input sinusoidal current waveform that control specific energy control DCM BOOST converter produces high-quality (near unity power factor), has improved the input power range that satisfies IEC 1000-3-2A level harmonic standard greatly.(control circuit technology of the present invention is similar to traditional average current type current control technology, but difference is arranged, and in fact it is a kind of non-linear Average Current Control technology, but still is called the Average Current Control scheme here.)
The Average Current Control scheme of this patent invention has been used for single-phase input (150V-265VAC), 400V@1.5KW in the single-phase DCM Boost converter of output, its typical power factor can satisfy the Harmonics of Input requirement of IEC1000-3-2A standard code easily greater than 0.99.Compare with the single-phase BOOSTPFC with UC3854 and MC33368 control, can realize identical input current quality, but control is simpler, cost is lower, thereby cost performance is higher.
Claims (2)
1. single-phase power factor correcting step-up converter, comprise single-phase input (Vin), output (Vo), single phase rectifier circuit, Voltage loop (1), electric current loop (2), described single-phase input (Vin) order cross streams power supply, output (Vo) is output as direct current, at the positive output end of rectification circuit through the negative output terminal of an inductance (L) electronic switch of cross-over connection (S) to rectification circuit, the control end of this electronic switch (S) links to each other with the output of a pulse-width modulation circuit (PWM), and the inverting input of this pulse-width modulation circuit (PWM) links to each other with outside input triangular signal; The normal phase input end of described electric current loop (2) connects the output of Voltage loop (1), and inverting input connects the output of current sampling circuit (K);
It is characterized in that: the output signal of described electric current loop (2) is leaded up to feedback resistance (Rf) and is fed back to the output of current sampling circuit (K), and another road is connected to the normal phase input end of pulse-width modulation circuit (PWM).
2. single-phase rectifier as claimed in claim 1, it is characterized in that: the output signal of described electric current loop (2) is leaded up to feedback resistance (Rf) and is fed back to the output of current sampling circuit (K), and another Lu Jingyi voltage follower (3) is connected to the normal phase input end of pulse-width modulation circuit (PWM).
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