CN112234833A - Direct-current magnetic bias suppression method and device for double-active-bridge direct-current converter - Google Patents

Abstract

The invention discloses a direct current magnetic bias suppression method and a direct current magnetic bias suppression device for a double-active-bridge direct current converter. The integral voltage of each half period is input to a sampling holding circuit, the sampled integral voltage is input to a control regulator as a difference, an error signal of the duty ratio is output and is superposed with a driving signal of the original duty ratio to obtain the final duty ratio, and the driving signal is output. In practice, the voltage source is not an ideal voltage source, and is usually composed of an inverter, so that the ripple of the power source at the front stage is superimposed on the ripple of the input voltage. The invention adopts the band-pass filter to filter the input voltage, and can inhibit the direct current offset only by considering the switching frequency of the double-active-bridge direct current converter, thereby improving the practicability and reliability of the system.

Description

Direct-current magnetic bias suppression method and device for double-active-bridge direct-current converter

Technical Field

The invention belongs to the technical field of control of direct current converters, and particularly relates to a direct current magnetic bias suppression method and device for a double-active-bridge direct current converter.

Background

The Dual Active Bridge dc converter (DAB) has many advantages such as bidirectional energy flow, high power density, electrical isolation, and easy soft switching, and thus is widely used in high-power situations such as distributed power generation, new energy electric vehicles, and uninterruptible power supplies. However, the parasitic parameters of the circuit hardware are not completely symmetrical, and the high-frequency transformer has direct-current bias due to problems such as delay of driving signals. The peak value of the inductive current is increased due to the direct current bias, the switching loss and the stress are increased, even the magnetic element is saturated due to the excessive direct current bias, the current generates a peak, the temperature is increased, and finally the circuit is burnt.

At present, the traditional method for eliminating direct current magnetic bias is mainly to connect a blocking capacitor and a sampling inductor current in series on an inductor side to control and adjust the duty ratio. The series blocking capacitor can bring larger power loss and longer service life, and the active control method of the sampling current has higher requirements on the sampling precision and the bandwidth of the current sampling module.

Disclosure of Invention

The invention aims to overcome the defects and provides a method and a device for inhibiting direct current magnetic bias of a double-active-bridge direct current converter, which can effectively eliminate bias voltage, thereby reducing loss in the operation process of the direct current converter and improving the reliability of a system.

In order to achieve the above object, a method for suppressing dc magnetic bias of a dual-active-bridge dc converter includes the following steps:

step one, the voltage v at two ends of a capacitor is measured_inFiltering to obtain a filtered voltage v_bpf；

Step two, the filtering voltage v is filtered_bpfIntegrating the voltage and the voltage twice in each half switching period to obtain an integrated voltage v_integ1And the integral voltage v_integ2；

Step three, the integral voltage v is measured_integ1And the integral voltage v_integ2Sampling at a fixed time to obtain a sampling voltage v_sample1And a sampling voltage v_sample2For the sampling voltage v_sample1And a sampling voltage v_sample2And controlling and adjusting, outputting an error signal delta d of the duty ratio, and superposing the error signal delta d and a driving signal with the original duty ratio of 50% to obtain the adjusted actual duty ratio d.

When a positive DC bias is present, the filtered voltage v_bpfIn phase with the inductor current, the filter voltage v when a negative DC bias occurs_bpf180 deg. out of phase with the inductor current.

A direct current magnetic bias suppression device of a double-active-bridge direct current converter comprises a band-pass filter, a control regulator, two integrating circuits and two sampling and holding circuits;

the band-pass filter is used for filtering the voltage v at two ends of the capacitor_inFiltering to obtain a filtered voltage v_bpf；

The integration circuit being arranged to couple the filtered voltage v_bpfIntegrating the voltage and the voltage twice in each half switching period to obtain an integrated voltage v_integ1And the integral voltage v_integ2；

Using circuits for integrating voltage v_integ1And the integral voltage v_integ2Sampling at a fixed time to obtain a sampling voltage v_sample1And a sampling voltage v_sample2；

For controlling the regulator to measure the sampled voltage v_sample1And a sampling voltage v_sample2And controlling and adjusting, and superposing the error signal delta d of the duty ratio with the driving signal of the original duty ratio to obtain the adjusted actual duty ratio d.

The cut-off frequency of the band-pass filter is related to the switching frequency of the dual active bridge converter.

Two paths of integrating circuits are respectively connected with a driving signal P for integral zero clearing_i1And a drive signal P_i2。

Two sampling holding circuits are respectively connected for samplingDrive signal P of sample-and-hold circuit_s1And a drive signal P_s2。

Compared with the prior art, the method for respectively carrying out integral sampling on the switching frequency secondary voltage component generated by the direct current magnetic biasing in each half switching period and adjusting the duty ratio of the power switching device can effectively inhibit the direct current magnetic biasing problem in the operation process of the DAB converter and effectively eliminate the bias voltage, thereby reducing the loss in the operation process of the direct current converter and improving the reliability of the system; the invention adopts a voltage integral sampling method, not only solves the problem of high requirements of current sampling on precision and bandwidth, but also can eliminate the influence of interference and noise existing in single voltage sampling, and improves the accuracy and stability of the control method.

The device inputs the input voltage to a band-pass filter for filtering by utilizing the influence of direct current bias on input voltage ripple in a double-active-bridge direct current converter, the filtered voltage is input to two independent voltage integrating circuits, and the integrating period is a half period. The integral voltage of each half period is input to a sampling holding circuit, the sampled integral voltage is input to a control regulator as a difference, an error signal of the duty ratio is output and is superposed with a driving signal of the original duty ratio to obtain the final duty ratio, and the driving signal is output. In practical use, the voltage source is not an ideal voltage source and is usually composed of an inverter, so that the input voltage ripple is superposed with the ripple of the power supply at the front stage. The invention adopts the band-pass filter to filter the input voltage, and can inhibit the direct current offset only by considering the switching frequency of the double-active-bridge direct current converter, thereby improving the practicability and reliability of the system.

Drawings

FIG. 1 is a main circuit topology of the present invention;

FIG. 2 is a general block diagram of the control system of the present invention;

FIG. 3 is a waveform diagram showing the phase relationship between the filter voltage and the inductor current when DC bias occurs;

FIG. 4 is a timing diagram of the voltage signal and the sampling driving signal and the integration zero clearing driving signal;

FIG. 5 is a waveform diagram of the inductor current when DC bias is applied and when DC bias is removed;

FIG. 6 is a graph of input voltage and filter voltage waveforms as it occurs when DC bias is removed and when DC bias is removed;

FIG. 7 is a waveform diagram of simulation verification for suppressing DC magnetic bias by using the control method proposed by the present invention.

Detailed Description

The following is further described with reference to the accompanying drawings.

Referring to fig. 1, a dc magnetic bias suppression circuit of a dual-active bridge dc converter includes a full-bridge inverter circuit, a transformer T, and a full-bridge rectifier circuit; the transformer T is arranged between the full-bridge inverter circuit and the full-bridge rectifier circuit, and the full-bridge inverter circuit is connected with the input capacitor C in parallel₁And an input voltage V₁The full-bridge rectifier circuit is connected with an output capacitor C in parallel₂And an output voltage V₂。

The full-bridge inverter circuit and the full-bridge rectifier circuit are all four full-control power semiconductor devices to form a bridge circuit; the fully-controlled power semiconductor device forms a bridge circuit and comprises a diode and a triode serving as a power electronic switch, wherein a collector of the triode is connected with an anode of the diode, a cathode of the diode is connected with an emitting electrode of the triode, and a base of the triode serves as a signal input end.

Referring to fig. 2, a dc magnetic bias suppression device of a dual-active bridge dc converter includes a band-pass filter, a control regulator, two integrating circuits, and two sample-and-hold circuits;

the band-pass filter is used for filtering the voltage v at two ends of the capacitor_inFiltering to obtain a filtered voltage v_bpf；

The integration circuit being arranged to couple the filtered voltage v_bpfIntegrating the voltage and the voltage twice in each half switching period to obtain an integrated voltage v_integ1And the integral voltage v_integ2；

Using circuits for integrating the voltage v_integ1And the integral voltage v_integ2Sampling to obtain a sampling voltage v_sample1And a sampling voltage v_sampl_e2；

Controlling the regulator to sampleVoltage v_sample1And a sampling voltage v_sample2And controlling and adjusting, and superposing the error signal delta d of the duty ratio with the driving signal of the original duty ratio to obtain the adjusted actual duty ratio d.

The cut-off frequency of the band-pass filter is related to the switching frequency of the dual active bridge converter.

Two paths of integrating circuits are respectively connected with a driving signal P for integral zero clearing_i1And a drive signal P_i2. Two paths of sample hold circuits are respectively connected with the driving signal P of the sample hold circuit_s1And a drive signal P_s2。

Referring to fig. 4, the driving signal P is sampled_s1And a drive signal P_s2Sampling the integral voltage during rising edge, and driving signal P at integral zero clearing switch after sampling_i1And a drive signal P_i2And clearing the integral voltage at the rising edge. Wherein the drive signal P is sampled_s1And sampling the drive signal P_s2And a switching tube S₁Switch tube S₂I.e. the integrated voltage is sampled around the peak of the inductor current.

A direct current magnetic bias suppression method of a double-active-bridge direct current converter comprises the following steps:

step one, the voltage v at two ends of a capacitor is measured_inFiltering to obtain a filtered voltage v_bpf；

Step two, the filtering voltage v is filtered_bpfIntegrating the voltage and the voltage twice in each half switching period to obtain an integrated voltage v_integ1And the integral voltage v_integ2；

Step three, the integral voltage v is measured_integ1And the integral voltage v_integ2Sampling to obtain a sampling voltage v_sample1And a sampling voltage v_sample2For the sampling voltage v_sample1And a sampling voltage v_sample2And controlling and adjusting, and superposing the error signal delta d of the duty ratio with the driving signal with the original duty ratio of 50% to obtain the adjusted actual duty ratio d.

The cut-off frequency of the band-pass filter is designed to be only equal to the switching frequency of the double-active-bridge converterAnd off. When operating normally, the frequency of the input voltage is 2f_s. When DC magnetic bias occurs, the frequency of the input voltage ripple wave is f_sIt can be considered as being in the original 2f_sOn the basis of which is superimposed a frequency f_sThe voltage component of (a). Therefore, the ripple component of the switching frequency caused by the DC offset is filtered out only by the band-pass filter. In practical engineering application, the converter is generally the preceding stage of the input power supply, the converter will affect the ripple of the input voltage of the subsequent stage, and the filtering method can also eliminate the influence of the preceding stage converter on the ripple voltage, thereby improving the accuracy. As shown in fig. 3, the solid line represents the filter voltage waveform when a positive dc bias occurs, and the dotted line represents the filter voltage waveform when a negative dc bias occurs. When a positive DC bias is present, the filtered voltage v_bpfIn phase with the inductor current, the filter voltage v when a negative DC bias occurs_bpfThe phase difference between the voltage and the inductive current is 180 degrees, so that the filtering voltage is integrated according to the phase relation between the filtering voltage and the inductive current, and the closed-loop control is performed by utilizing the difference of the polarities of the integrated voltage sampled when different direct current biases appear, so that the existing direct current bias is eliminated.

Fig. 5 shows the inductor current waveform of the dual-active-bridge converter after the dc offset occurs and the dc offset is eliminated. The solid line shows the waveform of the inductor current when no dc bias is present, and the dotted line shows the waveform of the inductor current when dc bias is present. When no dc offset occurs, the inductor current waveform is symmetrical about the time axis, and when a dc offset occurs, a dc component exists in the inductor current waveform.

Fig. 6 shows the waveform of the input voltage after the dc offset appears and is eliminated in the dual-active bridge converter. The solid line is the input voltage waveform when dc bias occurs, and the dotted line is the input voltage waveform after dc bias is removed. When the DC offset is removed, i.e. f, in the input voltage, due to the DC offset_sThe component is eliminated and the frequency of the input voltage is changed to 2f again_s。

Fig. 7 shows the result of simulation verification of the method for suppressing the rectified magnetic bias according to the present invention. In the simulation results, the dotted line waveform indicates the waveform when the DC magnetic bias occursThe waveform is realized when the method of the invention is adopted to restrain the DC magnetic bias. Wherein v is_bpfRepresenting the filter voltage waveform i_LRepresenting the inductor current waveform. Simulation results prove that the method can effectively inhibit the direct current magnetic bias existing in the circuit.

The invention abandons the traditional method of connecting the blocking capacitors in series, and the transformer is arranged between the full-bridge inverter circuit and the full-bridge rectifier circuit, the full-bridge inverter circuit is connected with the input capacitor and the input voltage in parallel, and the full-bridge rectifier circuit is connected with the output capacitor and the output voltage in parallel, thereby reducing the volume and the power loss of the DAB converter, and improving the service life of the converter and the system reliability.

Claims (6)

1. A method for suppressing direct current magnetic bias of a double-active-bridge direct current converter is characterized by comprising the following steps:

step one, the voltage v at two ends of a capacitor is measured_inFiltering to obtain a filtered voltage v_bpf；

Step two, the filtering voltage v is filtered_bpfIntegrating the voltage and the voltage twice in each half switching period to obtain an integrated voltage v_integ1And the integral voltage v_integ2；

Step three, the integral voltage v is measured_integ1And the integral voltage v_integ2Sampling to obtain a sampling voltage v_sample1And a sampling voltage v_sample2For the sampling voltage v_sample1And a sampling voltage v_sample2And controlling and adjusting, and superposing the error signal delta d of the duty ratio with the driving signal of the original duty ratio to obtain the adjusted actual duty ratio d.

2. The method of claim 1, wherein the filtered voltage v is applied when a positive DC bias is present_bpfIn phase with the inductor current, the filter voltage v when a negative DC bias occurs_bpf180 deg. out of phase with the inductor current.

3. A direct current magnetic bias suppression device of a double-active-bridge direct current converter is characterized by comprising a band-pass filter, a control regulator, two paths of integrating circuits and two paths of sampling and holding circuits;

the band-pass filter is used for filtering the voltage v at two ends of the capacitor_inFiltering to obtain a filtered voltage v_bpf；

The integration circuit being arranged to couple the filtered voltage v_bpfIntegrating the voltage and the voltage twice in each half switching period to obtain an integrated voltage v_integ1And the integral voltage v_integ2；

Using circuits for integrating the voltage v_integ1And the integral voltage v_integ2Sampling to obtain a sampling voltage v_sample1And a sampling voltage v_samp ^l _e2；

For controlling the regulator to measure the sampled voltage v_sample1And a sampling voltage v_sample2And controlling and adjusting, and superposing the error signal delta d of the duty ratio with the driving signal of the original duty ratio to obtain the adjusted actual duty ratio d.

4. The apparatus according to claim 3, wherein the cut-off frequency of the band-pass filter is related to the switching frequency of the dual-active-bridge DC converter.

5. The DC magnetic bias suppression device of the dual-active-bridge DC converter according to claim 3, characterized in that the two integrating circuits are respectively connected with a driving signal P for integral zero clearing_i1And a drive signal P_i2。

6. The apparatus according to claim 3, wherein the two sample-and-hold circuits are respectively connected to the driving signal P of the sample-and-hold circuit_s1And a drive signal P_s2。

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