CN112737324B

CN112737324B - Automatic voltage-sharing bipolar Zeta DC-DC converter

Info

Publication number: CN112737324B
Application number: CN202011568029.1A
Authority: CN
Inventors: 邾玢鑫; 刘昱; 张耀; 李振华; 王灿
Original assignee: China Three Gorges University CTGU
Current assignee: China Three Gorges University CTGU
Priority date: 2020-12-25
Filing date: 2020-12-25
Publication date: 2022-02-01
Anticipated expiration: 2040-12-25
Also published as: CN112737324A

Abstract

An automatic voltage-sharing bipolar Zeta DC-DC converter comprises a direct current input source, a basic Zeta converter,m‑1a plurality of extension units with the same polarity,nand a reverse polarity voltage extension unit. The homopolar and antipolar extension units are composed of an inductor, two capacitors and a diode, and the input and output gains of the converter and the voltage stress of the switching device can be adjusted by adjusting the number of the extension units. The converter has the advantages of simple control and drive circuit, wide input and output voltage regulation range, low voltage stress of a switching device and the like, and is suitable for application occasions where positive and negative power supply output is needed for output and the change range of the input voltage and the output voltage is large.

Description

Automatic voltage-sharing bipolar Zeta DC-DC converter

Technical Field

The invention relates to a DC-DC converter, in particular to an automatic voltage-sharing bipolar Zeta DC-DC converter.

Background

In the application occasions with large input and output voltage changes, the input voltage can be higher than the output voltage or lower than the output voltage, and the common non-isolated Buck-Boost DC-DC converter suitable for the application occasions comprises Buck-Boost circuits, Cuk circuits, Sepic circuits and Zeta circuits. Theoretically, by adjusting the duty ratio D, the input-output gain of these converters can be varied from zero to infinity, but the boost capability of these converters is greatly limited due to the influence of the parasitic parameters of the components and circuits. At present, schemes for improving the input and output gains of the DC-DC converter are mainly constructed on the basis of Boost circuits, so that the circuits can only realize voltage output with the same polarity or the opposite polarity of a power supply at the same time. Therefore, the research on the novel bipolar wide-input-output buck-boost DC/DC converter which can realize high-gain boost and can realize bipolar output has important significance.

Disclosure of Invention

The non-isolated high-gain DC-DC converter aims to solve the problem that the existing non-isolated high-gain DC-DC converter cannot generate high-gain bipolar voltage at the same time. The invention provides an automatic voltage-sharing bipolar Zeta DC-DC converter, which consists of a basic Zeta converter and a plurality of gain expansion units. The input and output gains of the converter and the voltage stress of the switching device can be adjusted by adjusting the number of the gain expansion units. The converter has the advantages of simple control and drive circuit, wide input and output voltage regulation range, low voltage stress of a switching device and the like, and is suitable for application occasions where positive and negative power supply output is needed for output and the change range of the input voltage and the output voltage is large.

The technical scheme adopted by the invention is as follows:

an automatic voltage-sharing bipolar Zeta DC-DC converter comprises a direct current input source, a basic Zeta converter, m-1 homopolar extension units and n reversed-polarity voltage extension units; wherein:

the basic Zeta-converter comprises two inductors L, L_P1Two capacitors C_P11、C_P12A power switch S₁A diode D_P1(ii) a The connection form is as follows: power switch S₁Is connected to the positive pole of the DC input source, power switch S₁Is connected with one end of an inductor L and a capacitor C_P11One terminal of (C), a capacitor_P11The other end of the first and second inductors are respectively connected with the inductor L_P1And a diode D_P1Is connected to the cathode of the inductor L_P1The other end of each of the first and second capacitors is connected to a capacitor C_P12Is connected with one end of the inductor L, the other end of the inductor L and the diode D_P1Anode and capacitor C_P12The other ends of the two-way switch are connected with the negative electrode of the direct current input source;

the 1 st homopolar extension unit comprises an inductor L_P2Diode D_P2Two capacitors C_P21、C_P22(ii) a Wherein, the capacitor C_P21The other end of the first and second inductors are respectively connected with the inductor L_P2And a diode D_P2Is connected to the cathode of the inductor L_P2Another terminal of (1) and a capacitor C_P22One end of the two ends are connected;

the 2 nd homopolar extension unit comprises an inductor L_P3Diode D_P3Two capacitors C_P31、C_P32(ii) a Wherein, the capacitor C_P31The other end of the first and second inductors are respectively connected with the inductor L_P3And a diode D_P3Is connected to the cathode of the inductor L_P3Another terminal of (1) and a capacitor C_P32One end of the two ends are connected;

.... times, in the ith homopolar extension unit, 1< i ≦ m-1,

the ith homopolar extension unit comprises an inductor L_P(i+1)Diode D_P(i+1)Two capacitors C_P(i+1)1、C_P(i+1)2(ii) a Wherein, the capacitor C_P(i+1)1The other end of the first and second inductors are respectively connected with the inductor L_P(i+1)And a diode D_P(i+1)Is connected to the cathode of the inductor L_P(i+1)Another terminal of (1) and a capacitor C_P(i+1)2One end of the two ends are connected; diode D_P(i+1)Anode of (2) is connected with a capacitor C_P(i+1)2The other end of (a);

the 1 st reverse polarity voltage extension unit comprises an inductor L_N1Diode D_N1Two capacitors C_N11、C_N12(ii) a Wherein, the capacitor C_N11The other end of the first and second inductors are respectively connected with the inductor L_N1And a diode D_N1Is connected to the cathode of the inductor L_N1Another terminal of (1) and a capacitor C_N12One end of the two ends are connected;

the 2 nd reverse polarity voltage extension unit comprises an inductor L_N2Diode D_N2Two capacitors C_N21、C_N22(ii) a Wherein, the capacitor C_N21The other end of the first and second inductors are respectively connected with the inductor L_N2And a diode D_N2Is connected to the cathode of the inductor L_N2Another terminal of (1) and a capacitor C_N22One end of the two ends are connected;

.... times, in the j-th reversed polarity voltage expansion unit, 1< j ≦ n,

the jth reverse polarity voltage extension unit comprises an inductor L_NjDiode D_NjTwo capacitors C_Nj1、C_Nj2(ii) a Wherein, the capacitor C_Nj1The other end of the first and second inductors are respectively connected with the inductor L_NjAnd a diode D_NjIs connected to the cathode of the inductor L_NjAnother terminal of (1) and a capacitor C_Nj2One end of the two ends are connected;

the connection form between the extension units with the same polarity is as follows:

1<i is less than or equal to m-1, and the capacitance C in the i-1 th homopolar extension unit_Pi2One end of (1), an inductance L_PiAnd the intersection point of the other end of (2)Capacitor C in ith homopolar extension unit_P(i+1)2Is connected with the other end of the capacitor C in the i-1 th homopolar extension unit_Pi1One end of the first capacitor and the capacitors C in the i same-polarity extension units_P(i+1)1Are connected at one end. And the same polarity extends the unit capacitance C_P(i+1)2Both ends of the capacitor C are connected with a basic Zeta converter capacitor C_P22The voltage at the two ends is the same.

The connection form between the reversed polarity extension units is as follows:

1<j is less than or equal to n, and the capacitor C in the jth extension unit_Nj2One end of (1) and an inductor L_NjAnd the intersection point of the other end of the first diode and the diode D in the (j-1) th reversed polarity extension unit_N(j-1)Anode and capacitor C_N(j-1)2The intersection points of the other ends are connected. Capacitor C_Nj1One end of the capacitor is connected with the capacitor C in the j-1 th expansion unit_N(j-1)1One end is connected. And each reverse polarity extension unit capacitor C_Nj2Both ends of the capacitor C are connected with a basic Zeta converter capacitor C_P22The voltage at the two ends is the same.

The connection relationship between the 1 st homopolar extension unit and the basic Zeta converter is as follows:

capacitor C in Zeta converter_P11And the intersection point of one end of the inductor L and the capacitor C in the 1 st extension unit with the same polarity_P21Is connected to one end of the Zeta converter, an inductor L in the Zeta converter_P1Another terminal of (1) and a capacitor C_P12And the intersection point of one end of the first extension unit is connected with the diode D in the 1 st extension unit with the same polarity_P2Anode and capacitor C_P22The intersection points of the other ends are connected.

The connection relationship between the 1 st buck extension unit and the basic Zeta converter is as follows:

capacitance C in basic Zeta converter_P11And the intersection point of one end of the capacitor L and one end of the inductor L and the capacitor C in the 1 st reversed polarity extension unit_N11Are connected to one end of a diode D in the Zeta-converter_P1Anode and capacitor C_P12And the intersection point of the other end of the first and second electrodes connected with the inductor L in the 1 st reversed polarity extension unit_N1Another terminal of (1) and a capacitor C_N12The intersections of one end are connected.

Load R_PLAre respectively connected with the m-th-capacitance C in 1 homopolar extension unit_Pm2One end of the direct current input source is connected with the cathode of the direct current input source;

load R_NLThe two ends of the first and the capacitor C in the nth reverse polarity voltage extension unit_Nn2The other end of the direct current input circuit is connected with the cathode of the direct current input source.

The gate of the power switch S1 is connected to a controller whose duty cycle can vary between 0 and 1.

The invention discloses an automatic voltage-sharing bipolar Zeta DC-DC converter, which has the following technical effects:

1) the buck-boost circuit can realize voltage boost and buck simultaneously, has high input and output gains, low voltage stress of a switching device and series and voltage-sharing output capacitors. When the current of the inductor L is continuously conducted, the following is concrete:

the homopolar output gain is:

the reverse polarity output gain is:

the maximum input-output gain is:

the voltage stress of the switching tube is as follows:

the voltage on each output capacitor is:

wherein D is the duty cycle, u_inIs an input voltage u_oTo output a voltage u_sFor the voltage stress of the power switch, m-1 is the number of homopolar extension units, n is the number of reversed polarity extension units, 0<i≤m,0≤j≤n。

2) The reference ground can simultaneously output a positive voltage and a negative voltage

3) And only 1 power switch is contained, and the control strategy and the driving circuit are simple.

Drawings

Fig. 1 is a schematic diagram of the circuit of the present invention.

Fig. 2 is a circuit topology diagram when the number of the homopolar extension units is 1 and the number of the antipolar extension units is 2 according to the present invention.

Fig. 3 is a schematic diagram of a conventional Zeta converter circuit.

Fig. 4 is a graph comparing the input/output gain of the present invention with the same-polarity extension unit number of 1 and the reverse-polarity extension unit number of 2 with the input/output gain of the conventional Zeta-potential converter.

Fig. 5 is a simulation diagram of an output waveform when D is 0.725 when the input voltage is 30V, the number of homopolar extension units is 1, and the number of reverse polarity extension units is 2 according to the present invention.

Detailed Description

Fig. 2 shows a circuit topology diagram when the number of extension units m is 2 and n is 2 according to the present invention:

an automatic voltage-sharing bipolar Zeta DC-DC converter comprises a direct current input source, two loads, a basic Zeta converter, 1 homopolar extension unit and 2 reverse polarity voltage extension units. Wherein:

the basic Zeta-converter comprises two inductors L, L_P1Two capacitors C_P11、C_P12A power switch S₁A diode D_P1. The connection form is as follows: power switch S₁The drain electrode of the capacitor is connected with the anode of the input power supply, and the source electrode of the capacitor is connected with one end of an inductor L and a capacitor C_P11One terminal of (C), a capacitor_P11Another end of (1) and an inductor L_P1And a diode D_P1Is connected to the cathode of the inductor L_P1Another terminal of (1) and a capacitor C_P12Is connected with one end of the inductor L, the other end of the inductor L and the diode D_P1Anode and capacitor C_P12And the other end of the second switch is connected with the negative electrode of the input power supply.

The homopolar and reverse polarity extension units all have the same internal structure, taking reverse polarity extension unit 1 as an example, it contains: an inductance L_N1A diode D_N1Two capacitors C_N11、C_N12. Wherein the capacitor C_N11Another end of (1) and an inductor L_N1And a diode D_N1Is connected to the cathode of the inductor L_N1Another terminal of (1) and a capacitor C_N12Are connected at one end.

The connection relationship between the 1 st homopolar extension unit and the basic Zeta converter is as follows: capacitance C in basic Zeta converter_P11And the intersection point of one end of the inductor L and one end of the capacitor C in the 1 st extension unit_P21Is connected to one end of the inductor L in the basic Zeta converter_P1Another terminal of (1) and a capacitor C_P12And the intersection point of one end of the first extension unit and the diode D in the 1 st extension unit_P2Anode and capacitor C_P22The intersection points of the other ends are connected.

The connection relationship between the 1 st buck extension unit and the basic Zeta converter is as follows: capacitance C in basic Zeta converter_P11And the intersection point of one end of the capacitor L and one end of the inductor L and the capacitor C in the 1 st reversed polarity extension unit_N11Are connected at one end, diode D in the basic Zeta converter_N1Anode and capacitor C_N12And the intersection point of the other end of the first extension unit and the inductance L in the 1 st extension unit_N2Another terminal of (1) and a capacitor C_N22The intersections of one end are connected.

Load R_PLBoth ends of (A) and a capacitor C in the same-polarity extension unit_P22One end of which is connected to ground. Load R_NLBoth ends of (A) and a capacitor C in the reverse polarity extension unit_N22The other end of which is connected to ground.

The gate of the power switch S1 is connected to its controller, and its duty cycle can be varied between 0 and 1. The on-off time of the power switch S1 can be controlled by adjusting the duty ratio, and the output voltage level can be adjusted according to the voltage balance formula of the inductor.

When the current of the inductor L is continuously conducted, the circuit can be divided into 2 working states according to the different states of the power switch:

1: power switch S₁Conducting, diode D_P1、D_P2、D_N1、D_N2Are all turned off, and the inductor L, L at the moment_P1、L_P2、L_N1、L_N2Capacitor C_P12、C_P22、C_N12、C_N22Charging, capacitance C_P11、C_P21、C_N11、C_N21Discharging; inductor L, L_P1、L_P2、L_N1、L_N2The terminal voltage is shown as follows:

2: power switch S₁Turn-off, diode D_P1、D_P2、D_N1、D_N2Are all turned on, and the inductor L, L is at the moment_P1、L_P2、L_N1、L_N2Capacitor C_P12、C_P22、C_N12、C_N22Discharge, capacitance C_P11、C_P21、C_N11、C_N21Charging; inductor L, L_P1、L_P2、L_N1、L_N2The terminal voltage is shown as follows:

the above circuit division into 2 operating states, based on the duty cycle of the controller connected to the gate of the power switch S1, yields the following voltage levels across each capacitor:

fig. 4 is a graph comparing the input/output gain of the present invention with the same-polarity extension unit number of 1 and the reverse-polarity extension unit number of 2 with the input/output gain of the conventional Zeta-potential converter. As can be seen from fig. 4, when the duty ratio is the same, the gain of the converter proposed by the present invention is twice that of the conventional converter, and bipolar voltages can be output.

Fig. 5 is a simulation diagram of an output waveform when D is 0.725 when the input voltage is 30V, the number of homopolar extension units is 1, and the number of reverse polarity extension units is 2 according to the present invention. The feasibility of the invention is verified by simulation, and the two ends of the two resistors have opposite voltage polarities relative to the ground and the same voltage magnitude.

Claims

1. An automatic voltage-sharing bipolar Zeta DC-DC converter is characterized in that: the converter comprises a direct current input source, a Zeta converter, m-1 homopolar extension units and n reversed polarity voltage extension units; wherein:

the Zeta-converter comprises two inductors L, L_P1Two capacitors C_P11、C_P12A power switch S₁A diode D_P1(ii) a The connection form is as follows: power switch S₁Is connected to the positive pole of the DC input source, power switch S₁Is connected with one end of an inductor L and a capacitor C_P11One terminal of (C), a capacitor_P11The other end of the first and second inductors are respectively connected with the inductor L_P1And a diode D_P1Is connected to the cathode of the inductor L_P1The other end of each of the first and second capacitors is connected to a capacitor C_P12Is connected with one end of the inductor L, the other end of the inductor L and the diode D_P1Anode and capacitor C_P12The other ends of the two-way switch are connected with the negative electrode of the direct current input source;

the 1 st homopolar extension unit comprises an inductor L_P2Diode D_P2Two capacitors C_P21、C_P22(ii) a Wherein, the capacitor C_P21The other end of the first and second inductors are respectively connected with the inductor L_P2And a diode D_P2Is connected to the cathode of the inductor L_P2Another terminal of (1) and a capacitor C_P22One end of the two ends are connected; diode D_P2Anode of (2) is connected with a capacitor C_P22The other end of (a);

the 2 nd homopolar extension unit comprises an inductor L_P3Diode D_P3Two capacitors C_P31、C_P32(ii) a Wherein, the capacitor C_P31The other end of the first and second inductors are respectively connected with the inductor L_P3And a diode D_P3Is connected to the cathode of the inductor L_P3Another terminal of (1) and a capacitor C_P32One end of the two ends are connected; diode D_P3Anode of (2) is connected with a capacitor C_P32In addition toOne end;

.... times, in the ith homopolar extension unit, 1< i ≦ m-1,

the 1 st reverse polarity voltage extension unit comprises an inductor L_N1Diode D_N1Two capacitors C_N11、C_N12(ii) a Wherein, the capacitor C_N11The other end of the first and second inductors are respectively connected with the inductor L_N1And a diode D_N1Is connected to the cathode of the inductor L_N1Another terminal of (1) and a capacitor C_N12One end of the two ends are connected; diode D_N1Anode of (2) is connected with a capacitor C_N12The other end of (a);

the 2 nd reverse polarity voltage extension unit comprises an inductor L_N2Diode D_N2Two capacitors C_N21、C_N22(ii) a Wherein, the capacitor C_N21The other end of the first and second inductors are respectively connected with the inductor L_N2And a diode D_N2Is connected to the cathode of the inductor L_N2Another terminal of (1) and a capacitor C_N22One end of the two ends are connected; diode D_N2Anode of (2) is connected with a capacitor C_N22The other end of (a);

.... times, in the j-th reversed polarity voltage expansion unit, 1< j ≦ n,

the jth reverse polarity voltage extension unit comprises an inductor L_NjDiode D_NjTwo capacitors C_Nj1、C_Nj2(ii) a Wherein, the capacitor C_Nj1The other end of the first and second inductors are respectively connected with the inductor L_NjAnd a diode D_NjIs connected to the cathode of the inductor L_NjAnother terminal of (1) and a capacitor C_Nj2One end of the two ends are connected; diode D_NjAnode of (2) is connected with a capacitor C_Nj2The other end of (a);

1<i is less than or equal to m-1, and the capacitance C in the i-1 th homopolar extension unit_Pi2One end of (1), an inductance L_PiAnd the intersection point of the other end of the first and second electrodes and the capacitor C in the ith homopolar extension unit_P(i+1)2Is connected with the other end of the capacitor C in the i-1 th homopolar extension unit_Pi1One end of the first capacitor and the capacitors C in the i same-polarity extension units_P(i+1)1One end of the two ends are connected;

1<j is less than or equal to n, and the capacitor C in the jth extension unit_Nj2One end of (1) and an inductor L_NjAnd the intersection point of the other end of the first diode and the diode D in the (j-1) th reversed polarity extension unit_N(j-1)Anode and capacitor C_N(j-1)2The intersection points of the other ends are connected; capacitor C_Nj1One end of the capacitor is connected with the capacitor C in the j-1 th expansion unit_N(j-1)1One end is connected;

the connection relationship between the 1 st homopolar extension unit and the Zeta converter is as follows:

capacitor C in Zeta converter_P11And the intersection point of one end of the inductor L and the capacitor C in the 1 st extension unit with the same polarity_P21Is connected to one end of the Zeta converter, an inductor L in the Zeta converter_P1Another terminal of (1) and a capacitor C_P12And the intersection point of one end of the first extension unit is connected with the diode D in the 1 st extension unit with the same polarity_P2Anode and capacitor C_P22The intersection points of the other ends are connected;

the connection relationship between the 1 st buck extension unit and the Zeta converter is as follows:

capacitor C in Zeta converter_P11And the intersection point of one end of the capacitor L and one end of the inductor L and the capacitor C in the 1 st reversed polarity extension unit_N11Are connected to one end of a diode D in the Zeta-converter_P1Anode and capacitor C_P12And the intersection point of the other end of the first and second electrodes connected with the inductor L in the 1 st reversed polarity extension unit_N1Another terminal of (1) and a capacitor C_N12The intersection points of one end are connected;

load R_PLAre respectively connected with the capacitor C in the m-1 th homopolar extension unit_Pm2One end of the direct current input source is connected with the cathode of the direct current input source;

2. The automatic voltage-sharing bipolar Zeta DC-DC converter according to claim 1, wherein: the gate of the power switch S1 is connected to a controller, the duty cycle of which varies between 0 and 1.

3. The automatic voltage-sharing bipolar Zeta DC-DC converter according to claim 1, wherein: when m is 2 and n is 2, when the current of the inductor L is continuously conducted, the circuit is divided into 2 operating states according to the different power switch states:

(1) power switch S₁Conducting, diode D_P1、D_P2、D_N1、D_N2Are all turned off, and the inductor L, L at the moment_P1、L_P2、L_N1、L_N2Capacitor C_P12、C_P22、C_N12、C_N22Charging, capacitance C_P11、C_P21、C_N11、C_N21Discharging; inductor L, L_P1、L_P2、L_N1、L_N2The terminal voltage is shown as follows:

(2) power switch S₁Turn-off, diode D_P1、D_P2、D_N1、D_N2Are all turned on, and the inductor L, L is at the moment_P1、L_P2、L_N1、L_N2Capacitor C_P12、C_P22、C_N12、C_N22Discharge, capacitance C_P11、C_P21、C_N11、C_N21Charging; inductor L, L_P1、L_P2、L_N1、L_N2The terminal voltage is shown as follows: