CN113890347A

CN113890347A - Single-input high-reliability capacitance current consistent Zeta DC-DC converter

Info

Publication number: CN113890347A
Application number: CN202111129459.8A
Authority: CN
Inventors: 邾玢鑫; 郭浩; 刘佳欣
Original assignee: China Three Gorges University CTGU
Current assignee: China Three Gorges University CTGU
Priority date: 2021-09-26
Filing date: 2021-09-26
Publication date: 2022-01-04

Abstract

A single-input high-reliability capacitance-current uniform Zeta DC-DC converter comprises a direct current input source, a basic Zeta converter,ma forward direction extension unit for the forward direction extension unit,nand a reverse voltage extension unit. The forward and reverse extension units are composed of two inductors, two capacitors and a diode, and the adjustment of the input and output gains of the converter can be realized by adjusting the number of the forward and reverse extension units. The converter has the characteristics of simple control and drive circuit, wide input and output voltage regulation range and high reliability; when one of the switching tubes of the gain expansion unit is damaged, other circuits can work normally; is suitable for outputting input voltage and output powerThe voltage variation range is large, two power supplies are needed to supply power simultaneously, and the reliability requirement is high.

Description

Single-input high-reliability capacitance current consistent Zeta DC-DC converter

Technical Field

The invention relates to a DC-DC converter, in particular to a single-input high-reliability capacitance current consistent Zeta DC-DC converter.

Background

In applications where both input and output voltages vary widely, the input voltage may be higher or lower than the output voltage. Common non-isolated Buck-Boost DC-DC converters suitable for the time are Buck-Boost, Cuk, Sepic 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, the scheme of the input and output gains of the single-input DC-DC converter is mostly constructed by cascading basic circuits, but the reliability is poor. Therefore, the research on the single-input buck-boost DC/DC converter which can realize high-gain boost and has high reliability has important significance.

Disclosure of Invention

The problem that the existing non-isolated single-input high-gain DC-DC converter is low in reliability is solved. The invention provides a single-input high-reliability capacitance current consistent type Zeta DC-DC converter based on a basic Zeta converter. The input and output gains of the converter can be adjusted by adjusting the number of the gain expansion units. The converter has the characteristics of simple control and drive circuit, wide input and output voltage regulation range and high reliability; when one of the switching tubes of the gain expansion unit is damaged, other circuits can work normally; the power supply is suitable for application occasions where the variation range of the output input voltage and the output voltage is large, two power supplies are required to supply power simultaneously, and the requirement on reliability is high.

The technical scheme adopted by the invention is as follows:

a single-input high-reliability capacitor-current unity-type Zeta DC-DC converter comprising:

a DC input source V_gThe Zeta converter comprises a basic Zeta converter, m positive expansion units and n negative expansion units;

the basic Zeta converter comprises an inductor L₀、L₀', capacitance C₀、C₀', power switch S₀Diode D₀；

Power switch S₀Drain connectionDC input source V_gPositive pole, power switch S₀The source electrodes are respectively connected with an inductor L₀One terminal, capacitor C₀One terminal, capacitor C₀The other ends are respectively connected with an inductor L₀' one terminal, diode D₀Cathode, inductor L₀' the other end is connected with a capacitor C₀' one end; capacitor C₀' the other end, diode D₀Anode, inductor L₀The other ends are connected with a direct current input source V_gA negative electrode;

m forward extension units:

the 1 st forward extension unit comprises an inductor L₁、L₂Diode D₁Power switch S₁Capacitor C₁、C₂(ii) a Wherein the content of the first and second substances,

power switch S₁The source electrodes are respectively connected with an inductor L₁One terminal, capacitor C₁One terminal, inductor L₁The other end is connected with a grounding end; capacitor C₁The other ends are respectively connected with a diode D₁Cathode, inductor L₂One end; inductor L₂The other end is connected with a capacitor C₂One terminal, capacitor C₂The other end is connected with a diode D₁An anode;

the 2 nd forward extension unit comprises an inductor L₃、L₄Diode D₂Power switch S₂Capacitor C₃、C₄(ii) a Wherein the content of the first and second substances,

power switch S₂The source electrodes are respectively connected with an inductor L₃One terminal, capacitor C₃One terminal, inductor L₃The other end is connected with a grounding end; capacitor C₃The other ends are respectively connected with a diode D₂Cathode, inductor L₄One end; inductor L₄The other end is connected with a capacitor C₄One terminal, capacitor C₄The other end is connected with a diode D₂An anode;

… …, and so on, m forward extension elements,

the mth forward extension unit comprises an inductor L_(2m-1)、L_2mDiode D_mPower switch S_mCapacitor C_(2m-1)、C_2m(ii) a Wherein the power switch S_mThe source electrodes are respectively connected with an inductor L_(2m-1)One terminal, capacitor C_(2m-1)One terminal, inductor L_(2m-1)The other end is connected with a grounding end; capacitor C_(2m-1)The other ends are respectively connected with a diode D_mCathode, inductor L_2mOne end; inductor L_2mThe other end is connected with a capacitor C_2mOne terminal, capacitor C_2mThe other end is connected with a diode D_mAn anode;

power switch S₁、S₂……S_mThe drain electrodes are connected with a DC input source V_gA positive electrode;

capacitance C in basic Zeta converter₀' one end is connected with a capacitor C in the 1 st forward extension unit₂The other end;

capacitance C in the 1 st forward extension unit₂One end of the capacitor C is connected with the 2 nd forward extension unit₄The other end;

… … and so on

Capacitance C in the (m-1) th forward extension unit_2m-2One end of the capacitor is connected with the capacitor C in the mth forward extension unit_2mAnd the other end.

n forward extension units:

the 1 st negative direction extension unit comprises an inductor L₁'、L₂', capacitance C₁'、C₂', power switch S₁', diode D₁'; wherein: power switch S₁The source electrodes are respectively connected with an inductor L₁' one terminal, capacitor C₁' one terminal, inductor L₁The other end is connected with a grounding terminal; capacitor C₁' the other end is respectively connected with a diode D₁' cathode, inductor L₂' one terminal, inductor L₂' the other end is connected with a capacitor C₂' one terminal, capacitor C₂' the other end is connected with a diode D₁' an anode;

the 2 nd negative direction extension unit comprises an inductor L₃'、L₄', capacitance C₃'、C₄', power switch S₂', diode D₂'；

Wherein: power switch S₂The source electrodes are respectively connected with an inductor L₃' one terminal, capacitor C₃' one terminal, inductor L₃The other end is connected with a grounding terminal; capacitor C₃' the other end is respectively connected with a diode D₂' cathode, inductor L₄' one terminal, inductor L₄' the other end is connected with a capacitor C₄' one terminal, capacitor C₄' the other end is connected with a diode D₂' an anode;

… …, and so on, n negative-going expansion units,

the nth negative extension unit comprises an inductor L_(2n-1)'、L_2n', capacitance C_(2n-1)'、C_2n', power switch S_n', diode D_n'; wherein the power switch S_nThe source electrodes are respectively connected with an inductor L_(2n-1)' one terminal, capacitor C_(2n-1)' one terminal, inductor L_(2n-1)The other end is connected with a grounding terminal; capacitor C_(2n-1)' the other end is respectively connected with a diode C_2n' cathode, inductor L_2n' one terminal, inductor L_2n' the other end is connected with a capacitor C_2n' one terminal, capacitor C_2n' the other end is connected with a diode D_n' an anode;

power switch S₁'、S₂'……S_nThe drains are all connected with a DC input source V_gA positive electrode;

capacitance C in basic Zeta converter₀' the other end is connected with the capacitor C in the 1 st negative direction extension unit₂' one end;

capacitance C in the 1 st negative extension cell₂The other end is connected with a capacitor C in the 2 nd negative direction extension unit₄' one end;

… … and so on

Capacitance C in the (n-1) th negative extension unit_2n-2The other end is connected with a capacitor C in the nth negative direction extension unit_2n' one end;

one end of a load R is connected with a capacitor C in the mth forward extension unit_2mOne end of the load R and the other end of the load R are connected with a capacitor C_2n' the other end.

The power switch S₀Power switch S₁、S₂……S_mPower switch S₁'、S₂'……S_n' the sources are connected with the controller, and the duty ratio of the sources can be changed between 0 and 1; when the power switch S₁、S₂……S_mPower switch S₁'、S₂'……S_n' when any one is damaged, the whole circuit can continue to work normally.

When the number of the extension units is m equal to 1 and n is 1, the invention provides a single-input high-reliability capacitance-current consistent type Zeta DC-DC converter, which comprises:

a DC input source V_gA basic Zeta converter, 1 positive extension unit and 1 negative extension unit;

Power switch S₀Drain electrode connected with DC input source V_gPositive pole, power switch S₀The source electrodes are respectively connected with an inductor L₀One terminal, capacitor C₀One terminal, capacitor C₀The other ends are respectively connected with an inductor L₀' one terminal, diode D₀Cathode, inductor L₀' the other end is connected with a capacitor C₀' one end; capacitor C₀' the other end, diode D₀Anode, inductor L₀The other ends are connected with a direct current input source V_gA negative electrode;

the 1 st forward extension unit comprises an inductor L₁、L₂Diode D₁Power switch S₁Capacitor C₁、C₂(ii) a Wherein the power switch S₁The source electrodes are respectively connected with an inductor L₁One terminal, capacitor C₁One terminal, inductor L₁The other end is connected with a grounding end; capacitor C₁The other ends are respectively connected with a diode D₁Cathode, inductor L₂One end; inductor L₂The other end is connected with a capacitor C₂One terminal, capacitor C₂The other end is connected with a diode D₁An anode;

power switch S₁Connecting a DC input source V_gCapacitance C in positive, basic Zeta converter₀' one end is connected with the firstCapacitance C in 1 forward extension unit₂The other end;

power switch S₁' Drain connected DC input Source V_gCapacitance C in positive, basic Zeta converter₀' the other end is connected with the capacitor C in the 1 st negative direction extension unit₂' one end;

one end of a load R is connected with a capacitor C₂One end of the load R and the other end of the load R are connected with a capacitor C₂' the other end.

The invention discloses a single-input high-reliability capacitance current consistent Zeta DC-DC converter, which has the following technical effects:

1) the buck-boost can be realized simultaneously, the input and output gains are high, and the output capacitors are connected in series and share voltage. When the inductor current is continuously conducted, the following details are provided:

when the input is V_gThe input and output gains are:

the voltage stress of the switching tube is as follows:

the stress on each diode is:

wherein: d is the duty cycle, V_gIs an input voltage u_oTo output a voltage u_s1、u_s1'、u_s0The voltage stress of the power switch is shown, and m and n are the number of the external expansion units.

2) When the power switch S₁、S₂……S_mPower switch S₁'、S₂'……S_n' when any one is damaged, the whole circuit can continue to work normally.

Drawings

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

Fig. 2 is a schematic diagram of a conventional Zeta converter circuit.

Fig. 3 is a circuit topology diagram when the number of forward extension units is 1 and the number of reverse extension units is 1 according to the present invention.

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

Fig. 5 is a simulation diagram of an output waveform when D is 0.6 when the input voltage is 30V, the number of forward extension units is 1, and the number of reverse extension units is 1 according to the present invention.

Fig. 6 is a simulation diagram of an output waveform when the switching tube S1 is broken when D is 0.6 when the input voltage is 30V, the number of forward extension units is 1, and the number of reverse extension units is 1 according to the present invention.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

As shown in fig. 3, a circuit topology diagram when the number of extension units m is 1 and n is 1 according to the present invention is shown:

a single-input high-reliability capacitance current consistent Zeta DC-DC converter comprises a direct current input source, a basic Zeta converter, m positive expansion units and n negative voltage expansion units; wherein:

the input unit of the basic Zeta converter comprises two inductors L₀、L₀', two capacitors C₀、C₀', a power switch S₀A diode D₀(ii) a The connection form is as follows: power switch S₀Is connected with a DC input source V_gPositive pole of (2), power switch S₀Are respectively connected with an inductor L₀One terminal of and a capacitor C₀One terminal of (C), a capacitor₀The other end of the first and second inductors are respectively connected with the inductor L₀' one terminal and diode D₀Is connected to the cathode of the inductor L₀The other terminal of the' and a capacitor C₀One terminal of' is connected to a capacitor C₀The other end of the' and a diode D₀Is connected with the anode of the inductor L₀And the other end of the DC input source V_gThe negative electrodes are connected;

the forward and reverse extension units all have the same internal structure, and taking the 1 st forward extension unit as an example, the forward extension unit comprises: inductor L₁、L₂Diode D₁Two capacitors C₁、C₂(ii) a Wherein, the capacitor C₁And one end of (A) and L₁One end of the two ends are connected; capacitor C₁The other end of the first and second inductors are respectively connected with the inductor L₂And a diode D₁Is connected to the cathode of the inductor L₁The other end of the first and second electrodes is grounded; capacitor C₂Another terminal of (1) and a diode D₁Are connected with each other.

The connection relationship between the 1 st forward extension unit and the basic Zeta converter is as follows: inductance L in basic Zeta converter₀The other terminal of the' and a capacitor C₀'the intersection point of one end of the' is connected with the diode D in the 1 st forward extension unit₁Anode and capacitor C₂The intersections of one end are connected.

The connection relationship between the 1 st negative-direction extension unit and the basic Zeta converter is as follows: inductance L in input unit₁One end of the' is connected with the cathode of an input source Vg, and a diode D in the input unit₀Anode and capacitor C₀'the intersection point of the other end of the' and the inductance L in the 1 st negative direction extension unit₂The other terminal of and a capacitor C₂' the intersections at one end are connected.

One end of a load R and a capacitor C in the mth forward extension unit_2mOne end of (1) and an inductor L_2mIs connected with the other end of the load R, and the other end of the load R is connected with the capacitor C in the nth negative direction extension unit_2nThe other end of the' and a diode D_n' intersection of anode connectionAre connected.

The gates of all power switches are connected to their controllers, and their duty cycles can be varied from 0 to 1. The on-off time of the power switch can be controlled by adjusting the duty ratio, and the output voltage grade can be adjusted according to the voltage balance formula of the inductor.

According to the different states of the power switch, the circuit can be divided into 2 working states:

mode 1: when S is₀、S₁、S₁' conducting, diode D₀、D₁、D₁' all off; inductor L₁、L₂、L₀、L₀'、L₁'、L₂' terminal voltage is shown as follows:

mode 2 when S₀、S₁、S₁' turn-off, diode D₀、D₁、D₁' all are on; inductor L₁、L₂、L₀、L₀'、L₁'、L₂' terminal voltage is shown as follows:

the voltage at two ends of the inductor is zero in one period, which can be obtained by volt-second balance of the inductor. The mathematical relation of the voltage at two ends of each capacitor and the duty ratio is obtained as follows:

fig. 4 is a graph comparing the input/output gain of the conventional Zeta converter with the forward extension unit number of 1 and the backward extension unit number of 1 according to the present invention. As can be seen from fig. 4, the gain of the proposed converter is three times that of the conventional converter when the duty ratio is the same.

Fig. 5 is a simulation diagram of an output waveform when the input voltage is 30V, the number of forward extension units is 1, and the number of reverse extension units is 1, and D is 0.6, according to the invention, and the feasibility of the invention is verified through simulation.

Fig. 6 is a simulation diagram of an output waveform when the switching tube S1 is damaged when the input voltage is 30V, the number of forward extension units is 1, and the number of reverse extension units is 1, and D is 0.6, according to the invention, and the reliability of the invention is verified by simulation.

Claims

1. A single-input high-reliability capacitance-current uniform type Zeta DC-DC converter, characterized in that the converter comprises:

m forward extension units:

the 2 nd forward extension unit comprises an inductor L₃、L₄Diode D₂Power switch S₂Capacitor C₃、C₄(ii) a Wherein the power switch S₂The source electrodes are respectively connected with an inductor L₃One terminal, capacitor C₃One terminal, inductor L₃The other end is connected with a grounding end; capacitor C₃The other ends are respectively connected with a diode D₂Cathode, inductor L₄One end; inductor L₄The other end is connected with a capacitor C₄One terminal, capacitor C₄The other end is connected with a diode D₂An anode;

… …, and so on, m forward extension elements,

… … and so on

Capacitance C in the (m-1) th forward extension unit_2m-2One end of the capacitor is connected with the capacitor C in the mth forward extension unit_2mThe other end;

n forward extension units:

the 2 nd negative direction extension unit comprises an inductor L₃'、L₄', capacitance C₃'、C₄', power switch S₂', diode D₂'; wherein: power switch S₂The source electrodes are respectively connected with an inductor L₃' one terminal, capacitor C₃' one terminal, inductor L₃The other end is connected with a grounding terminal; capacitor C₃' the other end is respectively connected with a diode D₂' cathode, inductor L₄' one terminal, inductor L₄' the other end is connected with a capacitor C₄' one terminal, capacitor C₄' the other end is connected with a diode D₂' an anode;

… …, and so on, n negative-going expansion units,

power switch S₁'、S₂'……S_nThe drains are all connected to a DC sourceSource V_gA positive electrode;

… … and so on

2. A single-input high-reliability capacitor-current-unity type Zeta DC-DC converter according to claim 1, characterized in that: the power switch S₀Power switch S₁、S₂……S_mPower switch S₁'、S₂'……S_n' the sources are connected with the controller, and the duty ratio of the sources can be changed between 0 and 1; when the power switch S₁、S₂……S_mPower switch S₁'、S₂'……S_n' when any one is damaged, the whole circuit can continue to work normally.

3. A single-input high-reliability capacitance-current uniform Zeta DC-DC converter is characterized in that: the converter includes:

Power switch S₀Drain electrode connected with DC input source V_gPositive pole, power switch S₀The source electrodes are respectively connected with the electric connectionFeeling L₀One terminal, capacitor C₀One terminal, capacitor C₀The other ends are respectively connected with an inductor L₀' one terminal, diode D₀Cathode, inductor L₀' the other end is connected with a capacitor C₀' one end; capacitor C₀' the other end, diode D₀Anode, inductor L₀The other ends are connected with a direct current input source V_gA negative electrode;

power switch S₁Connecting a DC input source V_gCapacitance C in positive, basic Zeta converter₀' one end is connected with a capacitor C in the 1 st forward extension unit₂The other end;

4. A single-input high-reliability capacitor-current-unity type Zeta DC-DC converter according to claim 3, characterized in that: provided with an inductor L_nAt a voltage of V_LnCapacitor C_nAt a voltage of V_n(ii) a n is the serial number of an inductor or a capacitor;

the voltage at two ends of the inductor is zero in one period; the mathematical relation of the voltage at two ends of each capacitor and the duty ratio is obtained as follows: