CN113890342A - Multi-input high-reliability Sepic DC-DC converter with consistent capacitance and current - Google Patents

Abstract

A multi-input high-reliability capacitance current consistent SepicDC-DC converter comprises n +1 direct current input sources, a basic Sepic converter and n gain expansion units. The gain expansion units are composed of two inductors, two capacitors, a power switch and a diode, and the adjustment of the input and output gains of the converter and the voltage stress of the switching device can be realized 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, and when one switching tube is damaged, other circuits can work normally; the power supply is suitable for application occasions with large variation range of output and input voltage and output voltage, need of a plurality of power supplies for supplying power simultaneously and high reliability requirement.

Description

Multi-input high-reliability Sepic DC-DC converter with consistent capacitance and current

Technical Field

The invention relates to a DC-DC converter, in particular to a multi-input high-reliability capacitance current consistency Sepic 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, basic circuits are mostly adopted to be constructed in parallel in the scheme of input and output gains of the double-input DC-DC converter, but the reliability is poor. Therefore, the research on the multi-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 multi-input high-gain DC-DC converter is low in reliability is solved. The invention provides a multi-input high-reliability capacitance current consistent Sepic DC-DC converter based on a basic Sepic circuit, which consists of a basic Sepic 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 characteristics of simple control and drive circuit, wide input and output voltage regulation range and high reliability; when one of the switching tubes is damaged, other circuits can work normally; the power supply is suitable for application occasions where the variation range of the output and input voltage and the output voltage is large, a plurality of 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 multi-input high-reliability capacitance current coincidence Sepic DC-DC converter comprises:

n +1 direct current power supplies, a basic Sepic converter, n gain expansion units, wherein:

basic Sepic converter contains electricityFeeling L₁、L₂Capacitor C₁、C₂Power switch S₁Diode D₁(ii) a Inductor L₁One end is connected with a direct current power supply u_in1Positive electrode, inductor L₁The other ends are respectively connected with a power switch S₁Drain electrode, capacitor C₁One terminal, capacitor C₁The other ends are respectively connected with an inductor L₂One terminal, diode D₁Anode, diode D₁Cathode connection capacitor C₂One terminal, capacitor C₂Another terminal, an inductance L₂The other end, power switch S₁The source electrodes are all connected with a direct current power supply u_in1A negative electrode;

of the n gain expansion units, the 1 st gain expansion unit includes an inductor L₁₁、L₁₂Capacitor C₁₁、C₁₂Power switch S₂Diode D₁₁(ii) a Wherein, the DC power supply u_in2Positive electrode connecting inductor L₁₁One terminal, inductor L₁₁The other ends are respectively connected with a power switch S₂Drain electrode, capacitor C₁₁One terminal, capacitor C₁₁The other ends are respectively connected with an inductor L₁₂One terminal, diode D₁₁Anode, diode D₁₁Cathode connection capacitor C₁₂One terminal, power switch S₂Source connected to DC power supply u_in2Negative electrode, capacitor C₁₂The other end is connected with an inductor L₁₂The other end; the 2 nd gain expansion unit comprises an inductor L₂₁、L₂₂Capacitor C₂₁、C₂₂Power switch S₃Diode D₂₁(ii) a Wherein, the DC power supply u_in3Positive electrode connecting inductor L₂₁One terminal, inductor L₂₁The other ends are respectively connected with a power switch S₃Drain electrode, capacitor C₂₁One terminal, capacitor C₂₁The other ends are respectively connected with an inductor L₂₂One terminal, diode D₂₁Anode, diode D₂₁Cathode connection capacitor C₂₂One terminal, power switch S₃Source connected to DC power supply u_in3Negative electrode, capacitor C₂₂The other end is connected with an inductor L₂₂The other end;

.... and so on;

the nth gain expansion unit comprises an inductor L_n1、L_n2Capacitor C_n1、C_n2Power switch S_n+1Diode D_n1(ii) a Wherein, the DC power supply u_in(n+1)Positive electrode connecting inductor L_n1One terminal, inductor L_n1The other ends are respectively connected with a power switch S_n+1Drain electrode, capacitor C_n1One terminal, capacitor C_n1The other ends are respectively connected with an inductor L_n2One terminal, diode D_n1Anode, diode D_n1Cathode connection capacitor C_n2One terminal, power switch S_n+1Source connected to DC power supply u_in(n+1)Negative electrode, capacitor C_n2The other end is connected with an inductor L_n2The other end;

DC power supply u_in2Negative electrode, DC power supply u_in3DC power supply u_in(n+1)The negative poles of the DC power supply u are all connected with the DC power supply u in the basic Sepic converter_in1A negative electrode;

capacitance C in the 1 st gain expansion unit₁₂One end of the capacitor C is connected with the basic Sepic converter₂On the other hand, the connection relationship between the gain expansion units is as follows:

capacitance C in the 1 st gain expansion unit₁₂The other end is connected with a capacitor C in the 2 nd gain expansion unit₂₂One end;

capacitance C in the 2 nd gain expansion unit₂₂The other end is connected with a capacitor C in the 3 rd gain expansion unit₃₂One end;

.... and so on;

capacitor C in the (n-1) th gain expansion unit_(n-1)2The other end is connected with a capacitor C in the nth gain expansion unit_n2One end; one end of a load R is connected with a capacitor C in the basic Sepic converter₂One end of the load R and the other end of the load R are connected with a capacitor C_n2And the other end.

The power switch S₁And S₂、…、S_n、S_n+1The gates of (A) are all connected with a controller, the duty ratio of the gates can be changed between 0 and 1 when S₂、…、S_n、S_n+1Therein is anyWhen one switch tube is damaged, the whole circuit can continue to work normally.

When the number of gain expansion units is 2, the converter comprises:

3 direct current power supplies, a basic Sepic converter, 2 gain expansion units, wherein:

the basic Sepic converter comprising an inductor L₁、L₂Capacitor C₁、C₂Power switch S₁Diode D₁(ii) a Inductor L₁One end is connected with a direct current power supply u_in1Positive electrode, inductor L₁The other ends are respectively connected with a power switch S₁Drain electrode, capacitor C₁One terminal, capacitor C₁The other ends are respectively connected with an inductor L₂One terminal, diode D₁Anode, diode D₁Cathode connection capacitor C₂One terminal, capacitor C₂Another terminal, an inductance L₂The other end, power switch S₁The source electrodes are all connected with a direct current power supply u_in1A negative electrode;

in the 2 gain-spreading units, the gain-spreading unit,

the 1 st gain expansion unit comprises an inductor L₁₁、L₁₂Capacitor C₁₁、C₁₂Power switch S₂Diode D₁₁(ii) a Wherein, the DC power supply u_in2Positive electrode connecting inductor L₁₁One terminal, inductor L₁₁The other ends are respectively connected with a power switch S₂Drain electrode, capacitor C₁₁One terminal, capacitor C₁₁The other ends are respectively connected with an inductor L₁₂One terminal, diode D₁₁Anode, diode D₁₁Cathode connection capacitor C₁₂One terminal, power switch S₂Source connected to DC power supply u_in2Negative electrode, capacitor C₁₂The other end is connected with an inductor L₁₂The other end;

the 2 nd gain expansion unit comprises an inductor L₂₁、L₂₂Capacitor C₂₁、C₂₂Power switch S₃Diode D₂₁(ii) a Wherein, the DC power supply u_in3Positive electrode connecting inductor L₂₁One terminal, inductor L₂₁The other ends are respectively connected with a power switch S₃Drain electrode, capacitor C₂₁One terminal, capacitor C₂₁The other ends are respectively connected with an inductor L₂₂One terminal, diode D₂₁Anode, diode D₂₁Cathode connection capacitor C₂₂One terminal, power switch S₃Source connected to DC power supply u_in3Negative electrode, capacitor C₂₂The other end is connected with an inductor L₂₂The other end;

DC power supply u_in2Negative electrode, DC power supply u_in3The negative poles of the DC power supply u are all connected with the DC power supply u in the basic Sepic converter_in1A negative electrode;

capacitance C in the 1 st gain expansion unit₁₂One end of the capacitor C is connected with the basic Sepic converter₂On the other hand, the connection relationship between the gain expansion units is as follows:

capacitance C in the 1 st gain expansion unit₁₂The other end is connected with a capacitor C in the 2 nd gain expansion unit₂₂One end; one end of a load R is connected with a capacitor C in the basic Sepic converter₂One end of the load R and the other end of the load R are connected with a capacitor C₂₂And the other end.

The invention discloses a multi-input high-reliability capacitance current consistent Sepic 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. Inductor L₁、L₁₁、......、L_n1When the current of (2) is continuously conducted, the following is concrete:

when u is_in1＝u_in2＝...＝u_innWhen the temperature of the water is higher than the set temperature,

the voltage stress of the switching tube is as follows:

the voltage on each output capacitor is:

wherein: d is the duty cycle, u_in1、u_in2、…、u_innIs an input voltage u_S1、u_S2、…、u_SnThe voltage stress of the power switch is adopted, and n is the number of gain expansion units;

2) when S is₂、…、S_n、S_n+1When one of the switch tubes is damaged, other circuits can 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 Sepic converter circuit.

Fig. 3 is a circuit topology diagram of the present invention with a gain expansion unit number of 2.

Fig. 4 is a graph comparing the input/output gain of the present invention with the input/output gain of the conventional Sepic converter when the number of gain expansion units is 2.

Fig. 5 is a simulation diagram of an output waveform when the input voltage is 30V and the number of gain expansion units is 2 and D is 0.6 according to the present invention.

Fig. 6 is a simulation diagram of an output waveform when the switching tube S3 is broken according to the present invention, the input voltage is 30V, the number of gain expansion units is 2, and D is 0.6.

Detailed Description

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

Fig. 3 shows a circuit topology diagram when the number of gain expansion units is 2 according to the present invention:

a multi-input high-reliability capacitance current uniform Sepic DC-DC converter comprises 3 direct current input sources, 1 basic Sepic converter and 2 gain expansion units, wherein:

the basic Sepic converter comprises two inductors L₁、L₂Two capacitors C₁、C₂A power switch S₁A diode D₁(ii) a The connection form is as follows:

inductor L₁One end of is connected with a direct current power supply u_in1Positive electrode of (1), inductor L₁Are respectively connected with a power switch S₁OfElectrode and capacitor C₁One terminal of (C), a capacitor₁The other end of the first and second inductors are respectively connected with the inductor L₂And a diode D₁Is connected to the anode of a diode D₁Cathode and capacitor C₂Are connected to one end of a power switch S₁Source electrode and inductor L₂And a capacitor C₂And the other end of the DC input power u_in1The negative electrodes are connected;

the first gain expansion unit comprises two inductors L₁₁、L₁₂Two capacitors C₁₁、C₁₂A power switch S₂A diode D₁₁(ii) a Wherein, the inductance L₁₁One end of is connected with a direct current power supply u_in2Positive electrode of (1), inductor L₁₁Are respectively connected with a power switch S₂Drain electrode of (1) and capacitor C₁₁One terminal of (C), a capacitor₁₁The other end of the first and second inductors are respectively connected with the inductor L₁₂One terminal and diode D₁₁Is connected with the anode of the inductor L₁₂Another terminal of (1) and a capacitor C₁₂Are connected to one end of a power switch S₂Source electrode of (2), diode D₁₁Cathode and capacitor C₁₂And the other end of the DC input power u_in2The negative electrodes are connected;

the second gain expansion unit comprises two inductors L₂₁、L₂₂Two capacitors C₂₁、C₂₂A power switch S₃A diode D₂₁(ii) a Wherein, the inductance L₂₁One end of is connected with a direct current power supply u_in3Positive electrode of (1), inductor L₂₁Are respectively connected with a power switch S₃Drain electrode of (1) and capacitor C₂₁One terminal of (C), a capacitor₂₁The other end of the first and second inductors are respectively connected with the inductor L₂₂And a diode D₂₁Is connected with the anode of the inductor L₂₂Another terminal of (1) and a capacitor C₂₂Are connected to one end of a power switch S₃Source electrode of (2), diode D₂₁Cathode and capacitor C₂₂And the other end of the DC input power u_in3The negative electrodes are connected;

the connection relationship between the first gain expansion unit and the basic Sepic converter is as follows: basic Sepic conversionInductor L in device₂And a capacitor C₂And the other end of the first gain expansion unit is connected with the diode D in the first gain expansion unit₁₁Cathode and capacitor C₁₂The other end of the U-shaped transformer is connected with the cross point of the other end of the U-shaped transformer, and the U of the direct current input power supply_in1Negative pole and DC input power u_in2The negative electrodes are connected;

the connection between the two gain expansion units is as follows: inductance L in the 1 st gain expansion unit₁₂And a capacitor C₁₂And the other end of the second diode is connected with the diode D in the 2 nd gain expansion unit₂₁Cathode and capacitor C₂₂The other end is connected with the cross point of the other end, and a direct current input power supply u_in2Negative pole of (1) and DC input power u_in3Are connected with each other.

One end of load R and diode D in basic Sepic converter₁Cathode and capacitor C₁Is connected with the other end of the load R and the inductor L in the second gain expansion unit₂₂Another terminal of (1) and a capacitor C₂₂Are connected at the intersection point where one end of the two ends are connected.

Power switch S₁、S₂、S₃The gate of (a) is connected to its controller, and its duty cycle can be varied between 0 and 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.

At the inductor L₁、L₁₁、L₂₁When the current is continuously conducted, the circuit can be divided into 2 working states according to different power switch states:

(1) power switch S₁、S₂、S₃Conducting, diode D₁、D₁₁、D₂₁Are all turned off, at the moment, the inductance L₁、L₁₁、L₂₁Capacitor C₁₂、C₂₂Charging, inductance L₂、L₁₂、L₂₂Capacitor C₁、C₂、C₁₁、C₂₁And (4) discharging. Inductor L₁、L₂、L₁₁、L₁₂、L₂₁、L₂₂The terminal voltages are as follows:

(2) power switch S₁、S₂、S₃Turn-off, diode D₁、D₁₁、D₂₁Are all conducted, at this moment, the inductance L₁、L₁₁、L₂₁Capacitor C₁₂、C₂₂Discharge, inductance L₂、L₁₂、L₂₂Capacitor C₁、C₂、C₁₁、C₂₁And (6) charging. Inductor L₁、L₂、L₁₁、L₁₂、L₂₁、L₂₂The terminal voltages are as follows:

according to the connection at the power switch S₁、S₂、S₃The duty cycle of the controller on the gate, the voltage level on each capacitor can be derived as follows:

fig. 4 is a graph comparing the input/output gain of the present invention with the input/output gain of the conventional Sepic converter when the number of gain expansion units is 2. 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 and the number of gain expansion units is 2 and D is 0.6 according to the present invention. The feasibility of the invention is verified by simulation.

Fig. 6 is a simulation diagram of an output waveform when the switching tube S3 is broken according to the present invention, the input voltage is 30V, the number of gain expansion units is 2, and D is 0.6.

Claims (4)

1. A multi-input high-reliability Sepic DC-DC converter with consistent capacitance and current is characterized by comprising:

n +1 direct current power supplies, a basic Sepic converter, n gain expansion units, wherein:

the basic Sepic converter comprising an inductor L₁、L₂Capacitor C₁、C₂Power switch S₁Diode D₁(ii) a Inductor L₁One end is connected with a direct current power supply u_in1Positive electrode, inductor L₁The other ends are respectively connected with a power switch S₁Drain electrode, capacitor C₁One terminal, capacitor C₁The other ends are respectively connected with an inductor L₂One terminal, diode D₁Anode, diode D₁Cathode connection capacitor C₂One terminal, capacitor C₂Another terminal, an inductance L₂The other end, power switch S₁The source electrodes are all connected with a direct current power supply u_in1A negative electrode;

of the n gain-spreading units, the gain-spreading unit,

the 1 st gain expansion unit comprises an inductor L₁₁、L₁₂Capacitor C₁₁、C₁₂Power switch S₂Diode D₁₁(ii) a Wherein, the DC power supply u_in2Positive electrode connecting inductor L₁₁One terminal, inductor L₁₁The other ends are respectively connected with a power switch S₂Drain electrode, capacitor C₁₁One terminal, capacitor C₁₁The other ends are respectively connected with an inductor L₁₂One terminal, diode D₁₁Anode, diode D₁₁Cathode connection capacitor C₁₂One terminal, power switch S₂Source connected to DC power supply u_in2Negative electrode, capacitor C₁₂The other end is connected with an inductor L₁₂The other end;

the 2 nd gain expansion unit comprises an inductor L₂₁、L₂₂Capacitor C₂₁、C₂₂Power switch S₃Diode D₂₁(ii) a Wherein, the DC power supply u_in3Positive electrode connecting inductor L₂₁One terminal, inductor L₂₁The other ends are respectively connected with a power switch S₃Drain electrode, capacitor C₂₁One terminal, capacitor C₂₁The other ends are respectively connected with an inductor L₂₂One terminal, diode D₂₁Anode, diode D₂₁Cathode connection capacitor C₂₂One terminal, power switch S₃Source connected to DC power supply u_in3Negative electrode, capacitor C₂₂The other end is connected with an inductor L₂₂The other end;

.... and so on;

the nth gain expansion unit comprises an inductor L_n1、L_n2Capacitor C_n1、C_n2Power switch S_n+1Diode D_n1(ii) a Wherein, the DC power supply u_in(n+1)Positive electrode connecting inductor L_n1One terminal, inductor L_n1The other ends are respectively connected with a power switch S_n+1Drain electrode, capacitor C_n1One terminal, capacitor C_n1The other ends are respectively connected with an inductor L_n2One terminal, diode D_n1Anode, diode D_n1Cathode connection capacitor C_n2One terminal, power switch S_n+1Source connected to DC power supply u_in(n+1)Negative electrode, capacitor C_n2The other end is connected with an inductor L_n2The other end;

DC power supply u_in2Negative electrode, DC power supply u_in3DC power supply u_in(n+1)The negative poles of the DC power supply u are all connected with the DC power supply u in the basic Sepic converter_in1A negative electrode;

capacitance C in the 1 st gain expansion unit₁₂One end of the capacitor C is connected with the basic Sepic converter₂On the other hand, the connection relationship between the gain expansion units is as follows:

capacitance C in the 1 st gain expansion unit₁₂The other end is connected with a capacitor C in the 2 nd gain expansion unit₂₂One end;

capacitance C in the 2 nd gain expansion unit₂₂The other end is connected with a capacitor C in the 3 rd gain expansion unit₃₂One end;

.... and so on;

capacitor C in the (n-1) th gain expansion unit_(n-1)2The other end is connected with a capacitor C in the nth gain expansion unit_n2One end;

one end of a load R is connected with a capacitor C in the basic Sepic converter₂One end, loaded with ROne end is connected with a capacitor C_n2And the other end.

2. The multi-input high-reliability capacitance current-matching Sepic DC-DC converter according to claim 1, characterized in that: the power switch S₁And S₂、…、S_n、S_n+1The gates of (A) are all connected with a controller, the duty ratio of the gates can be changed between 0 and 1 when S₂、…、S_n、S_n+1When any one of the switch tubes is damaged, the whole circuit can continue to work normally.

3. A multi-input high-reliability Sepic DC-DC converter with consistent capacitance and current is characterized by comprising:

3 direct current power supplies, a basic Sepic converter, 2 gain expansion units, wherein:

the basic Sepic converter comprising an inductor L₁、L₂Capacitor C₁、C₂Power switch S₁Diode D₁(ii) a Inductor L₁One end is connected with a direct current power supply u_in1Positive electrode, inductor L₁The other ends are respectively connected with a power switch S₁Drain electrode, capacitor C₁One terminal, capacitor C₁The other ends are respectively connected with an inductor L₂One terminal, diode D₁Anode, diode D₁Cathode connection capacitor C₂One terminal, capacitor C₂Another terminal, an inductance L₂The other end, power switch S₁The source electrodes are all connected with a direct current power supply u_in1A negative electrode;

in the 2 gain-spreading units, the gain-spreading unit,

the 1 st gain expansion unit comprises an inductor L₁₁、L₁₂Capacitor C₁₁、C₁₂Power switch S₂Diode D₁₁(ii) a Wherein, the DC power supply u_in2Positive electrode connecting inductor L₁₁One terminal, inductor L₁₁The other ends are respectively connected with a power switch S₂Drain electrode, capacitor C₁₁One terminal, capacitor C₁₁The other ends are respectively connected with an inductor L₁₂One terminal, diode D₁₁Anode, diode D₁₁Cathode connection capacitor C₁₂One terminal, power switch S₂Source connected to DC power supply u_in2Negative electrode, capacitor C₁₂The other end is connected with an inductor L₁₂The other end;

the 2 nd gain expansion unit comprises an inductor L₂₁、L₂₂Capacitor C₂₁、C₂₂Power switch S₃Diode D₂₁(ii) a Wherein, the DC power supply u_in3Positive electrode connecting inductor L₂₁One terminal, inductor L₂₁The other ends are respectively connected with a power switch S₃Drain electrode, capacitor C₂₁One terminal, capacitor C₂₁The other ends are respectively connected with an inductor L₂₂One terminal, diode D₂₁Anode, diode D₂₁Cathode connection capacitor C₂₂One terminal, power switch S₃Source connected to DC power supply u_in3Negative electrode, capacitor C₂₂The other end is connected with an inductor L₂₂The other end;

DC power supply u_in2Negative electrode, DC power supply u_in3The negative poles of the DC power supply u are all connected with the DC power supply u in the basic Sepic converter_in1A negative electrode;

capacitance C in the 1 st gain expansion unit₁₂One end of the capacitor C is connected with the basic Sepic converter₂On the other hand, the connection relationship between the gain expansion units is as follows:

capacitance C in the 1 st gain expansion unit₁₂The other end is connected with a capacitor C in the 2 nd gain expansion unit₂₂One end;

one end of a load R is connected with a capacitor C in the basic Sepic converter₂One end of the load R and the other end of the load R are connected with a capacitor C₂₂And the other end.

4. The multi-input high-reliability capacitance current-matching Sepic DC-DC converter according to claim 1, characterized in that: the number of gain expansion units is 2, and the inductance L₁、L₁₁、L₂₁When the current is continuously conducted, the circuit can be divided into 2 working states according to different power switch states:

(1) power switch S₁、S₂、S₃Conducting, diode D₁、D₁₁、D₂₁Are all turned off, at the moment, the inductance L₁、L₁₁、L₂₁Capacitor C₁₂、C₂₂Charging, inductance L₂、L₁₂、L₂₂Capacitor C₁、C₂、C₁₁、C₂₁Discharging; inductor L₁、L₂、L₁₁、L₁₂、L₂₁、L₂₂The terminal voltages are as follows:

(2) power switch S₁、S₂、S₃Turn-off, diode D₁、D₁₁、D₂₁Are all conducted, at this moment, the inductance L₁、L₁₁、L₂₁Capacitor C₁₂、C₂₂Discharge, inductance L₂、L₁₂、L₂₂Capacitor C₁、C₂、C₁₁、C₂₁Charging; inductor L₁、L₂、L₁₁、L₁₂、L₂₁、L₂₂The terminal voltages are as follows:

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