CN112737330B

CN112737330B - High-gain Buck-Boost DC-DC converter

Info

Publication number: CN112737330B
Application number: CN202011566124.8A
Authority: CN
Inventors: 邾玢鑫; 蓝海; 张耀; 杨楠; 马辉
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: CN112737330A

Abstract

A high-gain Buck-Boost DC-DC converter comprises a direct current input source, a basic Buck-Boost converter, m-1 voltage expansion units, 1 leakage inductance absorption unit and 1 transformer unit. The voltage expansion unit consists of an inductor, two capacitors and a diode, and the adjustment of the output gain of the converter and the voltage stress of the switching device can be realized by adjusting the number of the voltage expansion units. The converter has the advantages of simple control and drive circuit, high efficiency, low voltage stress of a switching device, fewer components and the like; is suitable for application occasions with larger voltage gain.

Description

High-gain Buck-Boost DC-DC converter

Technical Field

The invention relates to a DC-DC converter, in particular to a novel high-gain Buck-Boost DC-DC converter.

Background

Common non-isolated buck-boost DC-DC converters, such as: Buck-Boost, Cuk, Sepic and Zeta circuits are influenced by parasitic parameters of components and circuits, and high voltage gain is difficult to realize. The traditional non-isolated buck-boost DC-DC converter is improved to realize high voltage gain, but the circuit is complex and the number of components is large. The traditional isolated DC-DC converter can easily realize high gain, but the leakage inductance can generate larger voltage peak on the switching tube, so that the research on the novel high-gain boost DC/DC converter which can realize high-gain boost and eliminate the influence of the leakage inductance has important significance.

Disclosure of Invention

In order to solve the problem of voltage spike of a switching tube generated by leakage inductance of the existing isolation type high-gain DC-DC converter, the invention provides a high-gain DC-DC converter with a transformer based on a Buck-Boost circuit, and the converter is composed of a basic Buck-Boost converter, a transformer, a leakage inductance absorption unit and a plurality of gain expansion units. The improved circuit can utilize the energy in the leakage inductance to output to a post-stage circuit and solve the problem of voltage spike of the switching tube. The output gain of the converter can be realized by adjusting the number of the gain expansion units. The converter has the advantages of simple control and driving circuit, fewer components, lower stress of a switching tube and the like; is suitable for application occasions with larger voltage gain.

The technical scheme adopted by the invention is as follows:

a high-gain Buck-Boost DC-DC converter comprises a direct current input source, a basic Buck-Boost converter, m-1 voltage expansion units and 1 leakage inductance absorption unit; wherein:

the basic Buck-Boost converter comprises an original secondary side n₁:n₂Transformer T, two inductors L, L_rA capacitor C, a power switch S₁A diode D; the connection form is as follows:

switch S₁Is connected with the anode of the DC input source, a switch S₁The source electrode of the inductor is respectively connected with one end of the inductor L and the inductor L_rOne end of the inductor L, the other end of the inductor L and the lower end of the primary side of the transformer T are connected with the negative electrode of the direct current input source; inductor L_rThe other end of the transformer T is connected with the upper end of the primary side of the transformer T, the upper end of the secondary side of the transformer T is connected with the cathode of a diode D, the anode of the diode D is connected with one end of a capacitor C, and the other end of the capacitor C is connected with the lower end of the secondary side of the transformer T;

the leakage inductance absorption unit comprises a diode D₀A capacitor C₀(ii) a Wherein, the capacitor C₀And a diode D₀The anodes of the anode groups are connected; diode D₀Cathode of (2) is connected with an inductor L_rOne end;

the 1 st voltage extension unit comprises an inductor L₁Diode D₁Two capacitors C₁₁、C₁₂(ii) a Wherein, the capacitorC₁₁The other end of the first and second inductors are respectively connected with the inductor L₁And a diode D₁Is connected to the cathode of a diode D₁Anode and capacitor C₁₂Is connected to one terminal of a capacitor C₁₂Another end of (1) and an inductor L₁The other ends of the two are connected;

the 2 nd voltage extension unit comprises an inductor L₂Diode D₂Two capacitors C₂₁、C₂₂(ii) a Wherein, the capacitor C₂₁The other end of the first and second inductors are respectively connected with the inductor L₂And a diode D₂Is connected to the cathode of a diode D₂Anode and capacitor C₂₂Is connected to one terminal of a capacitor C₂₂Another end of (1) and an inductor L₂The other ends of the two are connected;

.... times in analogy, the ith voltage spreading unit, 1< i ≦ m-1,

the ith voltage expansion unit comprises an inductor L_iDiode D_iTwo capacitors C_i1、C_i2(ii) a Wherein, the capacitor C_i1The other end of the first and second inductors are respectively connected with the inductor L_iAnd a diode D_iIs connected to the cathode of a diode D_iAnode and capacitor C_i2Is connected to one terminal of a capacitor C_i2Another end of (1) and an inductor L_iThe other ends of the two are connected;

the connection form between the voltage expansion units is as follows:

1<i is less than or equal to m-1, and the capacitor C in the (i-1) th voltage extension unit_(i-1)2And a diode D_(i-1)The intersection point of the anode and the capacitor C in the ith voltage expansion unit_i2The other end and an inductor L_iThe other end is connected with the intersection point of the i-1 th voltage extension unit_(i-1)1And the capacitor C in the ith voltage extension unit_i1Are connected at one end.

The connection relation between the leakage inductance absorption unit and the basic Buck-Boost converter is as follows:

one end of an inductor L and a switch S in a basic Buck-Boost converter₁Source electrode and inductor L_rOne end crossing point and diode D in leakage inductance absorption unit₀Connected with the cathode of a basic Buck-An intersection point of the negative electrode of the direct-current power supply in the Boost converter and the other end of the inductor L and the capacitor C in the leakage inductance absorption unit₀The other ends of the two are connected;

the connection relationship between the 1 st voltage expansion unit and the basic Buck-Boost converter is as follows:

cathode of diode D in Buck-Boost converter and capacitor C in 1 st voltage expansion unit₁₁Is connected with the inductor L in the 1 st voltage extension unit, and the intersection point of the anode of the diode D and one end of the capacitor C in the basic Buck-Boost converter and the inductor L in the 1 st voltage extension unit₁The other end and a capacitor C₁₂The intersection points of the other ends are connected;

load R_LAre respectively connected with the capacitor C in the (m-1) th voltage extension unit_(m-1)2One terminal and a diode D_(m-1)Intersection point of anode and capacitor C in leakage inductance absorption unit₀And the other end of the two are connected.

The invention relates to a novel high-gain Buck-Boost DC-DC converter, which has the following technical effects:

1. the boost can be realized, the output gain is high, the voltage stress of the switch device is low, and the output capacitors are connected in series. When the current of the inductor L is continuously conducted, the following is concrete:

the output gain is:

the voltage stress of the switching tube is as follows:

the voltage on the output capacitor is:

wherein: d is the duty cycle, u_inIs an input voltage u_oTo output a voltage u_sFor power switch voltage stress, m-1 is the number of gain cells 0<i≤m-1。n₁And n₂The primary and secondary voltage variable-edge turns.

2. The number of components is small;

3. only 1 power switch is included, 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 voltage extension cells is 2 and the number of leakage inductance absorption cells is 1 according to the present invention.

Fig. 3 is a schematic diagram of a conventional isolated Buck-Boost converter circuit.

Fig. 4 is a graph comparing the output gain when the number of voltage expansion units is 2 and the number of leakage inductance absorption units is 1 with the input and output gain of the conventional Buck-Boost 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 voltage spreading units is 2, and the number of leakage inductance absorbing units is 1 according to the present invention.

Fig. 6 is a stress diagram of the switching tube when the input voltage is 30V, the number of voltage expansion units is 2, D is 0.725, and no leakage inductance absorption unit exists.

Fig. 7 is a stress diagram of the switching tube with leakage inductance absorption unit, wherein the input voltage is 30V, the number of voltage expansion units is 2, and D is 0.725.

Detailed Description

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

Fig. 2 shows a circuit topology diagram when the number of the voltage extension units is 2 and the number of the leakage inductance absorption units is 1 according to the present invention:

a novel high-gain Buck-Boost converter comprises a direct current input source, a load, a basic Buck-Boost converter, two voltage expansion units and a leakage inductance absorption unit. Wherein:

switch S₁Is connected with the anode of the DC input source, a switch S₁The source electrode of the inductor is respectively connected with one end of the inductor L and the inductor L_rOne end, inductor L and anotherThe end and the lower end of the primary side of the transformer T are connected with the negative electrode of the direct current input source; inductor L_rThe other end of the transformer T is connected with the upper end of the primary side of the transformer T, the upper end of the secondary side of the transformer T is connected with the cathode of the diode D, the anode of the diode D is connected with one end of the capacitor C, and the other end of the capacitor C is connected with the lower end of the secondary side of the transformer T.

The leakage inductance absorption unit comprises a diode D₀A capacitor C₀(ii) a Wherein, the capacitor C₀And a diode D₀The anodes of the anode groups are connected;

the 1 st and 2 nd voltage expansion units all have the same internal structure, and the 1 st voltage expansion unit is taken as an example;

the 1 st voltage extension unit comprises an inductor L₁Diode D₁Two capacitors C₁₁、C₁₂(ii) a Wherein, the capacitor C₁₁The other end of the first and second inductors are respectively connected with the inductor L₁And a diode D₁Is connected to the cathode of a diode D₁Anode and capacitor C₁₂Is connected to one terminal of a capacitor C₁₂Another end of (1) and an inductor L₁The other ends of the two are connected;

the connection form between the voltage expansion units is as follows:

capacitor C in 1 st voltage extension unit₁₂And a diode D₁The intersection point of the anode and the capacitor C in the 2 nd voltage extension unit₂₂The other end and an inductor L₂The other end of the capacitor is connected with the other end of the capacitor C in the 1 st voltage expansion unit₁₁And a capacitor C in the 2 nd voltage extension unit₂₁Are connected at one end.

one end of an inductor L and a switch S in a basic Buck-Boost converter₁The intersection point of the source electrode and the primary side end of the transformer and the diode D in the leakage inductance absorption unit₀Is connected with the cathode of the Buck-Boost converter, the intersection point of the negative pole of the direct current power supply in the basic Buck-Boost converter and the other end of the inductor L and the capacitor C in the leakage inductance absorption unit₀The other ends of the two are connected;

load R_LAre respectively connected with the capacitor C in the 2 nd voltage extension unit₂₂One terminal and a diode D₂The intersection of the anodes. And the capacitance C in the leakage inductance absorption unit₀And the other end of the two are connected.

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, D₀、D₁、D₂Are all turned off, and the inductor L, L at the moment₁、L₂、L_rCapacitor C₁₁、C₂₁Charging, capacitance C₀、C、C₁₂、C₂₂Discharging; inductor L, L₁、L₂、L_rThe terminal voltage is shown as follows:

(2): power switch S₁Off, diode D, D₀、D₁、D₂Are all turned on, and the inductor L, L is at the moment₁、L₂、L_rCapacitor C₁₁、C₂₁Discharge, capacitance C₀、C、C₁₂、C₂₂Charging; inductor L, L₁、L₂、L_rThe terminal voltage is shown as follows:

the circuit is divided into 2 working states, and according to the duty ratio of a controller connected to the grid of the power switch S1, the voltage level of each capacitor can be obtained as follows:

fig. 4 is a graph comparing the output gain when the number of the voltage expansion units is 2 and the number of the leakage inductance absorption units is 1 with the output gain of the conventional Buck-Boost converter. As can be seen from fig. 4, the gain of the converter proposed by the present invention is four times that of the conventional converter at the same duty ratio

Fig. 5 is a graph showing the simulation of the output waveform and the stress of the switching tube when D is 0.725 when the number of voltage extension units is 2 and the number of leakage inductance absorption units is 1 according to the present invention. The feasibility of the invention is verified by simulation, and the high gain of voltage is realized.

Fig. 6 and 7 are graphs of stress of the switching tube with or without the leakage inductance absorbing unit, where the number of the voltage spreading units is 2, D is 0.725. The feasibility of the invention is verified by simulation, and the voltage spike of the switching tube is obviously reduced.

Claims

1. A high-gain Buck-Boost DC-DC converter is characterized in that: the converter comprises a direct current input source, a Buck-Boost converter, m-1 voltage expansion units and 1 leakage inductance absorption unit; wherein:

the Buck-Boost converter comprises an original secondary side n₁:n₂Transformer T, two inductors L, L_rA capacitor C, a power switch S₁A diode D; the connection form is as follows:

switch S₁Is connected with the anode of the DC input source, a switch S₁The source electrode of the inductor is respectively connected with one end of the inductor L and the inductor L_rOne end, the other end of the inductor L, the lower end of the primary side of the transformer T and the DC inputThe negative electrodes of the sources are connected; inductor L_rThe other end of the transformer T is connected with the upper end of the primary side of the transformer T, the upper end of the secondary side of the transformer T is connected with the cathode of a diode D, the anode of the diode D is connected with one end of a capacitor C, and the other end of the capacitor C is connected with the lower end of the secondary side of the transformer T;

.... times in analogy, the ith voltage spreading unit, 1< i ≦ m-1,

the connection form between the voltage expansion units is as follows:

1<i is less than or equal to m-1, and the (i-1) th voltage expansion unitMiddle capacitor C_(i-1)2And a diode D_(i-1)The intersection point of the anode and the capacitor C in the ith voltage expansion unit_i2The other end and an inductor L_iThe other end is connected with the intersection point of the i-1 th voltage extension unit_(i-1)1And the capacitor C in the ith voltage extension unit_i1One end of the two ends are connected;

the connection relation between the leakage inductance absorption unit and the Buck-Boost converter is as follows:

one end of an inductor L in the Buck-Boost converter and a switch S₁Source electrode and inductor L_rOne end crossing point and diode D in leakage inductance absorption unit₀Is connected with the cathode of the Buck-Boost converter, the intersection point of the negative pole of the direct current power supply and the other end of the inductor L in the Buck-Boost converter and the capacitor C in the leakage inductance absorption unit₀The other ends of the two are connected;

diode D in leakage inductance absorption unit₀Anode and capacitor C₀The intersection point of one end of the Buck-Boost converter is connected with the other end of a capacitor C in the Buck-Boost converter;

the connection relationship between the 1 st voltage expansion unit and the Buck-Boost converter is as follows:

cathode of diode D in Buck-Boost converter and capacitor C in 1 st voltage expansion unit₁₁Is connected with the inductor L in the 1 st voltage extension unit, and the intersection point of the anode of the diode D and one end of the capacitor C in the Buck-Boost converter and the inductor L in the 1 st voltage extension unit₁The other end and a capacitor C₁₂The intersection points of the other ends are connected;

2. A high-gain Buck-Boost DC-DC converter as claimed in 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. A high-gain Buck-Boost DC-DC converter as claimed in claim 1, wherein: when the number of the voltage expansion units is 2 and the number of the leakage inductance absorption units is 1, and when the current of the inductor L is continuously conducted, the circuit is divided into 2 working states according to the difference of the power switch states: