CN203590025U - Single-switch high-gain boost converter - Google Patents

Abstract

The utility model provides a single-switch high-gain step-up converter, which mainly includes an ordinary Boost step-up circuit link composed of a DC voltage source, a first inductor, a fourth diode, a fourth capacitor and an output load; An energy storage circuit link composed of a diode, a second diode, a third diode, a first capacitor, a second capacitor, a third capacitor, a second inductor and a third inductor. The utility model has a simple structure, and compared with the existing DC step-up converter, it has a larger voltage gain under the same duty cycle; the switch stress is lower when the switch tube is turned off; only one The operation of the switching tube control circuit is simple to control, and is suitable for DC voltage conversion occasions requiring high voltage gain.

Description

A Single-Switch High-Gain Boost Converter

technical field

The utility model relates to the technical field of power electronic converters, in particular to a single-switch high-gain boost converter.

Background technique

In a solar power generation system or a fuel cell system, since a single solar cell or a single fuel cell provides direct current with a low voltage, it cannot meet the electricity demand of existing electrical equipment, nor can it meet the requirements of grid connection. It is necessary to convert the low-voltage direct current into the actually required high-voltage direct current. Therefore, the boost converter with high gain and stable performance has become a research hotspot, which is of great significance to promote the development of photovoltaic and fuel cell industries.

The most basic boost converter is a single-tube Boost converter. However, the boost range of this converter is very limited, and it is difficult to meet the conversion requirements of high gain. At present, there are three main types of high-gain single-switch boost converters. The first is to use a transformer to add a high-frequency transformer in the middle of the original DC-DC converter, and achieve the purpose of high-gain boost by changing the transformer ratio. At this time, the conversion process of electric energy actually changes from the original DC-DC to DC-AC-AC-DC, and the energy conversion efficiency of the entire system decreases. The second is to use coupled inductors, but the structure of coupled inductors is complex, which is not conducive to industrial processing, it is difficult to ensure the consistency of the circuit, and it will cause excessive voltage stress of switching devices, which will cause electromagnetic interference and other effects, resulting in large operating losses of the converter. . The third is to add cascaded boost units. The more units, the greater the voltage gain, but the more circuit components, the more complex the structure.

Utility model content

The purpose of the utility model is to overcome the shortcomings of the above-mentioned prior art and provide a single-switch high-gain boost converter.

The utility model is suitable for occasions requiring high-gain and high-performance power electronic converters such as photovoltaic systems, fuel cell systems, and energy recovery systems.

The utility model is realized through the following technical solutions:

A single-switch high-gain step-up converter includes a common Boost step-up circuit link and an energy storage circuit link.

The common Boost step-up circuit link includes a DC voltage source, a first inductor, a fourth diode, a fourth capacitor and an output load; the energy storage circuit link includes a first diode, a second diode, a third pole tube, a first capacitor, a second capacitor, a third capacitor, a second inductor and a third inductor.

One end of the first inductor is connected to the anode of the DC voltage source, and the other end is respectively connected to the anode of the first diode and the anode of the second diode;

The cathode of the second diode is respectively connected to the drain of the switch tube, one end of the second capacitor, one end of the third inductor and the anode of the fourth diode;

The other end of the second capacitor is respectively connected to the anode of the third diode and one end of the second inductor;

The other end of the third inductance is respectively connected to one end of the third capacitor and the cathode of the third diode;

The other end of the second inductance is respectively connected to one end of the first capacitor and the cathode of the first diode;

The other end of the first capacitor is respectively connected to the negative pole of the DC voltage source, the other end of the third capacitor, one end of the fourth capacitor, one end of the load, and the source of the switch tube;

The cathode of the fourth diode is respectively connected to the other end of the fourth capacitor and the other end of the load.

Compared with the prior art, the utility model has the following advantages:

The utility model has a simple structure, and compared with the existing DC step-up converter, it has a larger voltage gain under the same duty ratio; the switch stress is lower when the switch tube is turned off; only one The operation of the switching tube control circuit is simple to control, and is suitable for DC voltage conversion occasions requiring high voltage gain.

Description of drawings

Fig. 1 is the circuit diagram of a kind of single-switch high-gain boost converter implemented by the utility model;

Fig. 2, Fig. 3 and Fig. 4 are working mode diagrams of the circuit of the embodiment of the utility model shown in Fig. 1 in one switching cycle respectively. Figure 2 is a working mode diagram when the switch tube S is turned on, and Figures 3 and 4 are two working mode diagrams when the switch tube S is turned off. The solid line in the figure indicates the part where the current flows in the converter, and the dotted line indicates the part where the current does not flow in the converter.

Fig. 5 shows the output voltage V o of the embodiment of the present invention when the input voltage V _{g =} 12V, the duty ratio of the switch S is D = 0.4, the load R _L = 50Ω, the voltage V _ds at both ends of the switch tube flows through the diode (D ₁ , D ₂ , D ₃ , D ₄ ) Waveform diagram of current.

Fig. 6 is a relationship diagram of the output voltage gain M and the duty ratio D of the switch tube S under the duty ratio (0<D<0.5) of the circuit of the embodiment of the utility model.

Detailed ways

The utility model will be described in further detail below in conjunction with the accompanying drawings, but the embodiments of the utility model are not limited thereto.

As shown in Figure 1, a single-switch high-gain boost converter includes a common boost circuit and an energy storage circuit.

The common Boost step-up circuit link includes a DC voltage source V _g , a first inductor L ₁ , a fourth diode D ₄ , a fourth capacitor C ₄ and an output load _RL ; the energy storage circuit link includes a first diode D ₁ , the second diode D ₂ , the third diode D ₃ , the first capacitor C ₁ , the second capacitor C ₂ , the third capacitor C ₃ , the second inductor L ₂ and the third inductor L ₃ .

Specific connection method:

One end of the first inductance _L1 is connected to the anode of the DC voltage source, and the other end is respectively connected to the anode of the first diode _D1 and the anode of the second diode D2;

The cathode of the second diode _D2 is respectively connected to the drain of the switching tube S, one end of the second capacitor _C1 , one end of the third inductance _L3 and the anode of the fourth diode _D4 ;

The other end of the second capacitor _C1 is respectively connected to the anode of the third diode _D3 and one end of the second inductance _L2 ;

The other end of the third inductance _L3 is respectively connected to one end of the third capacitor _C3 and the cathode of the third diode _C3 ;

The other end of the second inductance _L2 is respectively connected to one end of the first capacitor _C2 and the cathode of the first diode _D1 ;

The other end of the first capacitor _C2 is respectively connected to the negative pole of the DC voltage source, the other end of the third capacitor _C3 , one end of the fourth capacitor _C4 , one end of the load _RL , and the source of the switch tube S;

The cathode of the fourth diode _D4 is respectively connected to the other end of the fourth capacitor _C4 and the other end of the load _RL .

The utility model only analyzes the embodiment in which the inductance current in the circuit is continuous.

Working mode 1:

As shown in FIG. 2 , the switch tube S is turned on, and the duty ratio of the switch tube S is set to D. The second diode D ₂ is turned on, the current of the first inductor L ₁ increases, the first capacitor C ₁ , the second capacitor C ₂ , the third capacitor C ₃ , and the fourth capacitor C ₄ are discharged, and the second inductor L ₂ , The current of the third inductor L ₃ also increases. At this stage, the voltages V _L1 , V _L2 , and V _L3 on both ends of the first inductance _{L 1} , the second inductance L ₂ , and the third inductance L ₃ are respectively:

V _L1 = V _g (1)

V _L2 =V _c1 +V _c2 (2)

V _L3 = V _c3 (3)

Among them, V _g is the input power supply voltage, and V _c1 , V _c2 , V _c3 , V _L1 , V _L2 , and V _L3 respectively represent the first capacitor C ₁ , the second capacitor C ₂ , the third capacitor C ₃ , and the first inductor L _1. The voltage across the second inductor L ₂ and the third inductor L ₃ .

Working mode 2:

As shown in Figure 3, the switch tube S is turned off, the fourth diode D ₄ is not turned on, the currents of the first inductor L ₁ , the second inductor L ₂ , and the third inductor L ₃ decrease, and the fourth capacitor C ₄ continues to discharge, and charge the first capacitor C ₁ , the second capacitor C ₂ , and the third capacitor C ₃ . At this stage, the voltages V _L1 , V _L2 , and V _L3 on both ends of the first inductance _{L 1} , the second inductance L ₂ , and the third inductance L ₃ are respectively:

V _L1 =V _g -V _c2 (4)

V _L2 =V _c2 -V _c3 (5)

V _L3 = V _c1 (6)

Working mode 3:

As shown in FIG. 4 , the switch tube S is turned off, and the fourth diode _D4 is turned on. When V _C3 +V _C1 >V _C4 , the circuit enters working mode 3. The currents of the first inductor L ₁ , the second inductor L ₂ , and the third inductor L ₃ continue to decrease, and the first capacitor C ₁ , the second capacitor C ₂ , the third capacitor C ₃ , and the fourth capacitor C ₄ are charged. In this stage, the voltages V L1 , _{V L2} , and V _L3 on both ends of the first inductance L ₁ , the second inductance _{L 2} , and the third inductance L ₃ are represented by Equation (4), Equation (5), and Equation (6), respectively.

Assuming that the duty cycle of the switching tube S is D, according to the volt-second balance characteristics of the inductor, and the simultaneous formula (1) ~ formula (6), it can be obtained:

V _g □D+(V _g -V _c2 )(1-D)＝0 (7)

(V _c1 +V _c2 ) D+(V _c2 -V _c3 )(1-D)＝0 (8)

V _c3 □D＝V _c1 (1-D) (9)

Simultaneous formula (7)～(8), get:

${\mathrm{<span\; class="notranslate">\; <figure-callout\; id="1"\; label="V\; c"\; filenames="130916173348.png"\; state="\{\{state\}\}">V</figure-callout></span><figure-callout\; id="1"\; label="V\; c"\; filenames="130916173348.png"\; state="\{\{state\}\}">\; </figure-callout>}}_{\mathrm{<span\; class="notranslate">\; </span>}}<span\; class="notranslate">\; =</span>\frac{\mathrm{<span\; class="notranslate">\; D.</span>}}{\mathrm{<span\; class="notranslate">\; 1</span>}<span\; class="notranslate">\; -</span>\mathrm{<span\; class="notranslate">\; 2</span>}\mathrm{<span\; class="notranslate">\; D.</span>}}{\mathrm{<span\; class="notranslate">\; V</span>}}_{\mathrm{<span\; class="notranslate">\; c</span>}\mathrm{<span\; class="notranslate">\; 2</span>}}<span\; class="notranslate">\; -</span><span\; class="notranslate">\; -</span><span\; class="notranslate">\; -</span><span\; class="notranslate">\; (</span>\mathrm{<span\; class="notranslate">\; 10</span>}<span\; class="notranslate">\; )</span>$

${\mathrm{<span\; class="notranslate">\; V</span>}}_{\mathrm{<span\; class="notranslate">\; c</span>}\mathrm{<span\; class="notranslate">\; 2</span>}}<span\; class="notranslate">\; =</span>\frac{\mathrm{<span\; class="notranslate">\; 1</span>}}{\mathrm{<span\; class="notranslate">\; 1</span>}<span\; class="notranslate">\; -</span>\mathrm{<span\; class="notranslate">\; D.</span>}}{\mathrm{<span\; class="notranslate">\; V</span>}}_{\mathrm{<span\; class="notranslate">\; g</span>}}<span\; class="notranslate">\; -</span><span\; class="notranslate">\; -</span><span\; class="notranslate">\; -</span><span\; class="notranslate">\; (</span>\mathrm{<span\; class="notranslate">\; 11</span>}<span\; class="notranslate">\; )</span>$

${\mathrm{<span\; class="notranslate">\; V</span>}}_{\mathrm{<span\; class="notranslate">\; c</span>}\mathrm{<span\; class="notranslate">\; 3</span>}}<span\; class="notranslate">\; =</span>\frac{\mathrm{<span\; class="notranslate">\; 1</span>}<span\; class="notranslate">\; -</span>\mathrm{<span\; class="notranslate">\; D.</span>}}{\mathrm{<span\; class="notranslate">\; 1</span>}<span\; class="notranslate">\; -</span>\mathrm{<span\; class="notranslate">\; 2</span>}\mathrm{<span\; class="notranslate">\; D.</span>}}{\mathrm{<span\; class="notranslate">\; V</span>}}_{\mathrm{<span\; class="notranslate">\; c</span>}\mathrm{<span\; class="notranslate">\; 2</span>}}<span\; class="notranslate">\; -</span><span\; class="notranslate">\; -</span><span\; class="notranslate">\; -</span><span\; class="notranslate">\; (</span>\mathrm{<span\; class="notranslate">\; 12</span>}<span\; class="notranslate">\; )</span>$

because

V _o =V _c1 +V _c3 (13)

so

${\mathrm{<span\; class="notranslate">\; V</span>}}_{\mathrm{<span\; class="notranslate">\; o</span>}}<span\; class="notranslate">\; =</span>\frac{\mathrm{<span\; class="notranslate">\; 1</span>}}{<span\; class="notranslate">\; (</span>\mathrm{<span\; class="notranslate">\; 1</span>}<span\; class="notranslate">\; -</span>\mathrm{<span\; class="notranslate">\; 2</span>}\mathrm{<span\; class="notranslate">\; D.</span>}<span\; class="notranslate">\; )</span><span\; class="notranslate">\; (</span>\mathrm{<span\; class="notranslate">\; 1</span>}<span\; class="notranslate">\; -</span>\mathrm{<span\; class="notranslate">\; D.</span>}<span\; class="notranslate">\; )</span>}{\mathrm{<span\; class="notranslate">\; V</span>}}_{\mathrm{<span\; class="notranslate">\; g</span>}}<span\; class="notranslate">\; -</span><span\; class="notranslate">\; -</span><span\; class="notranslate">\; -</span><span\; class="notranslate">\; (</span>\mathrm{<span\; class="notranslate">\; 14</span>}<span\; class="notranslate">\; )</span>$

That is, the voltage gain M of a single-switch high-gain boost converter described in the utility model is:

$\mathrm{<span\; class="notranslate">\; m</span>}<span\; class="notranslate">\; =</span>\frac{{\mathrm{<span\; class="notranslate">\; V</span>}}_{\mathrm{<span\; class="notranslate">\; o</span>}}}{{\mathrm{<span\; class="notranslate">\; V</span>}}_{\mathrm{<span\; class="notranslate">\; g</span>}}}<span\; class="notranslate">\; =</span>\frac{\mathrm{<span\; class="notranslate">\; 1</span>}}{<span\; class="notranslate">\; (</span>\mathrm{<span\; class="notranslate">\; 1</span>}<span\; class="notranslate">\; -</span>\mathrm{<span\; class="notranslate">\; 2</span>}\mathrm{<span\; class="notranslate">\; D.</span>}<span\; class="notranslate">\; )</span><span\; class="notranslate">\; (</span>\mathrm{<span\; class="notranslate">\; 1</span>}<span\; class="notranslate">\; -</span>\mathrm{<span\; class="notranslate">\; D.</span>}<span\; class="notranslate">\; )</span>}<span\; class="notranslate">\; -</span><span\; class="notranslate">\; -</span><span\; class="notranslate">\; -</span><span\; class="notranslate">\; (</span>\mathrm{<span\; class="notranslate">\; 15</span>}<span\; class="notranslate">\; )</span>$

Fig. 5 shows the output voltage V o of the embodiment of the present invention when the input voltage V _{g =} 12V, the duty ratio of the switch S is D = 0.4, the load R _L = 50Ω, the voltage V _ds at both ends of the switch tube flows through the diode (D ₁ , D ₂ , D ₃ , D ₄ ) current waveform diagram, it can be seen from the figure that the switching stress borne by the switching tube is low when it is turned off. Fig. 6 is the relationship diagram of the output voltage gain M and the duty ratio D of the switch tube S under the duty ratio (0<D<0.5) of the circuit of the embodiment of the utility model. It can be seen that the circuit of the utility model can achieve a very high voltage gain.

The utility model has a simple structure, and compared with the existing DC step-up converter, it has a larger voltage gain under the same duty cycle; the switch stress is lower when the switch tube is turned off; only one The operation of the switching tube control circuit is simple to control, and is suitable for DC voltage conversion occasions requiring high voltage gain.

Those skilled in the art can make various modifications or supplements to this specific embodiment or replace it in a similar manner without violating the principle and essence of the utility model, but these changes all fall within the protection scope of the utility model. Therefore, the technical scope of the present utility model is not limited to the above-mentioned embodiments.

Claims (1)

1. a single switch high gain boost converter, is characterized in that comprising common Boost circuit link and accumulator link; Common Boost booster circuit link comprises direct voltage source (V _g), the first inductance (L ₁), the 4th diode (D ₄), the 4th electric capacity (C ₄) and output loading (R _l); Accumulator link comprises the first diode (D ₁), the second diode (D ₂), the 3rd diode (D ₃), the first electric capacity (C ₁), the second electric capacity (C ₂), the 3rd electric capacity (C ₃), the second inductance (L ₂) and the 3rd inductance (L ₃);

Described the first inductance (L ₁) one end is connected with the positive pole of direct voltage source, the other end respectively with the first diode (D ₁) anode, the second diode (D ₂) anodic bonding;

The second described diode (D ₂) negative electrode respectively with drain electrode, the second electric capacity (C of switching tube (S) ₁) one end, the 3rd inductance (L ₃) one end and the 4th diode (D ₄) anodic bonding;

The second described electric capacity (C ₁) the other end respectively with the 3rd diode (D ₃) anode, the second inductance (L ₂) one end connect;

The 3rd described inductance (L ₃) the other end respectively with the 3rd electric capacity (C ₃) one end, the 3rd diode (C ₃) negative electrode connect;

The second described inductance (L ₂) the other end respectively with the first electric capacity (C ₂) one end and the first diode (D ₁) negative electrode connect;

The first described electric capacity (C ₂) the other end respectively with direct voltage source negative pole, the 3rd electric capacity (C ₃) other end, the 4th electric capacity (C ₄) one end, load (R _l) one end, switching tube (S) source electrode connect;

The 4th described diode (D ₄) negative electrode respectively with the 4th electric capacity (C ₄) the other end and load (R _l) the other end connect.

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