CN215934729U

CN215934729U - Novel wide-input-range three-port converter

Info

Publication number: CN215934729U
Application number: CN202121406695.5U
Authority: CN
Inventors: 高圣伟; 祝庆同; 牛萍娟; 于冠恒; 王博
Original assignee: Tianjin Polytechnic University
Current assignee: Tianjin Polytechnic University
Priority date: 2021-06-23
Filing date: 2021-06-23
Publication date: 2022-03-01
Anticipated expiration: 2031-06-23

Abstract

The utility model relates to a novel wide-input-range three-port converter. Belongs to the technical field of power electronic converters. The converter is provided with three ports of a photovoltaic cell PV, a storage battery Bat and a resistance load R, and comprises a Boost circuit Boost and a reversible buck-Boost Sepic-Zeta circuit. A Boost circuit Boost is used for connecting the photovoltaic cell PV and the load R; a reversible buck-boost circuit is used to connect the photovoltaic cell PV with the battery Bat and the battery Bat with the load R. The utility model has the advantages of small volume, wide input range, high integration level, high stability, high conversion efficiency and the like.

Description

Novel wide-input-range three-port converter

Technical Field

The utility model relates to the technical field of power electronic energy conversion, in particular to a novel wide-input-range three-port converter.

Technical Field

With the remarkable environmental problems and the shortage of fossil energy, new energy power generation technologies represented by solar energy and wind energy have attracted extensive attention. The traditional photovoltaic energy storage type power generation system usually needs a plurality of two-port converters to be combined for energy transmission, the problems of large number of converters, large volume, low power density and the like exist, the three-port converter is adopted to replace the original plurality of two-port converters, the structure of the whole system can be simpler, and the photovoltaic energy storage type power generation system has the advantages of small volume, high power density and the like. The three-port converter can realize the power generation of new energy, the energy storage and the connection and control of the load only by one combined converter, and can effectively improve the efficiency and the power density of a system.

However, most of the existing non-isolated three-port switching dc converters have a certain limitation on the relationship between the photovoltaic cell voltage and the battery voltage, for example: [1]Wanghui, Chengyao, Zengqing, Lishengqian, can be omephan, a multi-operating-condition high-gain multi-port DC/DC converter [ J ]]The three-port converter described in the journal of electrical engineering of China, 2019,39(07):2155-_pvLess than the voltage V of the accumulator_BApplication scenario of [2 ]]The three-port converter described in "Cost-effective regulated three-port DC-DC converter for EV/HEV applications with energy storage," European transformations on electric power engineering 29.10(2019): e12088.1-e12088.20 "can only be used for photovoltaic cell voltages V.sub.V._pvGreater than the voltage V of the accumulator_BThe application range of the converter is narrow, because the limited use range of the relation between the voltage of the photovoltaic cell and the voltage of the storage battery is small, the stability is poor, the conversion efficiency is low, and the use of the converter can be influenced after long-time use.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a novel wide-input-range three-port converter aiming at the defects of the prior art, and the novel wide-input-range three-port converter has the advantages of small volume, wide input range, high integration level, high stability, high conversion efficiency and the like.

The technical scheme of the utility model is as follows:

non-isolated three-port direct-current switch converter based on reversible Sepic-Zeta wide input range and control method thereof. The converter is provided with three ports of a photovoltaic cell PV, a storage battery Bat, a resistance load R, a Boost circuit Boost and a reversible buck-Boost Sepic-Zeta circuit. A Boost circuit Boost is used for connecting the photovoltaic cell PV and the load; a reversible buck-boost circuit is used to connect the photovoltaic cell PV with the battery Bat and the battery Bat with the load R. The specific circuit composition is as follows: the positive electrode of a photovoltaic cell PV in a Boost circuit Boost is connected with a capacitor C₁And a diode VD₁Anode of (2), diode VD₂Anode and inductor L₁Are connected at one end. Switch tube S₄Drain electrode of (1) and diode VD₄Anode and inductor L₁The other ends of the two are connected; diode VD₄Cathode of the filter is connected with an output filter capacitor C₄And one end of a load R; in the step-up/step-down Sepic-Zeta circuit, the positive pole of the storage battery Bat is connected with the capacitor C₂One terminal of (1) and an inductance L₂One end of (1), a switching tube S₂Drain electrode and capacitor C₃One end of (1) and an inductor L₂Is connected to the other end of the capacitor C₂The other end of the switch tube is led out of three branches, and one branch is connected with a switch tube S₁One branch of the source electrode of (1) is connected with a switch tube S₃The last branch of the drain is connected with an inductor L₃One end of (1), a switching tube S₁And diode series circuit and diode VD₁Cathode and inductor L₁Is connected with one end of a switch tube S₃And VD₃Is connected to the inductor L₂And the other end of the diode VD₄The anode of (1); the other end of the load R is connected with an output capacitor C₄Another end of (1), a switching tube S₄Source electrode and inductor L₃Another end of (1), a switching tube S₂Source electrode and capacitor C₂Another end of (1), a negative electrode of the storage battery Bat, and a capacitor C₁And the other end of the photovoltaic cell PV.

The utility model also provides a non-isolated three-port direct-current switch converter based on the reversible Sepic-Zeta wide input range and a control method thereof, wherein the non-isolated three-port direct-current switch converter comprises the following four working modes:

(1) the photovoltaic cell PV supplies power to a load R and charges a storage battery Bat:

switch tube S₂And a switching tube S₃Not working when switching tube S₁And a switching tube S₄On the one hand, the photovoltaic cell PV passes through the capacitor C₃Inductor L₂Charging the accumulator Bat, on the other hand the photovoltaic cell PV is an inductor L₂And an inductance L₃And (6) charging. When switching tube S₁Switch-off and switch tube S₄When continuing to conduct, on the one hand, the photovoltaic cell PV continues to be the inductor L₁Charging, on the other hand inductance L₃Is a capacitor C₃Charging inductor L₂Through a switching tube S₂Freewheeling of the body diode supplies the load. When switching tube S₄And a switching tube S₁When all are turned off, on the one hand, the photovoltaic cell PV and the inductor L₁For supplying power to a load, on the other hand the inductance L₃Continue to be capacitance C₃Charging inductor L₂Through a switching tube S₂The body diode freewheel of which continues to power the load.

(2) The photovoltaic cell PV and the storage battery Bat jointly supply power to a load R in an operating mode:

when the voltage V of the photovoltaic cell_pvGreater than the voltage V of the accumulator_BTime, switch tube S₁Out of operation, switching tube S₂And a switching tube S₃Complementary conduction when switching tube S₂Conducting and switching tube S₃And a switching tube S₄On the one hand, the photovoltaic cell PV and the inductance L are switched off₁For supplying power to a load R, and on the other hand the battery Bat is an inductor L₂Charging, capacitance C₃To the inductance L₃Charging, when the switch tube S₂Continuously conducting and switching tube S₃Switch tube S for continuous turn-off₄When conducting, on the one hand, the photovoltaic cell PV is an inductor L₁Charging, on the other hand, the storage battery Bat continues to be an inductor L₂Charging, capacitance C₃Continues to be an inductance L₂Charging, when the switch tube S₃Conducting and switching tube S₂And a switching tube S₄On the one hand, the photovoltaic cell PV and the inductance L are switched off₁For supplying power to a load R, on the other hand, a storage battery Bat and an inductor pass through a capacitor C₃Inductor L for supplying power to load₃The load R is also supplied with power.

When the voltage V of the photovoltaic cell_pvLess than the voltage V of the accumulator_BAnd satisfies the switch tube S₂Is less than the switching tube S₄At duty ratio of (3), the switching tube S₁Not working when switching tube S₄Conducting and switching tube S₂And a switching tube S₃When the photovoltaic cell is turned off, the photovoltaic cell PV is an inductor L₁Charging, when the switch tube S₄Continuously conducting and switching tube S₃Continuous turn-off and switching tube S₂When conducting, on the one hand, the photovoltaic cell PV continues to be an inductor L₁Charging, on the other hand, the battery Bat is an inductor L₂Charging, capacitance C₃Is an inductance L₃Charging, when the switch tube S₂And S₄Off, S₃When the photovoltaic cell PV and the inductor L are switched on₁Battery Bat and inductor L₂Inductor L₃While supplying power to the load R.

(3) The battery Bat supplies power to the load R independently:

switch tube S₁And a switching tube S₄Out of operation, switching tube S₂And a switching tube S₃Complementary conduction, the input power of the photovoltaic cell PV is zero when the switch tube S₂Conducting and switching tube S₃When the power is turned off, the storage battery Bat is used for the inductor L₂Charging, capacitance C₃To the inductance L₃Charging, when the switch tube S₂Switch-off and switch tube S₃Conduction, storage battery Bat and inductance L₂、L₃The energy in the middle is passed through a switch tube S₃To supply the load R.

(4) The photovoltaic cell PV solely supplies power to a load R in an operating mode:

switch tube S₁Switch tube S₂And a switching tube S₃Not working when switching tube S₄When conducting, the photovoltaic cell PV is opposite to the inductor L₁Charging, when the switch tube S₄At turn-off, the photovoltaic cell PV and the inductor L₁While supplying power to the load R.

Compared with the prior art, the utility model has the beneficial effects that:

the utility model has wider input voltage range, and the voltage between the photovoltaic cell PV and the storage battery Bat is reversibly increased and decreasedThe Sepic-Zeta circuit is connected, which can not only meet the voltage V of the photovoltaic cell_pvGreater than the voltage V of the accumulator_BWork under the condition of meeting the voltage V of the photovoltaic cell_pvLess than the voltage V of the accumulator_BThe operation is performed. The utility model also has the advantages of small volume, high integration level, high stability, high conversion efficiency and the like.

Drawings

FIG. 1 is a topology diagram of a non-isolated three-port DC switching converter according to the present invention;

FIG. 2 is an equivalent circuit diagram of the photovoltaic cell PV of the present invention during the operation of supplying power to the load R and charging the battery Bat;

FIG. 3 is an equivalent circuit diagram of the operation process of the photovoltaic cell PV and the storage battery Bat jointly supplying power to the load R according to the present invention;

FIG. 4 is an equivalent circuit diagram of the working process of the storage battery Bat supplying power to the load R alone according to the present invention;

FIG. 5 is an equivalent circuit diagram of the photovoltaic cell PV of the present invention operating to power a load R alone;

FIG. 6 is a diagram of the operating waveforms of the photovoltaic cell PV of the present invention for powering the load R and for charging the battery Bat;

fig. 7 and 8 are diagrams illustrating the working waveforms of the photovoltaic cell PV and the storage battery Bat together supplying power to the load R according to the present invention;

FIG. 9 is a waveform diagram illustrating the operation of the battery Bat supplying power to the load R alone according to the present invention;

fig. 10 is a diagram of the operating waveform of the photovoltaic cell PV alone powering the load R according to the utility model;

Detailed Description

The technical scheme of the utility model is specifically explained below with reference to the accompanying drawings.

The topological structure of the non-isolated three-port switch direct-current converter provided by the utility model is shown in figure 1; the converter is provided with three ports of a photovoltaic cell PV, a storage battery Bat and a resistance load R, and comprises a Boost circuit Boost, a reversible buck-Boost Sepic-Zeta circuit and a Boost circuit Boost which are used for connecting the photovoltaic cell PV and the load; a reversible buck-boost circuit is used to connect the photovoltaic cell PV with the battery Bat and the battery Bat with the load R. The specific circuit composition is as follows: in the Boost circuit Boost, the anode of the photovoltaic cell PV is connected with one end of a capacitor C1 and the anode of a diode VD1, and the anode of the diode VD2 is connected with one end of an inductor L1. The drain electrode of the switching tube S4 and the anode of the diode VD4 are connected with the other end of the inductor L1; the cathode of the diode VD4 is connected with one end of the output filter capacitor C4 and one end of the load R; in the buck-boost Sepic-Zeta circuit, the anode of a storage battery Bat is connected with one end of a capacitor C2 and one end of an inductor L2, the drain of a switch tube S2 and one end of the capacitor C3 are connected with the other end of the inductor L2, three branches are led out from the other end of the capacitor C2, one branch is connected with the source of a switch tube S1, the other branch is connected with the drain of a switch tube S3, the last branch is connected with one end of the inductor L3, a switch tube S1 and diode series circuit are connected with the cathode of a diode VD1 and one end of an inductor L1, and a series circuit of the switch tubes S3 and VD3 is connected with the other end of the inductor L2 and the anode of the diode VD 4. The cathode of the diode VD4 is connected with one end of the output filter capacitor C4 and one end of the load R; the other end of the load R is connected with the other end of the output capacitor C4, the source electrode of the switch tube S4, the other end of the inductor L3, the source electrode of the switch tube S2, the other end of the capacitor C2, the cathode of the storage battery Bat, the other end of the capacitor C1 and the cathode of the photovoltaic cell PV.

The utility model also provides a control method based on the non-isolated three-port switch direct-current converter, which comprises the following four working modes:

(1) the photovoltaic cell PV supplies power to a load and charges a storage battery Bat:

when the switching tube S2 and the switching tube S3 do not operate, and the switching tube S1 and the switching tube S4 are turned on, on one hand, the photovoltaic cell PV charges the storage battery Bat through the capacitor C3 and the inductor L2, and on the other hand, the photovoltaic cell PV charges the inductor L2 and the inductor L3. When the switch tube S1 is turned off, the switch tube

When the S4 is continuously turned on, on one hand, the photovoltaic cell PV continues to charge the inductor L1, on the other hand, the inductor L3 charges the capacitor C3, and the inductor L2 continues to supply power to the load through the body diode freewheeling of the switching tube S2. When the switch tube S4 and the switch tube S1 are both turned off, on the one hand, the photovoltaic cell PV and the inductor L1 supply power to the load, on the other hand, the inductor L3 continues to charge the capacitor C3, and the inductor L2 continues to supply power to the load through the body diode freewheeling of the switch tube S2.

when the photovoltaic cell voltage Vpv is greater than the storage battery voltage VB, the switching tube S1 does not operate, the switching tube S2 and the switching tube S3 are complementarily turned on, when the switching tube S2 is turned on, and the switching tube S3 and the switching tube S4 are turned off, on one hand, the photovoltaic cell PV and the inductor L1 supply power to the load R, on the other hand, the storage battery Bat charges the inductor L2, the capacitor C3 charges the inductor L3, when the switching tube S2 is continuously turned on, the switching tube S3 is continuously turned off, and the switching tube S4 is turned on, on the one hand, the photovoltaic cell PV charges the inductor L1, on the other hand, the storage battery Bat continues to charge the inductor L2, and the capacitor C3 continues to charge the inductor L2, and when the switching tube S3 is turned on, the switching tube S2 and the switching tube S4 are turned off, on the photovoltaic cell PV and the inductor L1 supply power to the load R, on the other hand, the storage battery Bat and the inductor supply power to the load R through the capacitor C3 and the inductor L3.

When the photovoltaic cell voltage Vpv is smaller than the storage battery voltage VB and the duty ratio of the switching tube S2 is smaller than the duty ratio of the switching tube S4, the switching tube S1 does not work, when the switching tube S4 is turned on, the switching tube S2 and the switching tube S3 are turned off, the photovoltaic cell PV charges the inductor L1, when the switching tube S4 is turned on, the switching tube S3 is turned off and the switching tube S2 is turned on, on one hand, the photovoltaic cell PV continues to charge the inductor L1, on the other hand, the storage battery Bat charges the inductor L2, the capacitor C3 charges the inductor L3, and when the switching tubes S2 and S4 are turned off and the switching tube S3 is turned on, the photovoltaic cell PV and the inductor L1, the storage battery Bat and the inductor L2, and the inductor L3 simultaneously supply power to the load R.

(3) The battery Bat supplies power to the load R independently:

the switching tube S1 and the switching tube S4 do not work, the switching tube S2 and the switching tube S3 are conducted complementarily, the input power of the photovoltaic cell PV is zero, when the switching tube S2 is conducted and the switching tube S3 is turned off, the storage battery Bat charges the inductor L2, the capacitor C3 charges the inductor L3, when the switching tube S2 is turned off and the switching tube S3 is conducted, the energy in the storage battery Bat and the inductors L2 and L3 supplies power to the load R through the switching tube S3.

the switch tube S1, the switch tube S2 and the switch tube S3 do not work, when the switch tube S4 is turned on, the photovoltaic cell PV charges the inductor L1, and when the switch tube S4 is turned off, the photovoltaic cell PV and the inductor L1 supply power to the load R at the same time.

The converter is suitable for working under the condition that the voltage Vpv of the photovoltaic cell is greater than the voltage VB of the storage battery, and can also work under the condition that the voltage Vpv of the photovoltaic cell is less than the voltage VB of the storage battery. The stability and the efficiency of the system are improved, so that the system can be suitable for occasions with high power density.

Fig. 2 is an equivalent circuit diagram of the converter in the working process of supplying power to a load R and charging a battery Bat by a photovoltaic cell PV, at this time, a switching tube S2 and a switching tube S3 are kept off, the photovoltaic cell supplies power to the load and the battery at the same time, duty ratios of two switching tubes S1 and S4 are used as two independent control variables to control power transfer, duty ratios of switching tubes S1 and S4 are D1 and D4, respectively, in the diagram, a photovoltaic cell voltage is Vpv, a battery voltage is VB, a load voltage is V0, and the relationship between the photovoltaic cell Vpv and the load voltage V0, and the relationship between the photovoltaic cell voltage Vpv and the battery voltage VB are obtained according to an inductance volt-second balance characteristic:

the operating waveforms in this mode are shown in fig. 6. When the switch tube S1 and the switch tube S4 are both turned on, the current of the inductor iL1 linearly rises, the current of the inductor iL2 and the current of the inductor iL3 linearly rise in the reverse direction, when the switch tube S1 is turned off and the switch tube S4 is continuously turned on, the current of the inductor L1 continuously linearly rises, the inductor L2 continuously flows through the body diode of the switch tube S2 to charge the battery, the current of the inductor L2 reversely and linearly drops, the inductor L3 continuously flows through the body diode of the switch tube S2 to charge the capacitor C3, and the current of the inductor L3 reversely and linearly drops.

Fig. 3 is an equivalent circuit diagram of the converter of the present invention during the operation of supplying power to the load by the photovoltaic cell PV and the battery Bat, wherein the switching tube S1 is kept off. The photovoltaic cell PV and the storage battery Bat supply power to a load R simultaneously, the distribution control of input power of two input sources is completed by controlling duty ratios of a switching tube S2, a switching tube S3 and a switching tube S4, the duty ratios of the switching tube S2, the switching tube S3 and the switching tube S4 are D2, D3 and D4 respectively, the voltage of the photovoltaic cell is Vpv, the voltage of the storage battery is VB, the voltage of the load is V0, and the relation between the voltage of the storage battery VB and the voltage of the load is obtained according to the inductive volt-second balance characteristic:

in this mode, when the photovoltaic cell voltage Vpv is greater than the battery voltage VB: the operating waveform is shown in fig. 7. When the switch tube S2 and the switch tube S4 are turned on, and the switch tube S3 is turned off, the inductor L1 is charged by the photovoltaic cell PV, the inductor L2 is charged by the battery Bat, the inductor L3 is charged by the capacitor C3, currents of the inductor L1, the inductor L2 and the inductor L3 all linearly increase, when the switch tube S2 and the switch tube S4 are turned off, and the switch tube S3 is turned on, currents of the inductor L1, the inductor L2 and the inductor L3 all linearly decrease, when the switch tubes S4 and S3 are turned off, and when the switch tube S2 is turned on, currents of the inductor L1 continue to decrease, and currents of the inductor L2 and the inductor L3 linearly increase.

When the photovoltaic cell voltage Vpv is smaller than the storage battery voltage VB and the duty ratio of the switching tube S2 is smaller than the duty ratio of the switching tube S4: the operating waveform is shown in fig. 8. When the switch tube S2 and the switch tube S3 are turned off, and the switch tube S4 is turned on, the photovoltaic cell charges the inductor L1, the current of the inductor L1 increases linearly, the currents of the inductor L2 and the inductor L3 are zero, when the switch tube S2 and the switch tube S4 are turned on simultaneously and the switch tube S3 continues to be turned off, the currents of the inductor L1, the inductor L2 and the inductor L3 all increase linearly, and when the switch tube S2 and the switch tube S4 are turned off and the switch tube S3 is turned on, the currents of the inductor L1, the inductor L2 and the inductor L3 all decrease linearly.

Fig. 4 is an equivalent circuit diagram of the working process of the storage battery Bat independently supplying power to the load R. At the moment, the switch tube S1 and the switch tube S4 are kept turned off, the storage battery Bat independently supplies power to the load R, distribution control of input power of the storage battery is completed by controlling duty ratios of the switch tube S2 and the switch tube S3, the duty ratios of the switch tube S2 and the switch tube S3 are respectively D2 and D3, voltage of the storage battery is VB and voltage of the load is V0, and the relation between the voltage of the storage battery and the voltage of the load is obtained according to the inductance voltage-second balance characteristic and is shown in formula 3.

The operating waveforms in this mode are shown in fig. 9. When the switch tube S2 is turned on and the switch tube S3 is turned off, the battery Bat charges the inductor L2, and the capacitor C3 charges the inductor L3. The current of the inductor L2 and the current of the inductor L2 both linearly rise, when the switch tube S2 is turned off, the switch tube S3 is turned on, the storage battery, the inductor L2 and the inductor L3 jointly supply power to the load, and the currents of the inductor L2 and the inductor L3 linearly fall.

Fig. 5 is an equivalent circuit diagram of the operation process of the photovoltaic cell PV alone supplying power to the load R according to the present invention. At the moment, the switching tube S1, the switching tube S2 and the switching tube S3 are kept off, the photovoltaic cell PV alone supplies power to the load R, distribution control of input power of the photovoltaic cell is completed by controlling the duty ratio of the switching tube S4, the duty ratio of the switching tube S4 is D4, the voltage of the photovoltaic cell in the graph is Vpv, the load voltage is V0, and the relationship between the voltage of the photovoltaic cell and the load voltage is obtained according to the inductive volt-second balance characteristic and is shown in formula 1.

The operating waveforms in this mode are shown in fig. 10. When the switching tube S4 is turned on, the photovoltaic cell PV charges the inductor L1. The current of the inductor L1 rises linearly, when the switching tube S4 is turned off, the photovoltaic cell PV and the inductor L1 supply power to the load R simultaneously, and the current of the inductor L1 falls linearly.

The foregoing shows and describes the general principles and broad features of the present invention and advantages thereof. While the utility model has been described with respect to the above embodiments, it will be understood by those skilled in the art that the utility model is not limited to the above embodiments, which are described in the specification and illustrated only to illustrate the principles of the utility model, but that various changes and modifications may be made without departing from the spirit and scope of the utility model as defined by the appended claims. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims

1. A novel wide-input-range three-port converter is characterized by comprising a photovoltaic cell PV, a storage battery Bat, a resistive load R, a Boost circuit Boost and a reversible buck-Boost Sepic-Zeta circuit, wherein the Boost circuit Boost is used for connecting the photovoltaic cell PV and the resistive load R; reversible buck-boost circuit is used for connecting photovoltaic cell PV and battery Bat and resistance load R, and concrete circuit composition is: the positive electrode of a photovoltaic cell PV in a Boost circuit Boost is connected with a capacitor C₁And a diode VD₁Anode of (2), diode VD₂Anode and inductor L₁Is connected with one end of a switch tube S₄Drain electrode of (1) and diode VD₄Anode and inductor L₁The other ends of the two are connected; diode VD₄Cathode of the filter is connected with an output filter capacitor C₄And one end of a load R; in the reversible buck-boost Sepic-Zeta circuit, the anode of the storage battery Bat is connected with the capacitor C₂One terminal of (1) and an inductance L₂One end of (1), a switching tube S₂Drain electrode and capacitor C₃One end of (1) and an inductor L₂Is connected to the other end of the capacitor C₂The other end of the three-way switch is led out, and one branch is connected with a switch tube S₁One branch of the source electrode of (1) is connected with a switch tube S₃The last branch of the drain is connected with an inductor L₃One end of (1), a switching tube S₁And diode series circuit and diode VD₁Cathode and inductor L₁Is connected with one end of a switch tube S₃And VD₃Is connected to the inductor L₂And the other end of the diode VD₄The other end of the load R is connected with an output capacitor C₄Another end of (1), a switching tube S₄Source electrode and inductor L₃Another end of (1), a switching tube S₂Source electrode and capacitor C₂Another end of (1), a negative electrode of the storage battery Bat, and a capacitor C₁And the other end of the photovoltaic cell PV.

2. A novel wide input range three-port converter as claimed in claim 1 wherein said resistive load R is provided with three ports.