CN110912245A

CN110912245A - Three-port integrated photovoltaic energy storage converter

Info

Publication number: CN110912245A
Application number: CN201911151912.8A
Authority: CN
Inventors: 秦岭; 田民; 周磊; 段冰莹; 沈家鹏; 高娟
Original assignee: Nantong University
Current assignee: Qiushan Energy Hubei Co ltd
Priority date: 2019-11-22
Filing date: 2019-11-22
Publication date: 2020-03-24
Anticipated expiration: 2039-11-22
Also published as: CN110912245B

Abstract

The invention discloses a three-port integrated photovoltaic energy storage converter, which comprises two switching tubes, three capacitors, two diodes and two inductors, wherein the two switching tubes are connected with the three capacitors; the three capacitors are respectively connected with the storage battery, the photovoltaic module and the load in parallel; the first switch tube and the second switch tube are conducted complementarily. A PWM + PFM modulation strategy is adopted to control the first inductor to work in a DCM, and frequency conversion control is adopted to realize maximum power point tracking control of the photovoltaic module; and controlling the second inductor to work in a CCM mode, and realizing constant voltage control of the load by adopting a variable duty ratio. The invention realizes the integration of the power switch by multiplexing the switch tube, reduces one switch tube and a driving module thereof, improves the integration level of the converter and reduces the cost.

Description

Three-port integrated photovoltaic energy storage converter

Technical Field

The invention belongs to the technical field of converter control, and particularly relates to a three-port integrated photovoltaic energy storage converter.

Background

With the increasing energy crisis and environmental pollution, photovoltaic power generation technology is receiving wide attention from governments and enterprises of various countries. Because solar energy has volatility and randomness, a photovoltaic power generation system needs to be provided with a storage battery to store and adjust electric energy, and continuous and stable power supply to loads (such as a direct current converter, an inverter, a direct current micro-grid and the like) is ensured. Therefore, the photovoltaic energy storage power generation system has three ports, namely a photovoltaic port, a storage battery and a load, and usually adopts two converters, namely a Boost photovoltaic interface and a Buck/Boost bidirectional energy storage interface, to respectively realize Maximum Power Point Tracking (MPPT) control of a photovoltaic array and charge and discharge control of the storage battery, as shown in fig. 1. The structure can effectively realize energy management and control of the photovoltaic energy storage system, but has the defects of large number of components, large volume and weight, low overall efficiency and the like.

Disclosure of Invention

In view of this, the invention provides a three-port integrated photovoltaic energy storage converter, which reduces switching tubes and driving modules thereof and improves the integration level of the converter.

The invention provides a three-port integrated photovoltaic energy storage converter, which comprises: the circuit comprises a first switch tube, a second switch tube, a first capacitor, a second capacitor, a third capacitor, a first diode, a second diode, a first inductor and a second inductor; the first switch tube and the second switch tube are conducted in a complementary mode, and the first inductor and the second inductor work in a DCM mode and a CCM mode respectively; the positive electrode of the photovoltaic array is connected with the first end of the first inductor and the first end of the first capacitor, and the negative electrode of the photovoltaic array is connected with the second end of the first capacitor, the negative electrode of the storage battery, the second end of the second capacitor, the source electrode of the first switching tube, the second end of the third capacitor and the negative electrode of the load; the positive electrode of the storage battery is connected with the first end of the second capacitor and the first end of the second inductor; the second end of the first inductor is connected with the anode of the first diode and the anode of the second diode; the cathode of the first diode is connected with the second end of the second inductor, the drain of the first switch tube and the source of the second switch tube; and the cathode of the second diode is connected with the drain of the second switching tube, the first end of the third capacitor and the anode of the load.

Preferably, the first switch tube and the second switch tube are both MOS tubes.

Compared with the prior art, the invention has the beneficial effects that: according to the invention, through multiplexing of the switching tube, a Buck/Boost bidirectional energy storage interface converter and a Boost photovoltaic interface converter in a traditional photovoltaic energy storage system are integrated together, and through a mixed modulation strategy of PWM and PFM, flexible control of power flow among three ports is realized. Compared with the traditional converter for the photovoltaic energy storage system, the three-port integrated converter reduces one switching tube and a driving module thereof, improves the integration level of the system and reduces the cost. In addition, the three-port integrated converter provided by the invention can adapt to extreme conditions such as photovoltaic power sudden change, load power sudden change and the like in a photovoltaic energy storage system, and the reliability and stable operation of the system are ensured.

Drawings

Fig. 1 is a schematic diagram of a converter circuit structure for a photovoltaic energy storage system.

Fig. 2 is a schematic circuit diagram of a three-port integrated photovoltaic energy storage converter according to an embodiment of the present application.

Fig. 3(a) - (c) are equivalent circuit diagrams of different modes of the three-port integrated converter according to the embodiment of the present application.

Fig. 4(a) is an operation waveform diagram of the three-port integrated converter according to the embodiment of the present application when the three-port integrated converter operates in a photovoltaic and storage battery combined power supply mode.

Fig. 4(b) is an operation waveform diagram of the three-port integrated converter according to the embodiment of the present application when the three-port integrated converter operates in a photovoltaic simultaneous power supply mode to the battery and the load.

Fig. 5(a) and (b) are control block diagrams of a three-port integrated converter system according to an embodiment of the present application.

Fig. 6(a) is a simulation waveform of the three-port integrated converter according to the embodiment of the present application, in which the operation mode is switched from the photovoltaic and battery combined power supply mode to the photovoltaic and battery and load power supply mode due to the reduction of load power.

Fig. 6(b) is a simulation waveform of the three-port integrated converter according to the embodiment of the present application, in which the operation mode is switched from the photovoltaic and battery combined power supply mode to the photovoltaic simultaneous power supply mode to the battery and the load due to the increase of the output power of the photovoltaic array.

Fig. 7(a) is a simulation waveform of the three-port integrated converter according to the embodiment of the present application, in which the operation mode is switched from the photovoltaic power supply mode to the photovoltaic power supply mode and the battery power supply mode simultaneously due to the increase of the load power.

Fig. 7(b) is a simulation waveform of the three-port integrated converter according to the embodiment of the present application, in which the operation mode is switched from the photovoltaic power supply mode to the photovoltaic power supply mode and the battery and battery combined power supply mode simultaneously due to the reduction of the output power of the photovoltaic array.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 2, in an embodiment of the present invention, a three-port integrated photovoltaic energy storage converter is provided, where three ports of the converter are respectively connected to a photovoltaic array PV, a storage battery and a load, and the converter includes a first switch tube S₁A second switch tube S₂A first capacitor C₁A second capacitor C₂A third capacitor C₃A first diode D₁A second diode D₂A first inductor L₁And a second inductance L₂(ii) a First switch tube S₁And a second switch tube S₂Complementary conduction, first inductance L₁And a second inductance L₂Respectively working in a DCM mode and a CCM mode; positive pole and first inductance L of photovoltaic array PV₁First terminal and first capacitor C₁Is connected with the first end of the photovoltaic array PV, the negative pole of the photovoltaic array PV and the first capacitor C₁Second terminal, negative pole of the accumulator, second capacitor C₂Second terminal, first switch tube S₁Source electrode of, and third capacitor C₃The second end of the load is connected with the negative pole of the load; positive pole of accumulator and second capacitor C₂First terminal, second inductance L₂Is connected with the first end of the first connecting pipe; first inductance L₁Second terminal and first diode D₁Anode of (2), second diode D₂The anode of (2) is connected; first diode D₁Cathode and second inductor L₂Second terminal, first switch tube S₁And a second switching tube S₂Is connected to the source of (a); second diode D₂Cathode and second switch tube S₂Drain electrode of (1), third capacitor C₃Is connected to the positive pole of the load.

In this embodiment, MOS transistors are used for the first switch transistor S1 and the second switch transistor S2.

When three-port integrated form photovoltaic energy storage converter in this application embodiment normally works, there are two kinds of mode: the photovoltaic and storage battery combined power supply mode and the photovoltaic power supply mode simultaneously supply power to the storage battery and the load. The basic operating principle of the converter in these two operating modes is next analyzed. To simplify the analysis, it is first assumed that the system operation has reached steady state and the following conditions are met: (i) besides considering the internal resistance of the power tube, not considering the influence of other parameters of the power tube; (ii) the energy storage elements are ideal elements, all the capacitance capacities are large enough, the voltage ripple is ignored, namely the voltage U of the storage battery_BVoltage U of the photovoltaic array_pvAnd a load voltage U_oConstant; (iii) first inductance L₁Operating in DCM with a second inductor L₂Operating in CCM mode.

(1) Mode 1: photovoltaic and storage battery combined power supply mode

When the power generated by the photovoltaic array cannot meet the load power, the converter works in a photovoltaic and storage battery combined power supply mode. The operation of the converter in one switching cycle can be divided into 3 modes, and the equivalent circuit corresponding to each operating mode is shown in fig. 3, wherein the solid arrows indicate the current directions of the modes. The main waveforms are shown in FIG. 4(a), and are analyzed below.

Mode 1: [ t ] of₀-t₁](etc.)The effective circuit is as shown in FIG. 3(a)

t₀Before the moment, the first switch tube S₁Off, the second switching tube S₂Conducting the first diode D₁A second diode D₂Are all in an off state. First inductance L₁Current of 0, second inductance L₂Through a second switch tube S₂And (4) linear discharging. At t₀At the moment, the first switch tube S is switched on₁Turning off the second switch tube S₂Modality 1 begins. At this time, the first diode D₁On, the second diode D₂And (6) turning off. First inductance L₁And a second inductance L₂Respectively bear forward voltage U_pvAnd U_BSo that the first inductor current i_L1(t) second inductor current i_L2(t) are linearly increased, and the expressions are respectively:

mode 2: [ t ] of₁-t₂](the equivalent circuit is shown in FIG. 3 (b))

t₁At any moment, the first switch tube S is turned off₁Turning on the second switch tube S₂Mode 1 ends and mode 2 begins. At this time, the first diode D₁A second diode D₂Are all turned on. First inductance L₁Subject to reverse voltage U_o-U_pvFirst inductor current i thereof_L1(t) decreases linearly, expressed as:

first inductor current i_L1(t) simultaneously through a second diode D₂Branch and first diode D₁And a second switch tube S₂The two branches of the series branch follow currents. Flows through the first diode D₁And a second diode D₂The currents of (a) are:

second inductance L₂Subject to reverse voltage U_o-U_BSecond inductance L₂Current i of_L2(t) via a second switching tube S₂Follow current, whose expression is:

modality 3: [ t ] of₂-t₃](the equivalent circuit is shown in FIG. 3 (c))

t₂At all times, the first inductance L₁Current i of_L1(t) falls to 0, modality 2 ends, and modality 3 begins. At this time, the second switch S₂Continuing to switch on the first switch tube S₁A first diode D₁And a second diode D₂Are all in an off state. Second inductance L₂Current i of_L2(t) still passes through the second switch tube S₂The follow current has an expression similar to that of the formula (6), and is not described again. To t₃At the moment, the first switch tube S is switched on₁Turning off the second switch tube S₂Mode 3 ends and the next switching cycle begins, and the process repeats.

(2) Mode 2: photovoltaic simultaneous supply mode to storage battery and load

When the power emitted by the photovoltaic array is larger than the load power, the system works in a photovoltaic simultaneous power supply mode for the storage battery and the load. The converter also has 3 modes in each switching period, an equivalent circuit corresponding to each working mode is shown in fig. 3, and a dotted arrow in the figure indicates the current direction in each mode. The main waveforms are shown in FIG. 4(b), and are analyzed below.

Mode 1: [ t ] of₀-t₁](the equivalent circuit is shown in FIG. 3 (a))

t₀Before the moment, the first switch tube S₁Off, the second switching tube S₂Conducting the first diode D₁A second diode D₂Are all in an off state, the first inductor L₁Current of 0, second inductance L₂Through a second switch tube S₂Is discharged linearly and the second inductor current i_L2The direction of (t) is opposite to the reference direction. At t₀At the moment, the first switch tube S is switched on₁Turning off the second switch tube S₂First diode D₁On, the second diode D₂And (6) turning off. First inductance L₁And a second inductance L₂Are all subjected to forward voltage and are respectively U_pvAnd U_B. So that the first inductor current i_L1(t) linear increase, second inductor current i_L2(t) is inversely linearly decreased, and the expressions are respectively formula (1) and formula (2).

Mode 2: [ t ] of₁-t₂](the equivalent circuit is shown in FIG. 3 (b))

t₁At any moment, the first switch tube S is turned off₁Turning on the second switch tube S₂Mode 1 ends and mode 2 begins. At this time, the first diode D₁A second diode D₂Are all turned on. First inductance L₁Subject to reverse voltage, its first inductor current i_L1(t) decreases linearly, and the expression is formula (3). First inductor current i thereof_L1(t) simultaneously through a second diode D₂Branch and first diode D₁And a second switch tube S₂The two branches of the series branch follow currents. Flows through the first diode D₁And a second diode D₂Current of (I)_D1(M2)And I_D2(M2)The same as in the formulas (4) and (5), and will not be described in detail. Second inductance L₂Subject to reverse voltage, second inductance L₂Current i of_L2(t) increases in inverse linearity, and its expression is formula (6).

Modality 3: [ t ] of₂-t₃](the equivalent circuit is shown in FIG. 3 (c))

t₂At all times, the first inductance L₁Current i of_L2(t) drops to 0, mode 2 ends and mode 3 begins. Second switchClosing pipe S₂Continuing to switch on the first switch tube S₁A first diode D₁And a second diode D₂Are all in an off state. Second inductance L₂Current i of_L2(t) still passes through the second switch tube S₂The slope continues to increase in an inverse linear manner before the holding, and the expression is similar to the expression (6) and is not described in detail. To t₃At the moment, the first switch tube S is switched on₁Turning off the second switch tube S₂Mode 3 ends and the next switching cycle begins and the process repeats.

The converter needs to supply the photovoltaic array voltage U under normal conditions_pvAdjusting to realize MPPT control of the photovoltaic array; to output voltage U_oAnd (5) adjusting to realize output constant voltage control. In order to realize the MPPT control and the load-side constant voltage control of the photovoltaic array, the converter provided by the present invention needs to perform the closed-loop control on the photovoltaic array voltage and the output voltage at the same time, which requires two control quantities. However, the first switch S of the two switches in the converter₁And a second switching tube S₂The complementary conduction is necessary, and the duty ratio cannot be respectively adjusted to realize the closed-loop control of two output variables. Therefore, the invention adopts a PWM + PFM mixed modulation strategy and simultaneously adjusts the frequency f_sAnd duty cycle D controls converter photovoltaic array voltage and output voltage. The control strategy requires a first inductance L₁Working in a Discontinuous Conduction Mode (DCM), the second inductor L₂The method works in an inductive current discontinuous Mode (CCM), PFM closed-loop control is adopted for the voltage of the photovoltaic array, and PWM closed-loop control is adopted for the output voltage.

The implementation methods of MPPT control and output constant voltage control were analyzed according to the converter system control block diagram shown in fig. 5.

Neglecting the influence of loss and other parasitic parameters of the converter and the voltage U at the photovoltaic array_pvAnd frequency f_sThe relationship of (A) is as follows:

under MPPT control, the other quantities are considered to be approximately constant. Then follows U_pvIncrease of (2), frequency f_sAnd gradually increases. The PFM control block diagram for this mode is shown in fig. 5 (a). In the figure, PFM is a frequency modulation circuit which can change the triangular carrier frequency f of a PWM modulator_sAnd f is_sFollowing the input voltage u of the PFM circuit_c1Is increased and gradually decreased.

Neglecting the influence of the losses and other parasitic parameters of the converter, outputting the voltage U_oThe relationship with duty cycle D is as follows:

under the control of output constant voltage, approximately consider U_BAnd is not changed. Then follows U_oThe duty ratio D is gradually increased. The PWM control block diagram of this mode is shown in fig. 5 (b). In the figure d represents the instantaneous value of the duty cycle.

In order to verify the working principle of the converter and the correctness of a control strategy, Saber simulation software is utilized to build a three-port photovoltaic energy storage converter model. The energy storage element in the model is an ideal device, and the influence of other parasitic parameters is neglected except for considering the internal resistance of the power tube. The parameters of each port are shown in table 1.

TABLE 1 parameters of the ports

Two situations exist when the mode 1 (photovoltaic and storage battery combined power supply) is switched to the mode 2 (photovoltaic supplies power to the storage battery and the load at the same time), and the simulation result is shown in fig. 6:

(1) photovoltaic array output power P_pv1kW, load power P_oMutation from 1.3kW to 0.7 kW.

As shown in FIG. 6(a), before the time of 100ms, the battery current i_BA value of 2.29A indicates that the battery is in a discharged state; and the photovoltaic array outputs power P_pv1kW (10A is multiplied by 100V), and the power P required by the load_o1.3kW (3.25 A.times.400V),P_pvless than P_oAnd the system is in a photovoltaic and storage battery combined power supply mode. Power P required by load at 100ms_oWhen mutation occurs, the system reaches steady state when mutation is changed from 1.3kW to 0.7kW (1.75A multiplied by 400V) and 107 ms. At this time, the photovoltaic array outputs power P_pvStill 1kW, P_pvGreater than P_oAnd battery current i_BChanging from 2.29A to-1.89A, the storage battery is in a charging state, and the system is in a photovoltaic simultaneous power supply mode for the storage battery and the load.

(2) Load power P_o1kW, photovoltaic array output power P_pvThe mutation from 0.7kW to 1.3 kW.

As shown in FIG. 6(b), before the time of 100ms, the battery current i_BA value of 2.22A indicates that the battery is in a discharged state; and the photovoltaic array outputs power P_pv0.7kW (7A is multiplied by 100V), the power P required by the load_o1kW (2.5 A.times.400V), P_pvLess than P_o(ii) a The system is in a photovoltaic and storage battery combined power supply mode. Photovoltaic array output power P at 100ms_pvThe mutation is generated, the mutation is from 0.7kW to 1.3kW (13A multiplied by 100V), and the system reaches a steady state at 111 ms. At this time, the load required power P_oStill 1kW, P_pvGreater than P_oAnd battery current i_BChanging from 2.22A to-1.85A shows that the storage battery is in a charging state, and the system is in a photovoltaic simultaneous power supply mode for the storage battery and the load.

The time for the switching process from the mode 1 to the mode 2 is only less than 11ms, and the voltage U at the photovoltaic array terminal is in the switching process_pvThe overshoot of (2) is very low, which shows that the system has very good rapidity and smoothness.

There are two cases of switching from mode 2 to mode 1, and the simulation result is shown in fig. 7:

(1) photovoltaic array output power P_pv1kW, load power P_oMutation from 0.7kW to 1.3 kW.

As shown in FIG. 7(a), before the time of 100ms, the battery current i_BA value of-1.89A indicates that the battery is in a charged state; and the photovoltaic array outputs power P_pv1kW (10A is multiplied by 100V), and the power P required by the load_oIs 0.7kW (1.7)5A×400V)，P_pvGreater than P_oThe system is in photovoltaic simultaneous supply mode to the battery and the load. Power P required by load at 100ms_oThe mutation is generated, the mutation is from 0.7kW to 1.3kW (3.25A multiplied by 400V), and the system reaches a steady state at 106 ms. At this time, the photovoltaic array outputs power P_pvStill 1kW, P_pvLess than P_oAnd battery current i_BThe change from-1.89A to 2.29A shows that the storage battery is in a discharging state, and the system is in a photovoltaic and storage battery combined power supply mode.

(2) Load power P_o1kW, photovoltaic array output power P_pvThe mutation from 1.3kW to 0.7 kW.

As shown in FIG. 7(b), before the time of 100ms, the battery current i_BA value of-1.85A indicates that the battery is in a charged state; and the photovoltaic array outputs power P_pv1.3kW (13A is multiplied by 100V), and the power P required by the load_o1kW (2.5 A.times.400V), P_pvGreater than P_oThe system is in photovoltaic simultaneous supply mode to the battery and the load. Photovoltaic array output power P at 100ms_pvThe mutation is generated, the mutation is from 1.3kW to 0.7kW (7A multiplied by 100V), and the system reaches a steady state at 110 ms. At this time, the load required power P_oStill 1kW, P_pvLess than P_oAnd battery current i_BThe change from-1.85A to 2.22A shows that the storage battery is in a discharging state, and the system is in a photovoltaic and storage battery combined power supply mode.

The time for the switching process from the mode 2 to the mode 1 is only less than 10ms, and the voltage U at the photovoltaic array terminal is in the switching process_pvThe overshoot of (2) is very low, which shows that the system has very good rapidity and smoothness.

From the simulation results, the three-port integrated photovoltaic energy storage converter provided by the invention can realize the maximum power output and the constant load voltage of the photovoltaic array by adopting a PWM + PFM hybrid modulation strategy, and the converter can reasonably distribute the power among the ports when the power of the photovoltaic array and the load changes, so that the mode switching is flexibly realized, and the stable and efficient operation of the system is ensured.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims

1. A three-port integrated photovoltaic energy storage converter having three ports connected to a photovoltaic array, a battery and a load, respectively, the converter comprising:

the first switch tube and the second switch tube are conducted complementarily, and the first inductor and the second inductor work in a DCM mode and a CCM mode respectively;

the positive electrode of the photovoltaic array is connected with the first end of the first inductor and the first end of the first capacitor, and the negative electrode of the photovoltaic array is connected with the second end of the first capacitor, the negative electrode of the storage battery, the second end of the second capacitor, the source electrode of the first switching tube, the second end of the third capacitor and the negative electrode of the load;

the positive electrode of the storage battery is connected with the first end of the second capacitor and the first end of the second inductor;

the second end of the first inductor is connected with the anode of the first diode and the anode of the second diode;

the cathode of the first diode is connected with the second end of the second inductor, the drain of the first switch tube and the source of the second switch tube;

and the cathode of the second diode is connected with the drain of the second switching tube, the first end of the third capacitor and the anode of the load.

2. The three-port integrated converter of claim 1, wherein said first switching transistor and said second switching transistor are MOS transistors.