Source: https://patents.google.com/patent/JP2013192382A/en
Timestamp: 2020-01-28 12:53:36
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Matched Legal Cases: ['art 1', 'art 2', 'art 1', 'art 1', 'art 2', 'art 1']

JP2013192382A - Solar power conditioner - Google Patents
Solar power conditioner Download PDF
JP2013192382A
JP2013192382A JP2012057232A JP2012057232A JP2013192382A JP 2013192382 A JP2013192382 A JP 2013192382A JP 2012057232 A JP2012057232 A JP 2012057232A JP 2012057232 A JP2012057232 A JP 2012057232A JP 2013192382 A JP2013192382 A JP 2013192382A
JP2012057232A
Akihiro Fukatsu
明弘 深津
真稔 小野田
2012-03-14 Application filed by Denso Corp, 株式会社デンソー filed Critical Denso Corp
2012-03-14 Priority to JP2012057232A priority Critical patent/JP2013192382A/en
2013-09-26 Publication of JP2013192382A publication Critical patent/JP2013192382A/en
PROBLEM TO BE SOLVED: To provide a solar power conditioner, capable of remarkably improving power conversion efficiency in a panel group of a solar cell panel while reducing a switching loss.SOLUTION: Power converters 3a-3d are respectively disposed on solar cell panels 2a-2d. The power converters 3a-3d performs voltage-current conversion by performing maximum power point tracking of the output power of the solar cell planes 2a-2d. It is possible to miniaturize reactors 6, 7 between output terminals O1-O2 and a capacitor C.
The present invention relates to a solar power conditioner that converts DC power of a solar cell into AC power.
This type of solar power conditioner is being developed by various companies. MPPT (Maximum Power Point Tracking) control is performed to efficiently acquire the generated power of the solar cell. In this MPPT control, since the operating voltage for obtaining the maximum power of the solar cell panel sequentially varies, the control is usually performed so as to maximize the power by varying the operating voltage (for example, Patent Document 1). ~ 2).
According to Patent Document 1, the output current and the output voltage of the solar cell module are controlled so that the power generation efficiency is always the maximum when the corresponding power converters perform MPPT control. A common output current flows through each output terminal of the power converter, and each output voltage is automatically adjusted so that the ratio of each is the ratio of the maximum power of each solar cell module.
According to Patent Document 2, the plurality of single-phase inverters include a first inverter that receives the first DC power source having the maximum voltage among the DC power sources, and a first inverter on the AC side of the first inverter. A configuration including one or more second inverters connected to a terminal and one or more third inverters connected to an AC-side second terminal of the first inverter is employed.
According to Patent Documents 3 and 4, the voltage generated by the solar cell panel is input to the buck-boost converter and charged to the capacitor, and the DC power of this capacitor is input to the first, second, and third single-phase inverters. Thus, a total voltage obtained by combining these generated voltages is output from the inverter unit. According to Patent Document 5, the charge accumulated in the capacitor is switched and AC output is performed.
JP-A-11-103538 Japanese Patent No. 4527767 JP 2008-178158 A JP 2007-504705 A JP 2007-58843 A
However, in the technical idea described in Patent Document 1, only DC-DC conversion is performed, and a power converter for performing DC-AC conversion is required separately, which increases switching loss. Moreover, in the technical thought of patent documents 2-4, since the voltage converter is installed corresponding to all the solar cell panels, the maximum electric power of a solar cell panel cannot be output efficiently. Further, according to the technical idea described in Patent Document 5, switching loss increases because switching between charge and discharge of the charge storage capacitor is controlled at a frequency several hundreds to several tens of thousands times the system frequency.
An object of the present invention is to provide a solar power conditioner capable of improving the power conversion efficiency of a panel group of solar cell panels as much as possible while reducing switching loss.
According to the first aspect of the present invention, since the power converter is provided for each panel group of one or a plurality of solar cell panels, the power conversion efficiency of the panel group can be increased as much as possible. In addition, the power conversion unit performs maximum power point tracking control on the output power of the panel group, and performs voltage-current conversion on the output power of each panel group.
Therefore, if the synchronization control unit superimposes the conversion voltages of the plurality of power conversion units in series to perform synchronization control to obtain a pseudo sine wave voltage or a target AC voltage, the DC power output by the panel group can be directly converted and output. The pseudo sine wave voltage or the target AC voltage can be output efficiently. Thereby, the power conversion efficiency of the panel group of a solar cell panel can be improved as much as possible.
1 is an overall configuration diagram of a solar power conditioner according to a first embodiment of the present invention. Example of solar cell panel configuration (Part 1) Example of solar cell panel configuration (Part 2) Circuit configuration example of power converter Characteristic diagram showing voltage dependence of output power of solar panel Example of PWM signal Example of PFM signal Waveform example showing part of pseudo sine wave output by each power converter Diagram showing on / off timing of each transistor Example of control (Part 1) Example of control configuration (2) Example of control mode (3) Control form example (4) FIG. 4 equivalent view showing a modification of the power converter (part 1) FIG. 4 equivalent diagram showing a modification of the power converter (part 2) Voltage output waveform example Whole circuit block diagram which shows 2nd Embodiment of this invention The figure which shows the output waveform of the principal part roughly FIG. 17 equivalent view showing the third embodiment of the present invention. 18 equivalent diagram Waveform shaping example FIG. 17 equivalent view showing the fourth embodiment of the present invention. 18 equivalent diagram The figure showing the control method when the output power of the panel group changes with time FIG. 17 equivalent diagram showing the fifth embodiment of the present invention. FIG. 17 equivalent view showing a modification of the fifth embodiment of the present invention. FIG. 1 equivalent view showing a sixth embodiment of the present invention
Hereinafter, a first embodiment of the present invention will be described with reference to FIGS. A solar power conditioner 1 shown in FIG. 1 is a power converter 3a for converting DC power output from a plurality of solar cell panels 2a to 2d into household AC power and connecting it to a system. ~ 3d. The power converters 3a to 3d are provided on the solar cell panels 2a to 2d, respectively, and are installed on the back surfaces of the panels.
The power converter 3a connects the solar cell panel 2a to the input terminal. Similarly, the power converter 3b connects the solar cell panel 2b to the input terminal, and the power converter 3c connects the solar cell panel 2c to the input terminal. The power converter 3d connects the solar cell panel 2d. The output sides of these power converters 3a to 3d are connected in series.
Although FIG. 1 shows an example in which the output sides of the power converters 3a to 3d are connected in series in four stages, the number of stages may be any number as long as it is a plurality of stages. The number of stages is determined according to the output DC voltage of the solar cell panels 2a to 2d and the amplitude of the target pseudo sine wave or AC voltage, but a specific example will be described later.
Control circuits 4a to 4d are connected to the power converters 3a to 3d, respectively. A communication line 5 is connected to these control circuits 4a to 4d, and these control circuits 4a to 4d cooperate with each other to synchronize and control the power converters 3a to 3d, respectively. The converters 3a to 3d each output power. In this case, since the plurality of power converters 3a to 3d are connected in series, the output voltages are output between the output terminals O1 and O2 with the output voltages superimposed.
The communication line 5 is, for example, a network such as CAN (Controller Area Network) or RS485. The communication line 5 may be provided as necessary. That is, for example, when this network is constructed as PLC (Power Line Communications), the communication line 5 becomes unnecessary.
The output of the power converter 3a is connected to the output terminal O1 of the solar power conditioner 1. The output of the power converter 3d is connected to the output terminal O2 of the solar power conditioner 1. As a result, the addition voltage vA + vB + vC + vD of the power converters 3a to 3d is output between the output terminals O1-O2.
In the present embodiment, reactors 6 and 7 and a capacitor C are connected as AC filters to the output terminals O1 and O2, respectively, in order to cut the high frequency and shape the waveform, and through the AC filters (6, 7 and C). An AC voltage is output between the output terminals O1 and O2.
The solar cell panels 2a to 2d shown in FIG. 1 are classified into a crystalline solar cell panel 8 shown in FIG. 2, a thin film solar cell panel 9 shown in FIG. The crystalline solar cell panel 8 shown in FIG. 2 is configured by, for example, assembling a solar cell element (solar cell element) 10 having a side of several tens of centimeters to a panel 11 having a side of 1 to several m. On the other hand, the thin-film solar cell panel 9 shown in FIG. 3 is configured by arranging a large number of minute thin-film solar cell elements 13 on a glass substrate 12, for example.
The solar cell elements 10 and 13 are rarely used alone and are often used in a connected state. That is, since the voltage alone is as low as about several hundred mV and is not particularly suitable for high power supply applications, the solar cell elements 10 and 13 are connected in series to increase the voltage. Thereby, the solar cell panels 8 and 9 can obtain a voltage output of about several to several tens of volts, for example. This embodiment demonstrates the aspect which applied such a solar cell panel 8 or 9 as solar cell panel 2a-2d, respectively.
The circuit configurations of the power converters 3a to 3d described above may be the same or different from each other, but in the present embodiment, an example in which they are the same is shown. Hereinafter, the circuit configuration of the power converter 3a will be described, and the description of the circuit configurations of the other power converters 3b to 3d will be omitted.
As shown in the circuit configuration of the power converter 3a in FIG. 4, the power converter 3a mainly includes a voltage conversion unit 14 connected to the solar cell panel 2a and a polarity provided in a subsequent stage of the voltage conversion unit 14. A conversion unit 15. The voltage conversion unit 14 is configured by, for example, a booster circuit including a reactor L1, a transistor M1, and a diode D1. The transistor M1 is composed of, for example, an N channel type power MOSFET. When a pulse signal is given from the control circuit 4a to the control terminal of the transistor M1, the voltage converter 14 converts the output DC voltage value according to the pulse signal.
The resistor R1 shown in FIG. 4 is configured as a current detector that measures the output current of the solar cell panel 2a, and the resistor R2 is configured as a voltage detector that measures the output voltage of the solar cell panel 2a. The control circuit 4a performs MPPT control according to the detection signals of these voltage detectors and current detectors. For example, the control circuit 4a controls the duty ratio or / and the cycle of the pulse signal applied to the control terminal of the transistor M1.
FIG. 5 shows the power (P) -voltage (V) characteristics of a general solar cell panel. If the output operating voltage increases, the output power tends to increase. However, if the output operating voltage exceeds a certain voltage, the amount of current supply decreases, so the output power decreases. Therefore, as shown in FIG. 5, the maximum power Pz can be obtained at a certain maximum output operating voltage Vz.
In the present embodiment, the duty ratio of the pulse signal applied to the control terminal of the transistor M1 by the control circuit 4a or the output voltage of the solar battery panels 2a to 2d becomes the maximum output operating voltage Vz or a value approximate thereto. MPT (Maximum Power Point Tracking) control is performed by changing the period with time. Thereby, the generated electric power of the solar cell panel 2a can be acquired efficiently.
6 and 7 show examples of control pulse signals applied to the control terminal of the transistor M1. FIG. 6 shows an example of pulse width modulation (PWM) in which the pulse width tw1, tw2, tw3,... Is changed with the period T of the pulse signal constant, and FIG. 7 shows the pulse signal with the pulse width tw constant. An example of pulse frequency modulation (PFM) in which the periods T1, T2, T3,.
In general, when the rising and falling waveforms are blunted using a soft switching technique, it is preferable to secure a pulse width tw or (tw1, tw2, tw3) at a certain level or more, and it is desirable to use pulse frequency modulation with a constant pulse width tw. However, in the case of a low load, it is necessary to control the frequency to be low, but the frequency is constant in a non-audible frequency band (for example, a predetermined frequency slightly higher than 20 kHz) so as not to become an audible band (<20 kHz). And pulse width modulation is preferable.
Now, the maximum output power of the solar cell panel 2a varies sequentially according to the influence of solar radiation intensity (weather, solar altitude, shade, etc.). For this reason, the control circuit 4a detects the voltage and current by the resistors R1 and R2 described above, monitors the power sequentially, and controls to always obtain the maximum power. A capacitor (not shown) may or may not be connected between the output nodes N1 and N2.
The polarity conversion unit 15 includes transistors M2 to M5. Each of these transistors M2 to M5 is configured by, for example, full-bridge connection of N-channel type power MOSFETs. In FIG. 4, when the control circuit 4a is M2: OFF, M3: ON, M4: ON, M5: OFF, a positive voltage is output between the output terminals O1a-O2a. If the control circuit 4a is M2: ON, M3: OFF, M4: OFF, M5: ON, a negative voltage is output between the output terminals O1a-O2a. Although the output terminals O1a and O2a are not shown in FIG. 1, the power converters 3a to 3d output voltages vA to vD between the output terminals O1a to O2a, respectively.
When the control circuit 4a turns on both the transistors M3 and M5 and turns off both the transistors M2 and M4, the control circuit 4a outputs approximately 0V between the output terminals O1a and O2a. Therefore, the power converter 3a can output a positive pulse voltage or a negative pulse voltage between the output terminals O1a and O2a.
When the control circuits 4a to 4d perform on / off control of the transistors M1 to M5, the power converters 3a to 3d output voltages as shown in FIG. In the time domain marked with “x” in FIG. 8, at least one of the transistors M2 to M5 is switching-controlled, and thereby outputs a partial voltage of a pseudo sine wave.
Further, in the time region (see (4) region and (7) region in FIG. 8) sandwiched between “x” marks not marked with “x” in FIG. 8, it is positive or negative and constant for a predetermined time. It shows that a pulse voltage as a voltage is being output.
For example, the output voltage vA of the power converter 3a is rapidly switched between 0V and a predetermined positive amplitude voltage + VA1 (refer to the time domain of (1)), and then 0V output and 0V and a predetermined negative amplitude. High-speed switching is performed between the voltage -VA2 (see the time domain in (2)). Thereby, in the time domain of (1) and (2), the power converter 3a outputs a short pulse voltage having a shorter cycle than the pulse voltage of the time domain of (4) or (7).
Further, the power converter 3b outputs a short pulse voltage that is switched at a high speed between 0 V and the positive amplitude voltage + VB1 as the output voltage vB (see (3) in the time domain) for a predetermined time (particularly (1)). (A short pulse voltage output period), a pulse voltage with a constant voltage of positive amplitude voltage + VB1 is output (refer to the time domain of (4)), and immediately after that, a short pulse voltage switched at high speed between 0 V and positive amplitude voltage + VB1 (See (5) time domain). The power converter 3b outputs approximately 0V for a predetermined period.
After that, the power converter 3b immediately switches between 0V and the negative amplitude voltage −VB2 as the output voltage vB and outputs a short pulse voltage for the pseudo sine wave (see (6) in the time domain). A constant voltage pulse voltage of negative amplitude voltage −VB2 is output for a predetermined time (especially, a short pulse voltage output period of (2)) (see the time domain of (7)), and immediately after that, 0V and negative amplitude voltage −VB2 Is switched at a high speed to output a short pulse voltage for a pseudo sine wave (see time domain of (8)). In this way, the power converter 3b outputs a pulse voltage and a short pulse voltage. Although description is omitted, as shown in FIG. 8, the power converters 3c and 3d similarly output a pulse voltage and a short pulse voltage as the output voltages vC and vD, respectively.
The power conditioner 1 can output a pseudo sine wave by synchronizing and outputting the output voltages vA to vD between the output terminals O1a and O2a of the power converters 3a to 3d in series and outputting them in synchronization. An AC voltage that is substantially sinusoidal can be output to the output terminals O1-O2 through the filters (6, 7, C).
FIG. 9 shows an on / off control method for transistors in the power converter. The power converter 3n (n is a to d) outputs, as its output voltage vN (N is A to D), a pulse voltage having a positive amplitude voltage + VN1 as an amplitude and a short pulse voltage as shown on the left side of FIG. When the transistors M2 and M5 are both turned off, the transistor M3 is turned on and off while the transistor M4 is turned on to perform switching control.
For example, in the time domain of (3) or (5) in FIG. 9, a short pulse voltage between 0 V and the positive amplitude voltage + VN1 is output as the output voltage vN, but the transistors M2 and M5 are both turned off. The transistor M3 is turned on / off at a high speed while the transistor M4 is kept on.
Further, in the time region of (4) in FIG. 9, when outputting a short pulse voltage between 0 V and the positive amplitude voltage + VN1 as the output voltage vN, the transistor M4 is turned off with both the transistors M2 and M5 turned off. The transistor M3 is turned on / off at a high speed while being kept on. At this time, in the time regions (3) and (5) of the transistor M3, the output signal constitutes a part of a pseudo sine wave. For this reason, the on-time width is gradually widened from the start timing to the end timing in (3), and the on-time width is gradually narrowed from the start timing to the end timing in (5).
Further, the power converter 3n (n is a to d) outputs the pulse voltage and the short pulse voltage of the negative amplitude voltage −VN2 as the output voltage vN (N is A to D) as shown on the right side of FIG. When the transistor M3 is turned off, the transistor M5 is turned on and off at a high speed while the transistor M2 is turned on.
At this time, the output signal forms part of a pseudo sine wave in the time domain of (6) and (8) of the transistor M5. For this reason, the on-time width is gradually widened from the start timing to the end timing in (6), and the on-time width is gradually narrowed from the start timing to the end timing in (8).
For example, when synchronous control by the control circuits 4a to 4d is performed using such power converters 3a to 3d and a pseudo sine wave targeted for an AC voltage of 50 Hz is generated, one period of the pseudo sine wave is 20 ms. Become. Therefore, each of the power converters 3a to 3d outputs a pulse positive voltage or a pulse negative voltage of several ms shorter than 20 ms, and synchronizes these voltages in series according to the control of the control circuits 4a to 4d. And output.
The control circuits (control units) 4a to 4d respectively control the corresponding power converters 3a to 3d. At this time, communication processing is performed with other control circuits connected to the communication line 5, and the power converter 3a Control the conversion power of ˜3d. For this reason, it is possible to change the power conversion status of its own power conversion unit while confirming the power conversion status by other power conversion units, and to improve the power conversion efficiency.
(Example of control: Part 1)
The power converter 3n (n is a to d) may vary the positive amplitude voltage + VN1 or the negative amplitude voltage -VN2 for the output voltage vN (N is A to D) shown in FIG. Power may be converted. Further, when outputting the short pulse voltage, the power converter 3n may change the time width Twa for switching at high speed, or may change the entire time width Twb of the pulse voltage and the short pulse voltage.
Here, when actually controlling, the pulse time width Twa or / and Twb is constant and the amplitude voltage + VN1 and -VN1 are changed and converted and output, or conversely, the amplitude voltage + VN1 and -VN1 are constant and the pulse time width is constant. It is preferable to change Twa or / and Twb. Then, since the number of parameters to change can be reduced, it can control easily.
(Example of control mode: 2)
FIG. 11 shows a control mode in a case where sunlight is irradiated only on the solar cell panels 2c and 2d and no sunlight is incident on the solar cell panels 2a and 2b. At this time, although the power converters 3a and 3b do not output the generated power, the power converters 3c and 3d output the generated power. For this reason, even if the power generation amount by the power converters 3a and 3b decreases, power generation can be performed using the power converters 3c and 3d, and the generated power is shaped into a part of the pseudo sine wave voltage and then superimposed in series. The voltage can be output together.
At this time, the terminal voltage of the resistors R1 and R2 is measured to detect the voltage and current of the solar battery panels 2a to 2d (8, 9), thereby determining whether or not the light is in a light-shielding state. When the light shielding is detected, the output power of only the solar cell panel where the light shielding is not detected may be converted. At this time, the voltage conversion unit 14 and the polarity conversion unit 15 corresponding to the solar cell panel detected to be shielded from light are not operated, and only the power converter corresponding to the solar cell panel not detected to be shielded from light is operated. Then, the switching loss of the transistors M1 to M5 constituting the voltage conversion unit 14 and the polarity conversion unit 15 can be reduced, and the power conversion efficiency can be improved. Thereby, the alternating voltage used as a sine wave can be output between output terminals O1-O2.
(Example of control mode: 3)
FIG. 12 shows an example of the control form, and only a part of the power converters 3a among the all power converters 3a to 3d outputs a short pulse voltage. Therefore, for the other power converters 3b to 3d, the transistors M2 to M5 are switched and a constant voltage is output as a pulse voltage only for a certain time interval. Thus, the roles of the power converter 3a that outputs a short pulse voltage and the power converters 3b to 3d that output a pulse voltage are determined in advance. Thus, if only a part of the power converters 3b to 3d is switched at high speed, a complicated control method is not required. Thereby, the alternating voltage used as a sine wave can be output between output terminals O1-O2.
(Example of control mode: 4)
As shown in the control form example of FIG. 13, the power converter 3a uses, as its output voltage vA, a pulse voltage output period twa1 of positive amplitude voltage + VA1 and a pulse voltage output period twa2 of negative amplitude voltage −VA2 different from each other. It is good as a period.
The power converter 3b has a relationship between the pulse voltage output periods twb1 and twb2 of the output voltage vB, a relationship between the pulse voltage output periods twc1 and twc2 of the output voltage vC of the power converter 3c, and the output voltage vD of the power converter 3d. The same applies to the relationship between the pulse voltage output periods twd1 and twd2. In short, based on the control of the control circuits 4a to 4d, the output voltages vA to vD of the power converter 3a are all superimposed so that a target pseudo sine wave is obtained. Thereby, the alternating voltage used as a sine wave can be output between output terminals O1-O2.
FIG. 14 shows a power converter 23a in place of the power converter 3a in a modification of the power converter. The power converter 23 a includes a voltage conversion unit 24 and a polarity conversion unit 15.
The voltage conversion unit 24 includes a capacitor C1, a transformer L2, and a transistor M1 at the output of the solar cell panel 2a. The capacitor C1 is connected to the output of the solar cell panel 2a, and the primary side of the transformer L2 and the series circuit of the transistor M1 are connected between both terminals of the capacitor C1, and the secondary side of the transformer L2 is a diode for rectification. The polarity conversion unit 15 is connected to the subsequent stage. Therefore, the voltage converter 24 is composed of an input / output insulation type circuit, and can control the output by tracking the maximum power point by controlling the on / off of the transistor M1, and the polarity converter 15 at the subsequent stage converts the polarity of the output voltage. A part of the pseudo sine wave can be output between the output terminals O1a-O2a.
FIG. 15 shows a power converter 33a in place of the power converter 3a in a modification of the power converter. The power converter 33 a includes a voltage converter 34 and a polarity converter 15. A capacitor C1 is connected between the terminals of the solar cell panel 2a, and a capacitor C2 is connected in parallel to the transistors M2 and M3 of the polarity converter 15.
The voltage converter 34 connects the transistors M6 and M7 in series with both ends of the capacitor C1, and also connects the transistors M8 and M9 in series with both ends of the capacitor C2. The common connection point of these transistors M6 and M7 and the transistors M8 and M9 are connected. The reactor L3 is connected between the common connection points.
The control circuit 4a performs on / off control of these transistors M6 to M9 to temporarily store the output power of the solar cell panel 2a in the reactor L3, and converts the stored power of the reactor L3 into voltage-current and outputs it to the polarity converter 15. To do. The polarity conversion unit 15 can output a part of the pseudo sine wave between the output terminals O1a and O2a by converting the polarity. In this case, the output voltage of the solar cell panel 2a can be stepped up and down, and the voltage can be further stabilized.
FIG. 16 schematically shows an example of a voltage output waveform. While the transistors M6 to M9 are switched, there are times t1 and t2 when the power converter 3n does not output a voltage. However, since the power converter 33a shown in FIG. 15 has capacitors C1 and C2 attached, Stable pulse voltage and short pulse voltage can be output immediately after time t1 and t2. Both of these capacitors C1 and C2 may be omitted, or only one of them may be attached. Capacitors C1 and C2 may be attached to the power converter 3a shown in FIG. 4 and the power converter 23a shown in FIG.
According to the present embodiment, the power converters 3a to 3d are provided for each of the solar battery panels 2a to 2d, and the power converters 3a to 3d track the output power of the solar battery panels 2a to 2d at the maximum power point. Therefore, power conversion efficiency can be improved as much as possible. The AC filter (6, 7) connected between the output terminals O1-O2 can be reduced in size.
Since the polarity converter 15 is provided in each of the power converters 3a to 3d, the positive / negative polarity of the pulse voltage can be converted for each of the power converters 3a to 3d, and the control circuits 4a to 4d have a high degree of freedom. Waveform shaping processing can be performed.
FIG. 17 shows a second embodiment of the present invention. The difference from the previous embodiment and the modification is that only one polarity conversion unit connected to the subsequent stage of all the voltage conversion units is provided. There is. In the present embodiment, an example using the configurations of the voltage conversion unit 34 and the polarity conversion unit 15 described in Modification 2 will be described. In the following description, the voltage conversion unit 34, the transistors M6 to M9, and the capacitor C1 that are configured to correspond to the solar cell panels 2a to 2d are denoted by reference numerals “a” to “d”, respectively, and the description is omitted. Hereinafter, different parts will be described.
As shown in FIG. 17, the secondary sides of the voltage converters 34a to 34d are connected in series. The voltage obtained by serially connecting the voltage conversion units 34 a to 34 d is given to one polarity conversion unit 15 as a whole. A control circuit 4e is connected to the polarity converter 15. The control circuit 4e sets a control signal to be applied to the transistors M2 to M5 of the polarity conversion unit 15 according to the detection voltage between the system output terminals O3-O4, and the polarity conversion unit 15 receives the input voltage (voltage conversion unit 34a). The conversion polarity of the conversion voltage obtained by connecting in series to 34d is converted and output.
When the control circuits 4a to 4d control the output voltages of the voltage converters 34a to 34d, voltage outputs are obtained as shown in the upper part of FIG. Since each of the voltage conversion units 34a to 34d outputs a part of the positive pseudo sine wave voltage, when these output voltages are superimposed in series, the polarity conversion unit 15 generates the voltage shown in FIG. Input a waveform (a pseudo sine wave positive waveform).
And the control circuit 4e carries out inversion control of the polarity for every half cycle about the pseudo sine wave of the input voltage of the polarity converter 15. At this time, the control circuit 4e outputs with the positive polarity in the time domain of (9) shown in FIGS. 18A and 18B, and converts to the negative polarity in the time domain of (10), (11) In the time domain, the signal is output with the positive polarity. This timing can be set according to the detection voltage between the output terminals O3 and O4. With this control, the polarity converter 15 outputs a pseudo sine wave. The polarity conversion unit 15 outputs a pseudo sine wave and can output a target AC voltage between the output terminals O3 and O4 via the AC filter (6, 7, C3). Instead of the voltage converter 34 (34a to 34d) of the present embodiment, the voltage converter 14 or 24 may be used.
FIG. 19 shows a third embodiment of the present invention. The difference from the previous embodiment and the modification is that a polarity conversion unit is provided at the subsequent stage of all the voltage conversion units, and at the subsequent stage of these polarity conversion units. Only one waveform shaping section is provided.
In the present embodiment, an example using the configuration of the voltage conversion unit 14 and the polarity conversion unit 15 described in the first embodiment will be described. In the following description, it corresponds to the voltage conversion unit 14, the polarity conversion unit 15, the transistors M1 to M5, the reactor L1, the capacitor C2, the diode D1, and the node N1, which are respectively configured corresponding to the solar cell panels 2a to 2d. The components are denoted by reference numerals “a” to “d”, are omitted from the description, and different portions will be described below.
The voltage conversion units 14a to 14d and the polarity conversion units 15a to 15d have the same configuration as that of the first embodiment. The voltage obtained by connecting the outputs of these polarity conversion units 15a to 15d in series is given to one waveform shaping unit 40 as a whole.
The waveform shaping unit 40 includes transistors M10 to M13, a capacitor C4, and a control circuit 4f connected to the communication line 5. The transistors M10 to M13 are connected by a full bridge. The capacitor C4 is connected between a common connection point between the transistors M10 and M12 and a common connection point between the transistors M11 and M13. One terminal of the series connection circuit of the polarity converters 15a to 15d is connected to the common connection point between the transistors M10 and M11, and the other terminal is connected to the input node constituting the AC filter (6, 7, C3). This voltage becomes the input voltage of the waveform shaping unit 40.
As the voltage conversion units 14a to 14d and the polarity conversion units 15a to 15d perform voltage conversion, a voltage waveform can be obtained as shown in FIG. Here, the pulse voltage waveform shown in FIG. 20A is a pulse voltage (single pulse rectangular wave) that becomes a constant voltage for a predetermined time, and the input voltage of the waveform shaping unit 40 is as shown in FIG. A stepped voltage is obtained by superposing pulse voltages (single-pulse rectangular waves) in series.
As shown in FIG. 21, the waveform shaping unit 40 accumulates electric power based on a rising rectangular voltage of a pulse voltage (single pulse rectangular wave) in a stepped voltage serving as an input voltage in a capacitor C4, and converts it into a voltage immediately after that. It is a circuit for adding and shaping into a target AC voltage waveform. When the waveform shaping unit 40 detects the rising voltage of the pulse voltage (single pulse rectangular wave), it turns on the transistors M10 and M13 and simultaneously turns off the transistors M11 and M12 to store the power in the capacitor C4. Is detected, the transistors M10 and M13 are turned off and then the transistors M11 and M12 are turned on to discharge the power to the output side, thereby adding the voltage to the subsequent voltage to obtain the target AC voltage waveform. Approximate. Then, as shown in FIG.20 (b), the target alternating voltage can be obtained between the output terminals O5-O6.
22 to 24 show a fourth embodiment of the present invention and are characterized by combining the above-described circuit configurations. The feature point is provided by combining the feature point of the second embodiment and the feature point of the third embodiment.
As illustrated in FIG. 22, the polarity conversion unit 15 inputs an output of a circuit in which all the voltage conversion units 34 a to 34 d are connected in series. As shown in FIG. 23 (a), when the stepped voltage is given to the polarity converter 15 with positive polarity, the polarity converter 15 converts to negative polarity every half cycle as shown in FIG. 23 (b), After the waveform shaping unit 40 shapes the waveform, the waveform is output between the output terminals O7 and O8 through the AC filter (6, 7, C3). Then, a target AC voltage is obtained as shown in FIG.
FIG. 24 shows an example of a control method when the output power of the solar cell panel changes with time during execution of MPPT control. The example shown in FIG. 24 shows an example in which the pulse width of the pulse voltage (single pulse rectangular wave) is fixed and the voltage amplitude of the single pulse rectangular wave is controlled to be stepped up / down.
That is, when the voltage converters 34a to 34d are performing MPPT control in accordance with the control signals of the control circuits 4a to 4d, respectively, the pulse width of the pulse voltage (single pulse rectangular wave) is set to a predetermined width. Step-up / step-down control of the amplitude of the pulse voltage is performed. By controlling in this way, the maximum power of the solar cell panels 2a to 2d can be obtained.
For example, it is assumed that, due to the influence of a sudden weather change or the like, only the solar light receiving areas of the solar cell panels 2c and 2d are shadowed and the power generation capacity of the solar cell panels 2c and 2d becomes almost zero. At this time, since the solar cell panels 2a and 2b have the power generation capability, the voltage converters 34a and 34b operate so as to maintain the maximum power point of the solar cell panels 2a and 2b, and according to the action of the MPPT control. Boosts the output automatically.
This is due to the following reason. The voltage converters 34a and 34b once accumulate the generated power of the solar cell panels 2a and 2b in the reactors L3a and L3b, respectively, and then discharge them to the output side. Since the energy accumulated in the reactors L3a and L3b is subjected to MPPT control, the energy of the maximum power of the solar cell panels 2a and 2b is stored, respectively. When the MPPT control is performed, the voltage converters 34a and 34b release the stored energy of the reactors L3a and L3b in order to maintain the maximum power point. The voltage converters 34a and 34b automatically increase the voltage on the output side and decrease the current in order to release the stored power. Then, by outputting power between the output terminals O7 and O8 through the polarity conversion unit 15, the waveform shaping unit 40, and the AC filter (6, 7, C3), as shown in FIG. 24B, the solar cell panel 2a, The pseudo sine wave can be shaped only with the generated power of 2b.
The control circuits 4a and 4b may independently perform the MPPT control on the power generation amount of the solar cell panels 2a to 2b, or sequentially receive information such as the power generation amount from the control circuits 4c and 4d connected by the communication line 5. It may be received and MPPT controlled. Therefore, even if only the solar light receiving areas of the solar cell panels 2c and 2d are hidden by shadows, the pseudo sine wave is shaped by MPPT control while maintaining the power generation capability of the solar cell panels 2a and 2b. Can do.
25 and 26 show a fifth embodiment of the present invention. The difference from the above embodiment is that a panel group in which a plurality of solar cell panels are connected in series is provided for each power converter. In addition, one polarity conversion unit and one waveform shaping unit are provided corresponding to the entire series connection of a plurality of power converters. In addition, the plurality of power conversion units are integrated as a whole corresponding to the plurality of panel groups. The same or similar parts as those of the above-described embodiment are denoted by the same reference numerals or similar numerals, and the description thereof will be omitted.
As shown in FIG. 25, a plurality of solar cell panels 2a are connected in series to the input terminal of the voltage converter 34a and provided as a panel group 2A. Similarly, a plurality of solar cell panels 2b to 2d are connected in series to the input terminals of voltage converters 34b to 34d, respectively, and are provided as panel groups 2B to 2D, respectively.
As described in the above embodiment, a single solar cell panel 2a can obtain a DC voltage of about several to several tens of volts. For example, four voltage converters 34a to 34d are connected in series, and the output of the system 200VAC is set as the target AC voltage. Since the maximum amplitude of the target AC voltage is 200 × √2 = 282.8V, for example, when one solar cell panel 2a outputs DC 15V, the solar cells connected to the input terminals of the voltage converters 34a to 34d. It is preferable to connect five panels 2a to 2d in series.
That is, one power converter 3a outputs one series voltage 15V × 5 = 75V, but when four power converters 3a to 3d are connected in series, 75V × 4 series = 300 VDC can be output. Therefore, a voltage exceeding the maximum amplitude 200 × √2 = 282.8 V can be sufficiently secured.
In the present embodiment, the device Pa is configured by integrating the voltage conversion units 34a to 34d, the polarity conversion unit 15, the waveform shaping unit 40, and the control circuits 4a to 4d and 4g. Then, the device Pa can output a pseudo sine wave between the output terminals O7 to O8 when the panel groups 2A to 2D are connected. For example, as shown in FIG. 8, in order to obtain the output voltages VA to VD of the power converters 3a to 3d, the voltage converters 34a to 34d output pseudo sine waves in cooperation with each other.
When the electrical configuration shown in FIG. 25 is adopted, the control circuits 4a to 4d and 4g perform coordinated control with each other, and the voltage conversion units 34a to 34d output voltages. Parallel processing is possible when cooperative control is performed. A control circuit that controls these controls may be determined in advance, and the overall control unit may perform the overall control. When the integrated device Pa is configured as in the present embodiment, the control circuit 4g that controls the polarity conversion unit 15 and the waveform shaping unit 40 in the final stage may be configured as an overall control unit.
This is because the control circuit 4g detects the voltage between the output terminals O7-O8 and performs feedback control, so that control commands can be output to the control circuits 4a-4d, respectively, and the output voltages of the voltage converters 34a-34d This is because the waveform shaping can be easily performed.
Further, as shown in FIG. 26, a monitor 41 may be provided separately from the control circuit 4g. The monitor 41 is connected to the communication line 5, detects the voltage between the output terminals O7-O8, and transmits detected voltage information to the control circuits 4a to 4d, 4g. The monitor 41 may be provided with a function as a general control unit. Then, the monitor 41 outputs the overall control information to each of the control circuits 4a to 4d and 4g, so that each of the control circuits 4a to 4d and 4g can perform control according to the overall control information. According to this embodiment, since the control circuit 4g or the monitor 41 performs overall control of the converted power of the plurality of power converters 3a to 3d, the power conversion efficiency can be improved.
FIG. 27 shows a sixth embodiment of the present invention. In the first embodiment, two reactors 6 and 7 are provided in the overall output of the solar power conditioner 1. However, as shown in the solar power conditioner 1a of FIG. The devices 43a to 43d may have the electrical configurations of the power converters 3a to 3d described above, and the reactors La to Ld and capacitors Ca to Cd may be provided at the outputs of the power converters 3a to 3d. Then, this solar power conditioner 1a can output a pseudo sine wave, and can output a target alternating voltage between the output terminals O1-O2.
In the drawings, 1 and 1a are solar power conditioners, 2a to 2d are solar cell panels (panel group), 2A to 2D are panel groups, 3a to 3c are a plurality of power converters (a plurality of power conversion units), and 4a to 4a. 4d indicates a control circuit (synchronization control unit), 5 indicates a communication line, 6, 7, and C3 indicate AC filters.
A synchronization controller;
A plurality of power converters provided for each panel group of one or a plurality of solar cell panels and connected in series with each other;
Each of the plurality of power conversion units tracks the output power of the panel group to a maximum power point and converts the output power to voltage-current,
The solar power conditioner is characterized in that the synchronous power is synchronously controlled and output so as to obtain a target pseudo sine wave voltage or an alternating voltage by superimposing conversion voltages of the plurality of power converters in series. .
The power conversion unit repeats a pulse voltage that is constant voltage for a predetermined time, and / or a pulse having a shorter cycle than the pulse voltage, with respect to the output power obtained by tracking the output power of the panel group at the maximum power point. Is converted to a short pulse voltage, which becomes a part of
A polarity conversion unit that converts positive and negative polarity of the conversion voltage of the power conversion unit;
The synchronization control unit synchronizes pulse voltages or / and short pulse voltages of the plurality of power conversion units in a state in which positive / negative polarity is converted by the polarity conversion unit to generate pseudo sine wave voltages. The solar power conditioner according to 1.
3. The solar power condition according to claim 1, wherein the power conversion unit performs voltage-current conversion by temporally changing an on / off duty ratio of the transistor using a circuit that switches on and off the transistor. 4. Na.
3. The solar power conditioner according to claim 1, wherein the power conversion unit performs voltage-current conversion by temporally changing an on / off frequency of the transistor using a circuit that switches on and off the transistor. 4. .
3. The solar power conditioner according to claim 1, wherein the power conversion unit performs voltage-current conversion by temporally changing both the duty ratio and frequency of on / off of the transistor.
6. The synchronization control unit according to claim 1, wherein when the output voltage of one of the power conversion units decreases, the synchronization control unit controls the output voltage of the other power conversion unit to increase. Solar power conditioner.
The solar power according to any one of claims 1 to 6, wherein the plurality of power conversion units perform conversion output while changing a time width for outputting the conversion voltage while keeping the value of each conversion voltage constant. Inverter.
The plurality of power conversion units perform conversion output by changing a voltage value of the conversion voltage while keeping a time width for outputting each conversion voltage constant. Solar power conditioner.
9. The output sharing for outputting a pulse voltage that is a part of the stepped voltage and a short pulse voltage having a shorter cycle than the pulse voltage is predetermined in the power conversion unit. A solar power conditioner described in any of the above.
When the light shielding of the solar cell panel is detected, the plurality of power conversion units do not operate the power conversion unit corresponding to the solar cell panel in which the light shielding is detected, and the power of the solar cell panel in which the light shielding is not detected. The solar power conditioner according to any one of claims 1 to 9, wherein only the power conversion unit for converting the power is operated.
A polarity conversion unit that converts and outputs the polarity of the conversion voltage of the power conversion unit,
The solar power conditioner according to any one of claims 1 to 10, wherein one polarity conversion unit is provided corresponding to the entire series connection of the plurality of power conversion units.
A waveform shaping unit for converting the stepped voltage or / and the pseudo sine wave voltage into a target AC voltage;
11. The solar power conditioner according to claim 1, wherein one waveform shaping unit is provided corresponding to the entire series connection of the plurality of power conversion units.
A polarity conversion unit for converting the polarity of the conversion voltage of the power conversion unit to output,
A waveform shaping unit that converts a stepped voltage or / and a pseudo sine wave voltage into a target AC voltage,
11. The solar according to claim 1, wherein each of the polarity conversion unit and the waveform shaping unit is provided corresponding to the entire series connection of the plurality of power conversion units. Inverter.
The solar power conditioner according to any one of claims 1 to 13, wherein the plurality of power conversion units are integrated as a whole corresponding to a plurality of panel groups connected to each other.
The synchronization control unit includes a plurality of control units that respectively control the plurality of power conversion units,
The solar power condition according to any one of claims 1 to 14, wherein each of the plurality of control units performs communication processing with another control unit to cooperatively control the conversion power of the power conversion unit. Na.
The synchronization control unit includes an overall control unit that controls the plurality of power conversion units,
The solar power conditioner according to any one of claims 1 to 14, wherein the overall control unit controls the conversion power of each of the plurality of power conversion units.
JP2012057232A 2012-03-14 2012-03-14 Solar power conditioner Pending JP2013192382A (en)
JP2012057232A JP2013192382A (en) 2012-03-14 2012-03-14 Solar power conditioner
US13/742,514 US20130242628A1 (en) 2012-03-14 2013-01-16 Solar power conditioner
CN2013100774385A CN103312021A (en) 2012-03-14 2013-03-12 Solar power conditioner
DE201310204257 DE102013204257A1 (en) 2012-03-14 2013-03-12 Solar inverter
JP2013192382A true JP2013192382A (en) 2013-09-26
ID=49044185
JP2012057232A Pending JP2013192382A (en) 2012-03-14 2012-03-14 Solar power conditioner
US (1) US20130242628A1 (en)
JP (1) JP2013192382A (en)
CN (1) CN103312021A (en)
DE (1) DE102013204257A1 (en)
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2012-03-14 JP JP2012057232A patent/JP2013192382A/en active Pending
2013-01-16 US US13/742,514 patent/US20130242628A1/en not_active Abandoned
2013-03-12 DE DE201310204257 patent/DE102013204257A1/en not_active Withdrawn
2013-03-12 CN CN2013100774385A patent/CN103312021A/en not_active Application Discontinuation
CN104283260B (en) * 2014-09-29 2017-01-11 陈忱 Network type MPPT solar charging controller and control method thereof
DE102013204257A1 (en) 2013-09-19
US20130242628A1 (en) 2013-09-19
CN103312021A (en) 2013-09-18
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