JP3182230B2 - Solar power generator - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to operation control of a photovoltaic power generator, and more particularly to a photovoltaic power generator capable of efficiently extracting the maximum power of a solar cell and enabling highly efficient operation.

[0002]

2. Description of the Related Art A solar cell used in a photovoltaic power generator has a voltage-current characteristic (broken line) as shown in FIG.
Has power characteristics (solid line). As you can see from the figure,
Power with increasing amount of sunlight also current also tended to increase, drawing P _1, P _2, P ₃ represents the maximum power point, Q _1,
Q ₂ and Q ₃ are points at which the voltage and current at the time of maximum power output are given.

As an operation control for efficiently extracting maximum power from a solar cell having such characteristics, a method of constantly following the maximum power point of the solar cell, a so-called hill-climbing method, is used.

In this method, a solar cell is operated at two different points, and the output power is compared to control the operating point of the solar cell to be the maximum output point.

For example, when the solar cell has a voltage-power characteristic as shown in FIG. 4 under a certain amount of solar radiation, first, the output voltage reference of the solar cell is determined from the open-circuit voltage V _{O at a} predetermined sampling period. At a constant change width ΔV. During this time, the power increases in the direction of arrow A in the figure. Then, the power exceeds the maximum power point P and decreases as indicated by an arrow B. Upon detecting this decrease in power, the output voltage reference is increased by the change width ΔV. As a result, the electric power increases in the direction of arrow C in the figure, and eventually exceeds the maximum power point P and returns to the direction of arrow D.
Begin to decrease in the direction. Therefore, the decrease of the power is detected, and the output voltage reference is changed again in the direction of decreasing the change width ΔV. By repeating the above operation, the output voltage reference is reciprocated near the maximum power point P, and the maximum power point of the solar cell is always followed.

In recent years, as disclosed in Japanese Patent Application Laid-Open No. 62-85312, the operating point is first changed with a constant change width ΔV, and the change width is set to a value smaller than ΔV in the region near the maximum power point P. , And a control method for performing precise tracking near the maximum power point P has been proposed.

[0007]

However, since the voltage-power characteristics of the solar cell are different at the maximum power point, when the operating point is changed from the side higher than the output voltage with respect to the maximum power point (hereinafter, referred to as "the power point"). When the operating point is changed from the side lower than the output voltage with respect to the maximum power point (hereinafter abbreviated as the first mode) (hereinafter abbreviated as the second mode), the amount of power change with respect to the fixed change width ΔV is small. Become.

Therefore, when the value of the change width ΔV is set to an optimum value for the first mode, it is possible to accurately detect whether the amount of power change with respect to the change width ΔV in the second mode is decreasing or increasing. Erroneous follow-up.

When the value of the change width ΔV is set to an optimum value for the second mode, the amount of power change with respect to the change width ΔV in the first mode is increased, and the accuracy and stability of following are reduced.

[0010] The present invention has been made in view of such a point, and is capable of accurately following a maximum power point of a solar cell.
Provided is a photovoltaic power generation device that performs the operation stably, efficiently extracts the maximum power of the photovoltaic cell, and enables highly efficient operation.

[0011]

The present invention comprises a solar cell,
Power conversion means for converting and outputting DC power generated from the solar cell to AC power, power detection means for detecting the output power of the solar cell at a predetermined cycle, and output power previously detected by the power detection means Power control means for calculating a power change amount with respect to the detected output power, and outputting a current reference for controlling an output current of the power conversion means, wherein the power control means changes the current reference by a predetermined change. A set mode including a first mode in which the current reference is increased by a width and a second mode in which the current reference is decreased by a predetermined change width is set to be switchable, and the power change amount is larger than zero, and If the change amount of the output current is equal to or smaller than a preset value that is smaller than the power change amount when the change amount of the output current is controlled to the change range of the current reference, the current setting mode is changed to another setting mode. A photovoltaic power generation apparatus characterized by switching the mode.

[0012]

According to the present invention, since the current reference from the power control means is changed by a predetermined change width to control the output current of the power conversion means, the operating point of the solar cell is far from the maximum power point. In the region, the power change amount is constant regardless of the setting mode of the power control means. Further, the swing width of the operating point near the maximum power point can be further reduced.

[0013]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing an embodiment of a method for controlling the operation of a photovoltaic power generator according to the present invention. FIG.
It is a schematic block diagram of the solar power generation device of the present invention.

In the figure, reference numeral 1 denotes a solar cell for directly converting the energy of sunlight into DC power, and 2 denotes a power conversion means for converting the DC power from the solar cell 1 into AC power of a constant voltage and outputting the converted power. And an inverter circuit composed of switching elements. The output side of the inverter circuit 2 is connected to a commercial power system 4 via a transformer 3 in series, and supplies power to a load 5 by interconnecting the solar cell 1 and the commercial power system 4. The transformer 3 is provided to insulate and transmit the AC power from the inverter circuit 2 to the secondary side, and has a turn ratio of 1: 1.

Reference numeral 6 denotes a power control unit, to which the output current I _S and the output voltage V _{S of} the solar cell 1 detected by the first current detection unit 7 and the voltage detection unit 8 are input at a predetermined sampling cycle.

In accordance with the control program stored in the ROM 9, the power control means 6 calculates the output power P _S of the solar cell 1 and the power variation ΔP _S from the input output current I _S and output voltage V _S. The calculation result is stored in the RAM 10
Together is temporarily stored in, based on the stored power variation [Delta] P _S in RAM 10, sets the current reference I _B for controlling the output current I _O of the inverter circuit 2, the current reference I _B
Is input to one end of the multiplication means 11.

[0017] Specifically, by changing the operating point from the higher side than the output voltage V _S of the solar cell 1 to the maximum power point, the current reference I _B in the case of the first mode to decrease the output voltage V _S given increased set by variation width [Delta] I _B, changing the operating point from the lower side than the output voltage V _S of the solar cell 1 to the maximum power point, the output voltage V _S current reference I _B in the case of the second mode to increase the Is set to decrease with the change width ΔI _B.

[0018] Then, the power change amount ΔP _S is the set value x (x
> 0) when: sets a current reference I _B reverses the setting mode. The set value x is the inverter output current I _O
The amount of change is set to the power variation [Delta] P _S value smaller than in the case of being controlled to vary the width [Delta] I _B of the current reference I _B. That is, in the region where the operating point of the solar cell 1 is separated from the maximum power point is set to the power variation [Delta] P _S value smaller than in the case of changing the current reference I _B in variation width [Delta] I _B.

Reference numeral 12 denotes a waveform generating means for generating a reference waveform of a commercial frequency, detects a voltage waveform of a system voltage of the commercial power system 4, and outputs a reference waveform corresponding to the system voltage. The output from the waveform generator 12 is input to the other end of the multiplier 11.

The multiplication means 11 multiplies the output from the power control means 6 by the output from the waveform generation means 12 and inputs the multiplication result to one end of an error amplifier 13. In other words, the multiplier unit 11, a current reference I _B set in the power control unit 6, is input and the reference waveform corresponding to the system voltage, since performing a multiplication of both, depending on the current reference I _B A multiplication means 11 outputs a sine waveform signal having a commercial frequency with an amplitude.

A second current detecting means 14 is connected to the output side of the inverter circuit 2 and detects the output current I _O from the inverter circuit 2. The second current detecting means 14 outputs the detected inverter output current I _O to the other end of the error amplifier 13. Is being entered.

The error amplifier 13 is connected to the multiplication means 11
After amplifying the difference between the output from the second current detector 14 and the output from the second current detector 14, it is input to a PWM comparator (pulse width modulator) 15.

The PWM comparator 15 compares the error signal from the error amplifier 13 with a reference triangular wave, and sends a switching control signal to the switching element of the inverter circuit 2 so that the error signal from the error amplifier 13 becomes zero. Supply.

[0024] Then, in the inverter circuit 2, the switching pulse width of the inverter circuit 2 based on the input signal from the PWM comparator 15 is controlled to a value inverter output current I _O from the inverter circuit 2 based on the current reference I _B Controlled.

As described above, since the operating point of the solar cell 1 is moved by changing the current reference I _B by a constant change width ΔI _B , the power change amount is in a region where the operating point is far from the maximum power point. ΔP _S is constant.

The power change amount ΔP _S is equal to the set value x (x>
0) In the following cases, since the setting mode is reversed, it is immediately detected that the operating point has exceeded the maximum power point. The swing of the operating point near the maximum power point is reduced, and the operating point can quickly follow the maximum power point.

Next, the operation control contents of the photovoltaic power generator configured as described above will be described with reference to the flowchart of FIG.

[0028] After the operation control initiation of photovoltaic device, first current reference I _B to set to zero and output as an initial setting process (S1). This is before starting the operation control of the solar power generator,
This is for stopping the operation of the inverter circuit 2 and setting the inverter output current _IO to zero.

Then, the current detecting means 7 and the voltage detecting means 8
, The output current I _S and the output voltage V _S of the solar cell 1 are read, and the current output power P _S1 of the solar cell 1 is calculated from these values (S3), and the calculated output power P _S1 is stored in the RAM.
10 is temporarily stored (S5). In this step S5,
Since current reference I _B is zero, the output power P _S1 = 0 is RA
It will be stored in M10.

Next, set output current reference I _B to the set mode to the first mode (S7), the process proceeds to the next step S9. In this case, the current reference I _B is set to ΔI _B.

In step S9, the current detecting means 7, the voltage
The output current I of the solar cell 1 from the detecting means 8_S, Output voltage V_S
Is read, and the output power of the current solar cell 1 is calculated from these values.
Force P _S2Is calculated.

Then, the calculated output powers P _S2 and R
The difference from the output power P _S1 stored in the AM 10, that is, the power change amount ΔP _S (ΔP _S = P _S2 −P _S1 ) is calculated (S1).
1) Substituting the output power P _S2 for the output power P _S1 (S1
3).

In the next step S15, the output power P
_S1 is temporarily stored in the RAM 10, and the process proceeds to step S17.

[0034] At step S17, the power change amount [Delta] P _S calculated in step S11 is, is positive, is and determine whether greater than the set value x, the process proceeds to step S19 in the case of YES, a step in the case of NO Proceed to S21.

[0035] At step S19, to maintain the current setting mode, and set output current reference I _B, the flow returns to step S9. Specifically, in the case of the first mode, the current reference I
_B is set to a value obtained by adding the change width ΔI _B to the current reference I _B currently set, and in the case of the second mode, the current reference I B
It is set to a value obtained by subtracting the current reference I _B to change width [Delta] I _B which is currently set to _B.

[0036] In step S21, reversing the current setting mode, i.e. switched to the second mode if the current first mode, the case of the step S19 as well as current reference I _B set output, the flow returns to step S9.

By repeating the above routine,
The operating point of the positive battery 1 is determined by its output power P _STo increase
Move and finally left around the maximum power point
It will swing to the right.

[0038] In the above embodiment, regardless of the position of the operating point of the solar cell 1 has described the case of moving the operating point by changing increments current reference I _B constant variation width [Delta] I _B, the other operating point may be set to a small value change width [Delta] I _B only in the vicinity maximum power point. Thereby, the swing width of the operating point near the maximum power point can be further reduced.

[0039]

[0040]

As described above, according to the present invention, the output current of the power conversion means is controlled by changing the current reference from the power means circuit by a predetermined change width. In a region away from the maximum power point, the power change amount is constant regardless of the setting mode of the power control means.

Further, the swing width of the operating point near the maximum power point can be reduced, the accuracy of following the maximum power point of the solar cell and the stability can be further improved, and the maximum power from the solar cell can be efficiently obtained. It can be taken out.

[Brief description of the drawings]

FIG. 1 is a schematic block diagram of a solar power generation device according to the present invention.

FIG. 2 is a flowchart showing operation control contents of the photovoltaic power generator of the present invention.

FIG. 3 is a voltage-current and voltage-power characteristic diagram of a solar cell when the amount of solar radiation is used as a parameter.

FIG. 4 is a voltage-power characteristic diagram of a solar cell under a certain amount of solar radiation.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 solar cell 2 inverter circuit (power conversion means) 3 transformer 4 commercial power system 5 load 6 power control means 7 first current detection means 8 voltage detection means 9 ROM 10 RAM 11 multiplication means 12 waveform generation means 13 error amplifier 14 second Current detection means 15 PWM comparator (pulse width modulation means)

Continued on the front page (72) Inventor Toshiyuki Hirata 2-18-18 Keihanhondori, Moriguchi-shi, Osaka Sanyo Electric Co., Ltd. (72) Inventor Kuniho 2-18-18 Keihanhondori, Moriguchi-shi, Osaka Sanyo Electric (56) References JP-A-63-36318 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) G05F 1/67

Claims (1)

(57) [Claims] 1. A solar cell, power conversion means for converting and outputting DC power generated from the solar cell to AC power, power detection means for detecting output power of the solar cell at a predetermined cycle, and power detection means And a power control means for calculating a power change amount between the previously detected output power and the currently detected output power, and outputting a current reference for controlling an output current of the power conversion means. Is set to be switchable between a set mode including a first mode in which the current reference is increased by a predetermined change width and a second mode in which the current reference is reduced by a predetermined change width, and the power change amount is set. But zero
And the amount of change in the output current is larger than the current base.
Smaller than the power change amount when the power is controlled to the standard change width
If: preset set value to have value, photovoltaic device characterized by switching the current setting mode to another setting mode.