JPH09238427A - Power supply apparatus and photovoltaic power generator using power supply apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To input a DC power outputted by the row of fractional solar cells to an inverter and improve the utilization factors of the solar cells and a body such as a roof on which the solar cells are installed and hence make the solar cell system more economical. SOLUTION: The target voltage value V1 of a fractional solar cells' row 27 is set by a voltage setting unit 34. A current corresponding to the difference between the target voltage value V1 set by the voltage setting unit 34 and the output voltage V0 of the fractional solar cells' row 27 is controlled by a current control means so as to have the output voltage V0 of the fractional solar cells' row 27 agree with the target voltage value V1 . Then the output current I0 of the fractional solar cells' row 27 is controlled (the output impedance is increased) by the current control means so as to make the output current I0 follow the input voltage of an inverter 10 by a DC/DC power converting circuit.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention satisfies a certain number of solar cell configurations by connecting a certain number of solar cell configurations formed by connecting a plurality of solar cells in series to each other in parallel to form a main solar cell configuration. The present invention relates to a power supply device that controls an output current of a non-fractional solar cell array to follow an input voltage of an inverter device, and a solar power generation device using the power supply device.

[0002]

2. Description of the Related Art In recent years, a system has been developed in which a distributed power source by photovoltaic power generation is connected to a commercial power source, and when the photovoltaic power generation alone cannot provide the power, the power is supplied from the grid side.

Such a system includes a solar cell for converting solar energy into electric energy, a junction box composed of a diode and a switch so that the output from the solar cell does not flow back to the solar cell, and DC power from the solar cell. It is composed of a power converter that converts AC power into AC power synchronized with the commercial power source and a protection device that detects an abnormality of the commercial power source.
In a low-voltage interconnection system intended for general households, usually, a solar cell is usually installed on the roof of a house, and a power converter is often installed indoors.

In the conventional photovoltaic power generation system, a certain number of solar cell arrangements formed by connecting a plurality of solar cell arrays in series are connected in parallel in a plurality of rows to form a solar cell arrangement. The output was input to the DC / AC power converter (inverter).

[0005]

In the above-described solar power generation device, the solar cell array cannot be installed in the same number in series due to the limitation of the shape / area of the roof on which the solar cell array is installed. There is a case that the roof does not have enough space because it cannot be done. That is, there is a problem that the roof area cannot be fully utilized.

The present invention has been made in view of the above problems, and the first object thereof is to utilize the DC power output by the fractional solar cell array, An object of the present invention is to provide a power supply device capable of increasing the utilization efficiency of an object on which a solar cell is installed, for example, a roof and the solar cell, and increasing economic efficiency.

The present invention has been made in view of the above problems, and a second object of the present invention is to provide a simple power supply device for the DC power output from the fractional solar cell array. It is an object of the present invention to provide a photovoltaic power generation apparatus that can be used and can increase the utilization efficiency of an object on which a solar cell is installed, for example, a roof and a solar cell, and improve economic efficiency.

[0008]

In order to achieve the above-mentioned first object, the power supply device according to the invention of claim 1 has a fixed number of solar cell structures in which a plurality of solar cells are connected in series. It is characterized in that a plurality of columns are connected in parallel to form a main solar cell configuration, and DC power output from a fractional solar cell array that is less than a certain number of solar cell configurations is used.

With this structure, the DC power output from the fractional solar cell array can be used. For this reason, the solar cell can be attached without being restricted by the shape / area of the object on which the solar cell is installed, for example, the roof, and the roof area can be fully utilized. Therefore, it is possible to increase the utilization of the object on which the solar cell is installed, for example, the roof and the solar cell, and improve the economical efficiency.

In order to achieve the above-mentioned first object, the power supply device according to the invention of claim 2 is such that a certain number of solar cell constitutions in which a plurality of solar cells are connected in series are arranged in a plurality of columns in parallel. Connected to form the main solar cell configuration, the DC power output by the fractional solar cell array that does not meet a certain number of solar cell configuration,
It is characterized in that the inverter is connected to the output side of the main solar cell structure.

With this configuration, the DC power output from the fractional solar cell array can be taken into the inverter device connected to the output side of the main solar cell configuration. To this end, the object on which the solar cell is installed, eg the shape of the roof /
It is possible to install solar cells without being limited in area, and the roof area can be fully utilized. Therefore, it is possible to increase the utilization of the object on which the solar cell is installed, for example, the roof and the solar cell, and improve the economical efficiency.

In order to achieve the above first object, the power supply device according to the invention of claim 3 is the power supply device according to claim 2, in which the target voltage value of the fractional solar cell array is set. The voltage value setting means controls the current corresponding to the voltage difference between the target voltage value set by the target voltage value setting means and the output voltage of the fractional solar cell array to control the output voltage of the fractional solar cell array to the target voltage value. And a control circuit for controlling the output current of the fractional solar cell array by the current control means to follow the input voltage of the inverter device.

With this configuration, not only the same operation as the invention of claim 2 can be achieved, but the target voltage value setting means sets the target voltage value of the fractional solar cell array, and the current control means sets the target voltage value. The target voltage value setting means controls the current corresponding to the voltage difference between the target voltage value and the output voltage of the fractional solar cell array to control the output voltage of the fractional solar cell array to be the target voltage value, In the control circuit, the output current of the fractional solar cell array can be controlled by the current control means (increasing the output impedance) to follow the input voltage of the inverter device.

Therefore, it is possible to connect the fractional solar cell array to the inverter device by a simple power supply means without affecting the inverter device such as satisfying the maximum power point tracking function of the inverter device.

In order to achieve the first object, the power supply device according to the invention of claim 4 is the power supply device according to claim 3, wherein the target voltage value setting means is the fractional solar cell array. Is a voltage setting means for setting a voltage value determined by using the open circuit voltage as a reference value as a target voltage value.

With this structure, the same operation as that of the above-mentioned invention of claim 3 can be achieved.

In order to achieve the first object, the power supply device according to the invention of claim 5 is the power supply device according to claim 3, wherein the target voltage value setting means is the fractional solar cell array. Is the maximum power point tracking control means for setting the voltage at the maximum power point of the output power of 1 as the target voltage value.

With this structure, the same operation as that of the above-mentioned invention of claim 3 can be achieved.

In order to achieve the above first object, the power supply device according to the invention of claim 6 is the power supply device according to claim 3, 4 or 5, wherein the current control means is A voltage detection unit that detects an output voltage of the fractional solar cell array, a current detection unit that detects an output current of the fractional solar cell array, a target voltage value set by the target voltage value setting unit, and the fractional solar cell. The voltage control unit that creates a current command value based on the voltage difference by comparing the output voltage of the battery array, the current command value output from the voltage control unit and the fractional solar cell array detected by the current detection unit. A current control unit that generates a drive pulse by comparing the output current value and a drive unit that controls the control circuit by a pulse signal from the current control unit are provided.

With this configuration, not only the same effect as that of the invention of claim 3 described above can be achieved, but also in the voltage control section, the target voltage value output from the target voltage value setting means and the fractional sun detected by the voltage detection section are obtained. The current command value is created based on the voltage difference by comparing the output voltage value of the battery array, and in the current control unit, the current command value output from the voltage control unit and the output of the fractional solar cell array detected by the current detection unit. The current value is compared and the current difference is detected to generate a pulse signal, and the pulse signal causes the drive unit to control the control circuit so that the output current corresponding to the current command value flows to the control circuit. The fractional solar cell array can be effectively used by inputting the output current of the fractional solar cell array into the inverter device while bringing the output voltage of the cell array close to the target voltage value.

In order to achieve the first object, the power supply device according to the invention of claim 7 is the power supply device according to claim 3, 4 or 5 or 6, wherein: The control circuit has a current control configuration in which the switching element is turned on / off by a pulse signal to control the conduction period of the switching element and the repetition frequency to control the output current of the fractional solar cell array.

With this structure, not only the same effects as those of the invention of claim 3, claim 4, claim 5, or claim 6 can be obtained, but also the structure of the power supply device can be simplified.

In order to achieve the above-mentioned second object, the solar power generation device according to the invention of claim 8 is one in which a plurality of solar cells are connected in series to form a fixed number of solar cells. Connected in parallel to form a main solar cell configuration, connect a power supply device to the output side of the fractional solar cell array that does not meet a certain number of solar cell configurations, and use this power supply device to output the DC power output by the fractional solar cell array. It is characterized by being used.

With this configuration, the DC power output from the fractional solar cell array can be used by the power supply device. For this reason, the solar cell can be attached without being restricted by the shape / area of the object on which the solar cell is installed, for example, the roof, and the roof area can be fully utilized. Therefore, it is possible to increase the utilization of the object on which the solar cell is installed, for example, the roof and the solar cell, and improve the economical efficiency.

In order to achieve the above-mentioned second object, the solar power generation device according to the invention of claim 9 is one in which a plurality of solar cells are connected in series and a fixed number of solar cell configurations are arranged in a plurality of rows. Connected in parallel to form a main solar cell configuration, connect a power supply device to the output side of the fractional solar cell array that does not meet a certain number of solar cell configurations, and use this power supply device to output the DC power output by the fractional solar cell array. The inverter device is connected to the output side of the main solar cell structure.

With this configuration, the DC power output from the fractional solar cell array can be taken into the inverter device connected to the output side of the main solar cell configuration. To this end, the object on which the solar cell is installed, eg the shape of the roof /
It is possible to install solar cells without being limited in area, and the roof area can be fully utilized. Therefore, it is possible to increase the utilization of the object on which the solar cell is installed, for example, the roof and the solar cell, and improve the economical efficiency.

[0027]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows a system interconnection system in which a distributed power source of solar power generation and a commercial power source are systemically connected. In this drawing, reference numeral 1 is a power system of a commercial power source, which is a main power source 2 of a power plant, a substation 3 for stepping down and distributing power from the power plant 2, and a circuit breaker 5 provided on a distribution line 4. And a pole transformer 6 for stepping down the supplied power and supplying it to each home.

The distributed power source installed in each home comprises a solar cell array 8 and an inverter device 10 incorporating an inverter (inverter circuit) 9 for converting DC power output from the solar cell array 8 into AC power. I have it.

This inverter device 10 detects the opening of the circuit breaker 11 for disconnecting the distributed power source from the power system 1 of the commercial power source and the breaker 5 of the power system 1 of the commercial power source based on the frequency fluctuation and the voltage fluctuation. In this configuration, a system interconnection protection device including an opening detection means 12 for opening the circuit breaker 11 is built in.

In this system interconnection system, the calculating means 14 for calculating the generated power of the solar cell array 8 based on the measured output voltage and output current of the solar cell array 8 and the output voltage of the solar cell array 8. By varying the output voltage of the solar cell array 8 by controlling the output varying means 15 to change the output voltage of the solar cell array 8 to search for the output voltage value that maximizes the generated power calculated by the calculating means 14. A control means 16 for intermittently performing the maximum power point tracking operation at regular time intervals and a display means 17 for displaying when the amount of power generation is abnormal are provided. The opening detecting means 12, the calculating means 14, the output varying means 15 and the controlling means 16 are the microcomputer 2
It is composed of 0s.

The control means 16 changes the output voltage of the solar cell array 8 by controlling the inverter circuit 9 via the output varying means 15 and the voltage value at which the electric power output from the arithmetic means 14 becomes maximum. Is to search for.

(Embodiment 1) FIG. 2 (1) is a perspective view of a house in which the solar power generation device according to the present invention is installed on the roof, and FIG. 2 (2) is a power supply device according to the present invention 1 is a configuration explanatory view of a first embodiment of a solar power generation device using a power supply device, FIG. 3 is a configuration explanatory view of a solar cell array of the same solar power generation device, and FIG. 4 is a configuration explanatory view of a module.

The first embodiment is implemented by using the system interconnection system described above. Then, on the roof 22 of the house 21, a large number of the solar cell arrays 8 constituting the photovoltaic power generator according to the present invention are installed.
In the case of a rated output of 3 KW, the solar cell array 8 is configured by connecting six modules M in series to form a module row N, and connecting five module rows N in parallel (a total of 30 modules). .

In general, in order to protect the module M (cell S which is a structural unit) from the difference in output voltage of each module M, the backflow prevention diode 23 is connected to each module row N of the solar cell array 8.

Further, since the modules M are connected in series in the module row N, when one module M is in a non-output state (a shaded state), it is in a released state. All will be in no output state. To prevent this, a bypass diode 24 is connected in parallel for each module M as shown in FIG.

Therefore, the solar cell array 8 constructed as described above is connected in series six pieces to form a fixed number of solar cell configurations 25, and the fixed number of solar cell configurations 25 are connected in parallel in four columns. Solar cell configuration (6 series 4 array array) 26
However, due to the difference in the solar cell installation area of the roof 22, a fractional solar cell array 27 having a smaller number of solar cell arrays 8 than the fixed number of solar cell configurations 25 is generated.

In the first embodiment of the present invention, the power supply device G is connected to the output side of the fractional solar cell array 27, and the DC power output from the fractional solar cell array 27 by this power supply device G is used as the main solar cell configuration. It is adapted to be taken into the inverter device 10 provided on the output side of the (6 serial 4 array array) 27.

According to the first embodiment of the present invention, a fixed number of solar cell configurations 25 formed by connecting six solar cell arrays 8 in series are connected in parallel in four rows to form a main solar cell configuration 26.
Then, a power supply device G, which is a power supply unit, is connected to the output side of the fractional solar cell array 27 that is less than the fixed number of solar cell configurations 25, and the DC power output from the fractional solar cell array 27 is supplied by the power supply device G. , The DC power output from the fractional solar cell array 27 is connected to the output side of the main solar cell configuration 26 by taking in the inverter device 10 connected to the output side of the main solar cell configuration 26. It can be incorporated in the inverter device 10.

Therefore, the solar cell can be attached without being restricted by the shape / area of the object on which the solar cell is installed, for example, the roof 22, and the roof area can be fully utilized. Therefore, it is possible to increase the utilization of the object on which the solar cell is installed, for example, the roof 22 and the solar cell, and improve the economical efficiency.

In the first embodiment described above, the main purpose is to take in the DC power output from the fractional solar cell array 27 into the inverter device 10 connected to the output side of the main solar cell configuration 26 by the power supply device G. However, the configuration of the power supply device G is not mentioned.

Therefore, when the DC power output from the fractional solar cell array 27 is taken into the inverter device 10,
A method is conceivable in which the undervoltage of the fractional solar cell array 27 is boosted to a constant voltage corresponding to a predetermined number of series by using a boosting power source and is input to the inverter device 10. The device 10 cannot perform the maximum power follow-up control, and the solar cell utilization efficiency decreases. Also,
When the output voltage of the step-up power supply device is made variable and the maximum power point is followed, the structure of the step-up power supply device becomes complicated and the cost increases. Such a problem is solved in the second embodiment described below.

(Embodiment 2) FIG. 8 shows Embodiment 2 of a power supply device according to the present invention and a photovoltaic power generator using this power supply device. Power supply G in embodiment 2 of this embodiment includes a target voltage setting means for setting a target voltage value V ₁ of the said fractional solar battery array 27, the target voltage value V ₁ of the target voltage value setting means has set the Fractional solar cell array 27
Current control means for controlling a current commensurate with the voltage difference between the output voltage V ₀ and the output voltage V ₀ to control the output voltage V ₀ of the fractional solar cell array 27 to reach the target voltage value V _1. And a control circuit that controls the output current I ₀ of the fractional solar cell array 27 by the current control means of the control unit 33 and follows the input voltage of the inverter device 10.

The control circuit includes negative and positive input connection terminals 28 and 29 and negative and positive output connection terminals 30 and 30.
The DC / DC power conversion circuit 32 includes a DC / DC power conversion circuit 32. The DC / DC power conversion circuit 32 includes capacitors C1 and C2, a coil L, a diode D, and a switching element (transistor Tr) T. Are installed in parallel with the input connection terminal 28.

Further, the control unit 33 is provided in the DC / DC power conversion circuit 32, and a voltage detection unit (detection sensor) 34 for detecting the output voltage of the fractional solar cell array 27, and a DC / DC
The fractional solar cell array 27 provided in the DC power conversion circuit 32
Current detection unit (detection sensor) 35 for detecting the output current of
A voltage setting unit 36 for setting a target voltage value (voltage command value) V ₁ of, for example, about 80% of the open circuit voltage of the fractional solar cell array 27, and a target voltage value V ₁ output from the voltage setting unit 36. The output voltage V _{0 of} the fractional solar cell array 27 detected by the voltage detection unit 34 is compared and the current command value I ₁ is based on the voltage difference.
PWM for comparing the current command value I ₁ output from the voltage control unit 37 with the output current I _{0 of} the fractional solar cell array 27 detected by the current detection unit 35
(Pulse With Modulation) A current controller 38 for generating a drive pulse and a PWM driver 39 which is a driver for controlling the switching element T by a pulse signal from the current controller 38 are provided.

In this case, the target voltage value setting means is the voltage setting section 36, and the current control means is the voltage detection section 34, the current detection section 35, the voltage control section 37, the current control section 38, and the PWM.
And a drive unit 39.

In the power supply device G having the above-described structure, the lead wires 40 and 4 are connected to the input connection terminals 28 and 29.
1 through the output terminals 27-1, 2 of the fractional solar cell array 27,
7-2, and the output connection terminals 30 and 31 are connected to the input terminals 10-1 and 10-2 of the inverter device 10 via the lead wires 42 and 43, respectively. It is incorporated in the output circuit of the array 26).

Next, the operation of the solar power generation device configured as described above will be described. In the voltage setting unit 36,
A target voltage value V ₁ of, for example, about 80% of the open circuit voltage of the fractional solar cell array 27 is set. Next, the voltage detector 34 detects the output voltage V ₀ of the fractional solar cell array 27. And
In the voltage control unit 37, the target voltage value V ₁ output from the voltage setting unit 36 is compared with the output voltage V _{0 of} the fractional solar cell array 27 detected by the voltage detection unit 34, and the current command value I based on the voltage difference. Create ₁ .

Output current I- in the fractional solar cell array 27
The relationship of the output voltage V has a curve characteristic as shown in FIG. Therefore, when the output voltage V ₀ is higher than the target voltage value V _{1, in} order to eliminate the voltage difference ΔV (V ₀ −V ₁ ), the fractional solar cell array 27 corresponding to the voltage difference ΔV 27
It suffices to supply a large amount of output current. In order to flow a large amount of this output current, that is, to eliminate the voltage difference ΔV, the current command value I ₁ is created.

Then, the current detector 35 detects the output current I ₀ of the fractional solar cell array 27. Next, the current controller 38
At the current command value I ₁ output from the voltage controller 37
And the output current I _{0 of} the fractional solar cell array 27 detected by the current detector 35 are compared to detect a current difference ΔI (I ₀ −I ₁ ), and a PWM drive pulse is generated. Then, the PWM drive unit 39 receives the pulse signal from the switching element T.
Is controlled so that the output current corresponding to the current command value I ₁ flows in the DC / DC power conversion circuit 32, and the output voltage V ₀ of the fractional solar cell array 27 is brought close to the target voltage value V ₁ to the fractional solar cell array. The output current of 27 is input to the inverter device 10, and the fractional solar cell array 27 is effectively used.

The output current is controlled in the DC / DC power conversion circuit 32. This current control is performed by the transistor Tr, which is the switching element T, being turned on / off by a pulse signal. That is, when the transistor Tr is turned on by the pulse signal, the output current I ₀ of the fractional solar cell array 27 flows from the input terminal (input power source Vin) through the coil L. Since the current flowing through the coil L monotonically increases in proportion to time as shown in FIG. 7, it becomes as shown in (Equation 1).

[0051]

[Equation 1] During the conduction period t = ton of the transistor Tr, the output current I
₀ −1 has the maximum value I ₀ p, and at this time, the electric energy P is stored in the coil L. This electric energy P is (Equation 2) per unit time, where f is the repetition frequency.
become that way.

[0052]

[Equation 2] Here, when the transistor Tr is turned off, the coil L
Generates a counter electromotive force to charge the capacitor C1 through the diode D. The voltage across the capacitor C1 becomes the output voltage V ₀ .

When the output current is I ₀ and the load resistance is R,
Since the output power P is equal to the stored power in the coil L, the equation (3) is obtained, and the output current I ₀ is as shown in the equation (4), which is proportional to the conduction period ton of the transistor Tr and the repetition frequency f. To do.

[0054]

(Equation 3)

[0055]

(Equation 4) Therefore, if the conduction period ton of the transistor Tr is lengthened and the repetition frequency f is increased, the output current I ₀ is increased. Conversely, if the conduction period ton of the transistor Tr is shortened and the repetition frequency f is decreased, the output current I ₀ is decreased. To do.

According to the second embodiment described above, the target voltage value V ₁ of the fractional solar cell array 27 is set by the voltage setting unit 36, and the target voltage value set by the voltage setting unit 36 is set by the current control means. The current corresponding to the voltage difference ΔV between the value V ₁ and the output voltage V ₀ of the fractional solar cell array 27 is controlled to control the output voltage V ₀ of the fractional solar cell array 27 to the target voltage value V _1. In the DC / DC power conversion circuit 32, the output current I ₀ of the fractional solar cell array 27 can be controlled (increased output impedance) by the current control means to follow the input voltage of the inverter device 10. it can.

Therefore, the inverter device 10 is maintained, for example, by maintaining the maximum power point tracking function.
The fractional solar cell array 27 can be connected to the inverter device 10 by the simple power supply device G without affecting the above.

(Embodiment 3) FIG. 9 shows Embodiment 3 of a power supply device according to the present invention and a solar power generation device using this power supply device. The power supply device according to the third embodiment and the solar power generation device using the power supply device are different from the power supply device according to the second embodiment and the solar power generation device using the power supply device in the power supply device. The configuration of the control unit 33 of the device G is the same as that of the power supply device of the second embodiment and the solar power generation device using the power supply device of the second embodiment, and thus the same reference numerals as those of the second embodiment are used. And the description is omitted.

The control unit 33 of the power supply device G of the solar power generation device of the third embodiment is provided in the DC / DC power conversion circuit 32 and detects the output voltage of the fractional solar cell array 27 (detection unit). Sensor) 34, a current detection unit (detection sensor) 35 provided in the DC / DC power conversion circuit 32 to detect the output current of the fractional solar cell array 27, and the maximum power point PMax of the output power of the fractional solar cell array 27. And a maximum power point tracking control unit (maximum power point tracking control means) 44 as target voltage value setting means for setting the voltage of the maximum power point PMax to the target voltage value V ₁ and this maximum power point tracking control. The voltage control unit that compares the target voltage value V ₁ output from the unit 44 with the output voltage V _{0 of} the fractional solar cell array 27 detected by the voltage detection unit 34 to create the current command value I ₁ based on the voltage difference ΔV. 37 and this voltage control Current command value I output from section 37
₁ and a current control unit 38 for generating a PWM drive pulse by comparing the output current I _{0 of} the fractional solar cell array 27 detected by the current detection unit 35, and the switching element T by the pulse signal from the current control unit 38. And a PWM drive unit 39 for controlling the.

The maximum power point follow-up control in the maximum power point follow-up control unit 44 basically uses a method of changing the voltage and determining the next changing direction according to the change in the power. For example, if the voltage is increased by 1 V and the power change is negative, the voltage is changed by -1 V next time.

That is, in the flowchart of FIG. 10, the output voltage V ₀ of the fractional solar cell array 27 is changed by ΔV from the upper limit of the output voltage range toward the decreasing direction and from the lower limit direction of the output voltage V ₀ toward the increasing direction (step S1), the direct current accompanying the change of the output voltage V ₀ is measured (step S
2), DC power is calculated by the calculating means (step S
3). It is determined whether or not this DC power is increasing compared to the DC power before the change (step S4), and when it is determined that the DC power is increasing, the voltage fluctuation direction is left as it is (step S5) and the step is performed. Head to S1. Also,
If it is determined in step S4 that the DC power has not increased, the voltage fluctuation direction is reversed (step S5), and the process proceeds to step S1.

Next, the operation of the solar power generation device configured as described above will be described. The maximum power point tracking control unit 44
, The output current I _{0 of} the fractional solar cell array 27 detected by the current detection unit 35 and the output voltage V _{0 of} the fractional solar cell array 27 detected by the voltage detection unit 34 are input to the fractional solar cell array 27. The maximum power point PMax of the output power is searched, and the voltage at the maximum power point PMax is set to the target voltage value V ₁ .

Then, in the voltage controller 37, the voltage setting is performed.
Target voltage value V output from the constant unit 36 ₁And voltage detector 34
Output voltage V of the fractional solar cell array 27 detected by₀Compare with
Then, based on the voltage difference ΔV, the current command value I₁Create

Next, in the current control unit 38, the current command value I ₁ output from the voltage control unit 37 is compared with the output current I _{0 of} the fractional solar cell array 27 detected by the current detection unit 35, and the current difference ΔI is obtained. Is detected and a PWM drive pulse is generated.
Then, the PWM drive unit 39 controls the switching element T by this pulse signal so that the output current I ₀ corresponding to the current command value I ₁ flows to the DC / DC power conversion circuit 32, so that the fractional solar cell array 27 is operated. The output voltage V ₀ is brought closer to the target voltage value V ₁ and the output current I ₀ of the fractional solar cell array 27 is increased.
Is input to the inverter device 10 to effectively use the fractional solar cell array 27.

According to the third embodiment described above, the maximum power point tracking control unit 44 searches for the maximum power point PMax of the output power of the fractional solar cell array 27, and the maximum power point P
The voltage of Max is set to the target voltage value V ₁ , and the voltage setting unit 3
6, the target voltage value V ₁ of the fractional solar cell array 27 is set, and the target voltage value V ₁ set by the voltage setting unit 36 and the output voltage V ₀ of the fractional solar cell array 27 are set by the current control means. The current corresponding to the voltage difference ΔV is controlled to control the output voltage V ₀ of the fractional solar cell array 27 to be the target voltage value V ₁ , and the DC / DC power conversion circuit 32 controls the current by the current control means. The output current I ₀ of the fractional solar cell array 27 can be controlled (increased output impedance) to follow the input voltage of the inverter device 10.

Therefore, the maximum power point tracking function of the inverter device 10 is maintained, and so on.
The fractional solar cell array 27 can be connected to the inverter device 10 by the simple power supply device G without affecting the above.

In the above-described first to third embodiments,
Although the power supply device installed on the roof 22 of the house 21 and the sunlight power generation device using this power supply device have been described, the power supply device according to the present invention and the solar power generation device using this power supply device are not limited to this. It can also be applied to objects such as cars that require solar power generation.

[0068]

As described above, according to the power supply device of the first aspect of the present invention, a fixed number of solar cell structures each having a plurality of solar cells connected in series are connected in parallel in a plurality of columns. By using the solar cell configuration and using the DC power output by the fractional solar cell array that is less than a certain number of solar cell configurations, it is possible to use the DC power output by the fractional solar cell array by the power supply device. it can. For this,
The solar cell can be mounted without being restricted by the shape / area of the object on which the solar cell is installed, for example, the roof shape / area, and the roof area can be fully utilized. Therefore, it is possible to increase the utilization of the object on which the solar cell is installed, for example, the roof and the solar cell, and improve the economical efficiency.

According to the power supply device of the second aspect of the present invention, a fixed number of solar cell configurations formed by connecting a plurality of solar cells in series are connected in parallel in a plurality of columns to form a main solar cell configuration. DC power output in the fractional solar cell array less than the number of solar cell configuration, by taking into the inverter device connected to the output side of the main solar cell configuration, in the fractional solar cell array by the power supply The output DC power can be taken into the inverter device connected to the output side of the main solar cell configuration. For this reason, the solar cell can be attached without being restricted by the shape / area of the object on which the solar cell is installed, for example, the roof, and the roof area can be fully utilized. Therefore, it is possible to increase the utilization of the object on which the solar cell is installed, for example, the roof and the solar cell, and improve the economical efficiency.

Further, according to the power supply device of the invention of claim 3, in the power supply device of claim 2, a target voltage value setting means for setting a target voltage value of the fractional solar cell array, and the target voltage value. Current control means for controlling the current corresponding to the voltage difference between the target voltage value set by the setting means and the output voltage of the fractional solar cell array so that the output voltage of the fractional solar cell array becomes the target voltage value. By having a control circuit that controls the output current of the fractional solar cell array by this current control means and follows the input voltage of the inverter device, it is possible to achieve the same effect as the invention of claim 2 described above. Alternatively, the target voltage value setting means sets the target voltage value of the fractional solar cell array, and the current control means sets the target voltage value set by the target voltage value setting means and the output voltage of the fractional solar cell array. The output voltage of the fractional solar cell array is controlled so that the output voltage of the fractional solar cell array becomes a target voltage value by controlling the current commensurate with the voltage difference, and the control circuit controls the output current of the fractional solar cell array by the current control means. (The output impedance is increased) to follow the input voltage of the inverter device.

Therefore, the fractional solar cell array can be connected to the inverter device by a simple power supply means without affecting the inverter device such as satisfying the maximum power point tracking function of the inverter device.

According to a fourth aspect of the power source device of the present invention, in the power source device of the third aspect, the target voltage value setting means determines the open circuit voltage of the fractional solar cell array as a reference value. By the voltage setting means for setting the voltage value as the target voltage value, the same effect as that of the above-described invention of claim 3 can be obtained.

According to the power supply device of the fifth aspect of the present invention, in the power supply device of the third aspect, the target voltage value setting means sets the voltage at the maximum power point of the output power of the fractional solar cell array. With the maximum power point tracking control means set as the target voltage value, the same effect as that of the above-described invention of claim 3 can be obtained.

According to a sixth aspect of the power supply device of the present invention, in the third or fourth or fifth power supply device, the current control means controls the output voltage of the fractional solar cell array. A voltage detection unit for detecting, a current detection unit for detecting an output current of the fractional solar cell array, a target voltage value set by the target voltage value setting means and an output voltage of the fractional solar cell array are compared. A voltage control unit that creates a current command value based on the voltage difference, a drive pulse by comparing the current command value output from the voltage control unit and the output current value of the fractional solar cell array detected by the current detection unit. Not only can the same effect as the invention of claim 3 be obtained by including the current control unit that generates the current and the drive unit that controls the control circuit by the pulse signal from the current control unit. Voltage controller The target voltage value output from the target voltage value setting means and the output voltage value of the fractional solar cell array detected by the voltage detection unit are compared to create a current command value based on the voltage difference, and the current control unit , The current command value output from the voltage control unit is compared with the output current value of the fractional solar cell array detected by the current detection unit to detect the current difference and generate a pulse signal, and the drive unit is controlled by this pulse signal. The circuit is controlled so that the output current corresponding to the current command value flows in the control circuit, the output voltage of the fractional solar cell array is brought close to the target voltage value, and the output current of the fractional solar cell array is input to the inverter device. This fractional solar cell array can be effectively used.

According to the power supply device of the invention of claim 7, in the power supply device of claim 3, 4 or 5 or 6, the control circuit uses a pulse signal for the switching element. 4. The current control configuration for controlling the output current of the fractional solar cell array by controlling the conduction period of the switching element and the repetition frequency by performing on / off operation, and thus the above-mentioned configuration is achieved.
Alternatively, not only the same effects as those of the invention of claim 4 or claim 5 or claim 6 can be obtained, but also the configuration of the power supply device can be simplified.

Further, according to the solar power generation device of the invention of claim 8, a fixed number of solar cell configurations, which are formed by connecting a plurality of solar cells in series, are connected in parallel in a plurality of columns to form a main solar cell configuration. , The fractional solar cell array is less than a fixed number of solar cell arrays, and the power supply device is connected to the output side of the fractional solar cell array so that the DC power output from the fractional solar cell array is used by the power supply device. The DC power output from the solar cell array can be used by the power supply device. To this end, the object on which the solar cell is installed, eg the shape of the roof /
It is possible to install solar cells without being limited in area, and the roof area can be fully utilized. Therefore, it is possible to increase the utilization of the object on which the solar cell is installed, for example, the roof and the solar cell, and improve the economical efficiency.

According to the ninth aspect of the present invention, there is provided a main solar cell configuration in which a fixed number of solar cell configurations each having a plurality of solar cells connected in series are connected in parallel in a plurality of columns. , A power supply device is connected to the output side of the fractional solar cell array that does not meet a certain number of solar cell configurations, and the DC power output from the fractional solar cell array by this power supply device is output to the output side of the main solar cell configuration. By being taken in by the connected inverter device, the DC power output from the fractional solar cell array can be taken in by the inverter device connected to the output side of the main solar cell configuration. For this reason, the solar cell can be attached without being restricted by the shape / area of the object on which the solar cell is installed, for example, the roof, and the roof area can be fully utilized. Therefore, it is possible to increase the utilization of the object on which the solar cell is installed, for example, the roof and the solar cell, and improve the economical efficiency.

[Brief description of drawings]

FIG. 1 is a configuration explanatory diagram of a grid interconnection system that grid-links a distributed power source by solar power generation and a commercial power source.

FIG. 2A is a perspective view of a house including a power supply device according to the present invention and a solar power generation device using the power supply device. (2) is a configuration explanatory view of a first embodiment of a power supply device according to the present invention and a solar power generation device using this power supply device.

FIG. 3 is a structural explanatory diagram of a power supply device according to the present invention and a solar cell array in a solar power generation device using the power supply device.

FIG. 4 is a structural explanatory view of a module included in the solar cell array.

FIG. 5 is an equivalent circuit diagram of the module.

FIG. 6 is a VI and VP characteristic diagram of the solar power generation device.

FIG. 7 is a current waveform diagram of the control circuit.

FIG. 8 is a configuration explanatory diagram of a second embodiment of a power supply device according to the present invention and a solar power generation device using the power supply device.

FIG. 9 is a configuration explanatory diagram of a third embodiment of a power supply device according to the present invention and a solar power generation device using the power supply device.

FIG. 10 is a flowchart of a maximum power point tracking operation.

[Explanation of symbols]

8 solar cell array 10 inverter device 25 constant solar cell configuration 26 main solar cell configuration 27 fractional solar cell array 32 DC / DC power conversion circuit (control circuit) 33 control unit 34 voltage detection unit 35 current detection unit 36 voltage setting unit 36 (Target voltage value setting means) 37 Voltage control section 38 Current control section 39 PWM driving section (driving section) 44 Maximum power point tracking control section (maximum power point tracking control means, target voltage value setting means) G power supply device (power supply means) )

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Office reference number FI Technical display location H02N 6/00 H01L 31/04 K

Claims (9)

[Claims] 1. A main solar cell configuration in which a fixed number of solar cell configurations formed by connecting a plurality of solar cells in series are connected in parallel to form a main solar cell configuration. A power supply device characterized in that it uses the output DC power. 2. A main solar cell configuration in which a fixed number of solar cell configurations formed by connecting a plurality of solar cells in series are connected in parallel to form a main solar cell configuration. A power supply device characterized in that the output DC power is taken into an inverter device connected to the output side of the main solar cell structure. 3. A target voltage value setting means for setting a target voltage value of the fractional solar cell array, and a voltage difference between the target voltage value set by the target voltage value setting means and the output voltage of the fractional solar cell array. A current control means for controlling the matching current to control the output voltage of the fractional solar cell array to a target voltage value, and the current control means for controlling the output current of the fractional solar cell array to control the output current of the fractional solar cell array. The power supply device according to claim 2, further comprising a control circuit that follows the input voltage. 4. The power supply device according to claim 3, wherein the target voltage value setting unit is a voltage setting unit that sets a voltage value determined by using an open circuit voltage of the fractional solar cell array as a reference value as a target voltage value. 5. The power supply device according to claim 3, wherein the target voltage value setting unit is a maximum power point tracking control unit that sets a voltage at a maximum power point of the output power of the fractional solar cell array as a target voltage value. 6. The current control unit includes a voltage detection unit that detects an output voltage of the fractional solar cell array, a current detection unit that detects an output current of the fractional solar cell array, and the target voltage value setting unit. A voltage control unit that creates a current command value based on a voltage difference by comparing the set target voltage value and the output voltage of the fractional solar cell array, a current command value output from the voltage control unit, and the current detection. A current control unit that compares the output current value of the fractional solar cell array detected by the unit to generate a drive pulse; and a drive unit that controls the control circuit by a pulse signal from the current control unit. The power supply device according to claim 3, claim 4, or claim 5. 7. The current for controlling the output current of the fractional solar cell array, wherein the control circuit operates a switching element on / off by a pulse signal to control a conduction period of the switching element and a repetition frequency. The power supply device according to claim 3, 4 or 5, or 6 having a control configuration. 8. A main solar cell configuration in which a fixed number of solar cell configurations formed by connecting a plurality of solar cells in series are connected in parallel to form a main solar cell configuration. A solar power generation device, wherein a power supply device is connected to the output side, and the DC power output by the fractional solar cell array is used by the power supply device. 9. A main solar cell configuration in which a fixed number of solar cell configurations formed by connecting a plurality of solar cells in series are connected in parallel to form a main solar cell configuration. A power supply device is connected to the output side, and the DC power output from the fractional solar cell array by the power supply device is taken into the inverter device connected to the output side of the main solar cell configuration. Solar power generator.