JP2012156317A - Solar battery power generation device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To propose a technology capable of remotely monitoring each solar battery panel from a management room or the like without patrolling.SOLUTION: In a solar battery power generation device obtained by connecting and arranging a plurality of solar battery panels in series, a positive pole side of the solar battery panel and an anode side of a diode are connected, and a negative pole side of the solar battery panel and a cathode side of the diode are connected. The solar battery power generation device has: a voltage detection means configured so as to detect a voltage between both end terminals of the diode and compare the detected voltage with a predetermined reference voltage, to output a power supply circuit operation signal in the case that the voltage between the terminals is equal to or less than the predetermined reference voltage, and not to output the power supply circuit operation signal in the case that the voltage between the terminals is larger than the predetermined reference voltage; a power supply circuit outputting a predetermined operation voltage based on the voltage between the terminals of the diode in the case that the power supply circuit operation signal is output; and a wireless transmission circuit configured so as to operate at the operation voltage and transmit an operation failure signal in the case that the operation voltage is output, and not to transmit the operation failure signal in the case that operation voltage is not output.

Description

  The present invention relates to a management system for a solar battery power generation apparatus in which a plurality of solar battery panels are connected in series and a large number of panels are arranged.

Due to environmental problems and resource problems in recent years, solar power generation devices using natural energy called sunlight have attracted attention. Among them, a solar battery power generation apparatus in which a plurality of solar battery panels are connected in series and a plurality of panels are arranged has been installed.
By the way, the equivalent circuit of a solar cell panel can be expressed as a parallel circuit of a current source, an ideal diode, and a resistor. When the solar cell panel breaks down and malfunctions, the current source disappears, and only the ideal diode and the parallel resistor are connected in the opposite direction.
Therefore, when one of the plurality of solar cell panels connected in series becomes malfunctioning, not only does the amount of power generated by the malfunctioning solar cell panel decrease and decrease, but the malfunctioning solar cell panel causes other There is a problem that current generated by the solar cell panel is blocked.
In order to avoid the problem that the solar cell panel that has malfunctioned in this way blocks the current, a forward diode is connected in parallel to each solar cell panel.
In addition, when there is a malfunctioning solar panel, it is necessary to identify the solar panel for replacement, repair, etc., but since it cannot be distinguished from a normal solar panel in terms of appearance, one by one It was necessary to check the terminal voltage with a tester.

In view of this, Japanese Patent Application Laid-Open No. H10-228707 proposes a technique that can easily find a solar cell panel that has malfunctioned.
The technique proposed in Patent Document 1 is
A diode connected in parallel to each solar cell panel is replaced with a light emitting diode, and the light emitting diode is turned on when the solar cell panel malfunctions.
This technology has made it possible to easily find a broken solar cell panel without using a tester or the like.

JP-A-8-97456

With the technique described in Patent Document 1, it has become possible to easily find a broken solar cell panel without using a tester or the like at night, etc. There is a problem that it is easy to overlook finding a broken solar cell panel among solar cell panels.
In addition, in order to find a light emitting diode that is lit, it is necessary to look around each solar cell panel, and there is a problem that it is necessary to secure personnel for patrol.

An object of the present invention is to propose a technique that enables remote monitoring from a management room or the like without looking around each solar cell panel.

In claim 1 of the solar cell power generator according to the present invention,
In the solar battery power generation device arranged by connecting a plurality of solar battery panels in series,
Connecting the positive electrode side of the solar cell panel and the anode side of the diode, connecting the negative side of the solar cell panel and the cathode side of the diode,
A voltage between terminals at both ends of the diode is detected and compared with a predetermined reference voltage. When the voltage between the terminals is equal to or lower than the predetermined reference voltage, a power supply circuit operation signal is output. A voltage detecting means configured not to output a power circuit operation signal when exceeding a predetermined reference voltage;
When the power supply circuit operation signal is output, a power supply circuit that outputs a predetermined operation voltage based on the voltage between the terminals of the diode;
A radio transmission circuit configured to operate at the operating voltage when the operating voltage is output and transmit an operation failure signal, and not to transmit an operation failure signal when the operation voltage is not output;
It is characterized by having.
In claim 2,
The wireless transmission circuit includes:
An operation failure signal including identification information for identifying the solar cell panel is transmitted.
In claim 3,
The wireless transmission circuit includes:
The timing for repeating the transmission of the malfunction signal is configured to be controlled based on a random number.

The solar cell power generator according to the present invention is
Connecting the positive electrode side of the solar cell panel and the anode side of the diode, connecting the negative side of the solar cell panel and the cathode side of the diode,
A voltage between terminals of both ends of the diode is detected and compared with a predetermined reference voltage. When the voltage between the terminals is equal to or lower than the predetermined reference voltage, a power supply circuit operation signal is output. Outputs a predetermined operating voltage based on
When the operation voltage is output, it is configured to operate at the operation voltage and transmit an operation failure signal.
If there is a solar cell panel that has malfunctioned, it can be confirmed at a remote location by receiving the malfunction signal without having to bother to visually check the site.
In addition, when there is a solar cell panel that has malfunctioned, it is configured so as to transmit an operational malfunction signal including identification information for identifying the solar cell panel, so that it is not necessary to go to the site for visual confirmation. In addition, by receiving the malfunction signal, it is possible to confirm remotely which solar cell panel is malfunctioning.
Further, by configuring the timing to repeat the transmission of the malfunction signal based on the random number, it is possible to identify the malfunctioning solar cell panel even when the plurality of photovoltaic panels are malfunctioning.

It is a block diagram of the solar cell power generator which concerns on this invention. It is a block diagram of the solar cell panel used for the solar cell power generation device of Example 1. FIG. 3 is a configuration diagram of a solar cell panel used in Example 2. FIG.

As a form for implementing this invention, as shown in FIG. 1, the several solar cell panel 1 is connected in series and the solar cell power generation device 10 is comprised.
Each solar cell panel 1 includes a solar cell unit 11, and a diode 12 is connected in parallel to the solar cell unit 11. The solar cell unit 11 and the diode 12 are connected in such a manner that the positive electrode side of the solar cell unit 11 and the anode side of the diode 12 are connected, and the negative side of the solar cell unit 11 and the cathode side of the diode 12 are connected. It has been done.
The solar cell unit 11 is configured so that the voltage Es of the electromotive force of the solar cell unit 11 is larger than the forward voltage Ed of the diode 12.

  Since the solar cell unit 11 and the diode 12 are in such a connection form, the electromotive force is applied to the diode 12 as a reverse bias when the solar cell unit 11 normally generates an electromotive force. Thus, the diode 12 is turned off, and the total electromotive force of the solar cell power generator 10 is normally output. In this state, the voltage Es due to the electromotive force of the solar cell unit 11 is applied between the terminals of the diode 12.

When the solar cell unit 11 breaks down and becomes inoperable, the current source in the equivalent circuit of the solar cell unit 11 disappears, and only the internal diode in the equivalent circuit is present. The panel electromotive force is applied as a reverse bias, and the internal diode becomes non-conductive. At this time, since the sum of the electromotive forces of the other solar cell panels is applied as a forward voltage to the diodes 12 connected in parallel, the diode 12 becomes conductive and blocks the electromotive forces of the other solar cell panels. The total electromotive force of the solar cell power generation apparatus 10 is reduced by the amount of the malfunctioning solar cell panel, but the reduced total electromotive force is output.
In this state, a forward voltage Ed is generated between the anode and the cathode of the diode 12 due to the characteristics of the diode 12. In the present invention, the failure state of the solar cell panel is notified using this forward voltage.

The configuration of Example 1 of the solar cell panel will be described with reference to FIG.
As shown in FIG. 2, the solar cell panel 1 includes a solar cell unit 11, a diode 12, a voltage detection circuit 13, a power supply circuit 14, and a wireless transmission circuit 15.
The wireless transmission circuit 15 further includes an ID setting circuit 16 and a timing control circuit 17.
An operation failure signal wirelessly transmitted by radio waves or the like from the wireless transmission circuit 15 is received by, for example, a center station provided corresponding to the solar battery power generation device 10, and from the center station by wireless communication or wired communication, Sent to the management device. The management device, for example, centrally manages a plurality of solar cell power generation devices, receives the operation failure signal, and the solar cell panel of which solar cell power generation device 10 is the solar cell panel 1 of the operation failure. 1 is identified and specified, and the maintenance staff can be instructed to replace or repair.

  The voltage detection circuit 13 compares the inter-terminal voltage V of the diode 12 with a predetermined reference voltage Eref, and determines that the solar cell unit 11 is normal when the inter-terminal voltage V is higher than the reference voltage Eref. Then, the power circuit operation signal is not output, but when the inter-terminal voltage V becomes equal to or lower than the reference voltage Eref, it is determined that the solar cell unit 11 is in a malfunctioning state and the power circuit operation signal is output. It is configured to output. For example, a constant voltage diode is used as the reference voltage Eref.

The power supply circuit 14 includes, for example, a DC / DC converter circuit that uses the inter-terminal voltage V of the diode 12 as an input voltage, and only when the power supply circuit operation signal is output from the voltage detection circuit 13. A desired operating voltage required for the wireless transmission circuit 15 is obtained and output as a power source for the operation of the wireless transmission circuit 15.
As the DC / DC converter circuit, for example, a charge pump that boosts the voltage without using an inductor can be employed.

The wireless transmission circuit 15 is configured to transmit a predetermined malfunction signal only when power having a predetermined operating voltage is supplied from the power supply circuit 14.
The malfunction signal includes identification information for identifying the solar cell panel 1, and this identification information is preset in the ID setting circuit 16 with different identification information that does not overlap with other solar cell panels. ing.

As described above, by including identification information in the malfunction signal, the center station can identify the malfunctioning solar cell panel 1, but it operates in a plurality of solar cell panels. In a state where the defective state is generated in parallel, an operation failure signal is simultaneously transmitted from each wireless transmission circuit.
In such a situation, there is a problem in the center station that a plurality of malfunction signals may interfere and the malfunctioning solar cell panel cannot be accurately identified.
Therefore, the wireless transmission circuit 15 is configured such that the transmission timing for repeating the transmission of the malfunction signal transmitted when the solar cell panel 1 malfunctions is the transmission timing of the malfunction signal transmitted from another solar cell panel. In order to control the transmission timing in the wireless transmission circuit 15, the timing control circuit 17 is provided.
Although the transmission timing may be shifted while adjusting with the wireless transmission circuit of another solar cell panel, a communication means with the other solar cell panel 1 is necessary for adjusting the timing. .
Therefore, it is preferable to prevent the transmission timings from overlapping each other by randomly changing the transmission interval of the malfunction signal transmitted from each wireless transmission circuit.
For this purpose, in the timing control circuit 17, a random number is generated in order to reduce the probability that the transmission timing overlaps, and the transmission timing is controlled so as to transmit the malfunction signal at intervals based on the random number. It is good to configure. In order to generate a random number, for example, a random number generation circuit using an algorithm that generates a pseudo-random number by digital calculation, a random number generation circuit that generates an analog random number using element characteristics, noise, and the like are provided. Good.
In this way, even when a state in which a plurality of solar cell panels 1 are malfunctioning occurs by randomly controlling the transmission timing based on random numbers, malfunctions transmitted from those solar cell panels 1 It is possible to reduce a situation in which the transmission timings of the signals coincide with each other and the malfunctioning solar cell panel 1 cannot be identified in the management device on the reception side. Even if there is a moment when the transmission timings of operation failure signals transmitted from a plurality of solar cell panels 1 coincide, there is very little probability that the next transmission timing will coincide. Things that cannot be done will not continue.
Is

  Note that, when the operation of each solar cell panel 1 is normal, power is not supplied to the wireless transmission circuit 15, and thus the malfunction signal is not transmitted.

  As described above, when the solar cell panel 1 has malfunctioned, an operation failure signal is transmitted from the wireless transmission circuit 15, and the center station that has received the operation failure signal receives the operation failure solar cell. Information for identifying which solar cell power generation device 10 the panel 1 belongs to is added to the management device and transmitted to the management device. It is possible to identify and specify which solar cell panel 1 of the power generation device 10 is instructed, and instruct maintenance personnel to replace or repair.

  Note that, by configuring the wireless transmission circuit 15 using elements that operate at a low voltage, the power supply circuit 14 can eliminate the need for a booster circuit.

  Further, the power supply circuit 14 can be configured to output a desired voltage using a DC / DC converter circuit, and a sufficient wireless transmission output can be obtained.

In the timing control circuit 17, the random number generation circuit can be omitted by converting the identification information into a numerical value instead of the random number and setting the numerical value as a transmission interval for repeating wireless transmission.
Moreover, the probability that the interval which repeats transmission in each solar cell panel 1 will overlap can be lowered | hung by making the said numerical identification information into a seed in the case of generating a random number with the random number generation algorithm by digital calculation.

Next, a configuration according to Embodiment 2 of the present invention will be described with reference to FIG.
In Example 2, the identification information is sequentially specified and transmitted wirelessly to each solar panel using a polling method, and the presence / absence of a reply indicates whether there is a malfunction of the called solar panel. Configured to recognize.
As shown in FIG. 3, a receiving circuit 18B is added to the solar cell panel 1B in addition to the wireless transmission circuit 15B in the first embodiment, and the center station has a calling function by a polling method.
The center station transmits a call signal including identification information for specifying each solar cell panel. When the solar cell panel 1B specified by the corresponding identification information is operating normally, no power supply for operation is supplied from the power supply circuit 14B to the wireless transmission circuit 15B, so that an operation failure signal is not transmitted. On the other hand, when the solar cell panel 1B specified by the identification information is malfunctioning, the power for operation is supplied from the power supply circuit 14B to the wireless transmission circuit 15B and the reception circuit 18B. The call signal is compared with the identification information set in the ID setting circuit 16B, and if they match, a malfunction signal is transmitted.
As described above, when each solar cell panel is called in turn and an operation failure signal is received, the solar cell panel is malfunctioning, and when it is not received, the solar cell panel operates. It can be determined to be normal.
In such a configuration, the transmitted malfunction signal need not include identification information. Further, a timing control circuit is not necessary.

DESCRIPTION OF SYMBOLS 10 Solar cell power generator 1 Solar cell panel 11 Solar cell unit 12 Diode 13 Voltage detection circuit 14 Power supply circuit 15 Wireless transmission circuit 16 ID setting circuit 17 Timing control circuit 1B Solar cell panel 14B Power supply circuit 15B Wireless transmission circuit 16B ID setting circuit 18B Receiver circuit

Claims (3)

In the solar battery power generation device arranged by connecting a plurality of solar battery panels in series,
Connecting the positive electrode side of the solar cell panel and the anode side of the diode, connecting the negative side of the solar cell panel and the cathode side of the diode,
A voltage between terminals at both ends of the diode is detected and compared with a predetermined reference voltage. When the voltage between the terminals is equal to or lower than the predetermined reference voltage, a power supply circuit operation signal is output. A voltage detecting means configured not to output a power circuit operation signal when exceeding a predetermined reference voltage;
When the power supply circuit operation signal is output, a power supply circuit that outputs a predetermined operation voltage based on the voltage between the terminals of the diode;
A radio transmission circuit configured to operate at the operating voltage when the operating voltage is output and transmit an operation failure signal, and not to transmit an operation failure signal when the operation voltage is not output;
A solar cell power generation device comprising: The wireless transmission circuit includes:
The solar cell power generation device according to claim 1, wherein the solar cell power generation device is configured to transmit an operation failure signal including identification information for identifying the solar cell panel. The wireless transmission circuit includes:
The solar cell power generator according to any one of claims 1 and 2, wherein the solar cell power generator is configured to control the timing of repeating the transmission of the malfunction signal based on a random number.

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