JPH09113561A - Abnormality detecting device for solar battery panel - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an abnormality detecting device that can detect the no current-conduction state of a solar battery panel easily and rapidly. SOLUTION: This device 11 is provided with current sensors 3A-3D fitted to output cables 2A for connecting a solar battery panel 41 to indoor electric equipment, so as to detect whether a current is flowing to each output cable 2A, and an abnormality informing means 5 for informing the no current- conduction state of output cables 2A, 2B on the basis of signals sent from the current sensors 3A-3D. In the failure state of the solar battery panel 41, the current does not flow to the output cables 2A, so that this is detected by the current sensors 3A-3D, and the no current-conduction state of the output cables 2A, 2B is informed by the abnormality informing means 5.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a solar cell panel abnormality detecting device for detecting that the plurality of solar cell panels arranged on a roof of a building are in an abnormal electrical state.

[0002]

BACKGROUND ART In order to effectively utilize solar energy, a solar system that uses a solar cell panel arranged on a roof of a building to generate electricity by itself is used in a house. In this solar system, in order to secure sufficient electric power, a plurality of solar cell panels are arranged in series on the roof to form a panel line, and the panel lines are arranged in a plurality of rows. The output cables whose one ends are connected to these panel lines, respectively, and the other ends are combined into one in the terminal box and are wired to the indoor electrical equipment.

Since the amount of power generation may decrease or become zero due to damage of the solar cell panel arranged on the roof,
It is checked whether or not the solar cell panel is energized. Conventionally, this check is performed for each panel line using a portable tester.

[0004]

Conventionally, since the energization state of the solar cell panel is individually measured using a portable tester, there is a problem that the measurement work is complicated. In addition, it is inconvenient because it cannot be measured unless a portable tester is at hand, and there is also a problem that detection of an abnormality in the energized state of the solar cell panel is delayed.

An object of the present invention is to provide an abnormality detecting device for a solar cell panel, which can automatically report an abnormality in the non-energized state of the solar cell panel.

[0006]

Therefore, according to the present invention, a current sensor is attached to an output cable of a solar cell panel to detect the energized state of the output cable, and an abnormality notifying unit notifies the user of the non-energized state. It is intended to achieve the above object. Specifically, the abnormality detection device for a solar cell panel of the present invention will be described with reference to the accompanying drawings. A panel line 1A configured by arranging a plurality of solar cell panels 41 in series on a roof 20A of a building 20. 1D is a solar cell panel abnormality detection device 11 for detecting that the energization state is abnormal, and is attached to output cables 2A and 2B that connect the solar cell panel 41 and the indoor electrical equipment 60. Current sensors 3A to 3D that detect whether or not electricity is flowing to 2A and 2B, and that the output cables 2A and 2B are in a non-energized state based on signals sent from the current sensors 3A to 3D It is characterized by including an abnormality notifying means 5.

In the present invention, when the solar cell panel 41 has no failure, the electricity generated by the solar cell panel 41 passes through the output cables 2A and 2B and the indoor electrical equipment 60 is installed.
And is effectively used by the indoor electric equipment 60.
At this time, since electricity flows through the output cables 2A and 2B,
The abnormality notifying unit 5 does not notify the non-energized state. On the other hand, when the solar cell panel 41 has a failure,
Since electricity does not flow to the output cables 2A and 2B, this is detected by the current sensors 3A to 3D, and the abnormality notifying unit 5 notifies that the output cables 2A and 2B are in the non-energized state. Therefore, the non-energized state of the solar cell panel 41 can be automatically notified. Therefore, the solar cell panel 41 can be quickly maintained, and the amount of power generation does not decrease.

Here, the abnormality notifying means 5 may have a structure having lamps 8A to 8D for notifying that the panel lines 1A to 1D are not energized. With this structure, the non-energized state of the solar cell panel 41 can be promptly notified visually. Further, the abnormality notifying means 5 may have a structure having a buzzer 9 for notifying that the panel lines 1A to 1D are in the non-energized state. With this structure, the non-energized state of the solar cell panel 41 can be promptly notified by hearing.

Further, the panel lines 1A to 1D are arranged side by side in a plurality of rows, and the abnormality notifying means 5 is arranged so that all the output cables 2A from the panel lines 1A to 1D in the plurality of rows are connected.
2B is normal when energized or de-energized, and output cables 2A, 2B from some of the plurality of rows of panel lines 1A-1D are energized,
And the output cables 2A, 2 from the remaining panel line
It may have a structure for notifying that B is abnormal when it is in a non-energized state.

In this structure, when only the output cables 2A and 2B from a part of the panel lines are in the non-energized state, a plurality of solar cell panels 41 are irradiated with light (in the daytime). It is possible to detect that some of the solar cell panels 41 are abnormal.
On the other hand, when all the output cables 2A and 2B from the panel lines 1A to 1D are in the energized state, it can be detected that all of the solar cell panels 41 are normal. further,
Since all the panel lines 1A to 1D do not break down at the same time, when all the output cables 2A and 2B from the panel lines 1A to 1D are in the non-energized state, the entire solar cell panel 41 cannot generate electricity at night. It is possible to detect that the panel line 41 as a whole is normal.

[0011]

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 shows a solar cell panel 41.
The building 20 in which is installed is shown. The building 20 of the present embodiment is configured to receive power from a commercial power source 30 and perform self-sufficiency of power or reverse power sale to the commercial power source 30 by means of a solar battery type private power generation device 40.

The commercial power source 30 is connected to the building 2 via a power line 31.
0, and the power supply line 31 is introduced into the building 20 through a pole 32 installed near the building 20. A power distribution box 33 is installed in the pole 32, and a purchased power integrator 34 that integrates the amount of power supplied from the power line 31 to the building 20 and power that flows backward from the building 20 to the commercial power source 30 are installed inside the distribution box 33. A reverse flow power integrating meter 35 for integrating the amount and an external circuit breaker 36 for disconnecting the power supply line 31 from the commercial power supply during maintenance are installed in series.

A distribution board 21 is installed in the building 20, and the introduced power supply line 31 is branched and connected by the distribution board 21 to a plurality of systems of indoor wiring 23 that reach a general load 22 such as a lighting fixture and an outlet in each part of the building 20. Has been done. In the switchboard 21, a main breaker 24 is installed in the middle of the power line 31 before branching, and a system breaker 25 is installed in the middle of the branched indoor wiring 23.

The solar cell type private power generator 40 is used for the building 20.
The solar power is converted into electric power by a plurality of solar cell panels 41 installed on the roof 20A of the above and used. The output of each solar cell panel 41 is collected by a terminal box 42 which is a wiring connector, converted from direct current to alternating current by an inverter 43, and then connected to a switchboard 21 through a transformer box 44. Here, the inverter 43,
An indoor electric equipment 60 is composed of the transformer box 44, the switchboard 21, and the general load 22.

In the transformer box 44, a transformer 4 is provided to insulate the front of the inverter 43 from the switchboard 21.
5, a relay circuit 46 that shuts off the power supply when the commercial power supply 30 to the switchboard 21 is cut off, and a breaker 47 that shuts off the power supply by an excessive current. An emergency outlet 52 is branched and connected via a breaker 51 to a portion between the transformer 45 and the relay circuit 46. The power line 48 extending from the transformer box 44 to the switchboard 21 is the switchboard 2
It is connected to the branch portion of the power supply line 31 and each indoor wiring 23 through one of the system-specific breakers 25.

The detailed structure of this embodiment is shown in FIG. In FIG. 2, a plurality of solar cell panels 41, three in the figure, are arranged in series on the roof 20A to form panel lines 1A to 1D, and the panel lines 1A to 1D are formed.
Are arranged in a plurality of rows along the inclination direction of the roof 20A, four rows in a row in the figure. In each of the panel lines 1A to 1D, the solar cell panels 41 are connected to each other by a positive pole wire and a negative pole wire, which are not shown, of which the solar cell panel 41 arranged at the end is used to send a current to the indoor electric equipment 60 The + pole output cable 2A and the − pole output cable 2B are connected, and these output cables 2A and 2B are merged into one on the indoor electric equipment side, respectively. Note that the output cables 2A and 2B are each formed from two positive pole conductors and two negative pole conductors in the figure, but in reality, since two-core cables are used, the appearance is one. .

First current sensors 3A to 3D are mounted on the panel line side from the junction of the + pole output cables 2A, and the second current sensor 4 is installed on the indoor electric equipment side of the + pole output cables 2A. Is attached.
Each of the first current sensors 3A to 3D has a hall element or the like, holds each output cable 2A, and determines whether electricity is flowing by the magnetic field generated on the panel line side from the confluence of the output cables 2A for each output cable 2A. It is a clamp sensor that detects. The second current sensor 2 has a hall element or the like, holds the output cable 2A, and detects whether or not electricity is flowing by the magnetic field generated on the indoor electric equipment side from the confluence of the output cable 2A as the entire output cable 2A. It is a clamp sensor.

An abnormality notifying means 5 for notifying that the output cable 2A is not energized is connected to these current sensors 3A to 3D, 4. This abnormality notification means 5
A PV monitoring function that receives signals sent from the first current sensors 3A to 3D to monitor the abnormality of the panel lines 1A to 1D and a signal sent from the second current sensor 4 to monitor the abnormality of the terminal box 42 A monitoring unit 6 having a TB monitoring function and a notification unit 7 for notifying a non-energized state are provided, and the notification unit 7 is configured to include lamps 8A to 8D and a buzzer 9.

The PV monitoring function of the monitoring unit 6 is such that when the first current sensors 3A to 3D detect the non-energized state of the output cable 2A, the lamp 8A corresponding to the sensors 3A to 3D.
~ 8D is turned on and the buzzer 9 is sounded to individually notify the abnormality of the panel lines 1A to 1D, and all the output cables 2A from the four rows of the panel lines 1A to 1D are in a normal state or a non-energized state. Yes, it is abnormal when the output cables 2A from a part of the four panel lines 1A to 1D are energized and the output cables 2A from the remaining panel lines are de-energized. This is a configuration for notifying.

On the other hand, the TB monitoring function of the monitoring unit 6 has the first current sensors 3A to 3D when the second current sensor 4 detects the non-energized state of the output cable 2A.
Is normal when all of them are in the non-energized state, but at other times, that is, when the second current sensor 4 outputs the output cable 2A.
When a part or all of the first current sensors 3A to 3D detect the non-energized state, the lamps 8A to 8D are all turned on and the buzzer 9 sounds and the terminal box 42 is abnormal. This is a configuration for notifying that Moreover, you may provide the display part which displays the electric power generation amount in the monitoring part 6 as needed. This display is for taking in the data of a power generation amount indicator (not shown) generally provided in the inverter 43 of FIG.

Here, the first current sensor 3A to 3D, the second current sensor 4 and the abnormality notifying means 5 constitute the abnormality detecting device 11 for the solar cell panel according to the present embodiment. The detection device 11 is arranged inside the terminal box 42. In addition, in FIG.
Reference numeral 10 is a diode forming a part of the terminal box 42, and reference numeral 12 is a switch for cutting off the DC output of the solar cell at the time of maintenance.

In the embodiment of this configuration, the PV monitoring function of the monitoring unit 6 operates to detect whether or not there is an abnormality in each of the panel lines 1A to 1D. When there is no failure in the solar cell panel 41, the electricity generated by the solar cell panel 41 is sent to the indoor electric equipment 60 through the output cable 2A, and is effectively used in the indoor electric equipment 60, or commercial. Reverse power is sold to the power supply 30. At this time, since electricity flows through each output cable 2A, the first current sensor 3
The energization state of the output cable 2A is detected by A to 3D, and the monitoring unit 6 and the notification unit 7 of the abnormality notification unit 5 are detected.
Therefore, the non-energized state indicating the abnormal state is not notified. Further, when it is impossible to generate electricity by sunlight, such as at night, all of the panel lines 1A to 1D do not fail at the same time, so all the output cables 2A from the four rows of panel lines 1A to 1D are not connected. It can be seen that all of the solar cell panels 41 are normal due to the energized state.

On the other hand, when one of the solar cell panels 41 has a failure, for example, when one of the panel lines 1A has an abnormality in the energization state, it is connected to the panel line 1A. Output cable 2
Since electricity does not flow to A, this is the first current sensor 3A
The signal is sent to the abnormality notifying means 5, and the monitoring unit 6 of the abnormality notifying means 5 turns on the lamp 8A and sounds the buzzer 9 to inform that the output cable 2A is in the non-energized state. . At this time, another panel line 1
Since electricity is flowing in the output cable 2A connected to B to 1D, this is detected by the first current sensors 3B to 3D, and the signal is sent to the abnormality notifying means 5 to monitor the abnormality notifying means 5. The lamps 8B to 8D are not turned on in the section 6.

The TB monitoring function of the monitoring unit 6 operates to detect whether or not the terminal box 42 has an abnormality. In the daytime, when there is no failure in the terminal box 42, electricity flows through the output cable 2A,
The energized state of the output cable 2A is detected by the second current sensor 4, and the non-energized state indicating the abnormal state is not notified by the monitoring unit 6 and the notification unit 7 of the abnormality notification unit 5. When electricity cannot be generated by sunlight at night, electricity does not flow through the output cable 2A, and
The current sensor 4 detects the non-energized state of the output cable 2A, but since all the first current sensors 3A to 3D are in the non-energized state, the non-energized state indicating an abnormal state is not notified. .

On the other hand, when there is an abnormality in the terminal box 42 during the daytime, the second current sensor 4 detects the non-energized state of the output cable 2A, so that signal is sent to the abnormality notifying means 5. The monitoring unit 6 of the abnormality notifying means 5 turns on all the lamps 8A to 8D and sounds the buzzer 9 to notify that the terminal box 42 is in an abnormal state. The PV monitoring function of the monitoring unit 6 and T
It works simultaneously with the B monitoring function.

Therefore, according to the present embodiment, the building 20
The solar cell panel abnormality detection device 11 for detecting that the energization state of the panel lines 1A to 1D configured by arranging a plurality of solar cell panels 41 in series on the roof 20A is abnormal. The current sensors 3A to 3D that are attached to the output cable 2A that connects with the indoor electrical equipment 60 and detect whether electricity is flowing through the output cable 2A, and output based on the signals sent from the current sensors 3A to 3D Since the cable 2A is provided with the abnormality notifying means 5 for notifying that the cable 2A is in the non-energized state,
It is possible to automatically detect an abnormality in the non-energized state of the solar cell panel 41. Therefore, the maintenance of the solar cell panel 41 can be performed quickly.

Further, in the present embodiment, the abnormality notifying means 5
Since the structure has the lamps 8A to 8D for notifying that the panel lines 1A to 1D are in the non-energized state, the non-energized state of the solar cell panel 41 can be quickly and visually notified. Further, since the abnormality notifying means 5 has a structure having the buzzer 9 for notifying that the panel lines 1A to 1D are in the non-energized state, the solar cell panel 41 is provided.
The non-energized state of can be promptly notified by hearing.

Further, the abnormality notification means 5 is normal when all the output cables 2A from the plurality of rows of panel lines 1A to 1D are in an energized state or a non-energized state, and one of the plurality of rows of panel lines 1A to 1D is in operation. Panel lines 1B-1D
Since the output cable 2A from the panel line 1A is in the energized state and the remaining output cable 2A from the panel line 1A is in the non-energized state, the panel lines 1A to 1D are informed regardless of the day and night. It is possible to detect an abnormality in the energized state of.

Further, the second current sensor 4 is attached to the indoor electric equipment side from the confluence of the output cables 2A, and the abnormality of the terminal box 42 is detected in the monitoring unit 6 based on the signal sent from the second current sensor 4. A TB monitoring function for monitoring is provided, and when the second current sensor 4 detects the non-energized state of the output cable 2A, all of the first current sensors 3A to 3D are in the non-energized state. Is normal when the lamp is in
Since all the 8D are turned on and the buzzer 9 is sounded to notify that the terminal box 42 is abnormal, the failure of the terminal box 42 itself can be automatically detected.

The present invention is not limited to the above-described embodiments, but includes the following modifications as long as the object of the present invention can be achieved. For example, in the above-described embodiment, the abnormality notifying means 5 has a structure having both the lamps 8A to 8D and the buzzer 9, but in the present invention, one of the lamps 8A to 8D and the buzzer 9 or an alternative thereto. Other means may be used. In order to notify the non-energized state of each panel line 1A to 1D by using the buzzer 9, the range or melody may be changed corresponding to the panel line 1A to 1D. Furthermore, it outputs contact signals, etc., and home automation (HA)
It may be incorporated into. The position where the lamps 8A to 8D and / or the buzzer 9 are installed is not limited to the terminal box 42, and may be a place that is easily noticed, for example, a wall of a living room.

Further, although the current sensors 3A to 3D and 4 are attached to the positive electrode output cable 41A, the negative electrode output cable 4 is used.
The current sensors 3A to 3D, 4 may be attached to 1B. Further, the present invention can also be applied to a single row of panel lines provided with the roof 20A.

[0032]

As described above, according to the present invention, a solar cell panel for detecting an abnormal electrical state of a panel line constructed by arranging a plurality of solar cell panels in series on a roof of a building. An anomaly detection device is attached to the output cable that connects the solar cell panel and indoor electrical equipment, and outputs based on the current sensor that detects whether electricity is flowing through this output cable and the signal sent from this current sensor. Since the configuration is provided with the abnormality notifying means for notifying that the cable is in the non-energized state, the abnormality in the non-energized state of the solar cell panel can be automatically notified.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram showing a building in which a solar cell panel is installed.

FIG. 2 is a configuration diagram showing a detailed configuration of a solar cell panel abnormality detection device according to the present embodiment.

[Explanation of symbols]

 1A-1D Panel line 2A, 2B Output cable 3A-3D, 4 Current sensor 5 Abnormality notification means 6 Monitoring part 8A-8D Lamp 9 Buzzer 11 Solar cell panel abnormality detection device 20 Building 20A Roof 41 Solar cell panel 60 Indoor electrical equipment

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI Technical display location H02H 7/00 H02J 7/35 H H02J 7/35 G01R 15/02 G H01L 31/04 K

Claims (4)

[Claims] 1. An abnormality detecting device for a solar cell panel for detecting an abnormal electricity state of a panel line, which is formed by arranging a plurality of solar cell panels in series on a roof of a building, the solar cell comprising: A current sensor that is attached to the output cable that connects the panel and the indoor electrical equipment and detects whether electricity is flowing through this output cable, and the output cable is de-energized based on the signal sent from this current sensor. An abnormality detecting device for a solar cell panel, comprising: an abnormality notifying means for notifying that there is an abnormality. 2. The solar cell panel abnormality detecting device according to claim 1, wherein the abnormality notifying means has a lamp for notifying that the panel line is in a non-energized state. Anomaly detection device. 3. The solar cell panel abnormality detecting device according to claim 1, wherein the abnormality notifying means has a buzzer for notifying that the panel line is in a non-energized state. Anomaly detection device. 4. The abnormality detecting device for a solar cell panel according to any one of claims 1 to 3, wherein the panel lines are arranged in a plurality of rows in parallel, and the abnormality notifying means includes all of the panel lines in the plurality of rows. Is normal when the output cable is in the energized state or the non-energized state, the output cables from some of the panel lines of the plurality of rows are in the energized state, and the output cables from the remaining panel lines are An abnormality detection device for a solar cell panel, which informs that there is an abnormality when the power is off.