JP6834334B2 - Arc failure detection system - Google Patents

Description

The present invention, in a DC power system and a DC power supply system for photovoltaic systems or the like, and relates to arc fault detection system for detecting an arc generated branch lines and trunk lines.

The following are proposed as conventional techniques for detecting an arc in a DC circuit such as a photovoltaic power generation system.
For example, in the arc detecting means described in Patent Document 1, it is considered that an arc is generated, a short circuit, and a disconnection failure occur due to forgetting to tighten a screw in the terminal block connected to the solar cell panel, and the output side from the terminal block. The fluctuation of the voltage between the wiring and the fluctuation of the current flowing from the terminal block to the output side wiring are detected at the same time.

Further, the arc detection device described in Patent Document 2 has a large number of solar cell panels and is arranged at a plurality of locations like a mega solar, and the switching noise of the inverter of the power conditioner (PCS) is superimposed. It is premised on application to such DC circuits.
In this arc detection device, the voltage across a DC circuit in which a plurality of solar cell panels are connected in series is detected, the output is converted into a power spectrum, and then the frequency band corresponding to the switching noise of the inverter is removed and removed. When the gradient of the power spectrum obtained at a plurality of points of the subsequent power spectrum exceeds a predetermined reference value, the generation of an arc in the DC circuit is determined.

In the prior art described in Patent Document 1, in principle, an arc is generated in the vicinity of the terminal block, in other words, in the vicinity of the voltage sensor, and can be detected when the voltage or the like fluctuates. However, especially in a large-scale photovoltaic power generation system such as a mega solar, since the cables are laid over a long distance, arc failures due to disconnection of the cables may occur at various places.
For this reason, it is difficult to detect an arc failure that occurs in a cable or the like on the solar cell panel side from the terminal block because there is almost no sudden voltage fluctuation at the installation position of the voltage sensor near the terminal block.

Further, the conventional technique described in Patent Document 2 is a detection method focusing on a high frequency component of a voltage generated when an arc is generated, but a failure occurs among a plurality of branch systems (strings) connected to the main system. In order to distinguish between a healthy system and a healthy system, it is necessary to have a photovoltaic power generation system with a backflow prevention diode.
However, in the global mainstream of photovoltaic power generation systems in recent years, PV fuses are used as a safety measure against backflow. According to this type of system, since the detection method described in Patent Document 2 cannot distinguish between a failed system and a healthy system, it is necessary to stop the entire system when a failure occurs, and it takes a lot of time to identify and recover the failure point. It took time and effort.
That is, it was not possible to determine the faulty system depending on the configuration of the photovoltaic power generation system, and it was difficult to stably continue the photovoltaic power generation.

In view of the above points, the applicant, as Japanese Patent Application No. 2016-161009 (hereinafter referred to as the prior application), facilitates the identification of the branch system or the main system in which the arc failure has occurred, and separates the failure location from the sound system. We have already applied for an arc failure detection system that enables continuous power supply.

As shown in FIG. 16, the prior invention comprises a main system having an AC power supply system 100, a power conditioner (PCS) 1, a circuit breaker 11, a DC bus 40, and a voltage detection device 25, and a DC bus 40. In a system including branch systems A and B connected between the positive bus P and the negative bus N, the branch systems A and B are on the path from the solar cell panels 4 and 5 to the DC bus 40. It has current detection devices 21 and 22 that detect the flowing current, respectively, and detects series arc failures in each branch system A and B based on the frequency spectrum of the current detection values by these current detection devices 21 and 22. is there. In the branch systems A and B, 12 and 13 are disconnecting switches, and 14 and 15 are short-circuit switches.

Here, the series arc failure refers to an arc failure that occurs on a single DC line, and the following parallel arc failure refers to an arc failure that occurs between positive and negative DC lines.
That is, in the case of parallel arc failure in each branch system, the current detection value of the branch system in which the failure occurred becomes a peculiar value due to the inflow of current from another system, and the voltage detection value of the DC bus 40 is significantly increased. It can be detected by lowering it.

In addition, the series arc failure of the main system is detected because the voltage detection values in all the branch systems A and B contain signal components peculiar to the arc failure, and the parallel arc failure of the main system is the voltage detection value of the main system. Is reduced to the arc voltage equivalent value (several tens of [V]), and the current detection value in the branch system is detected based on the fact that there is no change as compared with the normal state.

Japanese Unexamined Patent Publication No. 2011-7765 (paragraphs [0031] to [0040], FIGS. 1 to 3, etc.) Japanese Unexamined Patent Publication No. 2014-134445 (paragraphs [0012] to [0014], FIG. 1, etc.)

By the way, when the backflow prevention diode (not shown) for blocking the current from the DC bus 40 to the solar cell panels 4 and 5 is not provided as in the branch systems A and B of FIG. It is possible to detect parallel arc failures and identify the failure system.
However, when the above-mentioned backflow prevention diode is provided in the branch system, even if a parallel arc failure occurs in one branch system, no current flows from another healthy system, and voltage fluctuation cannot be detected. Therefore, there is a problem that the parallel arc failure cannot be detected.

In domestic photovoltaic power generation systems, a backflow prevention diode is usually attached to the junction box that connects the branch system and the main system, and even in such a system, series / parallel arc failure of the branch system can be detected. Is required.

Therefore, solving problems of the present invention, in a DC system of blocking diode is provided in the branch line, a reliably detectable with the arc fault detection system series arcing faults and parallel arc faults in a branch line or trunk line To provide.

In order to solve the above problem, the arc failure detection system according to claim 1 includes a DC bus constituting the main system and a DC power generation facility connected between the positive bus and negative bus of the DC bus. With one or more branching systems,
In a system in which a backflow prevention element for blocking a current in a direction from the positive bus to the DC power generation facility is connected to the branch system .
Has a branch mains voltage detector for detecting a voltage across the front Symbol backflow prevention element,
It is characterized in that when the voltage detection value by the branch system side voltage detection device of one said branch system exceeds a predetermined branch system side threshold value, a parallel arc failure generated between positive and negative DC lines in the branch system is detected. And.

The arc failure detection system according to claim 2 includes a DC bus constituting the main system and one or more branch systems having a DC power generation facility connected between the positive bus and the negative bus of the DC bus. With,
In a system in which a backflow prevention element for blocking a current in a direction from the positive bus to the DC power generation facility is connected to the branch system .
It has a branch system side voltage detection device that detects the voltage across the backflow prevention element .
When the voltage detection value by the branch system side voltage detection device installed in the branch system contains a vibration component peculiar to an arc failure, a series arc failure occurring on one DC line in the branch system is detected. It is characterized by that.

The arc failure detection system according to claim 3 includes a DC bus constituting the main system and one or more branch systems having a DC power generation facility connected between the positive bus and the negative bus of the DC bus. With,
In a system in which a backflow prevention element for blocking a current in a direction from the positive bus to the DC power generation facility is connected to the branch system.
A main system side voltage detection device that detects the line voltage between the positive bus and the negative bus, and
A branch mains voltage detector for detecting a voltage across the backflow prevention element,
Have,
The voltage detection values by the branch system side voltage detection devices installed in all the branch systems include vibration components peculiar to arc failure, and the voltage detection values by the main system side voltage detection devices are on the predetermined main system side. It is characterized by detecting a parallel arc failure that occurs between positive and negative bus lines in the main system when the voltage falls below the threshold value.

The arc failure detection system according to claim 4 includes a DC bus constituting the main system and one or more branch systems having a DC power generation facility connected between the positive bus and the negative bus of the DC bus. With,
In a system in which a backflow prevention element for blocking a current in a direction from the positive bus to the DC power generation facility is connected to the branch system.
It has a branch system side voltage detection device that detects the voltage across the backflow prevention element.
Detecting a series arc failure that occurred on one of the bus lines in the main system when the voltage detection value by the voltage detection device on the branch system side installed in all the branch systems contains a vibration component peculiar to an arc failure. It is characterized by.

The arc failure detection system according to claim 5 includes a DC bus constituting the main system and one or more branch systems having a DC power generation facility connected between the positive bus and the negative bus of the DC bus. With,
In a system in which a backflow prevention element for blocking a current in a direction from the positive bus to the DC power generation facility is connected to the branch system.
A shunt resistor connected in series with the backflow prevention element,
A branch system side voltage detection device that detects the voltage across the series circuit of the backflow prevention element and the shunt resistor, and
Have,
When the voltage value detected by the branch mains voltage detecting device of one of the branch lines exceeds a predetermined branching system side threshold, that you detect a parallel arc fault occurring between the positive and negative DC line in the branch line It is a feature.

The arc failure detection system according to claim 6 includes a DC bus constituting the main system and one or more branch systems having a DC power generation facility connected between the positive bus and the negative bus of the DC bus. With,
In a system in which a backflow prevention element for blocking a current in a direction from the positive bus to the DC power generation facility is connected to the branch system.
A shunt resistor connected in series with the backflow prevention element,
A branch system side voltage detection device that detects the voltage across the series circuit of the backflow prevention element and the shunt resistor, and
Have,
Sometimes included in the voltage values detected by the installed in one of the branch lines the branch mains voltage detecting device arcing faults peculiar vibration component, a series arc fault occurs on one side of the DC line in the branch line It is characterized by detecting.

The arc failure detection system according to claim 7 includes a DC bus constituting the main system and one or more branch systems having a DC power generation facility connected between the positive bus and the negative bus of the DC bus. With,
In a system in which a backflow prevention element for blocking a current in a direction from the positive bus to the DC power generation facility is connected to the branch system.
A main system side voltage detection device that detects the line voltage between the positive bus and the negative bus, and
A shunt resistor connected in series with the backflow prevention element,
A branch system side voltage detection device that detects the voltage across the series circuit of the backflow prevention element and the shunt resistor, and
Have,
All of the arc fault specific vibration component in the voltage values detected by the installed the branch mains voltage detecting apparatus to the branch line included, and the main trunk mains voltage detector voltage detection value is a predetermined main trunk mains by sometimes below the threshold, and detecting the parallel arc fault has occurred between the positive and negative busbars on the main trunk line.

The arc failure detection system according to claim 8 includes a DC bus constituting the main system and one or a plurality of branch systems having a DC power generation facility connected between the positive bus and the negative bus of the DC bus. With,
In a system in which a backflow prevention element for blocking a current in a direction from the positive bus to the DC power generation facility is connected to the branch system.
A shunt resistor connected in series with the backflow prevention element,
A branch system side voltage detection device that detects the voltage across the series circuit of the backflow prevention element and the shunt resistor, and
Have,
All of the at the voltage value detected by the branch mains voltage detecting device installed in a branch line that includes arc fault inherent vibration component, a series arc fault occurs on one side of the bus in the main trunk line It is characterized by detecting.

Arc fault detection system according to claim 9, Oite the arc fault detection system according to any one of claims 1-8,
The branch system includes a switch for disconnection that opens and closes between the DC bus and the DC power generation facility, and a short-circuit switch for short-circuiting between the positive and negative DC lines on the output side of the DC power generation facility. Yes, characterized in that.
The arc failure detection system according to claim 10 is the arc failure detection system according to any one of claims 1 to 9.
The DC power generation facility is a photovoltaic power generation facility, and the DC bus is connected to an AC power supply system via a power conditioner.

According to the present invention, in a DC system in which a backflow prevention diode is connected to each branch system, it is possible to reliably detect the occurrence of a series arc failure or a parallel arc failure in the branch system or the main system, and the failure system.

It is a block diagram of the arc failure detection system which concerns on 1st Embodiment of this invention. In the first embodiment, it is an operation explanatory diagram when a parallel arc failure occurs in a branch system. It is a voltage characteristic diagram of the voltage detection apparatus installed in the branch system of 1st Embodiment. In the first embodiment, it is an operation explanatory diagram after detecting the parallel arc failure of a branch system. It is a block diagram of the arc failure detection system which concerns on 2nd Embodiment of this invention. In the second embodiment, it is an operation explanatory diagram when a series arc failure occurs in a branch system. It is a voltage characteristic figure of the voltage detection apparatus installed in the branch system of 2nd Embodiment. In the second embodiment, it is an operation explanatory diagram after detecting the series arc failure of a branch system. In the second embodiment, it is an operation explanatory diagram when a series arc failure occurs in the main system. In the second embodiment, it is an operation explanatory diagram after detecting the series arc failure of the main trunk system. In the second embodiment, it is an operation explanatory diagram when a parallel arc failure occurs in a branch system. In the second embodiment, it is an operation explanatory diagram after detecting the parallel arc failure of a branch system. In the second embodiment, it is an operation explanatory diagram when a parallel arc failure occurs in a main system. In the second embodiment, it is an operation explanatory diagram after detecting the parallel arc failure of the main trunk system. It is a block diagram of the arc failure detection system which concerns on 3rd Embodiment of this invention. It is a block diagram which shows the arc failure detection system of the prior invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a configuration diagram of an arc failure detection system according to the first embodiment of the present invention. In FIG. 1, the same parts as those in FIG. 16 are assigned the same numbers, and the differences from FIG. 16 will be mainly described below. Needless to say, the number of branch systems connected to the DC bus 40 is not limited to the illustrated example.

In this first embodiment, the backflow prevention diodes 2 and 3 are connected between the positive bus P of the main system and the current detection devices 21 and 22 of the branch systems A and B with the polarities shown in the drawings, respectively. Further, branch system side voltage detection devices 23 and 24 are connected to both ends of these diodes 2 and 3, respectively.

Next, the operation of this embodiment will be described with reference to FIGS. 2 to 5.
FIG. 2 is an operation explanatory diagram when a parallel arc failure occurs in the branch system. Here, the parallel arc failure means a failure in which an arc is generated between the positive and negative DC lines between the current detection devices 21 and 22 and the solar cell panels 4 and 5.

Now, when a parallel arc 31 is generated in the branch system A as shown in FIG. 2, the current output from the solar cell panel 4 returns to the solar cell panel 4 via the path a passing through the parallel arc 31, and thus moves to the main system side. Does not flow. Further, due to the action of the backflow prevention diode 2, no current flows from the sound branch system B to the branch system A.
That is, since the current in which the signal component peculiar to the arc failure is superimposed and the current from the branch system B do not flow in the current detection device 21 provided in the branch system A, the parallel arc is based on the current detection value by the current detection device 21. 31 cannot be detected. This also applies when a parallel arc failure occurs between the current detection device 22 of the branch system B and the solar cell panel 5.
In FIG. 2, c and d indicate the current path between the branch system B and PCS1.

On the other hand, the line voltage of the branch system A in which the parallel arc failure occurred drops to several tens of [V], which is the arc voltage of the parallel arc 31, and the line voltage of the main system (operating voltage of the solar cell panels 4 and 5). A potential difference is generated between the number 100 to 1,000 [V]).
This potential difference is measured by the voltage detection device 23 via the disconnecting switch 12 in the on state and the parallel arc 31. That is, the voltage detection device 23 detects the difference between the line voltage of the main system and the arc voltage due to the parallel arc 31.

3 (a) shows the case where a parallel arc 31 at time t ₁ is generated in the branch line A, is a characteristic diagram showing a voltage detected by the voltage detector 23, [Delta] V is the potential difference between before and after the parallel arc occurs .. Note that FIG. 3B is a voltage characteristic diagram of the sound system B, and the voltage detection value does not change before and after the generation of the parallel arc.

When the parallel arc failure does not occur and the voltage is sound, the voltage detected by the voltage detection device 23 of the branch system A is the voltage between the terminals of the backflow prevention diode 2, for example, about several tens of [mV].
On the other hand, when the parallel arc 31 is generated, as described above, the voltage detection device 23 detects the difference between the line voltage of the DC bus 40 and the arc voltage, and the value is several tens [V] to several. It becomes 100 [V]. Therefore, if a predetermined threshold value (branch system side threshold value in the claim) is set within the range of arc voltage <threshold value <line voltage of the main system for the voltage detected value by the voltage detection device 23, the parallel arc 31 Can be detected.

Next, FIG. 4 shows a protection operation when a parallel arc failure of the branch system A is detected, and FIG. 32 is a parallel arc after the arc is extinguished.
When the parallel arc is detected by the operation of the voltage detection device 23, the output current of the solar cell panel 4 flows through the path b passing through the short-circuit switch 14 by turning on the short-circuit switch 14 of the branch system A, and the parallel arc Is extinguished. Further, by turning off the disconnecting switch 12, the branch system A is separated from the DC bus 40, and the operation of the photovoltaic power generation system can be continued by the branch system B and other sound systems.

In this first embodiment, the series arc failure generated in the DC line on one side of the branch systems A and B is the vibration peculiar to the arc failure in the voltage detection value by the voltage detection device 23 or 24 as shown in FIG. 7 described later. It can be detected based on the inclusion of the component.
Further, in the parallel arc failure occurring between the positive and negative bus lines P and N of the main system, the voltage detection values of the voltage detection devices 23 and 24 of all the branch systems A and B include the vibration component peculiar to the arc failure, and , The voltage detection value by the main system side voltage detection device 25 is lower than a predetermined threshold value (main system side threshold in the claim) and can be detected based on the fact that the voltage detection value drops to the arc voltage equivalent value.
Further, the series arc failure generated on the bus on one side of the main system is detected based on the fact that the voltage detection values of the voltage detection devices 23 and 24 of all the branch systems A and B include the vibration component peculiar to the arc failure. It is possible.

Next, a second embodiment of the present invention will be described.
FIG. 5 is a configuration diagram of an arc failure detection system according to a second embodiment of the present invention. In FIG. 5, the same parts as those in the first embodiment of FIG. 1 are assigned the same numbers, and the differences from FIG. 1 will be mainly described below.

In this second embodiment, the shunt resistors 41 and 42 are connected in series to the backflow prevention diodes 2 and 3, respectively, and the branch system side voltage detection device is connected in parallel to the series circuit of the backflow prevention diode 2 and the shunt resistor 41. 23 is connected, and the branch system side voltage detection device 24 is connected in parallel to the series circuit of the backflow prevention diode 3 and the shunt resistor 42. The current detection devices 21 and 22 in FIG. 1 have been removed.

Next, the operation of this embodiment will be described with reference to FIGS. 6 to 15.
FIG. 6 is an operation explanatory view when a series arc 33 is generated between the shunt resistor 41 of the branch system A and the solar cell panel 4.
In this case, the current between the solar cell panel 4 and the PCS 1 flows to the main system via the series arc 33, the shunt resistor 41, the backflow prevention diode 2, and the disconnect switch 12 as shown by the paths e and f. .. A signal component peculiar to arc failure is superimposed on this current, and the voltage detection value by the voltage detection device 23 includes a vibration component as shown in FIG. 7A. Therefore, if this vibration component is detected, it is possible to detect that the series arc 33 is generated in the branch system A.

At this time, since the signal component by the series arc 33 is hardly superimposed on the current flowing through the paths c and d between the branch system B and the PCS 1, the voltage detection device 24 of the branch system B is shown in FIG. 7A. The vibration component is not detected, and the voltage detection value by the voltage detection device 24 is as shown in FIG. 7B. This also applies to other healthy strains not shown.
Further, even the voltage detection device 25 installed in the main system does not detect the vibration component due to the series arc 33 of the branch system A.
Therefore, the series arc failure generated in the branch system can be detected only by the voltage detection device in the branch system, and the branch system can be specified as the failure system.

FIG. 8 shows a protection operation when a series arc failure is detected, and FIG. 34 is a series arc after the arc is extinguished.
After detecting the series arc, the branch system A is separated from the DC bus 40 by turning off the disconnecting switch 12. As a result, the operation of the photovoltaic power generation system can be continued only by the other healthy systems including the branch system B in the state where the faulty system is removed.

Next, FIG. 9 is an operation explanatory diagram when a series arc failure occurs on the positive bus P of the main trunk system.
When healthy, the output current of the solar cell panels 4 and 5 is transferred to the PCS1 via the shunt resistors 41 and 42, the backflow prevention diodes 2 and 3, the disconnecting switches 12 and 13 of the main system, and the disconnecting switch 11 of the main system. It is being supplied. In this state, for example, when a series arc 35 is generated on the positive bus P of the main system, the current flowing through the branch systems A and B, in other words, the series circuit of the shunt resistor 41 and the backflow prevention diode 2 and the shunt resistor. A signal component (vibration component) peculiar to an arc failure is superimposed on the current flowing through the series circuit of the 42 and the backflow prevention diode 3.

Therefore, the above signal components are also superimposed on the voltage detection values by the voltage detection devices 23 and 24 of the branch systems A and B. Therefore, by paying attention to the voltage detection values by all the voltage detection devices 23 and 24, it is possible to detect that some kind of arc failure has occurred in the main system.
However, it is not possible to determine whether the arc failure generated in the main system is a series arc failure or a parallel arc failure only by the voltage detection values of the voltage detection devices 23 and 24 of the branch systems A and B.

Here, even if the series arc 35 is generated in the main system as shown in FIG. 9, the line voltage detection value of the main system does not change, but for example, the positive and negative bus lines P and N are short-circuited between the lines. When a parallel arc failure occurs, the line voltage drops to the value equivalent to the arc voltage.
Therefore, a predetermined threshold value (main system side threshold value in the claim) is provided for the line voltage detection value by the voltage detection device 25, and parallel in the main system based on the line voltage detection value falling below this threshold value. The occurrence of arc failure can be detected.

That is, when the signal components peculiar to the arc failure are detected by the voltage detection devices 23 and 24 of the branch systems A and B, it is determined that some arc failure has occurred in the main system, and the voltage detection device 25 of the main system When the line voltage detection value according to is equal to or more than the main system side threshold value, it may be determined as a series arc failure, and when it is less than the above threshold value, it may be determined as a parallel arc failure.

In large-scale equipment such as mega solar, the number of branch systems may increase and the amount of power generation may vary. Therefore, it is conceivable that the signal detected by the voltage detection device also varies, and the signal drops to the detection threshold value or less in a specific branch system. Therefore, when determining the type of arc failure that has occurred in the main system, when a signal component peculiar to the arc failure is detected by the voltage detection devices of a plurality of branch systems (for example, three or more systems), the main system It is conceivable to determine that the series arc 35 has occurred in.

FIG. 10 shows a protection operation when a series arc failure of the main trunk system is detected, and 36 is a series arc after the arc is extinguished.
When a series arc failure is detected in the main system, the disconnector switch 11 of the main system is turned off, or the disconnector switches 12 and 13 of all the branch systems A and B are turned off. In FIG. 10, all disconnecting switches 11, 12, and 13 are turned off in order to eliminate the failure.

Next, FIG. 11 shows the operation when the parallel arc 31 is generated in the branch system A.
Similar to the case of FIG. 2 described above, the output current of the solar cell panel 4 returns to the solar cell panel 4 by the path a passing through the parallel arc 31, and therefore does not flow to the main system side. Further, due to the action of the backflow prevention diode 2, no current flows from the branch system B to the branch system A.
Therefore, the voltage detection devices 23 and 24 of the branch systems A and B cannot detect the signal component peculiar to the arc failure.

In this case, as in FIGS. 2 and 3A, when the parallel arc 31 is generated, the voltage detection device 23 detects the difference between the line voltage of the main system and the arc voltage due to the parallel arc 31. The parallel arc 31 can be detected by providing a predetermined threshold value (branch system side threshold value) for the voltage detection value by the voltage detection device 23. This threshold value may be set within the range of, for example, arc voltage <threshold value <line voltage of the main system in the same manner as described above.

FIG. 12 shows a protection operation when a parallel arc failure in the branch system A is detected, and FIG. 32 is a parallel arc after the arc is extinguished.
Similar to FIG. 4, when the parallel arc failure is detected, the short-circuit switch 14 of the branch system A is turned on, so that the current from the solar cell panel 4 flows through the path b and the parallel arc is extinguished. Further, if the disconnect switch 12 is turned off, the branch system A is separated from the DC bus 40, and the operation of the photovoltaic power generation system can be continued by the branch system B and other sound systems.

FIG. 13 is an operation explanatory diagram when a parallel arc failure occurs between the positive and negative bus lines P and N of the main system.
When a parallel arc failure occurs in the main system, the output currents of the solar cell panels 4 and 5 return to the solar cell panels 4 and 5, respectively, by the paths g and h passing through the parallel arc 37 of the main system. Therefore, the signal components peculiar to the arc failure are superimposed on the output currents of the solar cell panels 4 and 5, and the line voltage of the main system drops to the value equivalent to the arc voltage.
Therefore, the parallel arcs are based on the fact that the voltage detection devices 23 and 24 of the branch systems A and B detect the signal components, and the voltage detection value by the voltage detection device 25 of the main system falls below a predetermined threshold value. The occurrence of 37 can be detected.

FIG. 14 shows a protection operation when a parallel arc failure of the main trunk system is detected, and 38 is a parallel arc after the arc is extinguished.
When a parallel arc failure is detected, the disconnecting switches 11, 12, and 13 of the main system and the branch systems A and B are all turned off to disconnect all the branch systems including the PCS1 and other branch systems from the main system. As a result, power is no longer supplied to the parallel arc 37 of FIG. 13 generated in the main system, and the parallel arc can be extinguished as shown by reference numeral 38 in FIG.

Next, FIG. 15 is a configuration diagram of an arc failure detection system according to a third embodiment of the present invention.
This embodiment corresponds to the one in which the shunt resistors 41 and 42 in the branching systems A and B of the second embodiment are removed. Also in this embodiment, a series arc failure and a parallel arc failure in the branch system and the main system can be detected by the same method as in the first and second embodiments.

According to the present invention, in a system in which one or more branch systems having a DC power generation facility and a backflow prevention diode are connected to the main system, such as a photovoltaic power generation system, a series arc failure or parallel occurrence occurs in the branch system or the main system. It can be applied when detecting an arc failure.

A, B: Branch system P: Positive bus N: Negative bus 1: Power conditioner (PCS)
2,3: Backflow prevention diode 4,5: Solar cell panel 11,12,13: Disconnector switch 14,15: Short circuit switch 21,22: Current detection device 23,24: Branch system side voltage detection device 25 : Main system side voltage detector 31, 37: Parallel arc 32, 38: Parallel arc (after extinguishing)
33, 35: Series arc 34, 36: Series arc (after extinguishing)
40: DC bus 41, 42: Shunt resistance 100: AC power supply system

Claims (10)

It is provided with a DC bus constituting the main system and one or more branch systems having a DC power generation facility connected between the positive bus and the negative bus of the DC bus.
In a system in which a backflow prevention element for blocking a current in a direction from the positive bus to the DC power generation facility is connected to the branch system .
Has a branch mains voltage detector for detecting a voltage across the front Symbol backflow prevention element,
When the voltage detection value of one of the branch systems by the branch system side voltage detection device exceeds a predetermined branch system side threshold value, a parallel arc failure generated between positive and negative DC lines in the branch system is detected. Arc failure detection system. It is provided with a DC bus constituting the main system and one or more branch systems having a DC power generation facility connected between the positive bus and the negative bus of the DC bus.
In a system in which a backflow prevention element for blocking a current in a direction from the positive bus to the DC power generation facility is connected to the branch system .
It has a branch system side voltage detection device that detects the voltage across the backflow prevention element.
When the voltage detection value by the branch system side voltage detection device installed in the branch system contains a vibration component peculiar to an arc failure, a series arc failure occurring on one DC line in the branch system is detected. An arc failure detection system characterized by this. It is provided with a DC bus constituting the main system and one or more branch systems having a DC power generation facility connected between the positive bus and the negative bus of the DC bus.
In a system in which a backflow prevention element for blocking a current in a direction from the positive bus to the DC power generation facility is connected to the branch system.
A main system side voltage detection device that detects the line voltage between the positive bus and the negative bus, and
A branch mains voltage detector for detecting a voltage across the backflow prevention element,
Have,
The voltage detection values by the branch system side voltage detection devices installed in all the branch systems include vibration components peculiar to arc failure, and the voltage detection values by the main system side voltage detection devices are on the predetermined main system side. An arc failure detection system characterized in that a parallel arc failure that occurs between positive and negative bus lines in the main system is detected when the voltage falls below a threshold value. It is provided with a DC bus constituting the main system and one or more branch systems having a DC power generation facility connected between the positive bus and the negative bus of the DC bus.
In a system in which a backflow prevention element for blocking a current in a direction from the positive bus to the DC power generation facility is connected to the branch system.
It has a branch system side voltage detection device that detects the voltage across the backflow prevention element.
Detecting a series arc failure that occurred on one bus in the main system when the voltage detection value by the branch system side voltage detection device installed in all the branch systems contains a vibration component peculiar to an arc failure. An arc failure detection system featuring. It is provided with a DC bus constituting the main system and one or more branch systems having a DC power generation facility connected between the positive bus and the negative bus of the DC bus.
In a system in which a backflow prevention element for blocking a current in a direction from the positive bus to the DC power generation facility is connected to the branch system.
A shunt resistor connected in series with the backflow prevention element,
A branch system side voltage detection device that detects the voltage across the series circuit of the backflow prevention element and the shunt resistor, and
Have,
When the voltage detection value of one of the branch systems by the branch system side voltage detection device exceeds a predetermined branch system side threshold value, a parallel arc failure generated between positive and negative DC lines in the branch system is detected. arc fault detection system that. It is provided with a DC bus constituting the main system and one or more branch systems having a DC power generation facility connected between the positive bus and the negative bus of the DC bus.
In a system in which a backflow prevention element for blocking a current in a direction from the positive bus to the DC power generation facility is connected to the branch system.
A shunt resistor connected in series with the backflow prevention element,
A branch system side voltage detection device that detects the voltage across the series circuit of the backflow prevention element and the shunt resistor, and
Have,
Sometimes included in the voltage values detected by the installed in one of the branch lines the branch mains voltage detecting device arcing faults peculiar vibration component, a series arc fault occurs on one side of the DC line in the branch line An arc failure detection system characterized by detection. It is provided with a DC bus constituting the main system and one or more branch systems having a DC power generation facility connected between the positive bus and the negative bus of the DC bus.
In a system in which a backflow prevention element for blocking a current in a direction from the positive bus to the DC power generation facility is connected to the branch system.
A main system side voltage detection device that detects the line voltage between the positive bus and the negative bus, and
A shunt resistor connected in series with the backflow prevention element,
A branch system side voltage detection device that detects the voltage across the series circuit of the backflow prevention element and the shunt resistor, and
Have,
All of the arc fault specific vibration component in the voltage values detected by the installed the branch mains voltage detecting apparatus to the branch line included, and the main trunk mains voltage detector voltage detection value is a predetermined main trunk mains by sometimes below the threshold, an arc fault detection system and detects the malfunction parallel arc occurs between the positive and negative busbars on the main trunk line. It is provided with a DC bus constituting the main system and one or more branch systems having a DC power generation facility connected between the positive bus and the negative bus of the DC bus.
In a system in which a backflow prevention element for blocking a current in a direction from the positive bus to the DC power generation facility is connected to the branch system.
A shunt resistor connected in series with the backflow prevention element,
A branch system side voltage detection device that detects the voltage across the series circuit of the backflow prevention element and the shunt resistor, and
Have,
All of the at the voltage value detected by the branch mains voltage detecting device installed in a branch line that includes arc fault inherent vibration component, a series arc fault occurs on one side of the bus in the main trunk line An arc failure detection system characterized by detection. Oite the arc fault detection system according to any one of claims 1-8,
The branch system
Characterized in that it have a, a short-circuit switch for short-circuiting and disconnecting a switch for opening and closing, between DC line positive and negative output side of the DC power plant between the DC power generation equipment and the DC bus Arc failure detection system. In the arc failure detection system according to any one of claims 1 to 9.
An arc failure detection system characterized in that the DC power generation facility is a photovoltaic power generation facility, and the DC bus is connected to an AC power supply system via a power conditioner.

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