JP3754898B2 - Collector box for photovoltaic power generation, photovoltaic power generation apparatus and control method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a photovoltaic power collection box, a photovoltaic power generation apparatus, and a control method therefor, and in particular, is configured from a solar cell string arranged in series on a roof of a building and the like, in which a plurality of solar cell panels are connected. It is suitable for a solar power generation device having a solar cell array.
[0002]
[Prior art]
In recent years, with an increase in electric power demand, a photovoltaic power generation system that can be connected to a commercial electric power system having a role of complementing a large-scale power plant has become widespread. However, at present, in order to operate a grid-connected solar power generation system, safety must always be strictly secured. Similarly, it is preferable to always ensure strict safety even when the power generation system is used independently without being connected to the commercial power system. In order to further spread the photovoltaic power generation system to ordinary households in the future, it is necessary to supply power stably and keep it in a safe state without making the user aware of such functions. A system with
[0003]
FIG. 7 is a diagram illustrating a configuration example of a photovoltaic power generation system. This system includes a solar cell array 101 that is a DC power source, a current collection box 102 that collects the output of the solar cell array 101, a power conditioner 103 that is a power converter, and a load 104. The power conditioner 103 is provided with an inverter 106 whose input / output is non-insulated and a relay 107 for connection protection.
[0004]
What is necessary is just to comprise suitably the output voltage of the solar cell array 101 so that the voltage required as a solar power generation system may be obtained. In a photovoltaic power generation system linked to a 3kW output, single-phase 200V for private homes, the input voltage (operating voltage) of the power conditioner 103 is considered in consideration of the conversion efficiency of the power conditioner 103 and the maximum voltage at the open circuit voltage. It is preferable that the solar cell array 101 is configured so as to be about 200V. In the configuration shown in FIG. 7, when an abnormality occurs in the solar cell array 101 or the electric circuit between the solar cell array 101 and the power conditioner 103, the operation of the inverter 106 is stopped to protect the interconnection. It operates to open the relay 107.
[0005]
Japanese Patent Publication No. 61-18423 discloses a configuration in which the output of the solar cell array 101 is short-circuited when the power conditioner 103 is stopped as shown in FIG. With the configuration of FIG. 8, the output voltage of the solar cell array 101 can be set to 0 V by closing the short-circuit switch 111 when the ground fault abnormality of the solar cell array 101 is detected.
[0006]
[Problems to be solved by the invention]
In the configuration shown in FIG. 7, even if an abnormality such as a ground fault occurs and the operation of the power conditioner 103 is stopped, the output voltage of the solar cell array 101 is equal to the number of solar cell strings (until the repairer repairs). The state where the open circuit voltage for the number of solar cell panels in series) is maintained.
[0007]
Although it is possible to configure a photovoltaic power generation system by previously reducing the output voltage of the solar cell string, in other words, by reducing the number of strings, the step-up ratio of the power conditioner 103 is large when connecting to a 200 V system. As a result, the conversion efficiency deteriorates. In addition, the configuration of FIG. 7 has a drawback that the operation of the entire photovoltaic power generation system must be stopped even when an abnormality occurs in one string. The configuration shown in FIG. 8 is similar in that the entire system must be stopped when an abnormality occurs.
[0008]
Further, when a ground fault occurs due to damage to the cable connecting the solar cell array 101 and the current collecting box 102, there is a problem that the short-circuit current continues to flow to the cable damaged portion and the damaged portion is overheated.
[0009]
The present invention is intended to solve the above-mentioned problems individually or collectively, and aims to ensure the safety of a photovoltaic power generation system without causing deterioration of conversion efficiency. Another object is to eliminate the need to stop the operation of the entire solar power generation system when a ground fault occurs in a part of the solar cell array. Furthermore, when the cable which connects a solar cell array and a current collection box is damaged severely, it aims at preventing the overheating of a damaged part.
The features and effects of the present invention will be described in more detail below with reference to the drawings.
[0010]
[Means for Solving the Problems]
In order to solve the above problems, the present invention provides a detector that outputs an abnormality detection signal when an abnormality of a solar cell string in which a plurality of solar cell panels are connected in series is detected, and a midway of the solar cell string. A photovoltaic power collection box is provided that includes at least one intermediate switch that is provided and transitions to an open state in response to an abnormality detection signal from the detector.
[0011]
The detector preferably detects at least a ground fault as an abnormality, has a string switch that can be separated for each solar cell string, and preferably opens the string switch by an abnormality detection signal of the detector. The intermediate switch can be opened later than the string switch, and further includes a delay unit that delays the abnormality detection signal for a predetermined time, and the abnormality detection signal is directly supplied to the string switch. The intermediate switch is preferably supplied via the delay device, and preferably includes an alarm device that issues an alarm when an abnormality detection signal is output from the detector.
[0012]
Further, the present invention has any one selected from a plurality of intermediate switches and disconnectors provided in the middle of a solar cell string in which a plurality of solar cell panels are connected in series. Either one may be a solar power collection box that can be opened and closed simultaneously.
[0013]
The present invention also provides a solar cell string in which a plurality of solar cell panels are connected in series, a detector that outputs an abnormality detection signal when a ground fault of the solar cell string is detected, and an open state by the abnormality detection signal. A photovoltaic power generation apparatus is proposed in which the at least one switch is provided, and the at least one switch is provided in the middle of the solar cell string. In the case of this solar power generation device, when there are a plurality of the at least one switch, it is desirable that they can be simultaneously opened and closed, and the detector and the at least one switch are separated from the solar cell string. It may be stored in a box.
[0014]
Further, the present invention provides a plurality of solar cell strings in which a plurality of solar cell panels are connected in series, a plurality of detectors that output an abnormality detection signal when the ground fault is detected for each of the solar cell strings, and the abnormality A first switch that transitions to an open state in response to a detection signal, the plurality of solar cell strings are connected in parallel, and the first switch is connected to each of the plurality of solar cell strings. We propose a solar power generation device installed on the way.
[0015]
In the case of this solar power generation device, it is preferable that the solar cell string includes a second switch for separating the solar cell string from other solar cell strings, and the second switch is preferably shifted to an open state by the abnormality detection signal. And a delay device for delaying the abnormality detection signal for a predetermined time, wherein the abnormality detection signal is directly supplied to the second switch and supplied to the first switch via the delay device. It is desirable. The plurality of detectors and the first switch are preferably stored in a current collection box separated from the solar cell string, and when there are a plurality of the first switches, they are simultaneously opened and closed. Preferably it is possible.
[0016]
Moreover, in any of the above solar power generation devices, it is preferable to include an alarm device that issues an alarm when an abnormality detection signal is output from the detector.
[0017]
In the above configuration, when the solar cell array is abnormal, by opening a switch provided in the middle of the abnormal string, the open voltage of the solar cell string in which the abnormality has occurred is lowered, and the safety of the installed building, or the failed solar cell It increases the safety of workers who repair strings.
[0018]
Further, the present invention relates to a method for controlling a photovoltaic power generation apparatus comprising: a solar cell string in which a plurality of solar cell panels are connected in series; and at least one switch provided in the middle of the solar cell string, When a ground fault of a solar cell string is detected, a method for controlling a photovoltaic power generation apparatus is proposed in which the at least one switch is shifted to an open state.
[0019]
Further, the present invention includes a plurality of solar cell strings in which a plurality of solar cell panels are connected in series, and at least one first switch, and the plurality of solar cell strings are connected in parallel. The first switch detects a ground fault for each of the solar cell strings in the solar power generation device control method provided in the middle of each of the plurality of solar cell strings. When a ground fault is detected, the control method of the solar power generation device which makes the said 1st switch provided in the middle of the solar cell string transition to an open state is proposed.
[0020]
When the ground fault of the solar cell string is detected, the solar cell string may further include a step of transitioning a second switch for disconnecting the solar cell string from the other solar cell strings to an open state. When the ground fault is detected, the second switch is immediately shifted to the open state, and the first switch is preferably shifted to the open state after a predetermined time.
[0021]
In addition, the present invention can execute a control method of a photovoltaic power generation apparatus having a solar cell string in which a plurality of solar cell panels are connected in series, and at least one switch provided in the middle of the solar cell string In this program, the computer detects a ground fault of the solar cell string, and when a ground fault of the solar cell string is detected, opens at least one switch provided in the middle of the solar cell string. It may be a program for causing the steps to transition to the state to be executed in this order.
[0022]
Further, the present invention includes a plurality of solar cell strings in which a plurality of solar cell panels are connected in series, and at least one first switch, wherein the plurality of solar cell strings are connected in parallel. The first switch is a program capable of executing a control method of the photovoltaic power generation apparatus provided in the middle of each of the plurality of solar cell strings, and is connected to the computer for each solar cell string. A step of detecting a fault and a step of transitioning the first switch provided in the middle of the solar cell string to an open state in this order when a ground fault of the solar cell string is detected It may be a program.
[0023]
DETAILED DESCRIPTION OF THE INVENTION
As an embodiment of the present invention, before opening and closing the intermediate switch described later, the solar cell string is disconnected from the photovoltaic power generation system in advance, and the intermediate switch is opened and closed with no current flowing through the intermediate switch. You may comprise. By comprising in this way, a switch with a low electric current interruption capability can be used for an intermediate switch.
[0024]
In addition, as an embodiment of the present invention, a solar cell string in which a plurality of solar cell panels are connected in series and a plurality of intermediate switches described later provided between the solar cell strings are provided, and the plurality of intermediate switches However, it is good also as the current collection box of the solar power generation device comprised so that opening and closing is possible simultaneously manually. In such a configuration, in the event of an abnormality in the solar cell array, by simultaneously opening a plurality of intermediate switches provided in the middle of the abnormal solar cell string, it is possible to prevent some of the intermediate switches from being forgotten and to secure the solar cell string. And it can be safely divided into substrings. In addition, when the intermediate switches are turned on, a plurality of intermediate switches can be closed at the same time, and forgetting to insert some of the intermediate switches can be prevented.
[0025]
【Example】
Example 1
Hereinafter, Example 1 of the present invention will be described with reference to FIGS. 1 and 2. FIG. 2 is a schematic diagram of a solar power generation system using the current collection box according to the first embodiment. FIG. 1 is a diagram showing in detail a location including a solar cell array 1 surrounded by a dotted line in FIG. 2 and a current collection box 2 employed in the first embodiment. The photovoltaic power generation system according to the first embodiment includes a solar cell array 1, a current collection box 2, a power conditioner 3, an outlet 4 for supplying power to a load, a power sale meter box 5, a switchboard 6 and the like. ing. Hereinafter, the components in FIGS. 1 and 2 will be described in order.
[0026]
<Main components>
Solar cell array 1
The solar cell array 1 is configured by connecting a plurality of solar cell strings 1-1, 1-2, 1-3, and 1-4 connected in parallel with a plurality of solar cell panels in series. As the solar cell panel, those using amorphous silicon, polycrystalline silicon, or crystalline silicon are preferably used for the photoelectric conversion portion. The number of solar cell panels in series may be appropriately configured so as to obtain a voltage necessary for a photovoltaic power generation system. Usually, when connecting to a 200V commercial power system in a system for a private house, The battery string is preferably configured to output a voltage of about 200V.
[0027]
Solar cell string 1-1 to 1-4
The solar cell array 1 is configured by parallel connection of four solar cell strings 1-1, 1-2, 1-3, and 1-4 having the same configuration. Each of the solar cell strings 1-1 to 1-4 is composed of four sets of substrings, each of which includes four panels, as will be described in detail later. It is configured by series connection. In FIG. 1, since the structure of the solar cell string 1-2 to 1-4 is the same as that of the solar cell string 1-1, illustration of the solar cell panels 1-16 is abbreviate | omitted.
[0028]
Current collection box 2
The outputs of the solar cell strings 1-1 to 1-4 constituting the solar cell array 1 are collected by the current collection box 2. The current collection box 2 is installed at a location where a user or an inspector can inspect. In the current collection box 2, there are an intermediate switch 2-1, a string switch 2-2, a ground fault detector 2-3, a backflow prevention diode 2-4, a main switch 2-5 and the like described below. It is stored.
[0029]
Intermediate switch 2-1
Each solar cell string is divided into a plurality of substrings, and an intermediate switch 2-1 as a first switch is arranged between the substrings. The intermediate switch 2-1 in the first embodiment has a remote controllable input terminal and uses a type that can be tripped by an external signal. The intermediate switch 2-1 can be opened from an external trip signal or manually, and is turned on manually. In addition, the intermediate switch 2-1 in Example 1 must use what has the capability to supply and interrupt | block the maximum electric current which a solar cell string can flow.
[0030]
String switch 2-2
A string switch 2-2 which is a second switch is provided for each of the solar cell strings 1-1 to 1-4. The string switch 2-2 has a remote controllable input terminal and uses a type that can be tripped by an external signal. The string switch 2-2 can be opened by an external trip signal or manually, and is turned on manually. The string switch 2-2 is installed in order to isolate the defective string from the circuit at the time of maintenance and inspection of the solar cell strings 1-1 to 1-4, or when some of the solar cell panels are defective. In addition, the string switch 2-2 in Example 1 must use what has the capability to energize and interrupt the maximum current that the solar cell string can flow.
[0031]
Ground fault anomaly detector 2-3
A ground fault abnormality detector 2-3 is provided for each of the solar cell strings 1-1 to 1-4. The ground fault abnormality detector 2-3 is a clamp-type current sensor clamped on two positive and negative cables, and detects the amount of difference current flowing in the two cables. These current sensors measure a current without cutting the electric wire and convert it into a voltage. In addition, as the ground fault abnormality detector 2-3 in Example 1, the thing of the type which outputs an abnormality detection signal if the difference current was more than a predetermined value was used.
[0032]
Backflow prevention diode 2-4
A backflow prevention diode 2-4 is provided for each of the solar cell strings 1-1 to 1-4. Solar cells almost never generate electricity in the shadow of buildings 7 and the like. Since the solar cell array 1 is configured as a parallel circuit of the solar cell strings 1-1 to 1-4, an output voltage mismatch occurs between the solar cell strings 1-1 to 1-4. When the value is equal to or greater than the predetermined value, current flows from the other strings into the shadowed string, and a current in the opposite direction flows. In order to prevent this reverse current, the backflow prevention diode 2-4 is installed for each of the solar cell strings 1-1 to 1-4.
[0033]
Main switch 2-5
The main switch 2-5 is inserted in the middle of the circuit to the power conditioner 3 after collecting the outputs of the solar cell strings 1-1 to 1-4. The main switch 2-5 is used when the power supply from the solar cell to the power conditioner 3 is cut off, such as when the power conditioner 3 is abnormal or inspected. In addition, it is necessary to use what can satisfy | fill the maximum voltage of the whole solar cell array 1, and can open / close a maximum electric current for the main switch 2-5.
[0034]
Inverter 3
The output of the solar cell array 1 is collected in the current collection box 2 and then guided to the power conditioner 3. The power conditioner 3 converts the DC power of the solar cell into AC power. The output of the power conditioner 3 is consumed by the load.
[0035]
load
In a system that performs grid interconnection, the load can be a combination of the commercial power grid 9 and other electrical loads. In Example 1, the load to which electric power is supplied via the outlet 4 is a combination of the commercial power system 9 and the electric load 8 in the building 7.
[0036]
<System connection>
Connection of the above-described components according to the first embodiment will be described with reference to the drawings.
The building 7 on which the solar power generation system according to the first embodiment is mounted receives power supply from the commercial power system 9 and performs power self-supply by the solar power generation system and reverse power flow to the commercial power system 9.
[0037]
The commercial power system 9 is connected to the electrical equipment in the building 7 via an electric path. An electricity meter box 5 is installed in the middle of the electric circuit and the building 7, and an electric power meter that integrates the amount of power supplied from the electric circuit to the building 7 is installed inside the electricity meter box 5 A power sale power meter that integrates the amount of power that flows backward from the photovoltaic system to the commercial power system 9 is connected in series.
[0038]
Furthermore, the switchboard 6 is installed in the building 7, and the electric circuit connected to the building 7 is to supply power to the load 8 via the lighting fixtures and outlets 4 of each part in the building 7 by the switchboard 6. Branch connected to indoor wiring. The distribution board 6 is provided with a main breaker for the purpose of separating the commercial power system 9 and the indoor wiring, and a branch breaker is installed in each branching electric circuit. The solar power generation system and the commercial power system 9 are connected via a solar power generation system interconnection breaker provided in the switchboard 6.
[0039]
Outputs of the solar cell strings 1-1 to 1-4 are collected by the current collection box 2, converted from direct current power to alternating current power by the power conditioner 3, and then connected to the switchboard 6.
[0040]
The output of the solar cell array 1 is consumed by the load 8 in the building 7. When the amount of power generated by the solar cell array 1 exceeds the amount of power used in the building 7, surplus power is sold to the commercial power system 9 via the power meter box 5.
On the contrary, when the power generation amount of the solar cell array 1 is lower than the power consumption amount in the building 7, the shortage power is purchased from the commercial power system 9 through the power meter box 5.
[0041]
<Solar cell panel>
As the solar cell panel in Example 1, an amorphous solar cell panel having the following characteristics was used. The characteristics per panel are 12V for maximum output operation, 4A for maximum output operation, and 48W nominal output. The open circuit voltage when the output is open is 15V. Sixteen solar battery panels were connected in series to form a solar battery string with a maximum output operating voltage of 192 V (output 768 W, open voltage 240 V). The solar cell strings 1-1 to 1-4 are arranged on the same roof surface of the building 7, and a solar power generation system having a maximum output of about 3 kW is configured.
[0042]
In addition, as shown in FIG. 1, one string is divided into four substrings and is composed of four solar cell panels of one substring. Then, both terminals of each substring are drawn into the current collection box 2. Further, an intermediate switch 2-1 is inserted between adjacent substrings of the same string.
[0043]
Further, both side terminals of the string are connected to the string switch 2-2 in the current collection box 2. Furthermore, the electric circuit of the string is connected to the current collecting point via the ground fault abnormality detector 2-3 and the backflow prevention diode 2-4.
[0044]
<Operation>
FIG. 3 is a circuit diagram showing the connection between the current collection box 2 and one string.
In FIG. 3, a solar cell string 1-1 includes a substring 1-11 configured by solar cell panels 1-4, a substring 1-12 configured by solar cell panels 5-8, and solar cell panels 9-12. And a substring 1-14 composed of solar cell panels 13-16, and these substrings are connected in series via the intermediate switch 2-1.
[0045]
In such a form, the photovoltaic power generation system including the current collection box 2 of Example 1 operates as follows.
In the configuration shown in FIG. 3, it is assumed that a ground fault occurs at any location of the string 1-1. When a ground fault occurs in the electric circuit of the string 1-1, the ground fault abnormality detector 2-3 in the current collection box 2 provided in the electric circuit of the string 1-1 outputs an abnormality detection signal. This abnormality detection signal is sent to the string switch 2-2 and the intermediate switch 2-1. When the string switch 2-2 and the intermediate switch 2-1 receive the abnormality detection signal from the ground fault abnormality detector 2-3, they are opened. At this time, among the four strings shown in FIG. 1, the three strings 1-2 to 1-4 continue to operate as usual, and the power conditioner 3 generates the power generation outputs of the three strings 1-2 to 1-4. Convert to AC power and continue to supply to the load.
[0046]
When the string switch 2-2 is opened, the open voltage of the entire string 1-1 becomes 240V. However, since the intermediate switch 2-1 is also opened at the same time, the open voltage is 60V of each substring. It becomes possible to suppress to.
[0047]
The abnormality detection signal of the ground fault abnormality detector 2-3 is also sent to an alarm device (notifier) 2-6 that is provided in the current collection box 2 and generates an alarm. The alarm device 2-6 is for notifying the user that a ground fault has occurred and the solar cell string is disconnected from the electric circuit. The alarm device 2-6 need not be provided for each solar cell string, and may be provided for the solar cell array 1. The user recognizes the occurrence of the ground fault by the alarm of the alarm device 2-6, and requests the installer of the photovoltaic power generation system or the contractor to repair the ground fault location. Even if a ground fault occurs on the roof surface, the open circuit voltage of the string that caused the ground fault is suppressed to a low voltage by opening the intermediate switch 2-1, so that the worker can work safely. It can be carried out. After repairing the ground fault, the operator manually closes the string switch 2-2 and the intermediate switch 2-1 of the string in which the ground fault has occurred, and restarts the operation of the stopped string.
[0048]
In Example 1, although the example which reduces the open circuit voltage 240V of a string to 60V was shown, what is necessary is just to set the voltage to reduce suitably according to the use environment and the intended purpose.
[0049]
If a large number of intermediate switches 2-1 are provided, the open voltage of the substring can be further reduced. However, in consideration of cost, installation space, etc., the open voltage of the substring is set to 60 V in the first embodiment. did.
[0050]
Further, in Example 1, the solar cell string is equally divided into four to form the substring. However, the portion to be divided may be selected for the convenience of wiring, and only the maximum open voltage of the substring needs to be noted. .
[0051]
In the first embodiment, the ground fault abnormality detector 2-3 is provided in the current collection box 2, and the intermediate switch 2-1 and the string switch 2-2 are opened by the output. The electric box 2 may not have the ground fault abnormality detector 2-3 and may be configured to open the intermediate switch 2-1 and the string switch 2-2 in accordance with the abnormality detection signal from the power conditioner 3. . However, in this case, since it is not known in which string of the plurality of strings the ground fault has occurred, the intermediate switches 2-1 and string switches 2-2 of all the strings must be opened, The power generation of the entire system must be stopped.
[0052]
(Example 2)
Hereinafter, the solar power generation system of Example 2 which concerns on this invention is demonstrated. Note that the same reference numerals in the second embodiment denote the same parts as in the first embodiment, and a detailed description thereof will be omitted.
[0053]
<Configuration>
FIG. 4 is a diagram showing the connection between the current collection box 2 and the solar cell string 1-1 in the second embodiment.
In the configuration of the first embodiment, a switch having a current switching capacity equivalent to that of the string switch 2-2 is used as the intermediate switch 2-1. This is because when an abnormality detection signal from the ground fault abnormality detector 2-3 is generated, it is sent to the string switch 2-2 and the intermediate switch 2-1 at the same time, and these switches are opened at the same time. . On the other hand, in the current collection box 2 according to the second embodiment, the signal delay unit 2-7 is provided, and the intermediate switch 2-1 is opened after a predetermined time after the string switch 2-2 is opened. Therefore, a switch having a low current switching capacity can be used as the intermediate switch 2-1.
[0054]
Since the intermediate switch 2-1 in the second embodiment is always opened in a state where the string switch 2-2 is opened, a switch having a low current interrupting capability such as a disconnecting switch can be used. However, the current-carrying capacity is required to satisfy the maximum current that can flow through one string. In addition, it is preferable that the closing is performed in the order of the intermediate switch 2-1 and the string switch 2-2.
[0055]
A signal delay unit 2-7 that outputs an abnormality detection signal after a predetermined time is provided between the ground fault abnormality detector 2-3 and the intermediate switch 2-1. The signal delay unit 2-7 may be a delay unit such as a timer, a DIP switch and a counter that can be set, or a CR (combination of a capacitor and a resistor) is used to fix the delay time. It doesn't matter.
[0056]
<Operation>
The photovoltaic power generation system according to Example 2 operates as follows. In the configuration shown in FIG. 4, it is assumed that a ground fault occurs at any location of the solar cell string 1-1.
[0057]
When a ground fault occurs in the electric path of the solar cell string 1-1, the ground fault abnormality detector 2-3 provided in the solar cell string 1-1 outputs an abnormality detection signal, and this signal is the string switch 2-2. To the signal delay unit 2-7. When the string switch 2-2 receives the output from the ground fault abnormality detector 2-3, the string switch 2-2 is opened. On the other hand, the signal delay unit 2-7 outputs the abnormality detection signal about 1 second after the abnormality detection signal is input. Therefore, the intermediate switch 2-1 is opened when receiving the abnormality detection signal from the signal delay unit 2-7 about one second after the abnormality detection signal is output.
[0058]
Thus, by operating the intermediate switch 2-1 with a time difference after opening the string switch 2-2, the intermediate switch 2-1 can be opened in a state where no current flows. Become.
[0059]
At this time, the other solar cell strings 1-2 to 1-4 in which no ground fault has occurred continue to operate, and the power conditioner 3 continues to convert their power generation output to AC power and supply it to the load.
[0060]
In addition, the open circuit voltage of the solar cell string 1-1 in which the ground fault has occurred becomes the open circuit voltage of the entire string when the string switch 2-2 is opened, but is approximately the set value of the signal delay unit 2-7. Since the intermediate switch 2-1 is also opened after 1 second, the open voltage of the string can be suppressed to a low open voltage of the substring.
[0061]
Moreover, also in Example 2, it is also possible to take the structure which provided the alarm device (alarm device) 2-6 similarly to Example 1. FIG. In the second embodiment, when the abnormality disappears (the ground fault is eliminated) and the disconnected string is connected to the system again, before the string switch 2-2 is turned on, the intermediate switch is turned off in a state where no current flows. 2-1 needs to be input.
[0062]
Example 3
Hereinafter, the solar power generation system of Example 3 which concerns on this invention is demonstrated. Note that the same reference numerals in the third embodiment denote the same parts as in the first embodiment, and a detailed description thereof will be omitted.
[0063]
<Configuration>
FIG. 5 is a connection diagram of the intermediate switch 2-1 in the current collection box 2 of the third embodiment, and FIG. 6 is a connection diagram of the entire current collection box 2 according to the third embodiment. The current collection box 2 of Example 3 has a plurality of intermediate switches 2-1 provided in the middle of the solar cell strings 1-1 to 1-4, and these intermediate switches 2-1 are manually or automatically. It can be opened and closed at the same time.
[0064]
The intermediate switch 2-1 in the third embodiment also serves as a string switch 2-2 that separates individual strings from the system. The intermediate switch 2-1 in the third embodiment is configured such that a plurality of switches are simultaneously opened and closed with the same lever.
[0065]
The method of opening / closing the intermediate switch 2-1 may be either manually opened / closed or automatically / manually opened / closed, but in the third embodiment, it can be operated only manually.
[0066]
When the intermediate switch 2-1 is operated only when the main switch 2-5 is opened due to an interlock, an operation instruction, etc., the ability to pass the maximum current of the string is necessary, but the maximum current is cut off. The ability to do is not necessary. However, if the main switch 2-5 is turned on, that is, if the intermediate switch 2-1 is operated in a state where current is flowing, the maximum current that can be passed through the solar cell string is turned on and off. You must use the ability to do.
[0067]
<Operation>
The photovoltaic power generation system including the current collection box 2 according to the third embodiment operates as follows.
In the intermediate switch 2-1 in FIG. 5, five switches can be opened / closed simultaneously by the lever 2-8. When the intermediate switch 2-1 is opened by the lever 2-8, the solar cell string 1-1 is Are connected so as to be disconnected in substring units at the same time as being disconnected from the system.
[0068]
By adopting such a configuration, in Example 3, by operating the lever 2-8 of the intermediate switch 2-1, the solar cell string in which an abnormality has occurred is disconnected from the system and disconnected from the system. Further, it is possible to simultaneously reduce the open voltage of the solar cell string to a safe voltage. In this way, when the solar cell array is abnormal, by opening the intermediate switch 2-1 provided in the middle of the abnormal solar cell string, the solar cell string is divided into substrings. Therefore, problems such as forgetting to cut easily do not easily occur, and the solar cell string can be divided into substrings reliably and securely. Also, when the intermediate switch 2-1 is turned on, problems such as closing a plurality of switches simultaneously and forgetting to turn on some of the switches are unlikely to occur.
[0069]
Thus, also in Example 3, as in Example 1 and Example 2, it becomes possible to divide the open voltage of the solar cell string separated from the system into safe voltage values.
[0070]
In the present invention, the above-described configuration may be realized by a computer. Specifically, the step of detecting a ground fault of the solar cell string and the solar cell when the ground fault of the solar cell string is detected. The step of transitioning the switch provided in the middle of the string to the open state may be realized by a program executed by a computer in this order.
[0071]
【The invention's effect】
The present invention has the following effects.
(1) By providing the intermediate switch in the middle of the solar cell string, the intermediate switch of the solar cell string in which an abnormality has occurred can be opened, and the open voltage of the solar cell string can be lowered.
(2) The intermediate switch can reduce the open-circuit voltage without flowing current to the solar cell string in which an abnormality has occurred. Therefore, even when a cable or the like is severely damaged and a ground fault occurs, the short-circuit current can be reduced. It does not continue to flow into the damaged part and can prevent overheating of the damaged part.
(3) Since only the solar cell string in which an abnormality has occurred can be separated from the photovoltaic power generation system by the string switch, normal operation of the solar cell string can be continued.
(4) Opening the string switch first when shutting off and opening the intermediate switch with a delay makes it possible to reduce the current that can be opened and closed by the intermediate switch, making the intermediate switch inexpensive and compact Can be.
(5) When installing the solar cell array, when connecting the cable connecting the solar cell array and the current collector box to the current collector box, if the intermediate switch is opened, the open voltage of the solar cell string will be Connection is possible in a low state, and it is not necessary to perform the connection work at night or to cover the solar cell with a light-shielding sheet, making the work safe and easy.
(6) By simultaneously opening a plurality of intermediate switches provided in the middle of a solar cell string in which an abnormality has occurred, it is possible to prevent some of the intermediate switches from being forgotten and to ensure that the solar cell string in which an abnormality has occurred is securely and safely Can be divided into substrings. In addition, even when a plurality of intermediate switches are turned on, forgetting to insert some of the intermediate switches can be prevented by simultaneously closing the plurality of intermediate switches.
[Brief description of the drawings]
1 is a diagram showing a solar cell array and a current collection box according to Example 1. FIG.
FIG. 2 is a diagram showing a solar power generation system employing the solar cell array and the current collection box shown in FIG. 1, and a building in which the solar power generation system is installed.
FIG. 3 is a circuit diagram illustrating connection between the current collection box and one string according to the first embodiment.
4 is a circuit diagram showing a connection between a current collecting box and one string according to Embodiment 2. FIG.
FIG. 5 is a diagram illustrating connection of intermediate switches in the current collection box according to the third embodiment.
FIG. 6 is a connection diagram of the entire current collection box according to the third embodiment.
FIG. 7 is a diagram illustrating a configuration example of a solar power generation system.
FIG. 8 is a diagram showing another configuration example of the solar power generation system.
[Explanation of symbols]
1: Solar cell array, 1-1, 1-2, 1-3, 1-4: Solar cell string, 1-11, 1-12, 1-13, 1-14: Substring, 2: Current collector box 2-1: Intermediate switch (first switch), 2-2: String switch (second switch), 2-3: Ground fault abnormality detector, 2-4: Backflow prevention diode, 2 -5: Main switch, 2-6: Alarm (notifier), 2-7: Signal delay, 2-8: Lever, 3: Power conditioner, 4: Outlet, 5: Electricity meter box, 6 : Switchboard, 7: building, 9: commercial power system, 101: solar cell array, 102: current collection box, 103: power conditioner, 104: load, 106: inverter, 107: interconnection protection relay, 111: short circuit Switch.

Claims (22)

A detector that outputs an abnormality detection signal when an abnormality is detected in a solar cell string in which a plurality of solar cell panels are connected in series, and an open state that is provided in the middle of the solar cell string by an abnormality detection signal from the detector A collector box for photovoltaic power generation, comprising at least one intermediate switch for transition. The collector box for photovoltaic power generation according to claim 1, wherein the detector detects at least a ground fault as an abnormality. The solar cell current collector according to claim 1, further comprising a string switch that can be separated for each solar cell string, wherein the string switch is also opened by an abnormality detection signal of the detector. box. 4. The solar power collection box according to claim 3, wherein the intermediate switch opens after the string switch.
A collection box for solar power generation. The apparatus further comprises a delay device that delays the abnormality detection signal for a predetermined time, and the abnormality detection signal is directly supplied to the string switch, and is supplied to the intermediate switch through the delay device. The collector box for photovoltaic power generation according to claim 3 or 4. The solar power collection box according to any one of claims 1 to 5, further comprising an alarm device that issues an alarm when an abnormality detection signal is output from the detector. It has either one selected from a plurality of intermediate switches or disconnectors provided in the middle of a solar cell string in which a plurality of solar cell panels are connected in series, and either one of them selected is opened and closed simultaneously A solar power collection box characterized by being capable. A solar cell string in which a plurality of solar cell panels are connected in series, a detector that outputs an abnormality detection signal when a ground fault of the solar cell string is detected, and at least one open / close that transitions to an open state by the abnormality detection signal A solar power generator, wherein the at least one switch is provided in the middle of the solar cell string. The solar power generation device according to claim 8, wherein when there are a plurality of the at least one switch, they can be opened and closed simultaneously. The solar power generation device according to claim 8 or 9, wherein the detector and at least one switch are stored in a current collection box separated from the solar cell string. A plurality of solar cell strings in which a plurality of solar cell panels are connected in series, a plurality of detectors that output an abnormality detection signal when a ground fault is detected for each solar cell string, and an open state by the abnormality detection signal And a plurality of solar cell strings are connected in parallel, and the first switch is provided in the middle of each of the plurality of solar cell strings. A solar power generation device characterized by that. 12. The switch according to claim 11, further comprising a second switch for separating the solar cell string from another solar cell string, wherein the second switch is shifted to an open state by the abnormality detection signal. Solar power generator. A delay unit for delaying the abnormality detection signal for a predetermined time; the abnormality detection signal is directly supplied to the second switch; and the first switch is supplied via the delay unit. The solar power generation device according to claim 12. 14. The sun according to claim 11, wherein the plurality of detectors and the at least one first switch are stored in a current collection box separated from the solar cell string. Photovoltaic generator. The solar power generation device according to claim 11, wherein when there are a plurality of the at least one first switch, they can be simultaneously opened and closed. The solar power generation device according to any one of claims 8 to 15, further comprising an alarm device that issues an alarm when an abnormality detection signal is output from the detector. In a control method of a solar power generation apparatus having a solar cell string in which a plurality of solar cell panels are connected in series and at least one switch provided in the middle of the solar cell string,
When the ground fault of the said solar cell string is detected, the said at least 1 switch is changed to an open state, The control method of the solar power generation device characterized by the above-mentioned. A plurality of solar cell strings connected in series, and at least one first switch; wherein the plurality of solar cell strings are connected in parallel; In the control method of the photovoltaic power generation apparatus provided in the middle of each of the plurality of solar cell strings, the switch is configured to detect a ground fault for each solar cell string, and to detect a ground fault of the solar cell string. And a step of transitioning the first switch provided in the middle of the solar cell string to an open state when detected. The method further comprises a step of transitioning a second switch for separating the solar cell string from another solar cell string to an open state when a ground fault of the solar cell string is detected. Or the control method of the solar power generation device of 18. The second switch is immediately shifted to an open state when a ground fault of the solar cell string is detected, and the first switch is shifted to an open state after a predetermined time. The control method of the solar power generation device of 19. In a program capable of executing a control method of a solar power generation device having a solar cell string in which a plurality of solar cell panels are connected in series and at least one switch provided in the middle of the solar cell string, Detecting a ground fault of the solar cell string; transitioning at least one switch provided in the middle of the solar cell string to an open state when a ground fault of the solar cell string is detected; A program to execute the programs in this order. A plurality of solar cell strings connected in series, and at least one first switch; wherein the plurality of solar cell strings are connected in parallel; In the program that can execute the control method of the photovoltaic power generation device provided in the middle of each of the plurality of solar cell strings,
The computer detects a ground fault for each of the solar cell strings, and when a ground fault of the solar cell string is detected, opens the first switch provided in the middle of the solar cell string. A program for executing the steps of transition to the state in this order.

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