JP2015186286A - Output control apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an output cut-off apparatus capable of quickly cutting off outputs of solar cell modules when abnormality is generated in a facility provided with solar panels, while suppressing cost increase.SOLUTION: An output control apparatus 1 includes: switch sections 10 each of which is connected in series to one connection terminal 81A out of a pair of connection terminals 81 included in each solar cell module 80 and switches a connection state between the one connection terminal 81A and a connection conductor to which an output of the solar cell module 80 is transmitted in order to control an output of a solar panel 100 including strings 90 each configured by connecting a plurality of solar cell modules 80 in series; an information acquisition unit 20 for acquiring abnormal state indication information indicating that a state of a facility in which the solar cell modules 80 are arranged becomes abnormal; and a control unit 30 for turning a connection state of the switch sections 10 to an open state when the state of the facility becomes abnormal on the basis of the abnormal state indication information.

Description

  The present invention relates to an output control device that controls the output of a solar panel including a plurality of strings in which a plurality of solar cell modules are connected in series.

  Conventionally, power generation using a solar panel has been performed. The solar panel is configured by connecting solar cells in series and parallel to form a solar cell module, and further connecting in parallel a string in which the solar cell modules are connected in series. A direct current voltage of several hundred volts is output from each string of solar panels. For example, when a fire occurs in a facility provided with a solar panel, it is conceivable that the covering of the cable connecting the solar cell modules to each other melts and the conductor is exposed. On the other hand, the solar panel generates electricity using the fire in the fire as a light source at night and at night. For this reason, if water for extinguishing a fire is sprinkled on an exposed conductor regardless of whether it is day or night, there is a risk that a person who performs a fire extinguishing operation or a rescue operation through this water may receive an electric shock. As technologies that can be used to prevent such an electric shock, there are technologies described in Patent Documents 1 and 2 that are cited below.

  The monitoring system described in Patent Document 1 includes a string configured by a plurality of solar cell panels and a monitoring module that monitors the operating state of the solar cell panel. The monitoring module controls the output of each string in order to operate the solar panel efficiently. Moreover, the solar power generation system described in Patent Document 2 includes a solar power generation module provided with a solar cell group and an open / close matching unit having an open / close unit at the output end of the solar cell group. The opening / closing unit is controlled according to the voltage value of the output terminal of the photovoltaic power generation module, and as a result, the output of the photovoltaic power generation module is shut off.

Special table 2010-512139 gazette JP 2013-252046 A

  According to the technique described in Patent Document 1, for example, when there is an abnormality in the solar cell panel, it is considered that the monitoring module can reduce the output of the solar cell panel. Since it is configured, it causes an increase in cost. In addition, the dedicated controller communicates with the equipment provided in the solar panel to control the operating state of the solar panel, so that it can be applied to existing equipment where the solar panel is installed. Equipment also has to be attached, which causes further cost increase. In addition, if a cable used for communication between the dedicated controller and the solar cell panel is melted down by a fire, the output of the solar cell panel cannot be controlled, and the state where the output is reduced may not be maintained.

  In the technology described in Patent Document 2, the open / close unit is controlled by using the output voltage of the photovoltaic power generation module as a trigger, and the output of the photovoltaic power generation module is shut off. The output from the photovoltaic module cannot be cut off immediately. Also, if the voltage at the output end of the photovoltaic module does not increase even if a fire breaks out, the output from the photovoltaic module will not be cut off, so the person performing fire fighting and rescue activities will be cut off There is a possibility of electric shock.

  In view of the above problems, an object of the present invention is to provide an output shut-off device that quickly cuts off the output of a solar cell module when an abnormality occurs in a facility provided with a solar panel while suppressing an increase in cost. It is in.

  In order to achieve the above object, a characteristic configuration of an output blocking device according to the present invention is provided in the solar cell module in order to control the output of a solar panel including a string in which a plurality of solar cell modules are connected in series. A switch unit that is connected in series to one of the pair of connection terminals, and that switches a connection state between the one connection terminal and a connection conductor to which an output of the solar cell module is transmitted, and the solar cell module An information acquisition unit that acquires abnormal state explicit information indicating that the state of the arranged facility is abnormal, and connection of the switch unit when the state of the facility becomes abnormal based on the abnormal state explicit information And a control unit for opening the state.

  If it is set as such a characteristic structure, it can be made into an open state by using as a trigger that abnormality occurred in the facility in which the solar panel was provided. For this reason, since the output of a solar cell module can be interrupted when an abnormality occurs in the facility, the output voltage of the string can be reduced immediately after the occurrence of the abnormality. Therefore, it is possible to prevent an unexpected electric shock accident in fire fighting and rescue activities when an abnormality occurs in the facility.

  In addition, when the state of the facility is not abnormal, the control unit transmits a control signal to the switch unit to close the connection state of the switch unit, and when the state of the facility becomes abnormal, the control signal It is preferable that the transmission state of the switch unit is stopped and the connection state of the switch unit is opened.

  With such a configuration, it is possible to transmit a control signal under circumstances where there is no abnormality, and stop transmission of the control signal when an abnormality occurs. Therefore, it is possible to automatically shut off the output of the solar cell module in accordance with the stop of energization to the control unit at the time of abnormality.

  The abnormal state clarification information is preferably information that clearly indicates at least one of the occurrence of a fire and the occurrence of flood in the facility.

  With such a configuration, the output of the solar cell module can be shut off when a fire or water damage occurs in a facility provided with the solar cell module. Therefore, it is possible to prevent an electric shock accident through the water of a person who performs fire fighting and rescue activities in the event of a fire or flood.

  In addition, it is preferable that the switch unit is provided on the one connection terminal of each of the plurality of solar cell modules.

  With such a configuration, each of the plurality of solar cell modules originally connected in series can be separated from each other when an abnormality occurs in the facility. Therefore, the voltage generated at each part of the string when an abnormality occurs can be maintained at the minimum value.

It is the figure which showed typically the structure of the solar energy power generation system provided with the output control apparatus. It is the figure which showed the structure of the switch part. It is a time chart which shows a process to an output control apparatus. It is the figure which showed the structure of the switch part which concerns on other embodiment. It is an example of arrangement of a switch part concerning other embodiments. It is the figure which showed the structure of the switch part for high voltage | pressure which concerns on other embodiment. It is the figure which showed the structure of the switch part for low voltage | pressure which concerns on other embodiment. It is a time chart which shows a process to the output control apparatus which concerns on other embodiment.

  The output control device according to the present invention has a function of blocking the output of the solar cell module when an abnormality occurs in a facility provided with a solar panel. Hereinafter, the output control apparatus 1 of this embodiment is demonstrated using drawing. FIG. 1 is a schematic diagram showing the configuration of the output control device 1 according to this embodiment.

  The output control device 1 controls the output of the solar panel 100 including a string 90 in which a plurality of solar cell modules 80 are connected in series. As shown in FIG. 1, the solar panel 100 forms a solar cell module 80 by connecting solar cells 70 in series and parallel, and a string 90 configured by connecting the solar cell modules 80 in series is connected in parallel. Connected and configured. Each output of the string 90 is input to the connection box 200, and the output of the connection box 200 is input to the current collection box 300. Since the output of each string 90 collected in the current collection box 300 is DC power, it is converted by the power conditioner 400 into AC power that can be used by electrical appliances, electrical equipment, and the like. In addition, the output control apparatus 1 can also control the output of the solar panel 100 including one string 90 in addition to the solar panel 100 in which a plurality of strings 90 are connected in parallel.

  The output control device 1 is configured to include each functional unit of the switch unit 10, the information acquisition unit 20, and the control unit 30. In particular, in the information acquisition unit 20 and the control unit 30, the above-described functional units for performing various processes for controlling the output of the solar panel 100 using the CPU as a core member are constructed by hardware and / or software.

  The switch unit 10 is connected in series to one connection terminal 81 </ b> A of the pair of connection terminals 81 included in the solar cell module 80. The solar cell module 80 is provided with a pair of positive and negative connection terminals 81, and generated DC power is output from one connection terminal 81 </ b> A of the pair of connection terminals 81.

  In this embodiment, the switch part 10 is provided in the connection terminal 81A which each of the some solar cell module 80 has. One connection terminal 81 </ b> A is connected to the other connection terminal 81 </ b> B of the solar cell module 80 connected in series via the switch unit 10. However, among the solar cell modules 80 connected in series, the other connection terminal 81B of the most upstream (low voltage side) solar cell module 80 is grounded, and one of the most downstream (high voltage side) solar cell modules 80 is grounded. The connection terminal 81A is connected to the connection box 200. In the present embodiment, the switch unit 10 connected to one connection terminal 81 </ b> A of the downstream (high voltage side) solar cell module 80 is built in the connection box 200.

  In the present embodiment, the switch unit 10 includes a semiconductor switch such as a MOS-FET (metal-oxide-semiconductor field-effect transistor) or a bipolar transistor. In the present embodiment, an example in which the switch unit 10 includes an N-type MOS-FET (hereinafter referred to as “MOS-FET”) 11 will be described.

  FIG. 2 shows the switch unit 10 according to the present embodiment. The switch unit 10 includes a MOS-FET 11, a state maintaining unit 12, and a driver 19. The drain terminal of the MOS-FET 11 is connected to the connection terminal 81A described above, and the source terminal is connected to the connection terminal 81B or the connection terminal 201 of another solar cell module 80. Further, the gate terminal is connected to a control unit 30 described later via a resistor R and a driver 19 constituting the state maintaining unit 12. In addition, one terminal of the capacitor C constituting the state maintaining unit 12 is connected to the input stage of the driver 19, and the other terminal of the capacitor C is grounded. As a result, when a control signal is transmitted from the control unit 30, the capacitor C is charged through the resistor R, and the voltage across the capacitor C exceeds the operating threshold value of the MOS-FET 11. The MOS-FET 11 is closed. Since the voltage between the terminals of the capacitor C rises according to the saturation curve, the MOS-FET 11 gradually shifts from the open state to the closed state even when the rise of the control signal is steep (rise time is about several tens of microseconds). Can do. Therefore, the inrush current when the MOS-FET 11 is in the closed state can be reduced.

  Further, when the transmission of the control signal from the control unit 30 is stopped, the charge of the capacitor C is discharged through the resistor R, and the voltage between the terminals of the capacitor C becomes less than the operating threshold value of the MOS-FET 11. Then, the MOS-FET 11 is opened. Although the voltage between the terminals of the capacitor C decreases exponentially, even when the control signal falls, the closed state of the MOS-FET 11 can be maintained for a time preset by the capacitor C and the resistor R. In this way, the capacitor C and the resistor R maintain the open state for a preset time from when the instruction to transfer to the open state (control signal transmission) is received from the control unit 30 until the closed state, It functions as the state maintaining unit 12 that maintains the closed state for a preset time from when the control unit 30 issues an instruction to shift to the closed state (stop of transmission of control signal) until the control unit 30 enters the open state. Note that the driver 19 may be omitted when the control signal has high drive capability for driving the MOS-FET 11.

  Thus, the switch part 10 switches the connection state of one connection terminal 81A of the solar cell module 80 and the connection conductor to which the output of the solar cell module 80 is transmitted according to the control signal. The connection conductor corresponds to the connection terminal 81 </ b> B of another solar cell module 80 directly connected to the solar cell module 80 or the connection terminal 201 of the connection box 200. The connection state refers to the operation state of the switch unit 10, and specifically refers to whether the MOS-FET 11 is closed or open. Therefore, the MOS-FET 11 controls the connection terminal 81 </ b> A of the solar cell module 80 and the connection terminal 81 </ b> B of another solar cell module 80 connected in series to the solar cell module 80 or the connection terminal 201 of the connection box 200. Is switched to a conductive state (closed state) or a non-conductive state (open state) in accordance with a control signal from.

  The information acquisition unit 20 acquires abnormal state clarification information indicating that the state of the facility where the solar cell module 80 is disposed is abnormal. In this embodiment, the facility in which the solar cell module 80 is disposed corresponds to a building, a solar power plant, or the like in which the solar cell module 80 is disposed. The state of the facility becoming abnormal means that the facility is in a state where it is not possible to continue the power generation by the solar panel 100. Specifically, it means that a disaster has occurred in a facility where a fire has occurred in the facility or at least part of the facility has been submerged. The occurrence of such a disaster can be detected by, for example, a fire alarm if it is a fire, and can be detected by a water level detector if it is submerged. For this reason, in this embodiment, the abnormal state clarification information corresponds to information that clearly indicates at least one of the occurrence of a fire and the occurrence of flood in the facility. Such abnormal state clarification information is acquired by the information acquisition unit 20 from a detection unit that detects the occurrence of a disaster, such as a fire alarm or a water level detector. When acquiring the abnormal state explicit information, the information acquisition unit 20 transmits a signal indicating that the abnormal state explicit information has been acquired to the control unit 30 described later.

  Based on the abnormal state explicit information, the control unit 30 opens the connection state of the switch unit 10 when the facility state becomes abnormal. The abnormal state clarification information is transmitted from the information acquisition unit 20 described above. In this embodiment, the time when the state of the facility becomes abnormal means the time when a fire or flooding occurs in a facility such as a building or a solar power plant equipped with the solar panel 100. . Therefore, the control unit 30 opens the MOS-FET 11 when a fire or water damage occurs in the facility.

  Here, in this embodiment, when the state of the facility is not abnormal, the control unit 30 transmits a control signal to the switch unit 10 to close the connection state of the switch unit 10 and the state of the facility becomes abnormal. Sometimes the transmission of the control signal is stopped and the connection state of the switch unit 10 is opened. As described above, in this embodiment, the MOS-FET 11 is an N-type MOS-FET. Therefore, when the state of the facility provided with the solar panel 100 is not abnormal, a signal having a voltage value equal to or higher than the operation threshold is transmitted as a control signal to the gate terminal of the MOS-FET 11 to close the MOS-FET 11. On the other hand, when the state of the facility provided with the solar panel 100 is abnormal, the transmission of this control signal is stopped and the MOS-FET 11 is opened. As a result, when a fire or water damage occurs in the facility, transmission of the control signal is stopped by stopping energization of the control unit 30, and the output of the solar panel 100 is automatically shut off for each solar cell module 80 can do. In this case, even when the cable for transmitting the control signal is disconnected due to fire or water damage, the transmission of the control signal is stopped, and the output of the solar panel 100 is automatically cut off for each solar cell module 80. be able to.

  Such a control unit 30 can be incorporated into, for example, a fire alarm panel, or incorporated into a central monitoring panel provided in a disaster prevention center of a building, a manual stop switch, or a power conditioner 400. Is also possible. In this case, the above-described control unit 30 may be provided in the self-report panel, the central monitoring panel, the manual stop switch, and the power conditioner 400.

Next, the operation of the output control apparatus 1 will be described using the time chart of FIG.
Power is supplied to the output control device 1 at t = 0 (step # 1). In this state, when the information acquisition unit 20 has not acquired the abnormal state explicit information, a control signal is transmitted from the control unit 30 to the MOS-FET 11 (step # 2). Although FIG. 3 shows an example in which the control signal is also output at t = 0, a predetermined delay time may be provided from when power is supplied until the control signal is output.

  When a control signal is output from the control unit 30, charging of the capacitor C is started via the resistor R connected to the MOS-FET 11 via the driver 19 (step # 3). If the potential of the gate terminal of the MOS-FET 11 becomes equal to or higher than the operation threshold value VTH (step # 4), the MOS-FET 11 is gradually closed and the output of the solar cell module 80 is started (step # 5). This state continues until the information acquisition unit 20 acquires the abnormal state explicit information.

  When the information acquisition unit 20 acquires the abnormal state explicit information at t = 1, a signal indicating that the abnormal state explicit information has been acquired is transmitted to the control unit 30, and the control unit 30 stops outputting the control signal ( Step # 6). As a result, the potential of the gate terminal of the MOS-FET 11 gradually decreases (step # 7). If the potential of the gate terminal of the MOS-FET 11 becomes less than the operation threshold VTH (step # 8), the MOS-FET 11 is opened and the output of the solar cell module 80 is stopped (step # 9). As described above, in this embodiment, the control unit 30 transmits a control signal for closing to the MOS-FET 11 and has a predetermined delay time D1 until the output of the solar cell module 80 is performed. -It is comprised so that it may have predetermined | prescribed delay time D2 until the output of the solar cell module 80 is interrupted | blocked after transmitting the control signal which the control part 30 opens to FET11.

  Thereby, the inrush current when the MOS-FET 11 is in the closed state can be suppressed. Moreover, since the output can be cut off for each solar cell module 80 in the event of an abnormality, it is unforeseen for a person who performs fire fighting and rescue activities through water that is sprinkled in the event of a fire or water that has been distributed in the event of a flood. It is possible to prevent an electric shock accident.

[Other Embodiments]
In the above-described embodiment, the switch unit 10 has been described as including the N-type MOS-FET 11. However, the switch unit 10 may include the P-type MOS-FET 18. In this case, for example, as shown in FIG. 4, the source terminal of the P-type MOS-FET 18 is connected to the connection terminal 81 </ b> A of the solar cell module 80, and the drain terminal is a connection terminal of the solar cell module 80 different from the solar cell module 80. It may be connected to 81B or the connection terminal 201. Similarly to the above embodiment, the output of the solar cell module 80 is output when there is a control signal from the control unit 30, and the output of the solar cell module 80 is blocked when there is no control signal from the control unit 30. Includes an npn transistor Tr having a collector terminal connected to the gate terminal of the P-type MOS-FET 18 via a resistor R (two resistors R connected in series in FIG. 4), and a grounded emitter terminal. It is good to provide. Thereby, the output of the solar cell module 80 can be controlled according to the presence or absence of the control signal. Note that by providing the capacitor C between the source terminal and the gate terminal, it is possible to delay the input of the control signal to the npn transistor Tr until the P-type MOS-FET 18 is closed. is there. This makes it possible to use a P-type MOS-FET 18 that is less expensive than the N-type MOS-FET 11.

  In the above-described embodiment, the control unit 30 transmits a control signal to the switch unit 10 when the facility state is not abnormal, closes the connection state of the switch unit 10, and controls the control signal when the facility state becomes abnormal. However, the control unit 30 transmits a control signal to the switch unit 10 when the state of the facility becomes abnormal, and the switch unit 10 It is also possible to adopt a configuration in which the connection state is opened, and transmission of the control signal is stopped and the connection state of the switch unit 10 is closed when the facility state is not abnormal.

  In the above-described embodiment, the switch unit 10 has been described as being provided with the state maintaining unit 12 that maintains the closed state for a preset time from when the control unit 30 receives an instruction until the switch unit 10 enters the open state. When the open / close state of the switch unit 10 is switched according to the rise and fall timing of the control signal, the state maintaining unit 12 may be omitted.

  In the above-described embodiment, the abnormal state clarification information has been described as information that clearly indicates at least one of the occurrence of a fire and the occurrence of water damage in a facility, but it may be information indicating other abnormality.

  In the embodiment described above, the switch unit 10 is provided on the connection terminal 81 </ b> A included in each of the plurality of solar cell modules 80, and the switch unit 10 is operated simultaneously with a control signal from the control unit 30. For example, the control unit 30 may be configured to individually input control signals to each of the switch units 10 as necessary, and to cut off the output of only the intended solar cell module 80. As shown in FIG. 5, a switch unit 10 is provided for each of the plurality of solar cell modules 80 (for each of the two solar cell modules 80 in FIG. 5), and the output is blocked for each of the plurality of solar cell modules 80. It is also possible. Furthermore, it is also possible to provide the switch unit 10 for each of the plurality of solar cell modules 80 so that only the desired plurality of solar cell modules 80 can block the output.

  In the above embodiment, the type of the switch unit 10 provided in the solar cell module 80 has not been described, but it is possible to configure the switch unit 10 in common (using the same component). In this case, each switch unit 10 has a breakdown voltage (a drain-source voltage and a gate voltage in the case of a MOS-FET) based on the highest terminal voltage among the solar cell modules 80 of the string 90. -Select the voltage considering the source voltage. Thereby, since the classification of components can be reduced, member management cost can be reduced.

  On the other hand, the switch unit 10 can be used properly according to the terminal voltage of the solar cell module 80. In this case, the switch unit 10 includes a high-voltage switch unit 13 provided in the connection terminal 81 of the solar cell module 80 in which the terminal voltage of the solar cell module 80 is higher than a preset voltage in the string 90. The low-voltage switch unit 14 provided in the connection terminal 81 of the solar cell module 80 having a voltage equal to or lower than a preset voltage can be configured. In this way, by using the high-voltage switch unit 13 and the low-voltage switch unit 14 in accordance with the terminal voltage of the switch unit 10, the low-voltage switch unit 14 can use components that are less expensive than the high-voltage switch unit 13. As a result, the cost of the components can be reduced as compared with the case where all the common switch units 10 are used.

  The circuit configuration of such a high voltage switch unit 13 is shown in FIG. 6, and the circuit configuration of the low voltage switch unit 14 is shown in FIG. The high voltage switch unit 13 shown in FIG. 6 is opened for a preset time from when the low voltage switch unit 14 is closed to when the high voltage switch unit 13 is closed according to an instruction from the control unit 30. An open state maintaining unit 15 that maintains the state is provided, and the low pressure switch unit 14 shown in FIG. A closed state maintaining unit 16 is provided that maintains the closed state for a preset time until the open state is reached.

  As a result, as shown in FIG. 8, a predetermined delay time (several milliseconds) can be set until the high-voltage switch unit 13 is closed with respect to the timing at which the control signal is transmitted. Therefore, the inrush current when the high-voltage switch unit 13 is closed can be reduced. In addition, a predetermined delay time (several milliseconds) can be set until the low-voltage switch unit 14 is opened with respect to the timing when transmission of the control signal is stopped. The voltage applied to each of the high voltage switch unit 13 and the low voltage switch unit 14 is lowered by controlling the sequence when switching the connection state of the high voltage switch unit 13 and the low voltage switch unit 14 in this way. Therefore, it can be configured using inexpensive parts with low withstand voltage.

  Here, the plurality of solar cell modules 80 constituting one string 90 are connected in series as described above. Conventionally, such connection has been performed by fitting connectors provided in the solar cell module 80 to each other in order to facilitate the work. The switch unit 10 according to the present invention can be temporarily connected to such a conventionally used connector, and can be connected by being interrupted and fitted. Thereby, it becomes possible to apply the output control apparatus 1 of this invention easily also to the solar panel 100 currently installed conventionally.

  The switch unit 10 can be incorporated in a power supply box provided on the back surface of the solar cell module 80. Thereby, the waterproof and dustproof effect can be enhanced for the switch unit 10.

  When wiring to each of the solar cell modules 80, it is possible to easily route each of the cable connecting the connection terminal 81 and the switch unit 10 and the cable transmitting the control signal by using a two-core cable. It becomes.

  The output control device 1 has a function of shutting down the output of the solar cell module 80 when the facility is abnormal. For example, when performing maintenance and inspection work for a plurality of solar cell modules 80, the output control device 1 is a target of the work. Can be used to block the output of the solar cell module 80.

  INDUSTRIAL APPLICABILITY The present invention can be used for an output control device that controls the output of a solar panel provided with a plurality of strings in which a plurality of solar cell modules are connected in series.

1: Output control device 10: Switch unit 12: Closed state maintaining unit 20: Information acquisition unit 30: Control unit 80: Solar cell module 81: Connection terminal 81A: Connection terminal 90: String 100: Solar panel

Claims (4)

An output control device for controlling the output of a solar panel provided with a string in which a plurality of solar cell modules are connected in series,
A switch unit that is connected in series to one connection terminal of the pair of connection terminals of the solar cell module, and switches a connection state between the one connection terminal and a connection conductor to which an output of the solar cell module is transmitted; ,
An information acquisition unit for acquiring abnormal state clarification information indicating that the state of the facility where the solar cell module is disposed is abnormal;
Based on the abnormal state explicit information, a control unit that opens the connection state of the switch unit when the state of the facility becomes abnormal,
An output control device comprising:   When the state of the facility is not abnormal, the control unit transmits a control signal to the switch unit to close the connection state of the switch unit, and transmits the control signal when the state of the facility becomes abnormal The output control device according to claim 1, wherein the connection state of the switch unit is opened to stop the operation.   The output control device according to claim 1, wherein the abnormal state clarification information is information that clearly indicates at least one of a fire occurrence and a flood damage in the facility.   The output control device according to any one of claims 1 to 3, wherein the switch unit is provided in the one connection terminal of each of the plurality of solar cell modules.

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