DE102011079074A1 - Control system for a voltage-safe photovoltaic system - Google Patents

Abstract

The invention relates to a control system for a photovoltaic system. The control system has a control device with an input for a photovoltaic module and with an output for connection to an electrical load, in particular an inverter or an energy store for storing electrical energy. The control device has a controllable disconnect switch, in particular a relay or a semiconductor switch. The circuit breaker is connected to the input for the photovoltaic module and to the output and designed to separate the output from the input in response to a control signal received on the input side, in particular the enable signal. The control system has a transmitting unit which is designed to generate the control signal. The controller also includes a receiver for the control signal, the receiver being configured to receive the control signal and to send the control signal to the circuit breaker.

Description

State of the art

Disclosure of the invention

The invention relates to a control system for a photovoltaic system. The control system has a control device with an input for a photovoltaic module and with an output for connection to an electrical load, in particular an inverter or an energy store for storing electrical energy. The control device has a controllable disconnect switch, in particular a relay or a semiconductor switch. The circuit breaker is connected to the input for the photovoltaic module and to the output and designed to separate the output from the input in response to a control signal received on the input side, in particular the enable signal. The control system preferably has a transmitting unit which is designed to generate the control signal. The controller also includes a receiver for the control signal, the receiver being configured to receive the control signal and to send the control signal to the circuit breaker. The photovoltaic module preferably comprises at least one solar cell, more preferably a plurality of solar cells.

By virtue of the control system designed in this way, a photovoltaic system which, in the case of a plurality of photovoltaic modules connected in series, can generate a voltage of, for example, more than one hundred volts, one thousand volts or more than one thousand volts, can be used in the event of a fault or fire the output connected electrical loads, in particular an inverter or be separated from an electrical energy storage. In the case of a fire can be prevented so advantageous that when extinguishing the fire with extinguishing water, a rescuer receives an electric shock on the fire water.

The circuit breaker is for example a relay or a semiconductor switch. The semiconductor switch is, for example, a thyristor or a transistor, in particular a field-effect transistor.

The transmitting unit is also called transmitter in the following.

The transmitting unit preferably has a connection for an AC voltage network and is designed to generate the control signal by means of an AC voltage from the AC voltage network.

In a preferred embodiment, the control device is designed to receive a supply voltage from the input of the photovoltaic module. As a result, advantageously no separate power supply for operating the control device needs to be present. Further advantageously, the circuit breaker may be formed to connect the output to the input by means of the circuit breaker in response to the control signal. When the circuit breaker, such as a relay, receives the control signal, the output remains connected to the input as long as the control signal is generated. In the case of a failure of the photovoltaic module, the photovoltaic module is disconnected from the inverter or the energy storage, as far as the control device receives no supply voltage to generate the control signal or the control unit generated by the transmission unit to the circuit breaker, in particular the relay or a Forward semiconductor switch.

In a preferred embodiment of the control system, the control device has a control connected to the output controllable switch, in particular an opener and is adapted to short-circuit the output by means of the switch in response to the control signal or to connect low resistance. This advantageously allows a photovoltaic module in a string comprising at least two or more photovoltaic modules to be bridged in the event of a fault, so that the remaining modules of the string can still generate an output voltage. As a result, in the case of a fire in the region of the at least one photovoltaic module which is mounted, for example, on a roof of a house, a rescuer can not be endangered by an electric shock since a photovoltaic voltage generated by means of solar radiation is also present in a circuit breaker short-circuited by a defect can not rest on the output of the photovoltaic module.

Further advantageously, the photovoltaic modules can be connected without voltage during maintenance or installation, if the photovoltaic cells in the photovoltaic module during maintenance by solar irradiation already generate a photovoltage. Advantageously, a photovoltaic voltage generated by the photovoltaic module can thus reach an inverter or connection only after generating the enable signal.

In a preferred embodiment, the transmitting unit is designed to be indirectly connected to the output via an electrical line to the inverter or energy storage. The receiver is in this embodiment at least indirectly connected to the output and configured to receive the control signal at the output. So can advantageously the electric Connecting line from the control device to the inverter or energy storage as a message channel for transmitting the control signal, in particular enable signal serve.

The control signal is, for example, an alternating signal with a signal frequency which is superimposed on the electrical line which transmits a DC voltage generated by the photovoltaic module to the energy store or inverter, the DC voltage. The receiver is formed for example by a filter, which is designed to separate the alternating signal from the DC voltage and to provide the alternating signal of the control device for activating the disconnector. The control device has, for example, in a simple case, a signal amplifier, which is the input side connected to the receiver and the output side connected to the circuit breaker. By way of example, the control system has a processing unit, for example a microprocessor, a microcontroller, an ASIC (Application Specific Integrated Circuit) or an FPGA (FPGA = Field Programmable Gate Array), which is embodied as the control signal, in particular the enable signal receive from the receiver and generate a corresponding control signal and send to the disconnect switch to enable the disconnect switch to disconnect the output from the input. Preferably, the processing unit is configured to keep the disconnect switch connected in response to an enable signal, in particular by means of an electrical current representing the connection between the output and the input, and the current to the control signal, in particular in the absence of the control signal Disconnecting the circuit breaker disconnected so that the disconnector in the de-energized state separates the output from the input. As a result, in the case of a defective photovoltaic module or a defective control device, the photovoltaic module can advantageously produce no dangerous output voltage, since the disconnecting switch is preferably opened without a control signal.

In a preferred embodiment, the control system has at least one fire sensor connected to the transmission unit. The fire sensor is preferably designed to detect a fire and to generate an alarm signal depending on the fire. The fire sensor has, for example, a light or radiation barrier which is designed to detect an extinction caused by dust or soot particles for light or electromagnetic radiation and to generate the alarm signal as a function of the detected extinction. In another embodiment, the fire sensor has at least one gas sensor, which is designed to detect a gas, for example carbon monoxide, and to generate the alarm signal as a function of the detected gas.

The transmitting unit is preferably designed to generate the transmission signal as a function of the alarm signal. Preferably, the transmitting unit is designed to generate the control signal, in particular enable signal for activating the photovoltaic module and to interrupt or no longer generate depending on the alarm signal.

The invention also relates to a photovoltaic system with at least one photovoltaic module and with a control system according to the above-described type. The photovoltaic module preferably comprises the control device and is furthermore preferably connected to the control device. For example, the control device is connected to a housing or frame of the photovoltaic module. For this purpose, the control device is accommodated, for example, in a connection box of the photovoltaic module.

Thus, in the case of an alarm signal and a control signal no longer generated by the transmitter, in particular a release signal, a dangerous DC voltage generated by the photovoltaic module can already be switched off in the area of the photovoltaic module, for example in the area of a roof of a house, or additionally short-circuited.

In a preferred embodiment, the photovoltaic system has an emergency button or emergency switch connected to the transmitting unit. The emergency switch is configured to generate an alarm signal in response to user interaction. The transmitting unit can thus advantageously interrupt or no longer generate the transmission signal, in particular the release signal, as a function of an alarm signal generated by a user, and deactivate the at least one photovoltaic module in the manner already described.

In a preferred embodiment, the output is connected to an energy store for storing electrical energy. The energy store is, for example, an accumulator, in particular a lead-acid battery or a nickel-containing accumulator. In another embodiment, the energy storage device for storing electrical energy is an electrolysis device which is designed to split water into hydrogen and oxygen by means of electrolysis, the electrolysis device being connected to a hydrogen storage device and configured to store the hydrogen produced by electrolysis in the hydrogen storage device.

The invention also relates to a method for operating a photovoltaic system, wherein the photovoltaic system at least one photovoltaic module includes. Preferably, the photovoltaic system additionally includes a consumer connected to the photovoltaic module, in particular inverters and / or energy storage. In the method, an enable signal for operating the photovoltaic system is generated. Depending on a fire, the release signal is interrupted or no longer generated and the photovoltaic module separated in particular by means of a circuit breaker of the inverter and in particular connected by means of a further switch on the output side at least low impedance or shorted. More preferably, the photovoltaic module is in the local area of the module, in particular a module housing, short-circuited and / or separated from the energy storage device or consumer.

1 shows an embodiment of a photovoltaic system with a control system which is designed to switch the photovoltaic system in dependence of a fire voltage;

2 shows a method for operating a photovoltaic system.

1 shows an embodiment of a photovoltaic system 1 , The photovoltaic system 1 has a photovoltaic module 3 and a photovoltaic module 5 on. The photovoltaic modules 3 and 5 are connected in series with each other in this embodiment. The photovoltaic system 1 also has a control device 7 and a control device 9 on. The control device 7 is with the photovoltaic module 3 , In particular with a housing or a connection box of the photovoltaic module 3 connected. The control device 9 is with the photovoltaic module 5 , in particular a housing of the photovoltaic module 5 connected. The control device 7 has an entrance 40 and an entrance 41 on, with the inputs 40 and 41 are connected to the photovoltaic module, in particular with electrical terminals for receiving photovoltaically generated electricity. The control device 9 has an entrance 44 and an entrance 45 on which each with the photovoltaic module 5 are connected. The control device 7 has a disconnect switch 10 on, which is controllable. The circuit breaker 10 connects the entrance 40 with an exit 42 the control device 7 , The control device 7 also has a processing unit 18 on. The processing unit 18 is with the entrance 40 and the entrance 41 for receiving a supply voltage of the processing unit 18 connected. The processing unit 18 is also on the input side via a connecting line 58 with a receiver 22 connected. The processing unit 18 is via a connection line 60 on the output side with a control connection of a switch 14 , connected in this embodiment, a short-circuit switch. The short-circuit switch 14 has a switching path, which with a first connection to the output 42 and with a second connector with an output 43 the control device 7 connected is. The desk 14 is trained, the outputs 42 and 43 depending on a via the connecting line 60 received control signal from each other. In the case of no received control signal is the switch 14 trained, the outputs 42 and 43 to connect with each other. The desk 14 is formed in this embodiment as an opener. Also conceivable is an embodiment as a closing switch. The processing unit 18 is on the output side via a connecting line 59 with a control terminal of the circuit breaker 10 connected. The circuit breaker 10 is formed, depending on a via the connecting line 59 received control signal the input 40 with the exit 42 connect to. The entrance 40 and the exit 42 in this embodiment, in the case of none over the connecting line 59 received control signal from each other electrically isolated.

The photovoltaic system 1 also has a transmitter 25 on. The transmitter 25 is on the input side via a connecting line 56 with an emergency switch 29 connected and is formed over the connecting line 56 to receive an alarm signal generated by the emergency switch. The transmitter 25 is also via a connection line 55 on the input side with a fire sensor 27 connected. The fire sensor 27 is designed to detect flue gas and to generate an alarm signal depending on the detected flue gas and this output side via the connecting line 55 to the transmitter 25 to send. The transmitter 25 is formed, depending on the over the connecting line 56 and / or via the connection line 55 received alarm signal representing a control signal radio signal 70 and generate this to the receiver 22 to send. The transmitter 25 is in this embodiment via a connecting line 66 with an entrance 48 an inverter 30 connected as a consumer. The transmitter 25 is connected, for example, to an AC voltage network and is designed to generate the control signal, in particular the enable signal, by means of an AC voltage from the AC voltage network.

It is also conceivable the connection of the transmitter 25 to an energy storage device, for example an electrolysis device or an accumulator.

The entrance 48 is via an electrical line 50 with the exit 42 connected. The transmitter 25 is formed, the control signal - in the case of none of the fire sensor 27 or the alarm button 29 received alarm signal - to generate as an enable signal and the connection line 66 , continue over the entrance 48 , the electric wire 50 and the exit 42 to the control device 7 to send. The control device 7 is formed, the enable signal at the output 42 to recieve. The recipient 22 can the enable signal from the output 42 via the - disconnected without a control signal - disconnector 14 , and continue over the connecting line 64 receive. The recipient 22 can generate in dependence of the received enable signal, which is formed for example by a high-frequency signal, a control signal corresponding to the enable signal and this via the connecting line 58 to the processing unit 18 send. The recipient 22 has, for example, a filter on which the on the line 50 from the transmitter 25 modulated enable signal from one of the photovoltaic module 3 can separate generated DC voltage.

The processing unit 18 is formed, depending on the input side via the connecting line 58 received control signal to close the circuit breaker 10 to generate and this over the connecting line 59 to the control terminal of the disconnector 10 to send. The processing unit 18 can also be a function of the input side received control signal, a control signal to open the switch 14 generate and this over the connecting line 60 to the control terminal of the switch 14 send.

The recipient 22 points - as an alternative to the connecting line 64 or in addition - an antenna 32 on and is trained over the antenna 32 a radio signal representing the control signal 70 to receive, which represents the enable signal. The transmitter 25 indicates alternatively to the connecting line 66 or in addition to an antenna 35 on and is trained over the antenna 35 a radio signal 70 to broadcast, which represents the enable signal. The transmitter 25 is formed, for example, the radio signal 70 according to a DECT (Digital Enhanced Cordless Telecommunications) standard, a ZigBee standard or a Bluetooth standard.

If the fire sensor 27 a fire is detected, so the transmitter 25 depending on the fire sensor 27 received alarm signal generate a release signal, after previously without the alarm signal, an enable signal was generated. An active signaling of a fire to the control device is also conceivable 7 in which the control signal is generated when the alarm signal is present. However, the variant with the signaling of the fire on the enable signal is safer, since in case of damage to the transmitter unit by a fire in case of power failure or shutdown of the transmitter unit supplying energy supply network, the photovoltaic modules are disabled in the absence of enable signal.

The photovoltaic module 5 is with the photovoltaic module 3 connected serially to a string. This is the exit 43 the control device 7 with an exit 46 the control device 9 connected. The control device 9 is according to the control device 7 built up. The disconnect switch corresponds to this 12 the disconnector 10 , a switch 16 , In this embodiment, a controllable trained opener, the switch 14 , a processing unit 20 corresponds to the processing unit 18 , a receiver 24 corresponds to the recipient 22 , The recipient 24 is via a connection line 65 with the entrance 45 connected, which with an output 47 the control device 9 connected is. The processing unit 20 is via a connection line 62 with the control terminal of the switch 16 , and over a connecting line 61 with the control connection of the disconnector 12 connected. The recipient 24 is via a connection line 63 with the processing unit 20 connected. The recipient 24 has an antenna 34 on which of the antenna 32 Recipient 22 equivalent. The recipient 24 can over the antenna 34 the radio signal 70 receive. The photovoltaic modules 3 and 5 can thus by means of the receiver 22 and 24 receive the enable signal, and in the case of an alarm signal generated by the fire sensor 27 or from the alarm button 29 , interrupt the enable signal or no longer generate and so the photovoltaic module 3 or the photovoltaic module 5 by means of the switch 14 respectively 16 short circuit and by means of the circuit breaker 10 and 12 from the inverter 30 separate. The photovoltaic system has a circuit breaker in this embodiment 36 on which an output of the inverter 30 via another safety switch 37 with a phase L of an alternating voltage network connects. The inverter 30 is via a connection line 54 connected to a neutral conductor N of the AC voltage network.

The circuit breaker 36 has a control input and is connected to the control input to the transmitter 25 connected. The transmitter 25 is formed in this embodiment, in response to the input side received alarm signal first, a control signal to open the circuit breaker 36 and then terminate generating the enable signal. This advantageously ensures that the photovoltaic module 3 no load from the exit 42 is disconnected. The photovoltaic module 5 This is advantageous by means of the circuit breaker 12 load-free from the exit 46 separated. The exit 47 the control device 9 is by means of a connection line 53 with an entrance 49 of the inverter 30 connected. Such is the string, comprising two photovoltaic modules connected in series, namely the photovoltaic modules 3 and 5 , over the entrances 48 and 49 with the inverter 30 connected.

The control devices 7 and 9 In each case, for example, in addition to the components described above, a DC-DC converter, which is formed, one of the photovoltaic module 3 or the photovoltaic module 5 generated voltage to convert such a current, which of the control devices 7 and 9 can be issued is the same. In addition, the DC-DC converter may have an MPP tracker (MPP = maximum power point), which is designed to generate a load on the photovoltaic module electrical load resistor such that - according to a current-voltage characteristic of the photovoltaic Module generated electrical power is maximum.

If, for example, the photovoltaic module 3 fails due to a defect, so is the processing unit 18 no supply voltage available. Despite concern of a release signal, the processing unit 18 no control signal for the disconnector 10 or the switch 14 produce. The circuit breaker 10 disconnects the photovoltaic module from the string in this case, the switch 14 without the control signal being closed and the output 42 with the exit 43 combines. The other contained in the string photovoltaic modules, in this embodiment, the photovoltaic module 5 , can then continue to generate solar power and to the inverter 30 deliver.

In the case of only one with the inverter 30 connected photovoltaic module, such as the photovoltaic module 3 , the output can be 43 with the entrance 49 via a - dashed line - connecting line 51 be connected.

It is also conceivable bidirectional communication between the transmitter 25 and the receiver 22 , These are the recipients 22 and 24 in each case - by means of an additional transmitter - designed as a transceiver. The transmitter 25 is also formed in this embodiment by means of another receiver as a transceiver. The processing unit 18 For example, with one with the photovoltaic module 3 be connected connected temperature sensor. The processing unit 18 is formed in this embodiment, to receive from the temperature sensor, a temperature signal representing the module temperature and this at the - trained in this embodiment transceiver 22 to send. The transceiver 22 can convert the temperature signal into a radio signal and to the transceiver 25 send. The transceiver 25 For example, the temperature signal can be evaluated according to the alarm signal and can no longer generate the release signal as a function of the temperature signal. The photovoltaic modules, in particular the temperature sensor of the photovoltaic module can thus detect a malfunction of the photovoltaic module and prevent further increase in temperature of the photovoltaic module. At an excess temperature of the photovoltaic module 3 can the processing unit 18 - regardless of the enable signal - the disconnector 10 open and the switch 14 open, leaving the photovoltaic module 5 can continue generating electricity.

The processing unit 10 For example, in addition to the temperature signal, one of the photovoltaic module 3 at the entrance 40 and the entrance 41 detect generated voltage and generate a voltage signal - for example by means of an analog-to-digital converter - and this to the transceiver 22 send. The transceiver 22 can generate a corresponding radio signal and this to the transceiver 25 send, which can receive the radio signal. The transceiver 25 is formed, for example, in dependence on the radio signals of the transceiver 22 and 24 received module voltage signals to generate control signals for driving the aforementioned DC-DC converter and to send to the respective control device. So can by means of the transceiver 22 . 24 and 25 , Which each form a radio interface, regulated the output current of the photovoltaic modules and matched.

Also conceivable is an embodiment in which the transmitter 25 powered by a power grid to which the inverter 30 is connected for feeding. The power supply of the transmitter 25 can then depend on the alarm signal of the fire alarm 27 or by a remote shutdown of a power grid - for example, by a local network operator or energy supplier - done. The transmitter can no longer generate a release signal after switching off the network, so that the photovoltaic modules 3 and 5 from the inverter 30 disconnected and shorted.

2 shows in method for operating a photovoltaic system, wherein the photovoltaic system comprises at least one photovoltaic module and connected to the photovoltaic module loads, in particular inverters and / or energy storage.

The method is in one step 70 the photovoltaic module by means of a short-circuit switch, in particular a controllable opener, at least low-resistance connected or short-circuited, and separated by a circuit breaker from a consumer.

In one step 72 a release signal is generated and closed in response to the enable signal of the circuit breaker and the short-circuit switch opened. The photovoltaic module can deliver photovoltaically generated charge carriers from the solar irradiation to the inverter or energy storage. The enable signal is generated, for example, by means of an AC voltage of an AC network. In one step 74 In response to a fire, an alarm signal is generated and the consumer is disconnected from the photovoltaic module or disconnected from the load. It is also conceivable to switch off an AC voltage of a power grid connected to the inverter by an energy supplier, so that no release signal can be generated more.

In one step 76 the photovoltaic module is separated from the inverter in particular by means of a circuit breaker, after the consumer in step 70 unloaded or disconnected from the photovoltaic module.

In one step 78 the photovoltaic module on the output side, in particular by means of another switch, in particular a controllable opener, connected in the local area of the module, in particular a module housing, at least low-resistance or short-circuited.

In one step 80 an acknowledgment signal is generated, which represents a lack of voltage of the photovoltaic system. For example, an activated in response to the confirmation signal flashing light by means of, for example, green light a rescuer signal widely visible that the photovoltaic system is de-energized. The rescuer can then safely extinguish the fire with extinguishing water, without receiving an electric shock.

Claims (10)

Tax system ( 7 . 9 . 25 ) for a photovoltaic system ( 1 ), with a control device ( 7 . 9 ) with an input ( 40 . 41 . 44 . 45 ) for a photovoltaic module ( 3 . 5 ) comprising at least one solar cell, and having an output ( 42 . 43 . 46 . 47 ) for connection to an electrical consumer, in particular inverters ( 30 ) or with an energy store, and the control device ( 7 . 9 ) a controllable disconnect switch ( 10 . 12 ), in particular relay or semiconductor switch, which is connected to the input ( 40 . 41 . 44 . 45 ) for the photovoltaic module ( 3 . 5 ) and with the output ( 42 . 43 . 46 . 47 ) is connected and formed in response to a control signal received on the input side, in particular enable signal, the output ( 42 . 43 . 46 . 47 ) from the entrance ( 40 . 41 . 44 . 45 ) and the control system has a transmitting unit ( 25 ), which is designed to generate the control signal, and the control device ( 7 . 9 ) a receiver ( 22 . 24 ) for the control signal and is adapted to receive the control signal and the control signal to the circuit breaker ( 10 . 12 ) to send. Tax system ( 7 . 9 . 25 ) according to claim 1, characterized in that the control device ( 7 . 9 ), a supply voltage for operating the control device ( 7 . 9 ) from the entrance ( 40 . 41 . 44 . 45 ) of the photovoltaic module. Tax system ( 7 . 9 . 25 ) according to claim 1 or 2, characterized in that the control device ( 7 . 9 ) one with the output ( 42 . 43 . 46 . 47 ) connected controllable switch ( 14 . 16 ), in particular opener and is designed, the output ( 42 . 43 . 46 . 47 ) by means of the switch ( 14 . 16 ) short-circuit in dependence of the control signal or to connect low resistance. Tax system ( 7 . 9 . 25 ) according to one of the preceding claims, characterized in that the transmitting unit ( 25 ) is formed, via an electrical line ( 50 ) to the consumer ( 30 ) or energy storage indirectly with the output ( 42 ) and the recipient ( 22 . 24 ) with the output ( 42 ) is at least indirectly connected and configured, the control signal at the output ( 42 ) to recieve. Tax system ( 7 . 9 . 25 ) according to one of the preceding claims, characterized in that the control system ( 7 . 9 . 25 ) at least one associated with the transmitting unit fire sensor ( 27 ), which is designed to detect a fire and to generate an alarm signal depending on the fire, and the transmitting unit ( 25 ) is designed to generate the transmission signal in response to the alarm signal. Photovoltaic system ( 1 ) with at least one photovoltaic module ( 3 . 5 ) and with a tax system ( 7 . 9 . 25 ) according to one of the preceding claims, characterized in that the at least one photovoltaic module ( 3 . 5 ) the control device ( 7 . 9 ). Photovoltaic system ( 1 ) according to claim 6, characterized in that the photovoltaic system ( 1 ) one with the transmitting unit ( 25 ) associated emergency button ( 29 ) or emergency switch, which is designed to generate an alarm signal in response to a user interaction. Photovoltaic system ( 1 ) according to claim 6 or 7, characterized in that the output is connected to an electrical load, in particular inverter. Photovoltaic system according to claim 6 to 8, characterized in that the output is connected to an energy storage device for storing electrical energy. Method for operating a photovoltaic system ( 1 ), whereby the photovoltaic system ( 1 ) at least one photovoltaic module ( 3 . 5 ) and one with the photovoltaic module ( 3 . 5 ) connected consumer and / or energy storage, in which a release signal for operating the photovoltaic system is generated and the release signal is interrupted in dependence of a fire or no longer generated ( 74 ) and the photovoltaic module ( 3 . 5 ) in particular by means of a circuit breaker ( 10 . 12 ) by the consumer ( 30 ) is disconnected ( 76 ) and - in particular by means of a further switch ( 14 . 16 ) - connected on the output side at least low-resistance or short-circuited ( 78 ).

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