DE102006030751A1 - Solar energy utilizing device, has inverter for switching device such that energy is supplied to generator by power supply system, where inverter is operable in four-quadrant operation - Google Patents

Abstract

The device has a photovoltaic generator (1) for receiving sunlight, where the sunlight is converted into one form of energy by using the generator and is supplied to a power supply system (3). An inverter (2) switches the device in such a manner that the energy is supplied to the generator by the power supply system. The inverter is operable in a four-quadrant operation, where the inverter has a insulated gate bipolar transistor (IGBT) component. The IGBT component is attached to a microprocessor or digital signal processor (DSP).

Description

The The invention relates to a device for using solar energy according to the preamble of claim 1.

Known Devices have photovoltaic generators as solar receiving elements, on building roofs, other structural equipment or on other building surfaces mounted and convert the sunlight into electricity that enters the power grid is fed. Often is the entire roof area occupied with such photovoltaic generators, so that electricity to a large extent can be generated. While In the winter time, snow is deposited on the photovoltaic generators. The snow layers on the building roofs can do so thick, that building roofs can collapse. Around To counteract this danger, the snow loads on the roof cleared. However, this is partly associated with a high risk for the persons who stand on the roof and clear the snow.

The Invention is based on the object, the generic device form so that on the snow-collecting element or the snow-collecting element Ice can be removed safely.

These Task is in the generic device according to the invention with the characterizing features of claim 1 solved.

at the device according to the invention becomes the direction of the energy supply vice versa, so that the sunlight-transforming element no longer gives the energy form to the element But supplies consumers conversely received by the consumer. This has the consequence that the element is heated. As a result, the snow lying on this element or a corresponding Ice layer defrosted. This ensures in a simple yet reliable way that yourself on the element can not form high snow cover.

Advantageous is the element a photovoltaic module or the interconnection of several photovoltaic modules, which in the feed operation the sunlight convert into electricity and feed it into the power grid. The energy flow can at the device according to the invention be reversed so that the electricity from the power grid flows into the photovoltaic module and heats it. Thereby Is it possible, the snow or ice covering photovoltaic modules in winter be defrosted. This mode of operation of the device according to the invention has about it addition, the advantage that unnecessary energy losses through the snow or ice is removed, the photovoltaic modules for days cover.

Advantageous is the switching unit of the device according to the invention an inverter, preferably a transformerless inverter.

With it changes on the device between the feed and the melt operation are not necessary the inverter is advantageously operated in four-quadrant operation. This is an energetic return from the mains in the photovoltaic modules easily possible.

Of the Beginning of the Abschmelzvorganges can be done manually via a switch or sensor-controlled. Advantageously, the sensor-controlled switching of the inverter, so that snow / ice reliably defrosted become. Once the Abschmelzvorgang has occurred, the device switched either manually or sensor-controlled. This will be advantageous a temperature and / or a brightness sensor used. Especially a brightness sensor detects the defrosted photovoltaic modules because of the higher Light incidence, so that the Brightness sensor generates a corresponding switching signal, which the device from the melting operation back into the feed mode is switched.

The Photovoltaic modules can be placed on a roof cover as separate modules. The modules can but also be integrated in the roof tiles themselves. Likewise, the Modules are designed as roof-integrated systems that cover the roof form yourself.

Further Features of the invention will become apparent from the other claims, the Description and the drawings.

The The invention will be explained in more detail with reference to an embodiment shown in the drawings. It demonstrate

1 a schematic representation of a device according to the invention,

2 a switching example of an inverter of the device according to the invention.

1 shows a schematic diagram of the operation of the device. She has at least one photovoltaic generator 1 comprising at least one photovoltaic module, preferably a plurality of photovoltaic modules, and to an inverter 2 connected. He is connected to the electricity grid 3 connected. The device is usually operated so that the photovoltaic generator 1 Energy in the power grid 3 feeds. The mode of action of the photovoltaic generator 1 is known and is therefore not explained in detail. The photovoltaic generators 1 are usually on one Roof of a building mounted, this roof can be a flat roof or a pitched roof. It can cover the entire roof area with photovoltaic generators 1 to be occupied. But it is also readily possible to provide only a portion of the roof surface with such generators. The photovoltaic generators 1 Use the sun's rays to generate energy in the grid 3 can be fed. In 1 is the direction of energy flow in the described feed operation by the arrow 4 specified. The inverter 2 is in this case switched to the feed mode. The inverter 2 converts the from the photovoltaic generator 1 incoming DC voltage before being fed into the power grid 3 in AC voltage.

The inverter 2 can be switched from the feed mode into a snow melting mode. As a result, energy from the power grid 3 in the photovoltaic generator 1 is fed. The energy is in the connected photovoltaic generator 1 converted into heat. This makes it possible to snow, in the winter on the photovoltaic generators 1 lies, to defrost. As a result, unnecessary energy losses are eliminated by the snow, the photovoltaic generators for days 1 can cover. In 1 is the direction of energy flow during snow melting operation by the arrow 5 specified. Switching of the inverter 2 from the feed to the snow melting mode can be started manually via a switch or automatically, for example via a sensor. In the same way, after the melting of the snow, the inverter 2 be switched by a switch or preferably by means of at least one sensor from the snow melting operation in the feed mode.

The inverter 2 is preferably trafolos and is operated in four-quadrant operation, without any changes to the inverter 2 must be made.

The inverter is in a housing 6 ( 2 ) housed. It has two DC voltage connections 8th . 9 for the photovoltaic generator 1 , The DC voltage connections 8th . 9 are screw connections, but can also be designed as plug-in connections with which a secure electrical connection between the photovoltaic generator 1 and the inverter 2 is guaranteed. The connections 8th . 9 are at a module 10 connected, with which the ground fault is monitored and which serves as an EMC filter as well as overvoltage protection.

The of the connections 8th . 9 incoming energy or DC voltage will be an IGBT (Insulated Gate Bipolar Transistor) arrangement 11 fed. It is operated with a predetermined clock frequency, in the embodiment with 18 kHz, and is constructed in bridge circuit. The bridge circuit 12 the IGBT arrangement 11 is via a mains choke module 13 to a switching module 14 connected.

Between the module 10 and the IGBT arrangement 11 is an input capacity 15 with which the voltage is smoothed and energy is buffered.

The inverter 2 is with at least one sensor 16 provided for temperature monitoring.

The switching module 14 has two switching elements 17 . 18 , preferably relays, on.

At the housing 6 there is a connection 20 with which the inverter 2 to the mains 3 is connected. The connection 20 upstream is a module 21 , which has an EMC filter and overvoltage protection and is grounded. In the module 21 are Meßglied contained by a controller in a Schaltnetzteil- and signal conditioning module 28 be evaluated. If the device is used in snow melting mode, then the module stops 21 sure, that's from the mains 3 over the connection 20 supplied currents / voltage the photovoltaic generator 1 can not damage. Between the switching module 14 and the module 21 there is an AFI module 22 , which is also applied to ground. The AFI module 22 It is used for plant and personnel protection and detects residual currents that can occur in the inverter, in the PV modules or in the wiring of the PV modules.

From the connection 20 leads a protective conductor 23 to the module 21 , The neutral conductor 24 is from the connection 20 to the switching element 18 of the switching module 14 guided. Also the leader 25 is from the connection 20 to the switching element 18 guided. The ladder 26 and 27 lead from the terminal 20 to the module 21 , The ladder 26 . 27 are intended only for monitoring while on the ladder 25 the supply of electricity from the photovoltaic module 1 in the power grid 3 he follows.

The modules 10 . 15 . 11 . 14 . 21 and 22 are to the switching power supply and signal conditioning module 28 connected, located in the housing 6 of the inverter 2 located. The building block 28 is also used for signal conditioning and can be activated via a night activation button 29 to be activated.

The building block 28 is from a microprocessor 30 or a digital signal processor, which is also in the housing 6 is housed. The connection between the microprocessor 30 and the building block 28 takes place via a beneficial Ribbon cable 31 , It is also possible to use the microprocessor 30 into the building block 28 to integrate. The microprocessor 30 can be operated with keys (not shown) on the housing. It is advantageous on the housing 6 a display 32 provided, by means of which the inputs can be checked by means of the keys. The microprocessor 30 is advantageously designed as a redundant two-processor system, so that a failure of the microprocessor 30 is almost impossible.

The microprocessor 30 is with interfaces 33 to 35 provided, of which the interface 33 an RS232, the interface 34 an RS485 and the interface 35 is a S _o interface. The interfaces 34 . 35 are at control terminals 36 . 37 Internally connected directly to the control board.

the interface 33 is via a ribbon cable 39 with a corresponding connection 40 connected.

The microprocessor 30 has a fault signal relay 41 that with a control terminal 42 connected is. The S _o interface is used to connect to the internal device bus. About the interfaces 33 and 34 can transfer data to the processor 30 entered and / or read from it. For example, measurement data can be queried or, for example, new software can be imported.

The device can be operated in two different ways without the need for conversion. In normal operation (feed-in operation) converts the photovoltaic generator 1 the solar energy into electrical current that passes through the inverter 2 in the power grid 3 is fed. The switching elements 17 . 18 of the switching module 14 are closed, so that at the terminals 8th . 9 fed electricity to the connection 20 led and from there into the power network 3 can be fed. The module 10 ensures protection against overvoltage. Interference fields are filtered out by the EMC filter. With the IGBT arrangement 11 is by means of the bridge circuit 12 a four-quadrant operation possible.

The four-quadrant operation allows the power to flow into the grid not just in the usual way 3 is fed, but that, conversely, electricity the grid 3 taken and the photovoltaic generator 1 can be supplied. This is done when the photovoltaic generator 1 should be heated, for example, to defrost lying on it snow. The Abschmelzvorgang or switching to the snow melting mode can be done manually by means of a switch. Then the bridge circuit 12 controlled in a known manner so that the power to the grid 3 taken and the photovoltaic generator 1 is supplied.

The mains choke module 13 as inductance limits the circulating current of the four-quadrant drive. The mains chokes prevent the circulating current from becoming too high.

Switching from feed-in operation 4 in the snowmelt operation 5 can also be done sensor-controlled automatically. By heating the photovoltaic generator 1 The snow lying on it melts, so that it is reliably prevented that thick layers of snow form on the roof.

As soon as the snow has melted off, the switchover from the snow melting mode takes place 5 in the feed-in operation 4 , This can in turn be done manually by means of a switch or preferably sensor-controlled.

As a sensor, a temperature and / or brightness sensor or a combination of a plurality of sensors can be used. Once the snow on the photovoltaic generator 1 is defrosted, the sensor / sensor combination detects an increasing temperature, whereby it generates a corresponding switching signal, with which the bridge circuit 12 is switched. A brightness sensor can also be used for this switching task, because after the melting away of the snow, the light incident on the photovoltaic generator 1 is greater than in the case that there is a snow cover on it. Similarly, the sensor / sensor combination registers a decreasing temperature or lower light incidence when snow or ice on the photovoltaic generator 1 remains lying. Then the bridge circuit 12 switched over and the device from the feed operation 4 in the melting shop 5 transferred.

To the inverter 1 can use multiple photovoltaic generators 1 be connected. Also it is possible on the roof of a building several inverters with a corresponding number of photovoltaic generators 1 to use.

The described principle of heating can can also be used in solar systems that are not powered by electricity but with a heat transfer medium work. Here, the heat transfer takes place the solar system by means of a heat exchanger the respective consumer. Lies on the solar panels on the building roof Snow, then the heat exchanger be switched so that of Consumer heat transferred to the flowing through the solar cell medium which heats the solar cells and defrosts the snow become.

The device described can except on building roofs on other structural Facilities or surfaces are mounted.

Claims (17)

Device for using solar energy, with at least one sunlight-absorbing element ( 1 ), with which the sunlight is converted into another form of energy and supplied to a consumer, characterized in that the device is a switching unit ( 2 ), which switches the device so that energy from the consumer ( 3 ) the element ( 1 ) is supplied. Device according to claim 1, characterized in that the element ( 1 ) is a photovoltaic module or the interconnection of several photovoltaic modules. Apparatus according to claim 1 or 2, characterized in that the switching unit ( 2 ) is an inverter. Device according to one of claims 1 to 3, characterized in that the consumer ( 3 ) is the power grid. Apparatus according to claim 3 or 4, characterized in that the inverter ( 2 ) is operable in four-quadrant operation. Device according to one of claims 3 to 5, characterized in that the inverter ( 2 ) an IGBT module ( 11 ) having. Device according to Claim 6, characterized in that the IGBT component ( 11 ) a bridge circuit ( 12 ) having. Device according to Claim 6 or 7, characterized in that the IGBT component ( 11 ) to a microprocessor ( 30 ) or Digital Signal Processor (DSP). Device according to Claim 8, characterized in that the microprocessor ( 30 ) has a redundant two-processor system. Apparatus according to claim 8 or 9, characterized in that the microprocessor ( 30 ) at least one interface ( 33 to 35 ) for data input / output. Device according to one of claims 1 to 10, characterized that the Switching is done manually. Device according to one of claims 1 to 10, characterized that the Changeover is sensor-controlled. Apparatus according to claim 12, characterized in that for switching a temperature and / or brightness sensor ( 16 ) is provided. Device according to one of claims 1 to 13, characterized in that the element ( 1 ) Is part of a tile. Device for using solar energy, with at least one element receiving sunlight, with which the sunlight is converted into another form of energy and supplied to a consumer, characterized in that for defrosting snow / ice on the element ( 1 ) this element is heated by reversing the flow of energy. Apparatus according to claim 15, characterized in that the energy is supplied to the consumer ( 3 ) is taken. Apparatus according to claim 15 or 16, characterized in that the energy is electricity, the power grid ( 3 ) is taken.