DE102010007484A1 - Controller for photovoltaic system for generating alternating current from solar energy, has control unit, multiple inputs corresponding to number of photovoltaic moduIes and measuring unit - Google Patents

Abstract

The controller has a control unit (3), multiple inputs (4) corresponding to the number of photovoltaic moduIes (1), and a measuring unit. The control unit enables a variable connection of the photovoltaic moduIes to all or only a portion of an inverter (2). The measuring unit enables a continuous or intermittent measurement of direct current voltage applied to each input. A switching unit is provided which is connected with the inputs on one side and with a direct current output of the inverter on the other side.

Description

The invention relates to a control of photovoltaic systems for generating alternating current.

Such photovoltaic systems consist of a plurality of usually plate-shaped photovoltaic modules, which are arranged on roofs, on walls or on racks to absorb sunlight and convert it into electricity.

As a result, each photovoltaic module generates at its output an electrical voltage whose magnitude depends on the intensity of the incident light and a corresponding electrical current.

Since the intensity of the sun's radiation is very different depending on the time of day, weather conditions, cloud cover, shading by other objects, and angle of incidence in direct sunlight, the voltage generated by the respective module is correspondingly different.

The photovoltaic modules are followed by an inverter, which converts the direct current generated by the modules into alternating current, the voltage of which corresponds to the mains voltage, and which can be consumed or fed into the alternating current network.

In order for the inverters to work, the input voltage on the DC side of each inverter must reach a certain minimum value, but on the other hand must not exceed a certain maximum value so that the inverter is not damaged or destroyed by overvoltage loading. Since the voltage generated by the individual photovoltaic modules is relatively small each inverter is assigned a group of several such modules, which are already connected in series by mutual wiring or in the input of the associated inverter, so that their respective output voltages on Add the DC input of the inverter to a total voltage. How many photovoltaic modules are grouped together and assigned to a particular inverter naturally depends on the characteristics of the individual modules and the inverter. In order to avoid overloading the inverter by overvoltage, the group of photovoltaic modules assigned to it may only contain so many modules that the maximum expected light intensity is not exceeded by the summed total voltage of these modules, the permissible DC input voltage at the inverter.

For this, however, must be taken into account that in the lower range of light intensities no AC power generation is possible because then the voltage applied to the DC input of the inverter summed total voltage of the modules for the operation of the inverter necessary minimum input voltage is not reached. This minimum input voltage is approximately in the range of 20% of the maximum input voltage. This means that in a range of up to about 20% of the maximum occurring light intensity this minimum input voltage is not reached, and therefore no usable current can be generated. This unusable lower range of illumination levels at the photovoltaic modules always occurs over a period of time during dawn and dusk, but may also persist during the daytime in fog, heavy cloud or other unfavorable conditions.

The generation of electricity by photovoltaic systems is part of the concept of renewable energy, where relatively high production costs have to be used in comparison with power generation from fossil fuels or nuclear energy, so that in many cases investments in renewable energies can only be achieved through subsidies.

Therefore, it is necessary to use the most efficient materials and methods to improve the cost-benefit ratio. Achieving the highest possible efficiency is therefore particularly necessary for a renewable energy generating plant, which includes photovoltaic systems.

The invention is therefore the object of photovoltaic systems in such a way that even in the lower light intensity range, where in conventional systems, the threshold voltage of the inverter is not reached and therefore the DC generated can not be exploited, an effective AC power generation is possible and thus the Yield of a photovoltaic system can be significantly increased.

This object is achieved according to the invention by the arrangement specified in claim 1.

In contrast to conventional photovoltaic systems in which each inverter a fixed number of photovoltaic modules assigned and hardwired connected to the inverter, the control of the invention provides a variable assignment of photovoltaic modules of a system to the inverters of the system. The photovoltaic modules are single or in Small groups are connected directly to the controller, which also connects the inverters of the system. For example, a small group of modules may comprise two or three modules, which together comprise only a fraction of a hitherto customary group of modules permanently assigned to an inverter. The controller measures the instantaneous output voltage of each individual photovoltaic module connected to the controller or each module small group connected to the controller and calculates the programmed characteristics of the inverters, which are different from inverter to inverter even if different inverters are used in a system can be used to interconnect how many modules or module small groups must be connected so that their accumulated individual voltages are above the input voltage threshold of a particular inverter. Based on these calculations, the controller then switches so many modules or small groups of modules to a specific inverter that it can work.

In unfavorable light intensity ratios more photovoltaic modules are thereby switched to an inverter, as is the case with the conventional fixed assignment of a certain fixed number of modules to a specific inverter. Depending on how many modules must then be switched to each inverter, so that the DC voltage input is applied to the minimum voltage and he can work, then under unfavorable light intensity ratios only a more or less large part of the total existing in a system inverter with modules , While under such conditions in conventional systems none of the inverters can work more and consequently the system does not provide usable alternating current, in the inventive concept, even under very unfavorable conditions, at least a part of the inverters still operate and generate usable alternating current. The yield of the system can be increased over conventional arrangements by about 15 to 20%.

The invention will be described in more detail below with reference to an embodiment.

The accompanying schematic drawing shows a trained according to the invention photovoltaic system.

The system includes a larger number of photovoltaic modules (for example, 36 such modules are shown schematically) and a smaller number of inverters 2 (In the embodiment, three inverters are shown), and a control device 3 ,

The control device 3 indicates one of the number of photovoltaic modules 1 corresponding number of inputs 4 on. Every photovoltaic module 1 is directly with an entrance 4 the control device 3 connected.

Alternatively, small groups of photovoltaic modules can be combined, for example, two or three modules connected together, which are then connected to one input of the control device, in which case the number of inputs of the controller corresponds to the number of small groups. The control device can also be designed from the outset with a larger number of inputs to allow a later expansion of the photovoltaic system.

Every entrance 4 the control device is connected or equipped with a measuring device which measures the voltage and preferably also the current at the respective input. Thus, the controller individually detects the voltage provided by each module (or each module small group) and the power supplied, resulting in the respective power of the module (or module small group).

The control device 3 also has a (not specifically shown) central unit, to which the measuring devices of all inputs 4 are connected. The central unit contains a computer that, due to programmed characteristics of the inverter 2 namely, in particular, their minimum input voltage on the DC input side and maximum input voltage or power, and based on the data supplied by the measuring devices, the optimum assignment of the individual modules 1 (or module small groups) to the individual inverters 2 determined so that even at low power of the individual modules in unfavorable lighting conditions the highest possible yield of usable alternating current can be achieved.

The number of inverters is chosen so that they can still process the DC quantities then supplied by the modules at maximum light intensity.

Is the light intensity relatively low, so that the output voltage and output power of the individual modules or module small groups have dropped to a value or have such a low value that the inverter in question can no longer work efficiently or even the required minimum input voltage is no longer achieved grouped the central unit to the assignment of modules or small groups of modules to the inverters so that a larger number of modules, namely so many modules are switched to an inverter that it can work. Then only a part of the inverters works, because then no modules are connected to one or more inverters, but even in unfavorable conditions still usable alternating current is generated, whereas in conventional systems none of the inverters can work anymore and no usable power generation takes place can.

So the central unit controls a control center 5 the control device 3 with which the entrances 4 the control device and the inputs of the inverter 2 are connected. Under the control of the central unit thus configures the control center 5 the connections between the inputs 4 the controller and the inputs of the inverters 2 in the manner mentioned.

Likewise, the controller reconfigures the assignment of the modules (or small module groups) to the inverters as conditions change from low light intensity to higher or high light intensity to then distribute the output power of the modules (or module small groups) to more inverters ,

The other advantages of the arrangement according to the invention also include greater flexibility. An exchange of photovoltaic modules for such higher performance is possible as an exchange of existing inverter against other inverters with different characteristics, which is particularly important if after several years of operation defective components must be replaced, because then possibly components with the original Characteristics are no longer available. Differently high-performance modules or module small groups as well as inverters of different power are automatically taken into account in the calculation of the optimal configuration of the system under all lighting conditions.

Claims (1)

Control for photovoltaic systems, which use a larger number of photovoltaic modules ( 1 ) for photovoltaic generation of direct current due to incident light, and a smaller number of at least two inverters ( 2 ), wherein the plurality of photovoltaic modules ( 1 ) comprises a plurality of groups of a plurality of modules each, and the modules of each group are connected to the DC input of one of the inverters ( 2 ), characterized in that a control device ( 3 ) for the variable connection of the photovoltaic modules ( 1 ) on all or only part of the inverters ( 2 ), the photovoltaic modules ( 1 ) individually or in small groups, each with its own entrance ( 4 ) of the control device ( 3 ) and each input ( 4 ) of the control device ( 3 ) is associated with a measuring device for measuring at least the voltage applied to the respective input DC voltage that further the control device ( 3 ) a switching device ( 5 ) connected to the inputs ( 4 ) of the control device on the one hand and with the DC inputs of the inverters ( 2 ) and the optional connection of each input ( 4 ) of the control device ( 3 ) with any of the DC inputs of the inverters ( 2 ) and that the control device ( 3 ) contains a computer which, due to the programmable characteristics of the inverters ( 2 ) and at the entrances ( 4 ) the control device measured voltages applied to the switching device ( 5 ) in each case such that the sum of the voltages to the at each one inverter ( 2 ) inputs ( 4 ) does not exceed an admissible input voltage of the inverter, but on the other hand, when applying only low voltages at the inputs ( 4 ) of the controller by reconfiguring so many inputs ( 4 ) to the DC input of at least one inverter ( 2 ) are placed so that its minimum input voltage is exceeded.

Images