DE102010005567A1 - solar module - Google Patents

Abstract

The present invention relates to a solar module (1) for a solar system (14) - with at least one solar panel (2) with several solar cells that emit a solar voltage (USol) to a solar module output (3) when light falls, - with at least one in the solar module (1) Integrated energy storage device (4) which is connected on the input side via a control / regulating device (5) to the solar panel (2) and on the output side to the solar module output (3), with a predefined module voltage (UMod) at the solar module output (3) - The controlling control / regulating device (5) is designed in such a way that when the solar voltage (USol) is exceeded above the predefined module voltage (UMod) and when the solar voltage (USol) falls below the predefined module voltage (UMod), it Discharge the charging current to the energy store (4) and charge it if necessary. It is essential to the invention that the control / regulating device (5) is designed in such a way that, depending on the solar voltage (USol), it can separate the solar panel (2) or the energy store (4) or the solar panel (2) and the energy store (4 ) switches in parallel to the solar module output (3).

Description

The present invention relates to a solar module for a solar system with at least one solar panel having a plurality of solar cells, which emit a solar voltage at a solar module output in the event of light, according to the preamble of claim 1. The invention also relates to a solar system equipped with such a solar module.

Previous technical solutions for the production of electrical energy from solar energy use interconnected solar modules in conjunction with an external inverter and, if necessary, an external buffer for the electrical energy obtained from the solar modules. However, interconnected or partially shaded solar modules cause the corresponding string (series connection of solar modules) hardly contributes to energy, since the minimum input voltage of the inverter for this strand is undershot at already relatively low load current. As a common solution to this, the shaded or partially shaded solar modules are bridged with a switch to remove from the remaining, not shaded solar modules the full potential load current in the strand can. The disadvantage here, however, is that with several switched off solar modules in the strand, the minimum input voltage of the inverter can be exceeded, which means that this strand does not contribute to energy or the inverter is switched off, although the unshaded modules still bring the full power.

From the DE 20 2009 009 484 U1 is a generic solar module for a solar system with at least one solar panel and several solar cells known that emit a solar voltage to a solar module output in case of light. Also provided are at least one integrated into the solar module and rechargeable energy storage and a control / regulating device, which derives a charging current to the energy storage device when the solar voltage is exceeded via a predefined module voltage at the solar module output and thereby charges. In order to be able to keep the module voltage as constant as possible, that is to be able to compensate for shaded or partially shaded solar modules, the solar module voltage is stabilized via an output stage, wherein in unshaded solar modules, the energy storage is charged by the solar panels of the solar module, while shaded or partially shaded solar modules the energy storage is connected in series with the solar cells, to prevent the module voltage falls below a predetermined value. In this way it can be prevented that, in spite of shaded or partially shaded solar modules in the strand, this can still make a contribution to the generation of energy.

A disadvantage of the known solutions, however, is that a relatively high internal resistance of the shaded or partially shaded solar module in the strand remains fully effective through the series connection of the energy storage with the solar cells of the shaded solar module, which means that this solution increases the module voltage of the solar module, the maximum Strand current, however, is determined unchanged by the most heavily shaded solar module in the strand, although the other non-shaded solar modules in the strand could provide a substantially higher current.

The present invention therefore deals with the problem of providing for a solar module of the generic type an improved or at least one alternative embodiment, which in particular does not have the disadvantages known from the prior art.

This problem is solved according to the invention by the subject matters of the independent claims. Advantageous embodiments are the subject of the dependent claims.

The present invention is based on the general idea to provide an energy storage for intermediate storage of electrical energy in a known per se solar module for a solar system with multiple solar cells, as well as a control / regulating device, depending on the solar cell generated by the solar voltage solar cells or the Energy storage either separately or switch the solar cells and the energy storage parallel to an output of the solar module, thereby enabling a separate current drain from the energy storage, especially in a shaded or partially shaded solar module, without this makes the negative by the shading relatively high internal resistance of the solar cells , An electrical energy store is thus integrated in the solar module according to the invention, which electrically simulates the solar cells of the solar module in such a way that an optimum operating voltage range of the electrical energy store is within the optimum operating voltage range of the solar cells or the solar module and can be electrically connected in parallel, so that both from the Solar cells as well as from the integrated electrical energy storage in parallel or separately energy can be removed. In an unshaded solar module thus the integrated electrical energy storage is charged due to the relatively high power production in the solar cell, with always a sufficient proportion of the solar module generated by the solar or solar cells Energy is available externally. If one or more solar modules are shaded in a string, their internal resistance increases, which leads to a decrease in the output voltage of the solar modules, ie the module voltage, when loaded (current drain). If the module voltage of the shaded solar modules drops below that of the parallel-connected, integrated electrical energy store, they give off electrical energy and take over at least that part of the load current which the shaded solar modules or the shaded solar cells of the same can no longer supply. Since the operating voltage of the energy storage is in the range of the optimum operating voltage of the solar module or solar cells, the module voltage changes only slightly in shading, the maximum load current further removed and the residual energy that can provide the shaded solar cells, can be additionally exploited. Of particular advantage here is that energy from the solar cells, the integrated energy storage or both can be removed simultaneously, without requiring changes to external electrical controls or voltage converters (inverter) would be made. The integration of the energy storage in the respective solar module is achieved at the same time that the total capacity of the energy storage automatically changes with the number of interconnected solar modules, without additional external expenses would be required. By many decentralized and each integrated into the associated solar modules energy storage also optimal utilization of available for energy production area can be achieved because the energy storage no additional area is needed, but these can be easily built under already conventionally known solar modules. As a result, a significantly higher reliability with regard to the energy supply can be achieved. In case of failure, for example, a solar module of a modular solar system, now would not turn out the entire system, but only a corresponding percentage of the total capacity are no longer available. In addition, the solar modules according to the invention can be combined as desired, whereby a high degree of flexibility with regard to the energy supply system to be created can be achieved.

In an advantageous development of the solution according to the invention, at least one fan usable as a generator is provided below the solar module, which causes cooling of the energy store and / or the solar module in the fan mode and in the generator mode by means of wind energy charges the at least one energy storage of the solar module. By mounting the solar modules according to the invention on the associated roof surfaces, between these and the underlying roof surface creates a kind of chimney that creates a chimney effect, so that especially in wind arranged in this chimney fan can be used as electrical generators and used to charge the energy storage can. At comparatively high ambient temperatures and intense sunlight, the fans can also be used in fan mode and thereby cool the solar modules, which can be prevented even at a high power load too high a drop in the module voltage. In this case, a negative temperature coefficient of the solar voltage is to be observed in a too high heating of the solar modules, so that a significant decrease in power is observed especially in intense sunlight and strong heating of the solar cells, which in extreme cases can lead so far that a minimum input voltage of a Inverter falls below and thereby the solar module is switched off, although due to the intense sunlight optimum conditions for solar power generation would be given. The active cooling of the solar module by means of the intended fan thus the operation of the solar modules and at the same time a high power production is guaranteed even in intense sunlight, which significantly increases the performance of such solar modules, as these are not as previously in excessive heating due to the negative temperature coefficient of performance but can retain their efficiency due to the active cooling even in intense sunlight.

The invention is further based on the general idea of equipping a solar system with a plurality of interconnected solar modules as well as a likewise networked computer and control device, wherein the computer and control device is able to compensate for electrical peak and / or unbalanced and / / or to be able to temporarily store overcapacities in the decentralized energy stores of the solar modules and / or in an external energy store. For this purpose, of course, the individual solar modules and the external energy storage are provided with appropriate data interfaces for communication. For example, the computer and control device during the night hours, the respective solar modules switch so that only energy is taken from the respective decentralized energy storage, whereby a compensation between the day and night hours can be achieved. The computer and control device is able to access each of the networked, decentralized energy storage and to detect and process their charge states or capacities. The computer and control device can thus at any time a precise overview of, for example, the performance of the solar cell of the respective solar modules, the Supply state of decentralized and integrated into the solar modules energy storage or the external energy storage and thereby manage the power generation and storage centrally.

Other important features and advantages of the invention will become apparent from the dependent claims, from the drawings and from the associated figure description with reference to the drawings.

It is understood that the features mentioned above and those yet to be explained below can be used not only in the particular combination given, but also in other combinations or in isolation, without departing from the scope of the present invention.

Preferred embodiments of the invention are illustrated in the drawings and will be described in more detail in the following description, wherein like reference numerals refer to the same or similar or functionally identical components.

Show, in each case schematically,

1 an inventive solar module in a view from below and from the side,

2 a schematic diagram of the solar module according to the invention,

3 an integration diagram of the solar module in a solar system,

4 a schematic diagram of a solar system according to the invention.

According to the 1 has a solar module according to the invention 1 a solar panel 2 with a plurality of solar cells, not shown in detail, which, upon incidence of light, emit a solar voltage U _Sol to a solar module output 3 submit. in the solar module according to the invention 1 is beyond at least an electric, rechargeable energy storage 4 integrated, the input side via a control / regulating device 5 , also called charging circuit for short, (cf. 2 ) with the solar panel 2 and on the output side with the solar module output 3 connected, wherein at the solar module output 3 a predefinable module voltage U _mod ) is applied, with which the solar module 1 on a solar system 6 (see. 3 and 4 ) is aufschaltbar. The control / regulation device 5 conducts a charging current to the energy storage 4 and charge it, taking the solar panel 2 delivered solar voltage U _{Sol may be} greater or smaller than the predefined module voltage U _mod . The control / regulation device 5 is also designed such that it depends on the solar voltage U _Sol the solar panel 2 or the energy storage 4 each separately or the solar panel 2 and the energy storage 4 parallel to the solar module output 3 on.

With not shaded solar module 1 becomes the integrated electrical energy storage 4 via the controllable control / regulation device 5 Charging and discharging circuit with a smart energy management controls charged, with always a sufficient proportion of the solar module 1 or from the solar panel 2 generated electrical energy to a power grid 13 is issued, that is externally available. Will the solar panel 2 , Shaded by clouds, for example, increases its internal resistance, resulting in particular in a load (current drain) to a decrease in the solar voltage U _Sol and thus the module voltage U _mod . Decreases the module voltage U _{Mod of} the shaded solar module 1 below that of the parallel-connected integrated electrical energy store (s) 4 , so give this electrical energy and take over at least the part of the load current, the shaded solar panel 2 or the shaded solar cells can no longer deliver / can. According to the 1 and 2 is only a solar panel 2 and in each case only an electrical energy store 4 each solar module 1 it being understood, of course, that of these several may be arranged. As the operating voltage of the energy storage 4 in the range of the optimum operating voltage of the solar module 1 or the solar panel, the module voltage U _mod changes only slightly in shading, the maximum load current further removed and the residual energy that can provide the shaded solar cells, can be used simultaneously. With the solar module according to the invention 1 It is thus possible, an individual energy extraction from the solar panel 2 , the energy storage 4 or to choose from both simultaneously, with a simultaneous energy extraction from the solar panel 2 and the energy storage 4 these are connected in parallel and thereby a passage of the current from the energy storage 4 through the solar panel 2 and associated with it a high internal resistance of the solar panel 2 can be bypassed. With the parallel connection according to the invention, the performance of the solar module according to the invention increases 1 considerably.

The control / regulation device 5 is preferably designed so that they fall below the predefined and desired module voltage U _mod the energy storage when falling below the solar voltage U _Sol 4 parallel to the solar panel 2 turns off, leaving the solar module output 3 the solar voltage U _Sol and the storage voltage U _{Bat of} the energy storage 4 lie parallel and the load currents from solar panel 2 and energy storage 4 Add them to the Solar module output 3 discharged memory voltage U _Bat to the solar voltage U _Sol adapts, so that at the solar module output 3 always a precisely definable, and preferably constant module voltage U _Mod applied. The energy storage 4 can have at least one accumulator and / or a high-capacitance sensor or even a combination of both. The control / regulating device according to the invention 5 is able to output power into a state of charge of the at least one energy store 4 to monitor and control, with the operating voltage ranges of the energy storage 4 and the solar module 1 or of the solar module 2 preferably designed the same.

How the particular 1 can be further seen, below the solar module 1 at least one fan that can be used as a generator 6 be provided, which in cooling fan cooling of the energy storage 4 and / or the solar module 1 causes and generator operation by means of wind energy the at least one energy storage 4 of the solar module 1 charging. It should be noted that between the on a roof surface 7 mounted solar module 1 and the roof area 7 a fireplace-like cavity 8th arises, which creates a chimney effect especially in wind and sufficient, the fan 6 or a fan wheel of the respective fan 6 to move and thereby generate electrical energy. At the same time provide the invention arranged fan 6 the big advantage of being the solar module in high and intensive sunlight 1 and especially the solar panel 2 cool and thereby ensure their performance. In the case of very intense solar radiation, that of the solar panel sinks 2 producible solar voltage U _Sol due to the negative temperature coefficient, so that it may happen in the worst case, that an inverter 9 the solar panel 2 and thus the solar module 1 due to the low solar voltage generated U _Sol shuts off, although the sun's rays optimal for the energy production of the solar module 1 could be used. Here, the inventively arranged fan acts 6 against, by the solar module 1 cools and thereby counteracts the negative temperature coefficient, so that an undesirably strong decrease in the solar voltage U _Sol avoided and thus also an unwanted shutdown of the solar module 1 can be prevented.

Looking at the 2 , so you can tell that the solar panel 2 , the control / regulation device 5 and the at least one energy store 4 via an interface 10 and a data bus 11 communicating with each other.

Each of the solar modules according to the invention 1 has a (data) interface for data transfer and connection to an external server 12 (see. 4 ) as well as with other solar modules 1 , The according to the 4 illustrated solar modules 1 can be identical or different types. About the inverter 9 are the individual solar modules 1 to a power grid 13 connected. The individual solar modules 1 You can also use a solar system 14 summarized and optionally with an external energy storage 15 (see. 3 ), for example, a collective memory to be connected to store electrical energy, the server 12 puts one with the individual solar modules 1 as well as with the power grid 13 and optionally with the external energy storage 15 networked computer and control device which is designed such that the energy supplier can access them and control them so that electrical peak and / or unbalanced loads in the power supply network compensate and / or over-capacity in the energy storage 4 . 15 can be cached.

In general, the integration of the energy storage takes place 4 in the solar module 1 electrically and constructively such that solar modules 1 with energy storage 4 outward like the same solar modules 1 without electrical energy storage 4 behave and connect together. According to the invention can thereby electrical energy from the solar panels 2 , the energy storage 4 or simultaneously taken from both without making changes to the external electrical controls and inverters 9 (Inverter) would have to be made. Through the integration of energy storage 4 into the solar modules 1 can be achieved at the same time that the total capacity of the energy storage automatically changes with the number of interconnected solar modules, without additional external requirements would be required. The control / regulation device 5 is designed such that charging the energy storage 4 also via a (bidirectional) inverter from the power grid 13 can be done. The controllable charge and discharge circuit, that is the control / regulating device 5 has the interface mentioned above 10 That is, via a communication interface, for external control of the charge and discharge of the energy storage 4 and for external query of the current operating status of the solar module 1 that is the solar panel 2 and the integrated energy storage 4 , The individual solar modules 1 the solar system 14 are with each other via this communication point, that is via the interface 10 , networked and with the server 12 the solar system 14 connected, the server 12 the state of the individual solar modules 1 monitors and controls and thereby calculates the current state of the solar system. The server 12 can have a LAN / WAN interface that allows a consumer or utility to the current state (power output, charging capacity) of the solar system 14 to query and control and thereby prepare in particular, for example, peak loads, in which the energy storage 4 and / or the energy storage 15 is summoned. Through remote access via the LAN / WAN interface of the server 12 on the individual solar modules 1 In addition, rapid troubleshooting is possible and thus efficient preparation and execution of maintenance work. Of course, the normal current-carrying lines at the solar module output can also be used for data transmission 3 be used. In the external energy storage 15 For example, larger amounts of energy can be stored, especially if the solar modules 1 provide enough energy, but this is currently not needed and at the same time the electrical energy storage 4 in the individual solar modules 1 are fully charged. The external energy storage 15 is designed so that even energy from the mains 13 recorded, cached and, if necessary, back into the power grid 13 can be fed back, the energy storage 15 also has its own communication interface and thereby by means of the server 12 can be monitored and controlled.

Preferably, the individual solar systems 14 regionally networked and can, if necessary, compensate for peak loads or unbalanced loads in the power supply network by means of an intelligent controller and cache them via capacities. The advantage of such a decentralized, distributed and modular system lies in the significantly higher reliability and availability as well as any expandability. In particular, in the event of an accident, this has an advantageous effect, since not the entire system, but only single, easily replaceable, components would fail. It is also possible to use existing solar systems 14 during maintenance with the solar modules according to the invention easily 1 retrofit. Through the integration of energy storage 4 into the respective solar modules 1 In addition, the space requirement can be limited because no additional area is needed for the intermediate storage of electrical energy.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 202009009484 U1 [0003]

Claims (12)

Solar module ( 1 ) for a solar system ( 14 ) - with at least one solar panel ( 2 ) with a plurality of solar cells which, upon incidence of light, emit a solar voltage (U _Sol ) to a solar module output ( 3 ), with at least one into the solar module ( 1 ) integrated and rechargeable energy storage ( 4 ), the input side via a trained in the manner of a charging circuit control / regulation device ( 5 ) with the solar panel ( 2 ) and on the output side with the solar module output ( 3 ), wherein at the solar module output ( 3 ) a predefined module voltage (U _Mod ) is applied, with which the solar module ( 1 ) on the solar system ( 14 ), wherein the controlling control device ( 5 ) is designed such that, when the solar voltage (U _Sol ) is exceeded, it exceeds the predefined module voltage (U _Mod ) and falls below the predefined module voltage (U _Mod ) when the solar voltage (U _Sol ) falls below the predefined module voltage (U _Mod ). 4 ) and can charge it, characterized in that the control device ( 5 ) is designed so that it depends on the solar voltage (U _Sol ) the solar panel ( 2 ) or the energy storage ( 4 ) each separately or the solar panel ( 2 ) and the energy storage ( 4 ) parallel to the solar module output ( 3 ) switches. Solar module according to claim 1, characterized in that the control / regulating device ( 5 ) is designed such that, when the solar voltage (U _Sol ) falls below the predefined module voltage (U _Mod ), it stores the energy store ( 4 ) parallel to the solar panel ( 2 ), so that at the solar module output ( 3 ) the solar voltage (U _Sol ) and a storage voltage (U _Bat ) of the energy store ( 4 ) parallel, whereby the to the solar module output ( 3 ) output memory voltage (U _Bat ) is adapted to the solar voltage (U _Sol ), so that at the solar module output ( 3 ) always a precisely definable, preferably constant, module voltage (U _mod ) is applied. Solar module according to claim 1 or 2, characterized in that the energy store ( 4 ) has at least one accumulator and / or a high-capacitance capacitor. Solar module according to one of claims 1 to 3, characterized in that the control / regulating device ( 5 ) is designed such that it has a power output and a state of charge of the at least one energy store ( 4 ) monitors and controls. Solar module according to one of claims 1 to 4, characterized in that an operating voltage range of the at least one energy store ( 4 ) an operating voltage range of the solar module ( 1 ) or the solar panel ( 2 ) corresponds. Solar module according to one of claims 1 to 5, characterized in that below the solar module ( 1 ) at least one usable as a generator fan ( 6 ) is provided, which in cooling fan cooling of the energy store ( 4 ) and / or the solar module ( 1 ) causes and in generator mode by means of wind energy the at least one energy storage ( 4 ) of the solar module ( 1 ). Solar module according to one of claims 1 to 6, characterized in that a particular bidirectional inverter ( 9 ) is provided, which is a charge of the energy store ( 4 ) and / or an external energy store ( 15 ) by an external power supply. Solar module according to one of claims 1 to 7, characterized in that the solar module ( 1 ) a (data) interface for data transmission and for connection to an external server ( 12 ) or with other solar modules ( 1 ) having. Solar system ( 14 ) with at least one solar module ( 1 ) according to one of claims 1 to 8 and with an external energy store ( 15 ) for storing electrical energy supplied by a power grid ( 13 ) and with at least one solar module ( 1 ) connected is. Solar system according to claim 9, characterized in that a plurality of interconnected solar modules ( 1 ) as well as a likewise networked server ( 12 ) are provided which is designed such that it electrical peak and / or unbalanced loads in the power grid ( 13 ) and / or overcapacity from the electricity grid ( 13 ) in the energy stores ( 4 ) of the solar modules ( 1 ) and / or in the external energy store ( 15 ) can cache. Solar system according to claim 9 or 10, characterized in that a direct current power (P _DC ) of the solar cells of the solar panels ( 2 ) in the solar modules ( 1 ) is greater than a rated power (N _C ) of the (photovoltaic) inverter ( 9 ) and the power difference for charging the energy storage ( 4 ) is usable in the solar system, so that with reduced or no power output of the solar cells of the solar panels ( 2 ) for the inverters ( 9 ) required power from the energy storage ( 4 ), whereby, with the same illumination duration of the solar cells, an extension of the feed of the inverters ( 9 ) in the power grid ( 13 ). Solar installation according to one of claims 9 to 11, characterized in that a storage of energy in the external energy storage ( 15 ) in a non-electrical form, in particular chemically, thermally and / or mechanically.

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