DE102009055684A1 - Interconnected electrical component for e.g. power generation, in building, has sunlight-powered photovoltaic system generating primary energy for operation of photovoltaic system in building - Google Patents

Abstract

The system consists of several components that are interconnected and thus increase the yield of conventional photovoltaic systems. In detail, the system can be set up and operated as a combination of a photovoltaic system on a building roof and a photovoltaic system in the building, as well as an independent system in the building. Thus, the generation of ECO energy can be generated without environmental pollution. Photovoltaic cells convert light into electrical energy. The system uses both sunlight and / or artificial light. As an unavoidable by-product, heat is generated in this system, which has to be dissipated. This heat is used by the system for heating support and hot water preparation in the building.

Description

The system is applicable considering several configuration options. In the 1 and 2 The configuration shown is structured as follows:
The sunlight ( 1 ) is supported by the photovoltaic modules located on the rooftop ( 2 ) converted into electrical energy. This is via the supply line ( 3 ) on the one hand the solar charge controller ( 4 ) supplying both the accumulators ( 9 ), as well as the power of the inverter ( 8th ) for feeding via a counter in an AC mains supplies. The photovoltaic generator in the building ( 7 ) converts artificial light into electrical energy. The artificial light ( 5 ) draws the required energy from the batteries ( 9 ). The photovoltaic generator in the building ( 7 ) produced direct current is the inverter ( 8th ). However, this can also optionally also the solar charge controller ( 4 ). The artificial light ( 5 ) can be generated by a cooling water circulation system ( 15 ) are used for heating support and support of hot water preparation. (Removal of the generated heat is necessary for two reasons: 1. Extending the service life by reducing the wear of the lamps and 2. Reducing the heat generated at the photovoltaic modules in the building ( 7 ). The photovoltaic modules have a significant power loss from a temperature of 25 ° C on.) Here comes a hot water tank ( 16 ), which is connected to the heating and hot water network, and both the waste heat from the artificial lighting ( 5 ), as well as if necessary additionally electrically operated.

This in 3 shown system is identical in its function as in 1 and 2 described. However, the only difference is that the primary energy is not supplied by a solar-powered photovoltaic system, but by means of an artificially illuminated photovoltaic island system in the building.

This in 4 shown system is identical in its function as in 3 described. However, the only difference is that the primary energy is not obtained from a photovoltaic stand-alone system but from the in-house power grid. Alternatively, it is also possible to integrate accumulators in this system, which are charged via the in-house power grid.

Claims (6)

Interconnection of various electrical components for power generation, characterized by the combination of a solar-powered photovoltaic system on a building roof and a photovoltaic system powered by artificial light in the building. The photovoltaic system located on the building roof primarily generates the energy for the artificial light to operate the photovoltaic system in the building. ( 1 and 2 ) Interconnection of various electrical components for power generation, characterized by the combination of an artificial light powered photovoltaic system in a building, which derives its primary energy for the artificial lighting of an artificial light-powered photovoltaic stand-alone system in the building. ( 3 ) Interconnection of various electrical components for power generation, characterized by an artificial light operated photovoltaic system in a building, which receives its primary energy for the artificial lighting either from at least one accumulator or via an external power supply. ( 4 ) Interconnection of various electrical components for power generation, heating support and support of hot water in the building, characterized by the combination of a solar-powered photovoltaic system on a building roof and a photovoltaic system powered by artificial light in the building. Wherein the photovoltaic system located on the building roof primarily generates the energy for the artificial light for operating the photovoltaic system in the building, characterized in that the heat generated by the artificial light source is dissipated via a cooling circuit system and is directed into a hot water tank. ( 1 and 2 ) Interconnection of various electrical components for power generation, heating support and support of domestic hot water, characterized by the combination of an artificial light photovoltaic system in a building, which derives its primary energy for artificial lighting from an artificial light-powered photovoltaic stand-alone system in the building characterized in that the heat generated by the artificial light sources is dissipated via a cooling circuit system and is passed into a hot water tank. ( 3 ) Interconnection of various electrical components for power generation, heating support and support of domestic hot water, characterized by an artificial light photovoltaic system in a building, which has its primary energy for the artificial lighting of at least one Accumulator or via an external power supply relates, characterized in that the heat generated by the artificial light sources is dissipated via a cooling circuit system and is directed into a hot water tank. ( 4 )

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