CH701857A2 - Device for combined, multi-positional utilization of photovoltaic generators and wind generators, at e.g. line infrastructure construction of rail traffic, has blower controller converting electrical energy - Google Patents

Abstract

The device has an integrated blower controller (3) for converting electrical energy, and a storage medium (4) for storing the energy. The unit allows contact line rods and a contact line wire to accommodate vertical solar modules (1) and to directly transporting the obtained electrical energy. Power rods and a power line network are provided to accommodate the solar modules and for directly transporting the obtained electrical energy. A small wind generator (2) is provided with a vertical rotation axis on a head of the contact line and power rods. The unit is made of composite materials.

Description

The invention relates to the combined, multi-positional use of passive solar energy production components (photovoltaic and wind generators) in public infrastructure infrastructure such as: Infrastructure infrastructure buildings of rail transport Building infrastructure buildings of rail transport Lighting infrastructure buildings of public street space Energy transportation infrastructure buildings of energy supply

Photovoltaics in the form of solar modules are used for years increasingly in private buildings, large buildings complexes or public buildings, on building surfaces of industrial buildings for the production of electricity. Today, three types of solar cells are used heavily: Thin-film modules based on silicon (6-10% efficiency) Monocrystalline modules based on high-purity silicon (efficiency 16-21.5% / Ø 18.5%) Polycrystalline silicon solar cells (efficiency 14-16%) In the near future, so-called concentrator multilayer modules are expected on the market. With this method of construction, the degree of utilization compared to today's modules is increased to more than 35%.

Wind generators of all sizes and types of construction have been on the market for years. For the described, intended use especially small generators with vertical axis of rotation come into question.

The uses and applications described are concentrated mainly in regions of urban character, densely populated areas with a high degree of industrialization or in exposed regions with high insolation levels (e.g., deserts) at sea level or in alpine regions.

The efficiency and cost-effectiveness of these solutions is limited by local weather conditions, the average sunshine duration, the intensity of the radiation of the sun, the outside temperatures or by high flanking investment measures to additional necessary infrastructures such as pipeline networks.

Today, the electrical energy produced by photovoltaic and wind is conducted via converters (charge controller) in existing networks of electrical energy suppliers or stored in large accumulator systems. This process is also associated with additional material and financial investment.

The energy form of these two described renewable energy generation types is called supplementary energy, since they do not allow continuous energy production in comparison to the constant band energy of nuclear power plants and river or run power plants.

The purpose of the universal use of solar and wind energy infrastructure projects in public space is to produce the electrical energy where the necessary infrastructure for receiving solar modules and wind generators are present in large numbers and where the infrastructures for the transport of electrical won Energy is already realized. These infrastructure structures must have the character of a repetitive grid with the same modularity over a larger regional extent. The simultaneous combination of solar modules and wind generators on the same support structure, the weather disadvantages (lack of sun, night, calm) can be reduced and the fluctuations of this supplementary energy form can be optimized.

From the idea existing infrastructure elements (masts), which are in very great numbers worldwide in various functions in use, a development is to improve the construction of these infrastructure elements so that the primary function of the static element, the function of the extraction of take over renewable energies.

Existing Infrastructures:

These are in particular for the attachment and positioning of solar modules and wind generators: Pylons of rail transport Pylons of lighting pylons in public street space Pylons of transport networks of electric energy producers and energy suppliers Building surfaces of infrastructure buildings of the same typology along railway lines Areas of engineering structures of the same typology along railway lines

The universal use of solar and wind energy infrastructure projects in public space consists essentially of the following components: <Tb> FIG. 1 <sep> Scheme of existing railway infrastructure in rail transport <Tb> FIG. 1.1 <sep> best. line network <Tb> FIG. 1.2 <sep> best. mast <Tb> FIG. 2/1 <sep> Vertical solar modules on masts <Tb> FIG. 2/2 <sep> Small wind generator with vertical axis of rotation on the head of masts <Tb> FIG. 2.3 <sep> Charger Controller <Tb> FIG. 2.4 <sep> storage medium <Tb> FIG. 3 <sep> Horizontal arc solar modules between masts along the rail direction <Tb> FIG. 4 <sep> Horizontal arc solar modules between poles transverse to the rail direction

Calculation example:

If each line mast of a single-lane narrow-gauge railway with a mast spacing of on average 25 m equipped with a quadrant vertical solar module of 4.0 m × 0.5 m, this train has on the route length of 100 km an available solar panel area of about 6400 m <2> , This area can produce a rated power (conventional P with 165 W / m <2> / STC efficiency grave of 13.1%) of approximately 910 MWh / year of energy. In the same system, there are 4,000 micro-wind generators. With a minimum nominal power of 50 W, approx. 300 MWh / year electrical energy can be generated.

Claims (9)

1. Solar energy use in infrastructure buildings of railway traffic (overhead line), characterized in that the infrastructures with modular grid character and supraregional expansion, consisting of catenary masts and catenary wire for the inclusion of solar modules and the transport of electrical energy obtained are used directly. 2. Solar energy use in infrastructure buildings of public street space (street lighting), characterized in that the infrastructures are used with modular grid character and supraregional expansion, consisting of candelabra and power line network for the inclusion of solar modules and the transport of electrical energy. 3. Solar energy use in infrastructure buildings of the energy-producing sector (overhead lines), characterized in that the infrastructures are used with modular grid character and supraregional expansion, consisting of electricity pylons and power line network for the inclusion of solar modules and the transport of electrical energy. 4. Wind energy use in infrastructure buildings of railway traffic (overhead line), characterized in that the infrastructures with modular grid character and supraregional expansion, consisting of catenary masts and catenary wire for receiving wind generators and the transport of electrical energy obtained directly. 5. Use of wind energy in public road infrastructure (street lighting) characterized by the fact that the infrastructures with modular grid character and supraregional extension, consisting of candelabra and power line network, are used directly to accommodate wind generators and to transport the generated electrical energy. 6. use of wind energy infrastructure projects in the energy-producing sector (overhead lines), characterized in that the infrastructures are used with modular grid character and supra-regional expansion, consisting of electricity pylons and power line network for receiving wind generators and the transport of electrical energy. 7. Renewable energy use of infrastructure elements such as catenary masts, candelabra, power line masts, communication line masts, characterized in that they are made of composite materials and the surface treatment is performed with a solar cell coating in the thin-film process for the production of electrical energy. 8. Renewable energy use on infrastructure elements such as catenary masts, candelabra, power poles, communication towers, characterized in that they are made of composite materials and have integrated, rotating in the vertical axis wind generators. 9. Renewable energy use of infrastructure elements such as catenary masts, candelabra, power poles, communication towers, characterized in that they are made of composite materials and have integrated charge controller for the conversion of electrical energy and storage media for storing electrical energy.