DE19518992A1 - Solar energy storage to power buildings - Google Patents

Abstract

In the recovery of the energy requirements of buildings, sodium hydroxide is broken down using solar energy into sodium and water, with oxygen release. When energy is required, oxygen is produced by the bringing together of sodium and water, together with a release of heat. The oxygen is subsequently combusted giving out further heat energy, and additionally produces electricity in combustion engines through a generator.

Description

Method according to the above claim 1, characterized in that in a tank 1 (see picture) there is sodium hydroxide dissolved in water. This is conducted in solar collectors 2 (e.g. parabolic mirrors, curved line mirrors, etc.) and heated there by means of concentrated sunlight. Subsequently, the sodium hydroxide in the container 4 , into which it was transported via insulated lines, is split into sodium, water and oxygen with the help of electricity obtained from solar cells 3 from solar radiation. The oxygen escapes into the atmosphere. The resulting water is collected in the tank 5 , while the sodium is stored in the container 6 with the exclusion of oxygen and water. The process described so far mainly takes place in the summer months rich in solar energy, but can also be carried out in a weakened form in spring and autumn and again reduced in winter.

If heat energy or electricity is now required, 7 water and sodium are introduced from the containers 5 and 6 into the energy-free device. The water is transported in liquid form, while the sodium is either transported in solid form or it is transported in liquid form. In the latter case, the sodium must be liquefied by means of the energy supplied (either with electricity which is supplied via the external power line 15 or with the internal heat produced by the system). If water and sodium meet in system 7 , sodium hydroxide and hydrogen are suddenly formed with the release of heat. The heat released can now be used either for the aforementioned sodium liquefaction or it is required for heating up domestic water or heating water or air. The hydrogen resulting from the process is now burned with the help of oxygen from the air, with the resulting exhaust gas (water vapor) or the heat engine driving a power generator directly. The electricity thus produced is derived in the distribution station 8 . The sodium hydroxide is discharged into tank 1 , where the cycle then begins again. The water vapor produced during the combustion is brought back into contact with new sodium in the plant 7 or is discharged into the tank 12 after condensation. From this, the water can now be fed back to tank 5 (or tanks 5 and 12 can be combined into one unit) or the water is used as process water via lines 10 and 13, respectively. Both warm water can be removed or removed after heat, e.g. B. via a heat pump, cold water can be released. The heat generated during the combustion in FIG. 7 is drawn off via line 11 for heating the building.

The direct current arriving in the distribution station 8 can now be used as direct current in the building. Via an inverter system, which is also installed in FIG. 8 , alternating current can be generated, which is fed via line 9 to the consumer points in the house. Excess electricity can be fed via line 14 into the general local network or a network. This is also connected via the supply line 15 to the distribution station 8 , so that electricity can also be removed from the external network if required. In the distribution station or separately, a control system is installed that organizes the entire energy production, distribution and use process.

The sodium in the device described can be independent of time falling solar electricity by reaction with water to produce hydrogen range, so that no significant hydrogen storage and none The supply of hydrogen from the outside becomes necessary. An internal combustion engine with Generator is available as a source of electrical energy where needed in case of excess electricity and possible starting current via the connection the external network or via the installation of an electricity storage (battery) can be covered. By recycling sodium as often as you like Complete self-sufficiency can be achieved with hydroxide. Heat recovery Measures such as the condensation of water vapor call for a Improvement in efficiency. Only occur as emission products Oxygen and water, which is not a problem.

The energy supply system is used primarily for buildings as a direct installation Claim 1 come into consideration, but it can also in the corresponding Distance as a supply unit for foreign buildings, as in claim 2 described, built up.

Claims (2)

1. Device and method for storing the solar energy to cover the energy requirements of buildings, characterized in that sodium hydroxide is broken down with the help of solar radiation in sodium and water with the release of oxygen, wherein energy is generated by bringing the sodium with water hydrogen with heat release , which is then burned and thus continues to emit thermal energy and also generates electricity when used in internal combustion engines via a generator. 2. Device and method for storing solar energy to cover the Energy requirements of buildings according to claim 1, characterized, that the energy gained for both the building in which the system is installed is used, as well as via feeding into energy networks for external Ge building can be made available.