DE2810913A1 - Solar energy used to form hydrogen - having electrical cell energised by solar radiation used to electrolyse water to form and store hydrogen - Google Patents

Abstract

Hydrogen is formed by the use of a solar generator coupled to a system for the electrolysis of water. The energy released in the solar generator is used for the simultaneous degradation of water to H2 and O2. The H2 so produced is stored and can be used as a primary energy source. The system can be mounted on an artificial, unsinkable floating island. The generator can be a photovoltaic solar cell battery. Used for recovering and storing solar energy. Provides an economic alternative to fossil fuel sources.

Description

Plant and process for the production of hydrogen

The application relates to a plant and a method for generating it of hydrogen.

There are already diverse processes for the technical use of Known solar energy. They range from the production of hot domestic water with the help solar radiation, for example for heating purposes, through the generation of electrical energy in heat engines or photovoltaic generators up to bio-synthesis systems.

All known methods of using solar energy have in common that they are in principle no general alternative to fossil fuels or to Form nuclear energy. You can use solar energy only as a supplement to it offer to the other energy sources.

On the one hand, this is due to the problem of storing solar energy and on the other hand because the solar energy on the earth's surface only in the relatively 2 thinned form of a maximum of 1 kilowatt per inch.

In many applications, such as B. with process heating or mechanical Movements, however, require much higher power densities. Fossil fuels or nuclear energy cannot be replaced by solar energy in such cases.

The present invention has set itself the task of providing a way to use solar energy as a general alternative for fossil fuels and to describe nuclear energy and an economic route to large-scale use of solar energy.

To solve this problem is in a plant for the production of Hydrogen proposed that a solar generator with an arrangement for decomposition of water is coupled in such a way that each output from the solar generator Energy can be used simultaneously for the decomposition of water, that also means for Absorption and collection of the hydrogen produced by the decomposition of the water are provided so that continuous and automatic generation and storage of hydrogen as a primary energy carrier is possible.

Such an automatically working "hydrogen plantation" provides in a sense an analogue of an oil well. Once in operation is taken, it delivers with minimal maintenance over its entire service life automatically removes hydrogen when exposed to sunlight through the decomposition of water.

The decomposition of the water can take place electrolytically or thermally. The location for the hydrogen plantation is expediently in the tropics or at least place in the subtropics. You can z. B. in the Close to the equator, on the mainland or as an unsinkable artificial island floating freely on the high seas near the equator or anchored near the coast Bodies of water. The hydrogen released during the decomposition of the water is collected and stored in containers or chemically z. B. as hydride bound. The stored hydrogen is removed from the at regular intervals Picked up plantation. It can also be discharged continuously via a pipeline.

The solar generator can be a solar cell battery or a heat engine which converts solar energy into electrical energy.

In a heat engine, the absorbed solar energy is over converted into electrical energy in a thermodynamic cycle.

The solar generator can also be used as a high-temperature furnace for thermal Decomposition of water can be formed at which the temperature generated in the solar generator of> 8000C is achieved through a concentration of solar radiation.

The oxygen released during the decomposition can be chemically bound will. The released oxygen can also occur during the electrolytic decomposition of water be collected and stored.

If sea water is used for the decomposition, also can the Decomposition products of the salts dissolved in the seawater are collected and reused are fed.

In the following, the invention is based on an exemplary embodiment and their economic aspects are explained in more detail.

In Fig. 1, a solar cell battery 1 is shown, for example is constructed with polycrystalline silicon wafers. The solar radiation 2 will from the solar cell generator 1 with an efficiency of approx. 10% in electrical energy converted. The electrical energy is supplied via the voltage regulator 3 of the electrolysis cell 5 supplied. The released hydrogen is collected in line 6 and over the compressor 8 is passed into the hydrogen container 9. The released oxygen is collected in line 7 and via compressor 10 to the oxygen tank 11 supplied. The monitoring unit 4 ensures optimal interaction and a control of the overall device.

The device of FIG. 1 is used, for example, in a desert area (with sufficient ground water) placed near the equator. The global radiation there is 6.3 kWh per day and m2, or 2290 per m2 per year kWh. Because the efficiency of the solar cells -Battery is approx. 10%, 229 kWh per m² are available for the decomposition of water per year.

Theoretically, electrolysis produces 1 nl3 of hydrogen 2.8 kWh required under normal pressure.

In practice, however (mainly because of the electrolytic Overvoltage) around 4.5 kWh is required for 1 m3 of hydrogen gas under normal pressure. It can therefore per m2 solar cell surface in the year 229 = 50.8 m3 4.5 hydrogen Normal pressure can be generated.

Since the calorific value of 1 m3 of hydrogen under normal pressure is approx. 3 kWh and the calorific value of 1 kg of crude oil is approx.

2 is 12 kWh, an area of 1 In solar cell generates one per year Amount of hydrogen with a calorific value of 50.8 = 4 12.7 kg of crude oil. To the generation a petroleum equivalent of 1 tonne of petroleum per year in the form of hydrogen a solar cell area of 1000 = 78.7 m2 12.7 is required.

The necessary investment costs will increase in the foreseeable future through a cost-effective large-scale production of polycrystalline solar cells, that a sufficient return on the capital employed is achieved. It depends the interest rate or the return on capital time is sensitive to the oil price.

(If, for example, the oil price doubles in the period under review, then the return flow time would be halved - and the interest doubled.

Since the oil reserves are limited and the energy demand is constantly increasing, the system according to the invention can work inexpensively.

Improvements in the efficiency of the solar generator and water decomposition would also have a serious impact on costs and capital payback time. (With 100% efficiency of the solar generator and 100% efficiency of water decomposition the theoretical optimum for 1 tonne of petroleum equivalent per year would only be one solar generator area of 5.3 m are required.) With the help of the "hydrogen plantation" according to the invention solar energy could become a real alternative for fossil fuels that are becoming increasingly scarce Energy sources and for nuclear energy are expanded, since today also the possibility is to safely store and transport hydrogen.

With hydrogen, which is produced in a continuous process from solar energy is produced in hydrogen plantations floating on the equator Ocean or desert areas, could be for virtually unlimited periods of time an environmentally friendly energy source can be obtained, which is also one in terms of quantity Day could take on the role of oil and coal in the energy industry.

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Claims (13)

Claims 1) Plant for the production of hydrogen, thereby characterized in that a solar generator with an arrangement for the decomposition of water is coupled in such a way that the energy emitted by the solar generator is simultaneous can be used for the decomposition of water, that also means for taking up and collecting of the hydrogen generated by the decomposition of the water are provided, so that a continuous and automatic generation and storage of hydrogen as a primary energy source is possible. 2) Plant according to claim 1, characterized in that it is an artificial, unsinkable floating island is formed. 3) Plant according to claim 1 or 2, characterized in that the Solar generator consists of a photovoltaic solar cell battery. 4) Plant according to claim 1 or 2, characterized in that the Solar generator consists of a thermal heat engine that absorbs the Converts solar energy into electrical energy via a thermodynamic cycle process. 5) Plant according to claim 1 or 2, characterized in that the Solar generator designed as a high-temperature furnace for the thermal decomposition of water is. 6) Plant according to one of the preceding claims, characterized in that that receptacle for storing the gaseous, liquefied or solid Form bound hydrogen are provided. 7) Plant according to claim 6, characterized in that the receiving container Pipelines for the long-distance transport of the hydrogen are connected. 8) Use of a system according to one of the preceding claims for hydrogen production in the tropics or subtropics by means of an open Lake floating or anchored near the coast, or by means of a fixed installed system in desert areas with sufficient groundwater resources. 9) Process for the large-scale production of hydrogen as a primary energy carrier, characterized in that water is obtained by means of the solar generator electrical energy or thermal energy is decomposed, and that this hydrogen is collected and stored in gaseous, liquefied or bound form. 10) Method according to claim 9, characterized in that the decomposition of the water takes place electrolytically. 11) Method according to claim, characterized in that the decomposition of the water in hydrogen and oxygen takes place thermally. 12) Method according to claim 10, characterized in that also the Oxygen generated during the electrolysis of the water is captured and collected. 13) Method according to one of the preceding claims, characterized in that that sea water is electrolytically decomposed to generate the hydrogen, and that the decomposition products of the salts dissolved in the seawater are also collected.