DE2510226B1 - Solar power station with energy storage - electrolysis sea water into hydrogen and oxygen for later combustion to drive turbine-generator set - Google Patents

Abstract

The solar power station uses the electrical energy derived from a battery of solar cells to electrolyse sea water into gaseous oxygen and hydrogen for storage, and the oxygen and hydrogen are later burnt together to produce sufficient thermal energy to drive a turbine coupled to an electrical generator. The solar cell battery is connected to an electrolysis cell whose two gas outlets are connected to two storage tanks, and the storage tanks are connected to the combustion unit which is coupled to the turbine and generator. The plant produces electricity on an industrial scale.

Description

The gases from the gasometers are burned in an internal combustion engine, which in turn drives an electrical generator. Here it is in particular disadvantageous that to the decomposition of the water

Temperatures around 4000 "C are necessary today with concave mirrors should not be practically attainable, at least not for an economic one Production of electrical energy. So far only test facilities have become known in which with the help of a parabolic mirror with an area of 90 m2 a temperature of about 3000 "C was reached. In addition, the cost of separating the gases increases Separation apparatus this previously known system.

The invention is based on the object of a method and a To propose device of the type mentioned, with which in economic Way electrical energy can also be generated on a large industrial scale.

To solve this problem, the method according to the invention is characterized characterized in that the electrical energy obtained from the solar cells through Electrolysis of water to gaseous hydrogen and gaseous oxygen in chemical energy is converted, which, if necessary after storage of the gases, is converted into thermal energy through combustion to heated water vapor, in a turbine, into which the heated steam is introduced, with a with it coupled electrical generator is converted into electrical energy.

With this method, electrical energy can be produced economically will. Calculations have shown that when creating one according to the above Process-working plant with a nominal output of 500 megawatts about 365,000 t crude oil per year can be saved that would otherwise be used to manufacture the relevant Amount of electricity would be necessary.

This results in a saving of about 73 million DM per year with today's Prices. When building a system of 3000 megawatts, there is a saving of about 438 million DM per year. With a nominal output of 600,000 megawatts savings of around DM 87.6 billion.

The proposed method takes advantage of the fact that the solar cells generate DC voltage, so that the electrolysis carried out directly generated gaseous hydrogen and gaseous oxygen separately will. These gases can be stored, which means that the system can be operated at night is secured. According to the process, electricity can therefore be generated continuously. The combustion of the fuel gases creates high-pressure water vapor with which a turbine can be operated with high efficiency, so that a coupled therewith electric generator can produce high voltage electric current.

If necessary, the output voltage of the generator is used in transformers even higher for overhead lines.

It is preferred if the electrolysis is carried out in sea water will. The ionic current in the electrolysis vessel is reduced by the salts contained in the seawater maintained without further additives. In addition, sea water is practically unlimited Amount available.

A device for carrying out the described method with a plurality of electrically interconnected, a DC voltage source forming solar cells is characterized according to the invention in that the two electrical output lines of the field of the solar cells with one electrode each an electrolytic cell are connected, the separate outlet lines for water and oxygen gas, each with a storage tank for the gas in question are connected, of which connecting lines to a steam generator with burner lead, with which a turbine is connected to an electrical generator.

For reasons of space, it is preferred if at least the largest part this device is in the sea. The field of the solar cells can do this be designed as a floating platform on which the bell-shaped electrolytic cell is mounted so that it is immersed in the water and on which the storage tanks are attached as a float.

This part of the system is then partially flexible gas lines with the steam generator with turbine and electric, which is preferably installed on land Generator connected.

In the storage tanks, the fuel gases should be below a certain Pressure must be maintained in order to store a sufficient amount of the fuel gases there can, so that the operation of the plant is ensured at least until the next day is. To generate this pressure, in the connecting lines between the Electrolysis cells and the storage tanks booster compressors be attached. Preferred it will, however, if the electrolytic cell is at such a distance from the platform it is appropriate that the hydrostatic pressure prevailing in it below the fuel gases sets a pressure that corresponds to the required pre-pressure of the fuel gases in the storage tanks is equivalent to.

If two separate electrolytic cells are used, both can Cells at different heights are attached under the platform, creating in both Storage tanks different primary pressures are generated.

The efficiency of the combustion of the fuel gases to produce High pressure steam is particularly high when the burner is in the steam generator burns under water. This is not only caused by the combustion of the fuel gases generated water vapor, but also the resulting thermal energy directly for conversion of water used in steam.

Alternatively, the fuel gases can also be fed directly into the combustion turbine to which electrical generators are directly coupled.

To replace any water losses in the steam generator, at least a part of the condensate water of the turbine in a circuit in the steam generator to be led back.

The invention is illustrated below using an exemplary embodiment explained in more detail, from which other important features result. The figure shows a flow diagram of an apparatus according to the invention.

In a field 1 there is a large number of optoelectronic Semiconductors in a known manner in a series and group circuit are connected to an electric when exposed to daylight or sunlight To generate energy of preferably a few volts DC. The DC voltage is pending on output conductors 2, 3. With these ladders is a collector and Stabilization device 4 connected, which the output voltage of the field 1 constant holds. The outputs of the device 4 are via electrical lines 5 and 6 with electrolytic cells 7 and 8 connected. There are platinum electrodes 9 and 10 in the cells. The cells 7 and 8 are at least partially with electrically conductive water, preferably sea water filled, and the water also connects the two cells with each other, so that the Ions can migrate from one cell to another and vice versa. The cells are preferably designed as bells. In this training they are underwater, preferably Sea water.

A single electrolytic cell can be provided if care is supported so that the electrolytic cell two by a partition wall from each other has separate departments so that the fuel gases produced there are hydrogen and oxygen collected separately in the upper part of the cell.

In this upper area there are openings of connecting lines 11 and 12 are provided, via which the gases reach storage tanks 13 and 14 separately.

There they are saved under pressure.

The part of the device described so far is preferably as floating island formed in which the storage tanks 13 and 14 the function of swimmers who - via a suitable, not shown rod with the formed as a platform field 1 are connected. The electrolysis cells 7 and 8 are located below the platform and at a predetermined depth of her, so that in the cells 7 and 8 designed as bells a predetermined one there is hydrostatic pressure, which is transmitted via lines 11 and 12 to the storage tanks 13 and 14 is passed on.

On the output side of the tanks 13 and 14 are connecting lines 15 and 16 provided, through which the fuel gases hydrogen and oxygen to a pressure vessel trained steam generator 17 with a burner 18 arrive. Unless the first The lines 15 are part of the device designed as a floating island and 16 partially flexible.

The burner 18 burns the fuel gases, preferably below Water. The steam generator 17 has an output line 19 through which the high-tension, steam generated in the steam generator 17 in the direction of arrow 20 to a steam turbine 21 flows, which is driven by the water vapor. With the steam turbine 21 is mechanical coupled to an electrical generator 22, at the output line 23 directly or indirect electrical loads can be connected in a known manner.

A line 24 connects the steam turbine 21 to a condenser 25, which in turn is connected to a condensate collecting container 27 via a line 26 is. The condensate water that collects there is via a feed pump 28 and a line 29 is either pumped back into the steam generator 17 in a circuit or Excess condensate water is pumped out via a line 30 with a pump 31. It is preferred if the excess water is used for biological resuscitation is pumped up a hill, from where it is led as a river to valley.

Because it is fresh water, it can also be fed to other consumers will.

The steam generator 17 is sufficient to avoid energy losses thermally insulated.

Steam generator 17, turbine 21, electrical generator 22 and associated Components are preferably set up in a stationary manner on land.

The opto-electronic semiconductor panel 1 is preferred in its performance designed so that about two and a half times the power rating of the electrical Generator 22 is achieved in order to store enough fuel gases for nighttime operation.

Several of the systems described can be combined in modular form can be created, for example in capacities of 1000 megawatts per unit.

For smaller outputs, kits of around 250 megawatts can be provided will.

To increase the energy yield, the solar cells can be the respective The position of the sun can be tracked, so that the largest possible area of the solar cells is acted upon by sunlight. This can be done by the solar cells mounted on their base or the platform so that they can pivot together about an axis are. By rotating the floating or mobile platform around one The axis perpendicular to the plane of the platform can be used for tracking in the second Level to be effected.

Claims (10)

Claims: 1. A method for generating electrical energy from daylight or sunlight with conversion of light energy into electrical energy in solar cells, characterized in that the obtained from the solar cells electrical energy through electrolysis of water to gaseous hydrogen and Gaseous oxygen is converted into chemical energy, which, if necessary after storage of the gases, through combustion to heated water vapor in thermal Energy is converted into a turbine into which the heated water vapor is introduced is converted into electrical energy with an electrical generator coupled to it is converted. 2. The method according to claim 1, characterized in that the electrolysis is carried out in sea water. 3. Apparatus for performing the method according to claim 1 or 2 with a plurality of electrically interconnected, a DC voltage source forming solar cells, characterized in that the two electrical output lines (2, 3) of the field (1) of the solar cells, each with an electrode (9, 10) one Electrolysis cell (7, 8) are connected, the separate output lines (11, 12) for hydrogen gas and oxygen gas, each with a storage tank (13, 14) are connected for the gas in question, of which connecting lines (15, 16) lead to a steam generator (17) with burner (18) with which a turbine (21) is connected to an electrical generator (22). 4. Apparatus according to claim 3, characterized in that the field (1) the solar cells is designed as a floating platform on which the bell trained electrolytic cell (7, 8) is mounted such that it is in the water immersed, and on which the storage tanks (13, 14) are attached as a floating body. 5. Apparatus according to claim 4, characterized in that the electrolytic cell (7, 8) is mounted at a distance from the platform that the in her prevailing hydrostatic pressure puts the fuel gases under a pressure that the corresponds to the desired pre-pressure of the fuel gases in the storage tanks (13, 14). 6. Apparatus according to claim 3, 4 or 5, characterized in that that two separate electrolysis cells (7, 8) are provided. 7. Device according to one of claims 3 to 6, characterized in that that the burner (18) in the steam generator (17) burns under water. 8. Device according to one of claims 3 to 7, characterized in that that at least part of the condensate water of the turbine (21) in a circuit is returned to the steam generator (17). 9. The method according to claim 1 or 2, characterized in that the water vapor occurring at the exit of the turbine after its condensation as Fresh water is used. 10. The method according to any one of claims 1, 2 or 9, characterized in that that the fuel gases are burned in the turbine. 1 1, method according to claim 1, 2, 9 or 10, characterized, that the solar cells are tracked to the respective position of the sun. The invention relates to a method and a device for generating electrical energy from daylight or sunlight with conversion of light energy into electrical energy in solar cells. So far, no processes have become known that are economical light energy can be converted into electrical energy on a large scale, and in such a way that it reaches the energy production costs of conventional power plants or were undercut. Process for converting light energy into electrical energy Energy have therefore so far only been used for special areas, e.g. B. for the Power supply for satellites or other inaccessible power consumers. An example of this is shown in US Pat. No. 2,946,945, for the power supply an automatically working radio transmission station several solar cells one electric Charge the battery when the sun is shining. This ensures that the transmitter can also work at night. Electric Energy on an industrial scale is not intended according to the method proposed there getting produced. This is because of the large energy losses in storage It is also not economically feasible in the accumulator. Also would be a variety of then Accumulators to be used represent a major cost factor. By the US-PS 30 70 703 or the corresponding DT-PS 1200611 is it is known to fully concentrate solar energy in a burning mirror on an evaporator, in which mercury is evaporated, the steam of which drives an expansion turbine. An electrical generator is coupled to the turbine, which is operated via a switch is either connected directly to the payload, or to an electrolyte chamber, in which water is broken down into gaseous hydrogen and oxygen. The two gases are stored in separate tanks. you will be if necessary, d. H. if the sunlight fails, burned in a fuel cell, which in turn delivers the electrical energy generated in the process to the payload. The disadvantage here is not only the low efficiency of the fuel cell, but also the drive of the turbine with mercury vapor. A plant in the industrial Scale could not be produced economically according to this known system, especially because care must be taken about the concave mirror that the Evaporation temperature of mercury in the evaporator is reached and because the then required large amounts of mercury to make the facility very expensive. Through the DT-PS 8 36 129 is the energy production from water and Solar heat is known, with the water being raised to a temperature of 4000 "C via concave mirrors should be heated so that it is thermally converted into a mixture of gaseous hydrogen is decomposed with gaseous oxygen. This gas mixture must be in a separating apparatus separated into the two gases that can be stored in gasometers, to bridge failures in the sunless time.