DE3435614A1 - Process and apparatus for producing fresh water by desalination of sea water - Google Patents

Abstract

The present invention relates to a process and an apparatus for producing fresh water by desalination, using solar energy, the solar energy heating at least one collector medium in a collector system to a working temperature. Known plants in which evaporation and condensation are carried out in a single unit are technically complex and difficult to maintain, in combination with high capital costs. An increase in production of the fresh water flow rates is only possible to a slight extent. The problems are solved according to the invention in that sea water at roughly the working temperature in direct contact with a carrier gas is at least in part evaporated, the carrier gas being enriched with water vapour and then cooled, the fresh water condensing out. The sea water and/or the carrier gas are heated by means of solar energy.

Description

Method and device for the extraction of

Fresh water by desalination of sea water The present invention relates to a method and an apparatus for obtaining fresh water by desalination using solar energy, with solar energy in a collector system at least one collector medium to a working temperature heats up.

The French patent specification 1 261 066 describes a seawater desalination plant known, which works on the evaporation / condensation principle, although the use of solar energy is not intended. A procedure respectively a device for desalination of sea water using solar energy describes, however, the German Offenlegungsschrift 31 23 409. This seawater desalination plant works on the principle of gap evaporation, whereby water from a porous body evaporated in a gas gap and then by means of a condensation device is condensed. The system shown is characterized by the integration of evaporation and condensation device in a single unit technically complex and maintenance-unfriendly combined with high investment costs. An increase in production the amount of fresh water is only possible to a small extent, depending on from the special geometric conditions of such an integrated system. Of the Furthermore, the prior art mentioned does not show any possibilities, such as the water separation rate can be increased. The use of a special carrier gas is also possible not provided.

The invention has the task of presenting a desalination plant, which can be operated by means of solar energy and with the fresh water, preferably Drinking water can be provided inexpensively, especially in countries with high exposure to sunlight. Furthermore, the procedure should be independent of the respective Salt concentration of sea or brackish water work and only uncomplicated machine Have units that are largely maintenance-free or maintenance-friendly are.

Another part of the task is also to calculate the energy expenditure reduce and the water separation rate optimally to the respective operational requirements to be able to customize.

The object is achieved according to the invention in that that seawater is in direct contact with a carrier gas at around the working temperature at least partially evaporated, the carrier gas being enriched with water vapor and then cooled, the fresh water condensing out. The fresh water can be used as process water for irrigation in agriculture or as cooling water for Machine aggregates are used.

In an embodiment of the invention it is provided that the working temperature is around 80 degrees Celsius. Numerous series of tests have shown that that fresh water can be obtained particularly economically at this temperature can. However, higher temperatures were desirable provided the Kcilektorsysteme can be improved in this regard.

In a further advantageous embodiment of the invention it is provided that seawater is used as the collector medium. This simple procedure causes a particularly high degree of heat utilization with relatively little equipment Expenditure.

Air is advantageously used as the carrier gas, since air is not a special one Causes costs. However, other gases can also be circulated, for example gases that have a higher specific heat content such as helium or hydrogen.

In addition, it is also conceivable to use other gases if this is necessary for procedural reasons.

In a further embodiment, it is in a separate collector system Heated sea water and / or air as collector medium. Through this measure, can the working temperature in the evaporator can be increased.

Furthermore, it is provided with the invention that the sea water atomizes and is conducted in cocurrent with the carrier gas during evaporation. Through this evaporation or evaporation can be improved.

The invention can also expediently be used for the production of drinking water can be used, it may be necessary to check the quality of the drinking water Ensure addition of chlorine and / or fluorine and mineral salts in a known manner.

The invention can also be particularly advantageous for obtaining Use salt, especially in locations where salt is an expensive import product represents. The brine is further processed in a suitable manner, for example introduced into shallow basins, whereby the remaining water is exposed to sunlight evaporates and finally the pure salt can be obtained.

A particularly preferred device for carrying out the method for obtaining fresh water by using desalination of sea water of solar energy, the solar energy in a collector system at least one Collector medium heats up to a working temperature, provides that the collector system the outlet side is connected to an evaporator in its lower area a Evaporator inlet for the carrier gas and one in the upper part Has evaporator outlet for the carrier gas enriched with water vapor, wherein the evaporator outlet via a pipe in which a heat exchanger is arranged is connected to the condenser inlet in the lower part of a condenser, at its upper part is the condenser outlet for the largely water vapor freed carrier gas is located, which is connected to the evaporator inlet via a pipe connected to an intermediate fan.

In an advantageous embodiment of the invention, the outlet of the heat exchanger is connected to the condenser outlet. Furthermore, it is expediently provided that the evaporator outlet of the seawater brine via a branch with the collector inlet connected is. The branch is used to regulate the working temperature, respectively in this way to at least partially reduce the residual heat capacity of the seawater brine to be exploited In a further embodiment of the design of the invention, the fresh water drain is available with the condenser inlet via a line in a technical-functional connection.

The invention is advantageously developed further by that Evaporator and condenser have packing materials, consisting of the same shape Ceramic parts, preferably short pieces of pipe. Good results have been achieved with this, however, bricks, pebbles or plastic bodies can also be used or other corrosion-resistant packing.

In a further embodiment of the invention it is provided that in the evaporator Nozzles, preferably in the lower area of the wall and / or in the bottom of the evaporator are arranged. With this measure an even and fine distribution is achieved of the sea water, whereby the degree of evaporation can be increased.

Furthermore, an advantageous development of the invention provides that A collector system is arranged in the pipeline between the fan and the evaporator inlet is. In this way, the carrier gas can be used to improve the fresh water yield be heated either directly or indirectly before entering the evaporator.

Another advantageous development of the invention provides that the condenser inlet in the upper part and the condenser outlet in the lower part of the capacitor are arranged. It takes advantage of natural convection the carrier gas enriched with water vapor is introduced into the condenser from above, where it is in direct current with that also of introduced above Fresh water is cooled and water is condensed out. From the lower part of the Condenser, the carrier gas, which has largely been freed from the water, is then sent to the evaporator forwarded. With this procedure, there is no need for a fan in the gas circuit Further details, features and advantages of the invention emerge from the following Explanation of an embodiment example shown schematically in the drawing for carrying out the method according to the invention.

The system shown in the drawing as an example for implementation of the method according to the invention has a collector system as essential units 1, an evaporator 2 and a condenser 3, as well as several heat exchangers 10, 11, 12, the units being connected to one another via pipes 20 - 29, with pumps 40, 41, 42 and a fan 43 connected in between. The evaporator 2 has an evaporator inlet 50, an evaporator outlet 51, an evaporator Inlet 52 and an evaporator outlet 53. The capacitor 3 has a Condenser inlet 54, a condenser outlet 55, a condenser inlet 56 and a condenser outlet 5 #.

When the system is in operation, seawater comes through the seawater inlet 60, promoted with the supply pumps 40, 41 via the heat exchanger 11, 10 in the pipeline 23 to the collector inlet 62. A partial flow of the seawater Inlet 60 is only used to cool the fresh water in the cooler 12 and leaves it via the sea water drain 61. In the collector system 1, the sea water is heated and leaves it via the collector outlet 63 at a working temperature of about 80 degrees Celsius to roughly this temperature through the line 20 and the inlet 52 to enter the upper area of the evaporator 2. The sea water hits in countercurrent to carrier gas entering via inlet 50, the seawater partially evaporated or evaporated and with the carrier gas through the outlet 51 reaches the heat exchanger 10 and cools there, already condensing Part of the fresh water to be obtained from the pipeline 27 from the Condenser 3 admixed fresh water withdrawn via the outlet 57 and the line 28 will. The fresh water obtained is fed into the line 27 via the feed pump 42 promoted to the fresh water outlet 65, wherein it iv the heat exchangers 11, 12 cooled will.

The object of the invention is not based on that in the drawing schematically illustrated embodiment limited. For example, the entire system be run under pressure, whereby the fresh water yield would be improved. Without departing from the scope of the invention, trickling of the seawater can occur can also be carried out in cooling towers of a conventional type; For heating of the seawater could also be alternative or conventional heating methods are used in cooperation. It can also be useful, for example Arrange evaporator and condenser one above the other to save space.

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Claims (16)

Claims 1. A method for obtaining fresh water by Desalination of sea water using solar energy, taking solar energy at least one collector medium in a collector system to a working temperature heats up, characterized in that sea water at approximately the working temperature in direct contact with a carrier gas at least partially evaporates, whereby the carrier gas is enriched with water vapor and then cooled, wherein the fresh water condenses out. 2. The method according to claim 1, characterized in that the working temperature is around 80 degrees Celsius. 3. The method according to claim 1 or 2, characterized in that as Collector medium seawater is used. 4. The method according to any one of claims 1 to 3, characterized in that that air is used as the carrier gas. 5. The method according to any one of claims 1 to 4, characterized in that that in a separate collector system sea water and / or air as collector medium is heated. 6. The method according to any one of claims 1 to 5, characterized in that that the sea water evaporates and in cocurrent with the carrier gas during evaporation to be led. 7. The method according to any one of claims 1 to 6, characterized in that that it is used to make drinking water. 8. The method according to any one of claims 1 to 7, characterized in that that it is used for the extraction of salt. 9. Device for the production of fresh water by desalination of Sea water using solar energy, with solar energy in one Collector system at least one collector medium on one Working temperature heated, for performing the method according to any one of the preceding claims characterized in that the collector system (1) via the collector drain (63) is connected to an evaporator (2), which has an evaporator in its lower area Inlet (50) for the carrier gas and in the upper part an evaporator outlet (51) for comprises the carrier gas enriched with water vapor, wherein the evaporator outlet (51) via a pipe (25) in which a heat exchanger (10) is arranged with the condenser inlet (54) is connected in the lower part of a condenser (3), at its upper part is the condenser outlet (55) for the water vapor freed carrier gas is located, which is connected to the evaporator inlet (50) via a pipe (26) is connected to the intermediate fan (43). 10. Apparatus according to claim 9, characterized in that the outlet of the heat exchanger (10) with the condenser outlet (57) via the lines (27, 28) is connected. 11. Apparatus according to claim 9 or 10, characterized in that the evaporator outlet (53) via the line (21), the branch (22) and the line (23) is connected to the collector inlet (62). 12. Device according to one of claims 9 to 11, characterized in that that the fresh water outlet (65) with the condenser inlet (56) via a management (29) is in a technical-functional connection. 13. Device according to one of claims 9 to 12, characterized in that that evaporator (2) and condenser (3) have packing materials, consisting made of ceramic parts of the same shape, preferably short pieces of pipe. 14. Device according to one of claims 9 to 13, characterized in that that in the evaporator (2) nozzles for even and fine distribution of the sea water, preferably in the lower area of the wall and / or in the bottom of the evaporator (2) are arranged. 15. Device according to one of claims 9 to 14, characterized in that that between the fan (43) and evaporator inlet (50) in the pipe (26) Collector system is arranged. 16. Device according to one of claims 9 to 15, characterized in that that the condenser inlet (54) in the upper part and the condenser outlet (55) are arranged in the lower part of the capacitor (3).