DE2650482C3 - Device for desalination of sea water by distillation using sunlight - Google Patents

Description

The present invention relates to an apparatus for desalination of sea water by distillation by means of sunlight according to the preamble of the preceding claim 1.

Such a device is known from DE-OS 25 03 251, for example. This device has a basin designed as a shallow tub, which has four walls made of a suitable, light and heat-permeable material is surrounded, as well as Collecting channels for the drinking water. Cover from the four walls of the basin. When operating the device, the pool with the filled with seawater to be treated. The water heated by the incident sunlight evaporates and condenses on the inner surfaces of the inclined walls as soon as the saturation limit of the interior is reached Air is reached under the given conditions The condensate runs on the inner surfaces of the defeated Walls in the collecting channels from which it can be drawn off. A-ese device is disadvantageous It is noticeable in the prior art that the efficiency is not particularly satisfactory. It was also found that the condensate drain occurs relatively slowly.

The invention is therefore based on the object in such a way / υ improve the aforementioned apparatus for the desalination of sea water, that a considerably enlarged WιrkungεgΓad and a faster or richer condensation is created.

According to the invention this object is achieved in that the cover has a cavity.

In this way will the temperature differences? / wipe water vapor and cover enlarged. because not only the condensation plate is cooled, Instead, the water that is due to evaporate is also heated by this opposing cooling effect will.

As a result of the particularly simple design of the device according to the invention, more or less complicated additional units could be dispensed with, which would otherwise have increased the susceptibility to failure. Since the device according to the invention is constructed in a particularly simple manner , it can also be set up by trained staff at any deployment location with little effort.

Further advantages and features emerge from the preceding subclaims.

In the following, for a better understanding of the invention and in conjunction with the figures, a s embodiment of the device according to the invention for desalination of seawater described. It shows

Fig. 1 is a cross section through the structure of a known device for desalination of sea water,

2 shows a cross section through the structure of a device according to the invention,

F i g. 3 and 4 a cross section through the cavity according to the invention with indicated flow conditions,

F i g. 5 shows a cross section through the cavity according to the invention with an arrangement for the inlet and outlet Sequence,

F i g. 6 shows a cross section through the device according to the invention in connection with a solar collector,

F i g. 7 shows a cross section through the in FIG. 6 collector shown,

F i g. 8a and b cross-sectional views of arrangements of the device according to the invention with a solar collector and storage container,

F i g. 9 a cross section through the solar collector with container,

FIG. 10 shows a cross section through the one in FIG. 9 shown container,

11 shows a cross section through yet another embodiment of the device for the desalination of Sea water and

Fig. 12 is a schematic view of the two embodiments of the device according to the invention device, both of which are connected to a large container, as well as the associated circuit diagram.

In Fig. 1 shows a tub 10, the bottom of which absorbs solar heat well, and through which it slowly a thin layer of seawater 51 is called. The tub is covered with an inclined pane of glass 12, which lets sunlight through what through the inclined, from Arrows coming up on the right are shown.

The rising water vapor condenses on the

Underside of the glass pane 12. which is exposed to the outside air is relatively cold. The precipitated water flows on the underside of the glass panel J2 in a groove 13. the the water supplies.

The cold water taken from the sea is used

Passing through the heating bath 10 above at de:

'.o Glass plate along which the precipitation takes place guided, whereby the glass plate is kept much cooler than under normal circumstances by the Outside air. In addition, it absorbs the heat released during condensation from the underside of the glass plate path.

F ι %. In contrast, FIG. 2 shows a device according to the invention in which the glass plate is doubled and the sea water is passed through the cavity 16 between the two glass plates 14, 15.
The distance and position of the cover or of the two glass plates 14 and 15 should be such that not so much thermal radiation is reflected or absorbed by the upper flow water that the temperature reduction on the glass plate is made by an equally large temperature reduction on the heating tub and the temperature difference remains the same. This risk of constant temperature difference is avoided if the cold water passing through

serfilm is kept as thin as possible. A "heat island" within the cooling water due to uncontrollable Currents in the interior of the double plate can flow through several inflow and outflow points at the beginning and end the double plate or by passage through chambers can be counteracted; see Fig. 3 and 4.

This type of evaporation plant is best Use where there is a high air temperature and cold sea water, i.e. cold currents or cold upwelling water u;: d tropical-subtropical desert climate in meeting. This is in most deserts Coastal proximity is the case, e.g. coast of Morocco, Mauritania, North Chiie, South Peru. Since too slow Passing through the double glass plate, the ΐϊ is heated to reduce the temperature difference Cooling water takes place, the procedure can also be that only part of the cooling water of the Heating tub fed and the other part returned to the sea; see F i g. 5.

Since solar panels running through were less war- _> u reflecting radiation than the device discussed so far, temperature difference and flow rate can (and thus the yield / can be increased by using the previously shown Connects facility with a "solar collector" 17; 2> see Fig. 6. At the age of 18 there may be necessary pumps designated

Any solar collector can be used. In pass to sea water corrosion and deposition play a role: To Gsringhal- ι »processing of corrosion is to use an appropriate metal or metal alloy (copper / nickel, brass etc. aluminum.); the deposit can be reduced by physically or chemically effective additives (acid, fine sludge for condensation nuclei). Since the deposit increases as the temperature rises and the circulation slows down, this problem can also be influenced by the circulation speed.

Corrosion and deposits are also kept 4u less if the entire circuit is removed from the Withdrawal of the sea water is kept free of air until it enters the tub.

For dissolved in seawater, released within the cycle gas venting is useful * '<corrosion and deposit reducing that because of the high temperature differential heating in the collector above 100 ° C is not necessary and also acts - if it threatens - any time by increasing the Circulation speed can be prevented. so

For better utilization of the radiant heat and for easier mechanical cleaning of Deposits should - regardless of the possibility of using any collectors - the following collector provided:

The collector 17 consists of a bottom with a rim, a heat-absorbing cover and two spirals or right-angled metal strips (foils), which are used to guide the water (to align the Water flow) in such a way that cold and heated water flow in the first major part of the Flow have as much common wall area as possible, and which strips or foils of high Thermal conductivity with the lid firmly and superimposed on heat (but detachable for cleaning) And have constant contact with the ground; see F i g, 7.

The heat radiation is better emitted uses that once cold and heated flow areas in the predominant area of the collector in counterflow run side by side and furthermore the film separating the streams from the lid continues the heat transmits

The separating film or the separating strip also allow simple mechanical cleaning of Deposits.

The metal strip is highly elastic, the deposits (mainly calcium and magnesium sulfates and -Carbonates) are rigid and brittle, allowing slight movements or bends for cleaning If you have removed the metal strip, let the applied covering jump off without damaging the metal strip. Since the strip is firmly but detachably connected to the lid, it is also at the point of attachment on the lid a deposit-free line from which the deposit can be more easily removed.

The system described so far only works during the day. d. H. hot sunlight (even when it is overcast Sky because of the penetration of infrared radiation the cloud cover).

For the purpose of the hot water reserve during the night, this must be used in the system (if possible temperature-insulated) large container 19 for storing heated and to be heated sea water intended; see Fig. 8a + b. It must have enough content to keep it operating during the night to be able to.

I. Possibility

The large container 19 is fed from the cooling water that flows through the double glass plate 14, 15, and he gives his later heated sea water from the collector 17 to be passed on to the evaporation pan 10 (daytime operation and / or nighttime operation) or, if necessary, directly to the evaporation pan (nighttime operation); see again FIG. 8a + b.

The container 19 should because of the spatial extent of a solar heat evaporation system be installed underground under the system; this has the additional advantage that the heat dissipation from the container upwards partially to the collector 17 or the evaporation pan 10 takes place

The container 19 is heated during the day by Sonnenkollekto Ren 17, which in a Heizschlage 20 their heat release to the sea water of the container 19; see FIG. 9.

In addition, the seawater of the container can be used in areas of the sea with frequent winds (many coastal deserts are in the trade wind region) are electrically heated by wind energy (or not by temporarily waste energy that can be used in other ways, with the transport problem is to be considered).

The liquid that transfers the heat from the collectors 17 to the bulk tank is normal water; the path from collector 17 to heating coil 20 in. Container 19 is a closed circuit; the problem Corrosion and deposits only occur less here and only on the outside of the heat exchanging heating coil 20; the problem of heat exchange reduction Deposition can be counteracted by the appropriate length of the spiral.

The container should disintegrate into several chambers (ascending or side by side) to finish to bring hot water during night operation; see Fig. 10.

To that chamber from inside the container

which the seawater enters the collector and / or the evaporation pan, to heat the most intensively, the heat-exchanging chase snake should first enter the warmest chamber and then the rest to the coldest, which the sea water enters.

2nd possibility

Since the geographical zones in which the system can work economically have very little cloud cover and thus the atmosphere cools down very quickly at night (so that the air temperature can then very quickly be lower than the temperature of the incoming sea water used for cooling) the condensation surface of the evaporation pan can also be constructed as follows:
the double glass plate through which the cooling seawater runs is replaced by a simple metal foil 21 which, instead of the slight incline of the cover and condensation plate (as in Fig. I and 2), is erected much more steeply in the form of a successive row of Spüzdäcnern , at the bottom edge of which there are channels 13 for guiding away the condensed water; see Fig. 11.

This has the advantage that the condensation surface (here in relation to the cold outside air) is in front is much larger surface; In addition, the thin metal foil (plate) has a higher temperature has conductivity than a glass plate.

3. Combined option

There are both the evaporation tray according to Fig .; as well as according to Fig. 11 connected side by side Zt alternating operation. As soon as the sea water is warmer than the atmosphere (after nightfall is switched from an evaporator according to FIG. 2 to one according to FIG. 11; after sunrise gear is shifted down; see Fig. 12 with the scarf there (scheme.

The system can work according to the vacuum principle such as dif flash evaporators; but this would be essential more elaborate; it can be dispensed with; da: The system should be under normal atmospheric pressure work. The then escaping together with the draining condensate scr and the brine, do not differ niedefsuiuägcMuc Dumpf can additionally by a; Koriderisäliönsspirale, in which the surrounding cooling water what is the entering seawater, be knocked down.

In addition 6 sheets of drawings

Claims (3)

Patent claims: 1. Device for desalination of sea water by distillation using sunlight, with a Tub that is provided with a sloping cover that is permeable to sunlight, and with a Collector for condensate deposited on the underside of the coolable cover, thereby characterized in that the cover (14.15) has a cavity (16) 2. Device according to claim 1, characterized in that that the cavity (16) several parallel or in series of sea water flowed through Having areas 3. Device according to claims 1 and 2, characterized in that in the flow path of the Seawater between the cavity in the cover and the bottom of the tub in itself known solar collector (17) is connected