DE2940886A1 - Sea-water desalination plant - uses solar energy and preheated air carrier system - Google Patents

Abstract

Sea-water desalination plant uses a solar energy heated evaporator in which a carrier air stream for steam is utilised. The air stream before introduction into the evaporator is heated in at least one preheater, the preheater(s), evaporator, and a condenser in which the steam is condensed, being connected in a forced circuit. Pref. both the preheater and the evaporator are designed as plastics solar energy collectors. The condenser is fitted with a heat store for both day and night operation. The plant has a high output and does not deteriorate due to the effects of corrosion.

Description

Plant for desalination of sea water

The invention relates to a system for desalination of sea water with at least one seawater evaporator that can be heated by solar heat, in which a carrier air stream can be loaded with water vapor, as well as with at least one downstream Condenser in which desalinated water can be condensed from the carrier air flow.

In a known water distillation plant, outside air is in the form introduced by wind through a funnel into a sun-heated chamber, from there over the water led to the absorption of water vapor and then introduced into a chimney, in which the water vapor-air mixture rises, the water vapor at the The chimney wall condenses and the condensate is collected as desalinated water will. Since the outside air only has outside temperature when it comes into contact with the water, it takes the heat required to heat it up from that in the chamber Water, the water vapor formed and / or the container walls. Because of limited Exchange areas and exchange paths, which are predetermined by the length of the chamber there is only a slight heating of the air, so that its water vapor absorption capacity low and therefore the performance of the system is limited.

The invention is therefore based on the object of providing a system of the above mentioned type to indicate the high performance with simple and thus inexpensive Structure connects. Furthermore, the plant should meet the operational conditions, in particular with regard to corrosion, be fully grown.

The solution to this problem is now that the Carrier air flow before entering the evaporator in at least one preheater heatable and forced by the preheater, evaporator and condenser is feasible in the cycle. By heating the carrier air flow before it enters In the evaporator, the evaporation capacity is increased and the water vapor absorption capacity of the carrier air flow increased. Since the carrier air flow is circulated, will the residual heat and water vapor still contained in it when it leaves the condenser exploited, whereby the forced air flow, preferably by a fan, high air velocities in the condenser and thus improved heat exchange enables.

In addition, the evaporation and preheating in separate Components these are each specifically tailored to their intended function can be.

Under seawater within the meaning of the present invention, all.

salty water, such as seawater or brackish water, be understood.

In order to combine simple production with high corrosion resistance, is according to an advantageous development of the invention of the preheater and the Evaporator Each designed as a plastic solar collector, which also makes a Preheating is achieved using solar energy.

If the system is intended for day and night operation, it is recommended that that the condenser has a heat accumulator for absorbing the heat of condensation, that the evaporator with a solar heat absorbing second heat storage can be brought into connection, and that a second capacitor is provided, wherein the carrier air flow in daytime operation through the preheater, the evaporator and through the condenser can be guided by releasing the condensation heat to the heat accumulator is, on the other hand, in night mode by the one heated by the heat storage tank and now as The condenser used in the preheater, the evaporator heated by the second heat accumulator and can be conducted through the second capacitor. Through this training is too the system can be operated without direct solar heating, with the preheating and evaporation required energy heat storage is taken, which during the day be heated with solar radiation. As can be seen from the above, under the term daytime operation means working with directly absorbed solar energy, The term night mode, on the other hand, means working with stored solar heat to understand.

For an inexpensive production of the evaporator or

of the preheater, it is recommended that this the end Plastic foils is composed, with the foils arranged on the top transparent, that is, permeable to solar radiation, and the underside delimiting foils are dark in color.

The heat accumulator intended for the absorption of the condensation heat can be designed in any way, for example with a liquid heat storage medium, the solar heat storage provided for night operation, the essential one at night Part of the heat of vaporization supplies, advantageously consists of stone and is next to and placed under the evaporator.

2 In order to increase the evaporation heat per m, it is advisable to use the Underlay the evaporator with a metal plate that conducts heat well, which is attached to both Long sides protrudes 1 to 2 m and absorbed on both sides of the evaporator Releases solar energy through the bottom of the evaporator to the salt water.

In order to avoid heat loss here, the metal panel is advantageous on the area protruding from the evaporator with a transparent plastic film covered, which delimits an air space as insulation between itself and the metal panel.

Further advantages of the invention emerge from the following description of exemplary embodiments in connection with the schematic drawings. Here show: FIG. # 1 shows the top view of a system according to FIG Invention only for daytime operation, Figure 2 shows a cross section through the subject matter of Fig. 1 according to the section line II-II on a larger scale and Figure 3 shows a system according to the invention for day and night operation in plan view.

The same parts are given the same reference symbols in the individual figures Mistake.

The system according to FIG. 1 has a preheater 10, a seawater evaporator 12 and a condenser 14, the left ends of the preheater 10 and of the evaporator 12 are connected via the condenser 1> 4, and the right ends are connected to one another by a line 16.

In the connecting line 18 between the preheater 10 and the condenser 1> 4, a fan 20 is inserted, with which the carrier air flow in the circuit 20, 18, 10, 16, 12, 1> 4 is movable.

The condenser 1> 4 can be designed with water or air cooling be.

The preheater 10 and the evaporator 12 can be designed identically be, a cross section according to the section line II-II is in Figure 2 on a larger scale shown.

Thereafter, the elongated evaporator 12 is a plastic solar collector formed, which is composed of plastic films. As can be seen from Figure 2, it has three foils 2> 4, 26, 28 in the form of elongated tracks that at their edges 30 tightly connected to one another are so that the Evaporator is given an elongated, flat tubular shape. The slide 28 forms its underside and is colored black, whereas the upper side is formed by the two foils 24 and 26, which are so spaced from one another run so that an air cushion 32 serving as insulation is formed between them.

Since the foils 24 and 26 form the front of the evaporator, must this of course be permeable to solar radiation.

The profile of the evaporator 12 shown in FIG. 2 is only given to it by the carrier air flow, which the inherently slack films in the shown Shape inflates.

The air cushion 32 can in this case by the film 26 completely from Space 34, in which the carrier air flow is guided, be separated, the for the formation of the air cushion via an air arranged in the film 24, which is necessary for the formation of the air cushion Valve can be introduced from the outside.

However, it is also possible to remove the air cushion 32 from the dynamic pressure of the carrier air flow guided in space 34, including some small openings must be provided in the film 26 for the passage of air from the space 34 to build up the air cushion 32. In this case, of course, there is no valve required in slide 24.

The film 28, which forms the trough-shaped underside of the evaporator 12 forms, is arranged on a highly thermally conductive metal plate 38, which the outline of the evaporator 12 protrudes, as can be clearly seen in particular from FIG. The area> 40 protruding from the evaporator 12 is used for additional purposes Absorption of solar heat and its transmission to the sea water 36.

In order to protect the protruding area> 40 against heat loss protect, this is covered with a radiation-permeable film 42, which is between itself and the area 40 includes an air space 44 as insulation.

Finally, the space provided for evaporation is also in space Sea water 36 is shown, which is in the flat formed by the film 28 Gutter is located.

The sea water is supplied through lines not shown.

The lengths of the preheater 10 and the evaporator 12 are based on the respective To match performance and local conditions, the width is about 0.5 to 2 m with a total height of about 0.1 to 0.2 m. The protruding area> 40 the metal panel 38 has a width of about 1 to 2 m.

During operation, a shift is carried out in the space 34 of the evaporator 12 Sea water 36 introduced and continuously supplemented and the fan 20 switched on. There is now a carrier air flow, which in the preheater 10 through the incident Solar radiation is heated up. The carrier air stream heated in this way becomes fed to the evaporator 12 via the line 16 and via the seawater present there 36, which is also heated by the incident solar radiation is. Here, the carrier air stream absorbs water vapor and transports it in the Kondenstor 14, where this is precipitated as desalinated water and not through lines shown is removed. The carrier air then flows again Circuit to the fan 20.

While the system according to FIG. 1 is essentially only incident during the day Can utilize solar heat for seawater desalination, is a variant in Figure 3 shown, which can also be operated with stored solar heat. This plant has also a preheater 10, an evaporator 12, a condenser> 46 and a fan 20 suf, which as in the embodiment of Figure 1 to a Circuit are interconnected.

A second capacitor> 48 is also provided, which is used for Preheater is connected in parallel, with the one at the left end of the second condenser > 48 outgoing line 50 is provided with a shut-off device 52 and immediately is connected to the capacitor 46. Those from evaporator 12 to condenser 46 leading line 54 also has a shut-off device 56 and is through another Line 58 bridged, which contains a second fan 60.

In the present exemplary embodiment, the capacitor 46 has a Heat storage 62, for example with a liquid heat storage medium, through which a heat exchange pipe 66 is guided, which connects the evaporator 12 to the preheater 10 or second capacitor 48 connects. In addition, the evaporator 12 is also provided with a heat accumulator 68, which is solar-heated and in the present embodiment is formed from the ground, for example by stones 72, on which the evaporator 12 including metal plate 38 is arranged.

The shut-off device 52 is closed for daytime operation of the system, the shut-off valve 56 opened and the fan 20 put into operation, so that the Carrier air flow the circuit 20, 10, 12, 51, 66 completes. The way it works is in this case identical to the exemplary embodiment according to FIG. 1. There are differences however, in the fact that the desalinated water is obtained in the heat exchange pipe 66 and from there is withdrawn, the heat of condensation being absorbed by the heat accumulator 62 and is saved. At the same time, the heat from the sun is with the heat accumulator 68 in contact with the terzaVmpf% 12, in the present case the Underground, heated.

If there is no solar radiation, for example due to sunset or when the clouds rise, the fan 20, the shut-off device, is shut off 52 open, the shut-off element 56 closed and the second fan 60 in operation taken. The carrier air flow now carries out the cycle 60, 58, 12,> 48, 50, 66, which is entered with dashed arrows in FIG. To this undesirable To switch off circulations through the preheater 10, this can optionally by shut-off elements, not shown, are excluded from a flow.

The condenser> 46 now serves as a preheater for the carrier air flow, in which the heat accumulator 62 via the heat exchange pipe 66 heat to the carrier air flow releases so that it reaches the evaporator 12 in a heated state. The evaporator 12 is supplied with heat by the heat accumulator 68 formed by the subsurface, so that evaporation and water vapor loading take place under the carrier air stream can.

The carrier air stream then flows via line 70 to the second Condensate; 1tor 48, in which desalinated water is separated out as condensate and then continue on line 50 to new K ## ice skating. The second capacitor 48 can be carried out in any way; if the night air is used as a coolant, one can two-layer plastic hose, advantageously made of black polyethylene, as a condenser to serve.

With the system described above, it is thus possible to directly incident and also to use stored solar heat for seawater desalination.

Blank page

Claims (7)

Claims Plant for the desalination of sea water with at least one seawater evaporator (12) which can be heated by solar heat and in which a carrier air flow can be charged with water vapor, as well as with at least one downstream condenser (1'4; # 6, 48), in which desalinated water can be condensed from the carrier air stream, characterized in that the carrier air flow before entering the evaporator (12) can be heated in at least one preheater (10; 66) and through the preheater (10; 66), the evaporator (12) and the condenser (14; 45, # 8) forcibly in the circuit is feasible. 2. Plant according to claim 1, characterized in that the preheater (10) and the evaporator (12) are each designed as a plastic solar collector (Fig. 2). 3. Plant according to claim 1 or 2, characterized in that for Day and night operation of the condenser (# 6) a heat accumulator (62) for recording the heat of condensation has that the evaporator (12) with one the solar heat receiving second heat accumulator (68) can be brought into connection, and that a second condenser (48) is provided, the carrier air flow in daytime operation through the preheater (10), the evaporator (12) and the condenser (# 6) below Release of the condensation heat to the heat accumulator (62) can be carried out in night-time operation on the other hand, by the one heated by the heat accumulator (62) and now used as a preheater Capacitor (ei6), that of the second Heat accumulator (68) heated Evaporator (12) and through the second condenser (48) can be conducted. 4. Plant according to one of claims 2 to 3, characterized in that that the evaporator (12) and advantageously the preheater (10) made of plastic films (2> 4, 26, 28) is composed, with the foils arranged on the top (2> 4, 26) are transparent and the film (28) delimiting the underside is dark is colored. 5. Plant according to claim 3, characterized in that the second Heat accumulator (68) consists of stones (7: 2) on which the evaporator (12) is arranged is (Fig. 3). 6. Plant according to one of claims 2 to 5, characterized in that that under the evaporator (12) at least one highly thermally conductive metal plate (38) is arranged, the outline of which protrudes beyond the evaporator (12). 7. Plant according to claim 5, characterized in that the metal plate (38) on its area (40) protruding beyond the evaporator (12) with a transparent one Plastic film (42) is covered, the one between itself and the metal plate Airspace (44) limited.