DE3327896A1 - Building structure for the production of fresh water from sea water - Google Patents

Abstract

The building structure for southern latitudes permits the production of fresh water from raw water, exploiting solar energy for the evaporation of water, a conditioned climate being created at the same time in the interior, so that plants growing in the interior also can be supplied with the fresh water obtained. The building structure is composed of a first shell which encloses, with a gap, a second shell and defines an intermediate space climatically separated from the interior, in which intermediate space the raw water is sprayed via spraying devices. An airstream flows tangentially to the shells in the intermediate space between the first and second shells, which airstream penetrates the raw water sprayed mist and becomes enriched with water vapour, that is fresh water. The airstream is withdrawn from the intermediate space and passed through a heat exchanger whose other exchange surface is at a lower temperature than the interior of the building structure. The air having high moisture content passing through the heat exchanger drops below its dew point, and the fresh water condenses out and is collected. As a result, the air in the interior is simultaneously dehumidified and cooled so that plants growing therein find an ideal climate.

Description

Building construction for the production of

Fresh water from sea water The invention relates to a building structure according to the preamble of claim 1.

A building construction mentioned at the beginning has become known in Israel, which only consists of a single shell that is closed on all sides and defines a closed interior. The shell is made with clear plastic sheets covered or covered with transparent plastic film, so that the on the Solar radiation acting on the building structure gets into the interior and the The interior heats up very strongly. Inside is a basin filled with salt water present in which the salt water due to the existing high temperature in the interior evaporates Because of the resulting cold evaporation, the inside of the The shell slightly colder than the outside of the shell exposed to sunlight, so that fresh water condensation takes place on the inside of the shell and the condensed fresh water runs down the inside of the bowl and through In the foot area in the interior of the building construction, collecting channels are collected and is collected.

This well-known building construction is only for the desalination of sea water suitable, with the disadvantage that the contained in the evaporation basin, Fortified salt water is difficult to apply because it evaporates salt crystallization occurs.

Another disadvantage of this known building construction is that the interior is at such high temperatures that it can be used further this building construction, e.g. as an air-conditioned greenhouse, is hardly possible.

The invention has therefore set itself the task of a building structure of the type mentioned so that the building structure in areas with high solar radiation can be used as a greenhouse where both a production of fresh water with simultaneous air conditioning of the interior takes place and also ensures that the plants are supplied with fresh water is.

To solve the problem, the invention is characterized in that that the first shell spans a second shell at a distance and one from the interior Climatically separated intermediate space is defined in which the raw water via water distribution devices is sprayed that a tangential to the first and second shell air flow the Interspace penetrated, and that the air flow is withdrawn from the interspace and is passed through a heat exchanger whose other exchanger surface is cooler, than the temperature inside the building structure.

The air in the space between the two said shells will strongly heated by the sunlight. After in the space between If seawater is sprayed on the two shells, the one located there becomes Air highly enriched with moisture and drawn off by a fan. Of the Fan directs the air through a heat exchanger, that of a cooler one Medium is cooled, so that in the heat exchanger the water vapor with high humidity enriched air condenses (Falling below the dew point) and drains off as condensate and is collected.

The heat exchanger can be used as cocurrent, cross-current, cross-countercurrent or countercurrent heat exchangers, and consist of plates or tubes.

It is only important that the two media flows (on the one hand with high Air exposed to humidity and, on the other hand, a refrigerant) do not touch. The refrigerant here can be a chemical agent of a known type or also be groundwater, which in southern latitudes when taken from sufficient depths only partially has a temperature of around 100C.

In another embodiment of the present invention it is provided that the heat exchanger does not consist of a separate apparatus, but that instead of the heat exchanger, a third shell below the second shell in the Interior of the building structure is arranged. The one sucked in by the fan and air highly enriched with moisture is in the space between the second and third shell blown in and condensed on the inside of the second Dish, with the freshwater condensate draining onto the top of the third dish and is caught there, runs in the lower part of the construction and in a corresponding gutter is collected.

There is another option of fresh water supply that only - in comparison to the exemplary embodiments described above - a minimal one Requires additional effort. If you go into the space between the first and second Bowl of warm water at night (which was heated in a circuit during the day) sprays in and does not turn on the fan, then the water condenses on the Inside of the first shell, because the outside temperature at night is lower is as the temperature of the seawater heated in the circuit during the day.

Some of this water will drip off the surface of the inner film and flow back into the salt water circuit. Another part, however, will be - how - condense on the inside of the first shell and there through im Bottom area in the longitudinal direction extending water channels in the form of fresh water be caught.

The fresh water collected in the above-described embodiments is via well-known water distribution systems (e.g. capillary tubes, which on the root area the plant or through sprinkler systems that the fresh water in the interior of the Spraying the building structure) on the plants, unless it is as Drinking water should be used.

It is important with the invention that the production of domestic water takes place at the same time and with the arrangement of two climatically separated shells an air conditioning of the Interior of the greenhouse takes place.

After the sucked in air has cooled down in the heat exchanger, and one is able to use relatively large exchanger surfaces, it is possible to to cool the air flowing into the interior of the building structure accordingly, so that in the interior, for example, a temperature of 250 instead of an otherwise existing temperature of 300 results. This temperature reduction allows to arrange in the interior plants with appropriate plant beds, for this Plants optimal growth conditions can be created.

In this embodiment, the building construction described so used as a greenhouse. In other, not shown, embodiments However, it is intended to use the air-conditioned interior for others Purposes to be used where it matters, one in relation to the outside temperature to maintain a lowered interior space by maintaining a relatively low level of humidity.

The air humidity obtained in the interior depends on the efficiency of the the heat exchanger used and the temperature of the cooling medium. Such Building construction can therefore also be used as living, storage or manufacturing space Find.

The supporting structure for the building structure consists of one first preferred embodiment made of machine-rounded stainless steel tubes, the can be designed as round tubes or square tubes, with a semicircular or oval cross-section of the building structure is preferred because it is good Drainage areas for the water are formed in the area of the first and second bowl. Instead of using stainless steel pipes, you can also use correspondingly corrosion-resistant Plastic pipes are used.

Instead of being used, completely or partially more translucent Plastic foils can also be glass plates or translucent plastic plates Find use.

For a 50 m long building structure, which is about 10 m wide is, arises in southern latitudes, with solar radiation, as it is in the Middle East given are a drinking water production of about 4000 1 per day.

Another advantage of the building construction described is that that the dreaded salinization of the soil does not apply when using the inventive concept. By making fresh water from sea water, one is from fresh water sources independent and causes the controlled humidity existing in the interior no evaporation water withdrawal for the soil, which therefore cannot become too salty. In a further development of the invention according to claim 11, the incidence of light is through a fleece placed in the space on the upper side of the second shell or Tissue reduced and thus the thermal radiation captured in the space increased.

The evaporation surface is thus significantly increased and the efficiency the evaporation further increased.

In summary, the following advantages result: 1. Extraction of service water (fresh water) - partially or fully desalinated for a) drinking water b) irrigation of the plants in the interior of the building structure 2. Cooling of the interior through a) Blowing in cooled air b) Evaporation cold through water absorption 3. Protection from evaporation in the soil area and thus no salinisation of the soil.

The subject matter of the present invention does not result only from the subject matter of the individual claims, but also from the combination of the individual claims with one another.

All information and characteristics disclosed in the documents, in particular the spatial shown in the drawings Training claimed as essential to the invention insofar as they are individually or in combination with one another are new to the state of the art.

In the following the invention is based on several exemplary embodiments Illustrative drawings explained in more detail. Here go from the drawings and their description of further features and advantages of the invention that are essential to the invention emerged.

They show: FIG. 1: a perspective top view of a building structure according to the invention, Figure 2: Section through a first embodiment of a building structure, FIG. 3: Section through a second embodiment of a building structure, FIG 4: Top view of a building construction with a semicircular or rectangular cross-section with representation of the water nozzles and the air duct in the space between the Shells, Figure 5: Section through the building structure according to Figure 4, Figure 6: Partial section by a building construction in a fourth embodiment with illustration the air intake in the gable area, Figure 7: Cross-section through the building structure according to Figure 6, Figure 8: Partial longitudinal section through a fifth building structure with Air intake in the foot area, Figure 9: Cross-section through the building structure according to Figure 8.

The building structure according to Figure 1 consists of semicircular curved Support rods 16 and longitudinal rods 17 connecting the support rods in the longitudinal direction, wherein a first, outer shell 13 is defined.

Below and at a distance from the first shell is a second shell arranged, which consists of similar support rods 16 and the support rods 16 connecting Longitudinal rods 17 consists.

Both shells 13, 14 are completely or partially translucent Covered material, e.g. plastic panes, glass panes, double-walled panes or Plastic foils.

On the inside of the first shell there is a gutter 8 for collecting of fresh water is provided which runs down the inside of the first shell 13, while one on the outside of the second bowl was designed to collect salt water Gully 7 is present, another gully 8a for collecting fresh water is arranged on the inside of the second shell 14.

The second shell 14 spans an interior 12, which according to the above description is dehumidified and air conditioned. In the interior 12 can therefore plants are arranged which are watered by the fresh water produced. It is also possible to use the interior 12 as a living or working area.

Through the space 15 between the first and second shell 13, 14 a stream of air is moved (by convection or by forced ventilation), whereby the both shells are climatically separated from each other.

This means that the two shells 13, 14 are completely and airtight are closed from each other, with the exception of corresponding ventilation openings, through which the air flow in the space 15 between the first and second Shell 13,14 is blown or sucked in from the interior 12, possibly also Fresh air can be added from the outside. In the space 15 can be a partial translucent fleece or fabric 53 can be arranged to reduce the evaporation effect to increase.

The further details of the building structure shown in FIG are explained with reference to FIG.

From a reservoir 6 filled with raw water 36 is via the Line 21 and a water pump 2 taken a raw water stream and over the line 22 of the spray device arranged in the space 15 between the first and second shell 10 supplied under high pressure.

The sea water is in the form of a circular atomization circle 11 (see FIG. 4) in the space 15 between the first shell 13 and the second Bowl 14 finely sprayed. By in the direction of arrow 18 on the first shell 13 Acting, strong solar radiation, the space 15 is strongly heated, whereby the raw water sprayed via the spray device 10 evaporates and partially in the gaseous aggregate state passes over.

The raw water not affected by evaporation flows in the direction of the arrow 20 on the outside of the second shell 14 and is supported by one in Longitudinally extending gully 7 collected where it is collected and is in turn fed to the storage basin 6 via the line 27. Important is the finding that almost exclusively in the space 15, the fresh water in the gaseous aggregate state passes over, while the raw water in more saturated State flows off in the direction of arrow 20 on the outside of the second shell 14.

Due to the resulting temperature difference, part of the water in the gaseous state of aggregation on the inside of the first Condense shell 13, run down there in the direction of arrow 20 and from there Gully 8 are collected.

The warm air, which is highly enriched with water vapor, is used by one, for example in the middle of the building structure arranged fan 1 sucked off and through a heat exchanger 4 sent.

The other exchanger surfaces of the heat exchanger 4 are over the flow 23 and the return line 24, for example, cooled by groundwater, this cooling water is withdrawn via a water pump 3 or instead of the cooling water can also be a find another cooling medium use.

As a result of the cooling in the heat exchanger 4, the temperature falls below the heat exchanger 4 air flowing through the dew point temperature and condensation takes place, wherein the condensate 25 runs down and in the form of fresh water 37 in one Reservoir 5 is collected.

From there, the fresh water can be used to irrigate plants or collected and used to supply drinking water.

The cooled one leaving the heat exchanger 4 in the direction of arrow 26 and dehumidified air is released into the interior space 12, causing it to be as described Conditioning of the climate in the interior 12 is coming.

In the manner described with reference to FIGS. 5-9, the air from the interior space 12 back into the space 15 between the first shell 13 and the second shell 14, wherein between the first and second shell 13,14 corresponding air inlet openings are provided. The dehumidified and Cooled air flows as an air stream 39 in the direction of arrow 19 in the space 15 between the shells 13,14 upwards, whereby they are strongly heated by the solar radiation becomes, and again moisture through evaporation from the spray mist of the water nozzles 10 can accommodate.

Characterized in that the air flow 39 in the direction of arrow 19 in countercurrent to which flows on the outside of the second shell 14 running salt sole 40, is the evaporation efficiency is further improved.

The heated up flowing out of the return line 24 of the heat exchanger 4 Refrigerant is introduced into the line 27 and in whole, in part or not returned to the reservoir 6.

In the following figures, the same reference numerals are used for the same parts used.

In the embodiment according to FIG. 3, that shown in FIG. 2 is omitted Heat exchanger 4 and is instead replaced by a third shell 9, which is in the Spaced with the formation of a gap 38 arranged below the second shell 14 is. The fan 1 emits the air sucked in in the direction of the arrow 28 in the direction of the arrow 26 from. The high humidity air blown into the space 38 condenses on the underside of the second shell 14 and drips in the form of a condensate 29 as Fresh water 37 on top of the third tray 9 where the fresh water is in to the side attached gutters 8 is collected; the gutters8 are through a common line 31 connected to each other, which the collected water in the Reservoir 5 initiates. The third shell 9 thus acts as a condensate collecting film.

The condensate stream 29 which does not drip onto the third shell 9 runs down along the underside of the second shell 14 and enters one at a time gully 8 in the foot area.

FIG. 4 shows the air flow and water distribution in general a building construction according to Figure 1 or according to one of Figures 5-9.

It is preferred here if the air flow 39 from the gable ends 32,33 blown into the space 15 between the first and second shell 13,14 will.

The water nozzles 10 are arranged at a mutual distance from one another and each form an atomization circuit 11, so that those from the corners and gable sides or air 39 flowing in along the longitudinal side in a star shape in the direction of arrow 28 to the in the fan 1 arranged in the middle of the ceiling area flows. It arises with it a particularly favorable penetration of the spray generated by the water nozzles 1o through the air stream 39.

In Figure 5 it is shown that the building structure is only one narrow opening defined between a first shell 43 and a second shell 44, wherein the openings are each arranged on the gable ends 32, 33.

The air thus flows from the corners in the directions of arrows 34, 35 to the fan 1 arranged in the middle and on the ceiling, from where it moves in the direction of the arrow 26 is submitted. For the sake of simplicity, it is not shown here that the direction of the arrow 26 released air either in the space 38 of a third shell 9 or in a heat exchanger 4 is introduced.

FIG. 6 shows that the air is entering the space 15 the front sides of the building structure is given, while in Figures 8 and 9 of Air entry through openings 49, 50 arranged on the longitudinal sides 47, 48 in the second shell 14 takes place. The air is thus in the direction of arrow 51,52 from the interior 12 coming here deflected at the openings 49, 50 and then flows into the space 15 between the first shell 43 and the second shell 44.

The support structure 45, 46 shown in FIG. 5 forms here each a rectangular cross-section of the entire building structure.

DRAWING LEGEND 1 blower 2 water pump (spray tubes) 3 water pump (Heat exchanger) 4 heat exchanger 5 storage basin (fresh water) 6 storage basin (raw water) 7 Gully (raw water) 8 Gully (fresh water) 8a Gully (fresh water) 9 third shell 10 spray device 11 atomization circuit 12 interior 13 first shell 14 second shell 15 space 16 support rod 17 longitudinal rod 18 arrow direction 19 arrow direction (Air) 20 direction of arrow (water) 21 line 22 line 23 flow 24 return 25 Condensate 26 Direction of arrow (air) 27 Line 28 Direction of arrow (air) 29 Condensate (Fig. 3) 31 Line 32 Gable side (Fig. 4) 33 Gable side (Fig. 4) 34 Direction of arrow 35 Direction of arrow 36 Raw water 37 Fresh water 38 Gap (Fig. 3) 39 Air flow 40 salt sole 43 first shell (Fig. 5) 44 second shell (Fig. 5) 45 support structure 46 Support structure 47 Long side (Fig. 8,9) 48 Long side (Fig. 8,9) 49 Opening 50 Opening 51 Direction of arrow 52 Direction of arrow 53 Fleece or fabric - Blank page -

Claims (11)

Patent claims PN building construction for southern latitudes for generation of fresh water from sea, brackish and wastewater (raw water) using solar energy, consisting of at least one first shell illuminated by sun rays, which is closed on all sides and defines a closed interior in which the Raw water (salt water) is brought to evaporation, with the fresh water from the Raw water evaporates, characterized in that the first shell (13) with Distance a second shell (14) spanned and one from the interior (12) climatically separate intermediate space (15) defined in which the raw water (36) via water distribution devices (Water nozzles 10) is sprayed that one to the first and second shell (13,14) tangential Air flow (39) passes through the intermediate space (15), and that the air flow (39) from is withdrawn from the space (15) and passed through a heat exchanger (4,9), whose other exchanger surface is cooler than the temperature in the interior (12) of the Building construction. 2. Building construction according to claim 1, d a d u r c h g ek e n n z e i ch n e t that the heat exchanger (4) consists of a refrigerant or groundwater or seawater with a low temperature level, there is a cooled apparatus, (Fig. 3). 3. Building construction according to claim 1, d a d u r c h g e k e n n notices that the heat exchanger from the inside of the second shell and one at a distance below and defining an intermediate space (38) to the second shell (14) third shell (9) consists, and that the exhaust air flow of the fan (1) in this Interspace (38) is blown in or passes through free flow (convection). 4. Building construction according to claim 1, d a d u r c h g e k e n n shows that the first and second shell (13,14) each consist of one of a plastic film covered support structure (16,17; 45,46) made of support and There is longitudinal strut. 5. Building construction according to claim 4, d a d u r c h g e k e n n z e i ch n e t that the cross-section of the building structure is semicircular or oval-shaped is, (Figs. 1-3). 6. Building structure according to claim 1, d a d u r c h ge k e n n z e i ch n e t that the first and / or second shell (43,44) consists of one of translucent Plates covered support structure (45,46) and that the cross section of the Building construction is rectangular, (Figs. 5-9). 7. Building construction according to claim 1, d a d u r c h g e k e n n z e i c h n e t that the through the fan (1) in the space (15) between the first and second shell (13,14) introduced air flow (39) respectively at the gable ends (32,33) of the building structure from the interior (12) starting in the gap (15) is introduced (Fig. 6,7). 8. Building structure according to claim 1, d a d u r c h g e k e n n z e i c h n e t that the through the fan (1) in the space (15) between the first and second shell (13,14) introduced air flow (39) to the Long sides (44,48) in the foot area of the building structure over each one opening (49, 50) extending in the longitudinal direction from the interior (12) into the Gap (15) is guided (Fig. 8,9). 9. Building construction according to claim 1, d a d u r c h g e k e n n z e i c h n e t that in the space (15) between the first and second shell (13,14) each extending in the longitudinal direction of the building structure in the foot area Water channels (7,8; 8a) are arranged and that the fresh water (37) assigned Water channel (8) on the inside of the first shell (13) and the raw water (36) associated water channel (7) arranged on the outside of the second shell (14) is, (Figs. 1-3). 10. Building construction according to claim 3 and 9, d a d u r c h g e k It is noted that in the edge area of the third shell (9) another, extending in the longitudinal direction of the building structure to collect fresh water (37) certain, gully (8) is arranged, (Fig. 3). 11. Building construction according to claim 1, d a d u r c h g e k e n n z e i ch n e t that in the space (15) on the top of the second shell (14) there is a fleece or fabric (53) with an exactly definable shading value, that the light and heat radiation in the interior, on a fixable dimension and thus the thermal radiation captured in the space (15) thus increased.