EP2370363A1

EP2370363A1 - Solar condensation system with cascade evaporation

Info

Publication number: EP2370363A1
Application number: EP09763926A
Authority: EP
Inventors: Rudolf Kraft
Original assignee: Fh Oo Forschungs & Entwicklungs GmbH
Current assignee: Fh Oo Forschungs & Entwicklungs GmbH
Priority date: 2008-12-03
Filing date: 2009-11-26
Publication date: 2011-10-05
Also published as: WO2010063633A1; AT507297A4; AT507297B1

Abstract

The invention relates to a method and to a device, in particular operated according to the method, for recovering a processed fluid (9) from a contaminated fluid (6) through evaporation and condensation using heated air as a carrier material. In the process, the air is run through a substantially closed circuit (1) through natural convection, wherein the air is heated in an air collector (2) (solar collector) in order to then pass through a cascade evaporator (4) through which the contaminated fluid (6) flows. After the saturated hot air (7) exits the cascade evaporator (4), the absorbed moisture is released in a subsequent condenser (8). Then, the cooled and dried air is reintroduced into the air collector (2).

Description

Solar condensation plant with cascade evaporation

description

The present invention relates to a method for obtaining a treated liquid from a contaminated liquid by evaporation and condensation by means of heated air as a carrier material.

Furthermore, the invention relates to a device for obtaining a treated liquid in the form of a condensate from a contaminated liquid by evaporation and condensation, in particular according to the inventive method.

The invention primarily serves to recover drinking water from various sources of water, such as contaminated river water, brackish water or seawater, but may also be used to recover volatile solvents from liquid mixtures, with or without solid contents.

For the introduction of the required heat energy in the system, the use of a solar collector is described. Of course, it is also possible to obtain the required heat energy from other sources, for example geothermal energy, exhaust gases - for example from mobile power generation units - exhaust steam from process heat and the like.

State of the art

The provision of drinking water is becoming an increasingly pressing problem, especially in developing African countries. To remedy this situation, many different drinking water treatment processes have already been developed. Thus, numerous mechanical, biological, chemical and physical processes are known. The physical processes are essentially based on the principles of osmosis, electrolysis or evaporation. In particular, the evaporation offers a very good separation of suspended solids and dissolved impurities from the water. It has therefore been widely used so far. The raw water is generally under atmospheric pressure until heated to the boiling point. In a subsequent condensation stage, the purified drinking water is recovered. However, problems may occur here due to crystallization of the dissolved substances; for example, blockages may occur in plant components which lead to malfunctions. In addition, a high energy input is required for the evaporation, and in the countries affected by water shortage energy is usually in short supply, with the exception of solar energy, which is usually present to a large extent.

It was therefore obvious that in recent years many ideas have emerged to equip fresh water plants with solar panels. However, all these known devices have significant disadvantages, for example, that they require an additional entry of electrical energy or are less effective, are constructed of complicated components whose operation requires trained professionals and are maintenance-intensive. Also, it is usually impossible to provide with simple means corresponding spare parts.

Technical task

The present invention therefore has as its object to provide a method which allows the cost-effective and mobile recovery of pure liquids, in particular drinkable water.

Furthermore, the object of the invention is to provide a device for extracting pure liquids, in particular drinkable water, which preferably requires no additional electrical energy, is essentially maintenance-free, consists of modular components, which are light with the means even in rough areas can be transported to the place of use, can also be assembled by non-professionals, are cost-effective in their production and can be operated with locally available energy, such as solar energy or waste heat from existing heat sources

This object is achieved in terms of the method, starting from a method of the type mentioned in the present invention that the air is conducted in a substantially closed circuit by natural convection, the air heated in an air collector, then a Kas- It passes through the evaporated evaporator, which is then flowed through by the contaminated liquid, in order subsequently to discharge the moisture absorbed in the cascade evaporator in a downstream condenser before it re-enters the air collector. With regard to the device, the object is achieved starting from a generic device according to the invention that a substantially closed circuit is provided with air as a substrate at atmospheric pressure, in which a vertically or obliquely arranged air collector with means for receiving heat from an external heat source and Dissipate this heat to the air, a cascade evaporator and a condenser are integrated, so that the air moves through natural convection through the circulation.

The device is used in particular for carrying out the method according to the invention. Alternative embodiments or advantageous developments of the method and apparatus are the subject of the dependent claims. The method is based on the consideration that for the evaporation of a liquid a significantly lower energy input is required than for their evaporation and the performance of a device of the generic type substantially from the heat content of the contaminated liquid and the carrier medium, as well as their temperature difference in the separation of the treated liquid depend on. The process parameters should be adapted in particular to the local conditions at the site and the highest possible heat recovery be possible to create temperature and energy input optimized conditions.

According to the method of the invention, the stated objects are achieved and considerations implemented by the recovery of a treated liquid from a contaminated liquid by evaporation and condensation by means of heated air is carried out as a carrier material, wherein the air transported in a substantially closed circuit by natural convection becomes. In this circuit, an air collector for heating the carrier air, a cascade evaporator and a condenser for cooling the carrier material air and recovery of the treated liquid are integrated as a condensate. If the process is used to obtain drinking water, any water source can be used as the contaminated liquid, for example sea, lake, river, spring, groundwater or brackish water. This water may well be contaminated with suspended matter or dissolved substances. All of these undesirable ingredients are just as safely retained in the contaminated, concentrated liquid as they are in an evaporation evaporation.

The inventive method is also suitable for the recovery of volatile solvents from liquid mixtures. Only in the case of equipment wetted by the liquid or its vapors, the selection of the material must be considered. The structure of the device is also simplified by the fact that the process is operated at atmospheric pressure.

The natural convection of the air in the circulation is based on the principle that hot air rises in a closed circuit, while cold air sinks into it. By a vertical or oblique arrangement of the air collector, this effect is still supported.

An oblique arrangement is particularly useful when the air collector is designed as a solar collector. In doing so, the air below the translucent cover is heated by the solar radiation, whereby this effect is supported by a collector base made of blackened metal sheet. Radiation losses can be significantly reduced by known insulation measures.

However, it is also possible to use the heat from other heat sources for heating the carrier air via corresponding installations in the air collector, for example spiral or register tubes. Depending on local conditions, exhaust gases from a generator, process heat, geothermal energy, etc. may be considered.

EXEMPLARY EMBODIMENT The method will be explained in more detail below on the basis of an exemplary embodiment and a drawing. The only figure shows: 1 shows an embodiment of the solar condensation plant according to the invention with cascade evaporation on the basis of a schematic representation of the individual components and their interaction.

To simplify the presentation of the method principle, the solar radiation is assumed to be the energy source. The embodiment of the cascade evaporator shown here is merely illustrative of the principle and therefore does not limit its construction.

The air guided in the essentially closed circuit 1 is heated in the air collector 2 by the solar radiation 3 and / or by indirect transfer of the waste heat from another heat source, rises by natural convection and enters the cascade evaporator 4 through the inlet opening 15 , in which a predetermined number of horizontal or slightly inclined Verdunsterblechen 5 are arranged so that in the cascade evaporator 4 - preferably via a siphon-like installation 17 - introduced, contaminated liquid 6 on its way through the Kaskadenverdunster 4 has the longest possible way. In this case, part of the liquid in the form of vapor is taken up by the hot air 7 which slides over the liquid film. The residue of contaminated liquid 6 concentrated with the impurities is discharged in the lower region of the cascade evaporator 4, preferably via a siphon-like installation 18, and disposed of in a suitable manner. The saturated with moisture hot air 7 is supplied through the outlet opening 16 from the cascade evaporator 4 out of a condenser 8, in which the heat content of the hot air 7 - preferably by indirect contact with fresh contaminated liquid 6 - is deducted. The resulting in droplet form condensate 9 is discharged from the condenser and the cooled transport air flows back into the air collector 2 a. The air collector 2 is arranged obliquely or vertically, to support the natural convection of the transport air.

In an alternative embodiment, the air convection is supported by an additional fan 10. The inflow of contaminated liquid 6 into the condenser 8 and further into the inflow line 11 to the cascade evaporator 4 takes place via the pump 12. Of course, it is also possible for the contaminated liquid 6 directly, so without preheating in the condenser 8 via an entry device 13 of any type the cascade evaporator 4 supply.

The entry of the contaminated liquid 6 into the cascade evaporator 4 via the feed line 11 preferably takes place via a siphon-like installation 17. At the start of the discharge line 14 for the concentrated contaminated liquid 6, a siphon-like installation 18 is preferably also provided in order to ensure a largely closed circuit 1 to ensure.

Particularly preferably, the feed line 11 for the contaminated liquid 6 ends in a distributor device 19, for example a transverse channel, which is arranged on or above the first evaporator plate 5.

In a further preferred embodiment of the device according to the invention, the evaporator plates 5 are supplied with heat via additional devices, not shown here, in order to compensate for excessive cooling due to evaporation energy. Such devices may be, for example, outwardly projecting metal sheets heated by the sun or by other heat sources, which are in good heat-transmitting contact with the evaporator sheets 5. As an alternative, however, many other constructions familiar to the person skilled in the art are also conceivable. In order to prevent heat loss of the cascade evaporator 4, it is also possible to form this heat-insulated.

Claims

claims

1. A method for obtaining a treated liquid (9) from a contaminated liquid (6) by evaporation and condensation by means of heated air as a carrier material, characterized in that the air in a substantially closed circuit (1) by natural convection in which the air is heated in an air collector (2), then passes through a cascade evaporator (4) through which the contaminated liquid (6) flows, and then the moisture absorbed in the cascade evaporator (4) in a downstream condenser (FIG. 8) before entering the air collector (2) again.

2. The method according to claim 1, characterized in that the heated air (7) and the contaminated liquid (6) through the cascade evaporator (4) in the same direction or in the opposite direction.

3. The method according to claim 1 or 2, characterized in that the contaminated liquid (6) sea, brackish, river, sea or contaminated Quelloder groundwater and the treated liquid (9) is drinking water.

4. The method according to claim 1 or 2, characterized in that the contaminated liquid (6) is a mixture of volatile solvent in other liquids with or without solids or solutes and the treated liquid (9) is the volatile solvent.

5. The method according to any one of claims 1 to 4, characterized in that the contaminated liquid (6) in the condenser (8) is preheated with simultaneous cooling of the air and condensation of the treated liquid (9).

6. The method according to any one of claims 1 to 5, characterized in that the natural convection of the air in the air circuit (1) by a fan (10) is supported.

7. Apparatus for recovering a treated liquid (9) in the form of a condensate from a contaminated liquid (6) by evaporation and

Condensation, in particular according to a method according to claims 1 to 6, characterized by a substantially closed circuit

(1) with air as a carrier material at normal pressure in the a vertically or obliquely arranged air collector (2) with means for receiving heat from an external heat source and delivery of this heat to the air, a cascade evaporator (4) and a capacitor (8) integrated so that the air moves through natural convection through the circuit (1).

8. Apparatus according to claim 7, characterized in that the air collector

(2) is designed as a solar collector.

9. Apparatus according to claim 7 or 8, characterized in that the air collector (2) with internals, in particular spiral or register tubes is equipped to heat from other heat sources, such as geothermal energy, hot exhaust gases such as mobile power generators or Exhaust steam from process heat to supply the carrier material air.

10.Vorrichtung according to claim 7, 8 or 9, characterized in that the cascade evaporator (4) has an inlet opening (15) for hot air (7), an outlet opening (16) for vapor-saturated hot air (7), a plurality of Verdunsterblechen ( 5), an inlet (11) for the contaminated liquid (6) and a drain (14) for concentrated liquid, wherein the Verdunsterbleche (5) are arranged in a horizontal or slightly oblique position.

11.Vorrichtung according to any one of claims 7 to 10, characterized in that the Verdunsterbleche (5) are arranged offset from one another.

12. Device according to one of claims 7 to 11, characterized in that the Verdunsterbleche (5) have openings.

13. Device according to one of claims 7 to 12, characterized in that the Verdunsterbleche (5) are formed Strömungsverwirbelnd.

14. Device according to one of claims 7 to 13, characterized in that the cascade evaporator (4) is thermally insulated.

15. Device according to one of claims 7 to 14, characterized in that the cascade evaporator (4), in particular via the Verdunsterbleche (5) from the outside heat is supplied.

16. Device according to one of claims 7 to 15, characterized in that the removal of concentrated liquid from the Kaskadenverduns- ter (4) and preferably also the supply of contaminated liquid (6) in the cascade evaporator (4) via siphon-like internals (17 , 18).

17. Device according to one of claims 7 to 16, characterized in that the contaminated liquid (6) via a distributor (19), in particular a transverse channel is supplied to the first evaporator plate.

18. Device according to one of claims 7 to 17, characterized in that the condenser (8) for cooling the saturated hot air (7) with simultaneous heating of the contaminated liquid (6) is formed without contact the two media.

19. Device according to one of claims 7 to 18, characterized in that the contaminated liquid (6) via a pump (12) to the condenser (8) and / or the cascade evaporator (4) is supplied.

20. Device according to one of claims 7 to 19, characterized in that in the substantially closed air circuit (1), a fan (10) is integrated.