DE3123409A1 - Process and apparatus for sea water desalination - Google Patents

Abstract

A process and an apparatus for desalinating sea water by the gap evaporation principle, water being evaporated from a porous body into a gas gap and then being condensed by a condensation device, is to be further improved with respect to the necessary energy consumption and a high water separation rate. According to the invention, it is provided for this purpose that the sea water is first heated by absorbing the heat of condensation and is then heated by a heat source and that the heated sea water is then passed by the rear side of the porous body. The heat source preferably used is solar energy. <IMAGE>

Description

Method and device for salting seawater

The invention relates to a method for desalination of sea water according to the principle of gap attenuation, whereby water from a porous body in inec gas gap and then by means of a Yoncensatic device is condensed, as well as a device for performing this process, Bei The desalination of sea water, i.e. salt water in general, is made of salt Water Fresh water (for use as drinking or industrial water @) obtained.

The systems for fresh water extraction work mainly according to one Distillation process is an essential feature of this distillation unit can be accumulated in one or more stages, De »eh + generally in that evaporator and condensation surfaces have a relatively large distance from one another.

Therefore, a technically usable condensation or. Water separation rate can only be achieved with inert gas-free steam rooms. Since together with the salt water but air is constantly entering the distillation units, it is essential to that vacuum pumps are used in systems of the type described, what a not inconsiderable technical effort.

The effort mentioned can then be avoided if according to the principle the so-called gap evaporation is used. Here are the evaporator and Condensation surfaces of the distillation equipment a narrow one Gap, a so-called gas gap, separated from each other. In this case, too in the presence of inert gas, such as air, in the gas gap, the diffusion rate of the Water vapor to the condensation surface large enough to achieve technically usable water separation rates to be able to realize.

From US Pat. No. 3,129,145 there is a method and an apparatus for the production of pure water czus seawater, which according to the above Working principle. The corresponding device has two porous layers or bodies that are separated from each other by the gas gap. Both porous layers are arranged on impermeable walls, so-called separating layers, of which one is heated and the other is cooled. This way it evaporates from the Surface of the warmer porous layer to which the Neer water is fed, water, the formed WaS '? rdrn1pI passes through the gas gap, condenses ar or in the colder porous layer and is then removed from this layer.

With such an arrangement, narrow gap widths, for example on the order of a few millimeters, because the vaporizing Surface of the sea water is stabilized in a porous structure. The exit of sea water or

the condensate from the porous layer is replaced by the prevailing therein Capillary forces and beyond by maintaining a gas pressure in the Gas gap prevented.

However, the known method requires a considerable amount of energy, since the liquids have to travel long distances in the porous layers (they stream essentially laterally through the porous bodies, i.e. parallel to the separating layers); in addition, there is a uniform application of the elements used for evaporation porous layered seawater can hardly be reached Desillation device relatively expensive, since both on the evaporator as well as on the condensation side is a separating layer and a porous layer E40rbanden.

The object of the invention is to provide a method of the aforementioned Type of desalination of sea water, in which a porous body is used for evaporation, with regard to the required energy consumption and a high water separation rate to improve further.

This is achieved according to the invention in that the sea water first by absorbing heat of condensation and then heated by means of a heat source and that the heated sea water subsequently on the back of the porous body is passed by.

A device for carrying out the method according to the invention has a porous evaporation body and a condensation device, which limit the gas gap. The evaporation body is covered by a porous membrane formed, the condensation device is an impermeable, i.e. non-porous Condensation surface. The porous membrane and the condensing surface are respectively on the rear side, i.e. on the side facing away from the gas gap, the sea water flows through it. In the liquid line, i.e. in the line for the sea water, there is between a heat exchanger is arranged in the condensation device and the evaporation body, by which thermal energy is transferred from a heat source to the seawater.

Since in the process according to the invention, the sea water forms the porous evaporation body is not flowed through, but merely guided past it, the membrane is wetted by the liquid, less energy is required here. Furthermore, since the membrane is wetted evenly, the water separation rate is also high guaranteed. This method also has the advantage that the (external) heat source does not generate all of the heat of vaporization got to. D -.- iS sea water is namely, before it is heated by the heat source, on the back of the condensation surface and takes the heat of condensation of the water, i.e. the heat released during the condensation of the water vapor, on.

Finally, the device according to the invention is also distinguished by this s that it has a relatively simple structure. To carry out the gap evaporation is here namely in addition to the porous evaporation body only one non-porous Condensation surface required.

In the method according to the invention, the preferred heat source is Solar energy used. Seawater desalination plants are mostly used in Installed in areas with high levels of sun exposure. As a heat exchanger are generally used for solar collectors, including flat vacuums, so-called 1Heat Pipe "and concentrating collectors come into consideration. Comes the collector in direct contact with sea water, it must consist of a material which is resistant to hot salty water. But there is also the possibility that the heat exchanger via an intermediate circuit from (Solar) collector or another heat source is disconnected; then the requirement mentioned does not apply.

In the method according to the invention, it is possible to heat the seawater For example, superheated steam can also be used.

The escape of the sea water from the evaporation body can occur during erfindungsgeinäß.en method by applying the hydrostatic pressure of the Liquid compensating gas overpressure in the gas gap can be prevented; here Then the porous Vtemtran consists of hydrophilic material. Can be advantageous for Prevention of the leakage of liquid but also a hydrophobic Me-mbr & n used so that a gas overpressure is not required.

The invention is based on an exemplary embodiment and a figure further elaborated, el t wenlen In the figure, in which an advantageous embodiment a device for carrying out the method according to the invention schematically is shown, the reference numeral 10 denotes a gap evaporator cell. The cell 10 consists of two liquid spaces 11 and 12, between which a gas gap 13 is located.

The interface between the liquid space 11 and the gas gap 13 is formed by an impermeable condensation surface 14, the liquid space 12 is separated from the gas gap 13 by a porous membrane 15, the evaporator surface.

During the operation of the seawater desalination plant, the liquid guided through the Spaliver evaporator cell 10 in countercurrent. This is the sea water by means of a pump 16 initially in the liquid room 11 brought in, with the condensation heat of the (separated) Absorbs water. The preheated Neer water passes from the liquid space 11 a collector 17, where it - as shown symbolically in the figure by arrows -is brought to the required temperature by means of solar energy. Afterward the heated seawater enters the liquid chamber 12 of the split evaporator cell 10 where it comes into contact with an evaporator surface 15. This evaporates then water through the porous membrane into the gas gap 13. Through the evaporation process the concentrated seawater is cooled down due to the loss of fluid.

Further cooling takes place through the release of heat as a result of heat conduction. The cooled salt water finally leaves the liquid space 12.

The water vapor which has passed into the gas gap 13 condenses a the cold condensation surface 145 with the heat of condensation on that in the liquid space 11 located seawater is transferred. Another warming of the sea water takes place by direct heat conduction from the liquid space 12. That on the condensation surface 14 condensed water, the fresh water, is appropriately removed from the gas gap removed. Is the S.psltverdempferzelle 10, as shown in the figure vertical arranged, the condensate simply flows downwards.

The gas gap 13 is, for example, approximately 3 mm wide. Becomes a hydrophobic If the membrane is used as an evaporator surface, the gas gap is expediently with Air filled by atmospheric pressure. on the other hand, the condensation surface is a hydrophilic one Membrane, the hydrostatic pressure of the sea water in the liquid space 12 by a corresponding excess gas pressure in the gas gap 13 compensated. Is doing this in the gas gap Hydrogen sets one, so is the diffusion of water vapor through the gas gap especially high. If there is an overpressure in the gas gap 13, the rest of the condensate is formed. as shown in the figure, via a pressure lever 18.

Hydrophilic evaporator surfaces exist in the device according to the invention generally made of asbestos, the following materials, among others, are also suitable : Nickel and hydrophilized polyethylene or propylene. As a hydrophobic evaporator surface can, for example, Polytetrafluoräthy er (PTFS) or asbestos material hydrophobized with PTFE as well as polyethylene and propylene are used. The condensation surface that Should be a good heat conductor is preferably made of metal, such as nickel or VA steel ; But graphite papers or thin plastic films can also be used will.

To increase the water separation rate and to achieve a compact Structure and to reduce the heat dissipation to the environment can with the invention Device, several gap evaporator cells can be joined together to form a block. The cellular structure of such distillation devices also allows a simple Way a modular structure of larger seawater desalination plants. The corresponding Liquid spaces of the individual cells can be parallel with such a structure or connected in series.

In order to achieve an optimal water separation rate m, the invention Device - at a given heat flow CSR, that of the (outer) Heat source is transferred to the seawater - for the evaporator surface F and the supplied Keerwasserstrom M certain values selected. These result from the following considerations.

The heat flow in the gas gap is due to the evaporation-condensation process and due to thermal conduction: QWT = QV + QL # The one caused by the evaporation process conditional share # = QV / QWT - and then also the water separation rate - has in one Temperature difference ATSP between evaporator and condensation surface in the area of 5 K an optimum.

If heat losses to the environment are neglected and on the assumption that m <<M, the following applies (C = specific heat of the water): QS = C # M # (T3-T2) = C # M # (T4- T1) = C # M # ATSP and 1 QWT = C # M # (T3-T4) = --- QV # # The following applies: T1 is the inlet temperature of the sea water in the liquid space 11 and T2 the corresponding outlet temperature, T3 is the temperature at the outlet of the heat exchanger 17 or the inlet temperature of the sea water in the liquid space 12 and T4 the outlet temperature from this liquid space.

With a heat flow proportional to the area or

A water separation rate m1 proportional to the area for the gap evaporator cell also results in the following: With a solar irradiation of 800 W / m², a heat flow QS = 400 W / m² is transferred to the sea water using a flat plate collector, for example.

For the individual temperatures Kilt, for example, the following: T1 = 20 ° C and T3 = 80 ° C, #TSp = T4-T1 is 5 K. It was also determined experimentally that qV = 0.33 W / cm² and # = 0.5 , ie half of the heat is transported through evaporation and half through heat conduction. With the data given above, the following values result, in each case based on 1 m² collector surface: QV = 0.5 # ## # QS = 5.5 # QS = 2200 W / m² F = #### # QS = 6680 cm² / m²; m = 0.5 # 16.7 # QS = 3.36 kg / h # m² and For other operating conditions, such as QS = 400 W / m², T1 = 200C, T3 = 10000 and tTsp = 10 K, the value for F is, for example, 3640 cm2 / m2.

5 claims 1 figure

Claims (5)

Claims 1. A method for the desalination of seawater according to the Principle of gap evaporation, whereby water from a porous body into a gas gap is evaporated and then condensed by means of a condensation device, d a d u r c h e k e n n -z e i c h n e t that the sea water initially by absorption is heated by condensation heat and down by means of a heat source and that the heated seawater subsequently passed the back of the porous body will. 2. The method 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 solar energy is used as a heat source. 3. Device for performing the method according to claim 1 or 2 with a porous evaporation body and a condensation device limited gas gap, which means that the evaporation body a porous membrane and the condensation device an impermeable condensation surface is, which are flowed in each case on the back of the sea water, and that in the Liquid line between the condensation device and the evaporation body a heat exchanger for the transfer of thermal energy from a heat source to the Sea water is arranged. 4. Apparatus according to claim 3, d a d u r c h g e k e n n z e i c Note that the heat exchanger is a solar collector. 5. Apparatus according to claim 3 or 4, since d u r c h g e k e n n z It is clear that the porous membrane is made of a hydrophobic or hydrophilic material consists.