DE19654196A1 - Water desalination plant - Google Patents

Abstract

A method for the desalination of liquids containing salt, preferably salt water (especially sea water), to form a salt-free liquid and a separate salt-enriched sol, includes the step of spray-drying the sol. Also claimed is an apparatus used for this method, comprising a high pressure pump for the sol, linked to a spray nozzle system that sprays the sol into a drying chamber.

Description

1 State of the art

The actual task of the desalination process is to separate the solvent - here pure water - from the brine. Drinking or process water is nowadays obtained from naturally available salt water sources, such as sea water, up to a certain degree of exploitation by evaporation or thermal or membrane desalination processes. Before the actual desalination, insoluble impurities in the water are removed in a pretreatment, the "pretreatment", by treating all or most of the insoluble constituents by the following procedure:

• - Removal of insoluble substances by mechanical methods, mainly through coarse and fine filtration up to 1.0 m
• - Removal of colloidal components using chemical and / or physical chemical and biological processes.
• - Removal of solutes that tend to be colloidal as well as colloidal dispersed substances.
• - Organic compounds are also oxidized and / or adsorbed treated.

1 Thermal desalination process

The thermal seawater desalination process is one of the generally known distillation processes:
the most important is the "MSF; Multi Stage Flash" evaporation process. All types of MSF systems have brine heaters from a separate energy source. The brine is pumped to the bottom of the first chamber and then continues to flow in all subsequent stages in which the relaxation process is repeated, whereby:

• - The brine, which is located at the bottom of the chamber, forms steam while cooling.
• - The steam condensed on the condenser tubes simultaneously the countercurrent Brine warms up.

As a result of evaporation, the salt content in the brine increases from stage to stage. Around The salt content in the circulating brine must not be allowed to rise indefinitely on one A certain amount of brine is withdrawn from the circuit - the so-called "brine" or concentrate - back into the sea or indirectly through percolation wells to be led.

The increase in the yield or the decrease in the amount of brine beyond the current limits addition, possibly due to an increase in the brine temperature, is currently not technically possible. Despite a very strict surveillance system and compliance with the most permissible Temperatures of 90 ° C and acid metering quickly form solid deposits.

The water chambers and all pumps as well as are particularly at risk of corrosion Pipelines for sea water and brine, although they are made of sea water resistant Material had to be manufactured.

There are two types of MSF systems. A so-called circulation system because the brine with a special pump is circulated. The other is the continuous system, which is not a separate one Has heat dissipation part.

1-2 membrane desalination processes

Before 1980, the entire world desalination capacity was 7,277,000 m ³ / d, 75% of which is due to thermal seawater desalination plants. After 1980, predominantly membrane desalination plants were built. This happened as a result of the rapid development of the membrane shape and its material.

The membrane process is - from a physical point of view - a separation and Enrichment process based on selective mass transfer through semipermeable membrane declines, which are set within certain limits due to their salt retention capacity can. The osmotic pressure of the raw water compared to the of pure water, a measure of the difference in the thermodynamic activity of the saline water.

Before entering the membranes, the raw water must be pretreated, as with the "Pretreatment" of the thermal process. The sea water tends to have solid deposits to build.

Natural sea water is usually saturated or even saturated with calcium carbonate oversaturated, so when concentrating or heating solid calcium or Magnesium carbonate excreted. Because of this, it is extremely important to have one exact chemical analysis of the raw water, especially some sparingly soluble salts (see tab. 1) to be made. On the other hand, if possible, one must always take into account that the Concentration of the different salt components in the sea water their saturation point or approaches their solubility limit. Poorly soluble salts, such as calcium carbonate in natural sea water, is usually in saturated or even in over-saturated state present. Therefore, at high temperature as well as at pH Setting, the solubility limit of calcium, and magnesium sulfate reached and it separates as a solid deposit. This is even more difficult  Equilibrium shift with ion concentration change as far as the solubility generally influenced.

It must be emphasized here that the sea water in the "pretreatment" is not the Solubility products of its salt components may exceed. Another task of "Pretreatment" is the removal of accompanying suspended matter, as well as colloidal Dispersions.

The water was sterilized by chlorination, ozone or UV radiation. Besides, that is Removal of slime-forming suspended matter with the help of an effective "back wash" - System. The solution to desalination tasks in seawater desalination by means of the membrane process is, in the current state of the art, the two-stage Procedure, especially if the salinity in the sea water is 35000 ppm exceeds. An ideal case for a process combination is an ultrafiltration stage the two-stage membrane process.

1.3 "BRINE" treatment

The product water costs depend, whether in the thermal or membrane separation process the raw water salt content and its individual chemical compositions. The means you have to find a suitable demineralization process combination with the goal increasing the final yield and influencing product water costs, as well as in the first Line also to relieve the environment. Such processes are not technically possible today. Man determines whether the enriched brine or "Brine" or concentrate, directly or indirectly into the sea. This happens with a salinity up to 6.0% and a temperature of 60-80 ° C in the thermal processes; and until 7.5% as salinity and no increase in water temperature in the membrane process. It it must be stated expressly that in this case no further increase in yield is possible d. H. the remaining 60% are discharged into the open sea.

A comprehensive recovery rate of 40% or 60% as "Brine", which is was treated by pretreatment, d. H. 60% of the investment capacity must be economical seen not only for their investment costs, but also for operating costs, as Loss of obsession.

If you want to further concentrate the "brine" or increase the yield, the following phenomena occur:

• the risk of crystallization occurs in one of the known thermal processes, as well as the deposit problems not only in the pipes of the desalination plant, but also in the brine heaters, so such a process is for this Purpose still unsuitable.
• - The use of membrane processes is here due to the very high salt content or of osmotic pressure, also not possible. From a physical-chemical point of view, Solution in this case before in a saturated state and has its equilibrium condition reached.

Due to the above Finding and still is the only method of eliminating the "Brine" either direct return to the open sea, using this method for a long time View will not be possible, or because of environmental problems, especially where  Coral reefs are present, then the complete evaporation of the entire "brine" in "Evaporation Ponds".

The solubility product, or the product of the concentrations of Cations and the anions in a saturated aqueous solution

The solubility product, or the product of the concentrations of Cations and the anions in a saturated aqueous solution

2 Name of the invention

One can by the spray drying process without problems various solutions, as well Allow dispersions to dry in a very wide range of concentrations, with the dissolved substance is recovered and the water released into the air as water vapor can be. In other cases, e.g. B. if the solvent is not water, then a Recovery processes are used.

If you are in the spray dryer, with the help of the counterflow of the heating air, an optimal one Temperature profile has been reached, the heat is also optimally used and an economical one Evaporation process reached.

The spray drying process essentially consists of:

• - High pressure pump
• - Spray nozzle system
• - drying chamber  
• - air heater

Concentrate around brine using the spray drying method or to let it dry, this brine is pumped directly into the Spray nozzle system initiated. The fact is that using the spray dry If the brine only goes into the cold zone under turbulence. That means none There may be a risk of deposition.

3 Description of the process

3.1 Brine is connected to a ring-shaped with a high pressure pump under constant pressure Liquid distributor, the atomizer, directed and at a very high speed accelerates. This creates many small droplets that together form a large surface to have. When they are led into the drying chamber, they are countercurrently heated by highly heated air dried at a temperature of 500-800 ° C. The right atomizer is the one The key to the spray drying process.

3.2 A so-called centrifugal atomizer is best suited in this case because it flexible and reliable produces very small and regular droplets before they enter the Run in the drying chamber. Such a process in turn closes the deposit danger out.

3.3 The spray drying chamber is either in a conical or cylindrical shape Flat floor installed and is also with a "cleaning ring" scratch system or pneumatic hammer system. This to make sure that the back remaining deposits in the chamber are continuously eliminated.

3.4 Evaporation: The atomized Brine is in small droplets with indirect or direct air heating system heated and dried up to a temperature of 800 ° C, or evaporated.

3.5 Air heater system: The air heater is used with light oil, heavy oil or gas Fuel, provided.

In the indirect heater, in the form of a heat exchanger, the hot combustion gases heat up the air mixture without coming into contact with each other. The air mixture exists from fresh air and the circulating air from the drying chamber.

In the case of the direct air heater, the hot combustion gases are combined with a corresponding one Amount of the surrounding air mixed and led directly to the spray dryer. This system is the direct air heater system and gives the highest possible thermal Heat efficiency. In order to increase this degree of heat utilization, the excreted air coming out of the spray dryer into a closed loop, like follows.

3.5.1 The air that has been removed from the spray dryer and is saturated with moisture, is first passed through air / air heat exchanger system to remove the moisture it contains or to condense the water vapor and remove it from the system.  

3.5.2 The dry air components are then either directly or via a preheater system led to the air heater.

3.5.3 The water condensate that has been drawn out of the system is replaced by a Decarbonator or deaerator led to the water from its high content of being dissolved Rid of carbon dioxide.

3.6 The separated, dried brine is continuously removed from the bottom of the Spray drying chamber pulled out. The salt obtained can then be a by-product be designated and thus improves the economy of this process.

3.7 With this procedure, the brine is no longer returned to the sea. So here is solved the environmental problem of desalination plants, especially where coral reefs available.

It must be stated here that the decarbonized water condensate obtained contains less than 200 ppm salt, whereas water is used in the membrane process can produce a salinity higher than 500 ppm. If you mix this with the Condensate, a salt content of around 500 ppm is obtained.

3.3 In this process, the brine can either be fully or partially evaporated leave to then remove the highly concentrated brine and let it crystallize and in turn lead the mother liquor to evaporation.

3.9 The probability of the formation of deposits is obviously excluded here because the brine or salt concentrate, as mentioned above (under 3.2), only the cold zone of the Procedure goes through.

Claims (13)

1. A process for the desalination of saline liquids such as salt water, in particular sea water, in which at least largely salt-free liquid and a separate enriched brine are produced, characterized in that the enriched brine is spray dried. 2. The method according to claim 1, characterized, that the heat consumed in the spray drying at least at least partly through heat exchange between supplied Fresh air and the used heating air are recovered becomes. 3. The method according to claim 1 or 2, characterized, that the dried salt residues continuously abge pulled and be used for further use. 4. Device for performing the method according to one of the preceding claims, characterized, that one was struck by the fortified brine High pressure pump connected to a spray nozzle system is, which ver the brine in a drying chamber sprays.   5. The device according to claim 4, characterized, that the enriched brine with a high pressure pump under constant pressure on an annular liquid distribution manifold with atomizer and on a very high speed is accelerated. 6. The device according to claim 4 or 5, characterized, that in the drying chamber a temperature of 500 ° to 800 ° C is maintained. 7. Device according to one of claims 4 to 6, characterized, that the intended for the drying chamber Burner required and to be heated by the burner Fresh air is passed through a heat exchanger the exhaust gases are fed from the drying chamber. 8. Device according to one of claims 4 to 7, characterized, that the spray drying chamber is a conical or cylindrical cal shape with flat bottom and that it with a Scratch system or a pneumatic hammer system is prepared so that the remaining deposits continuously eliminated in the spray drying chamber the. 9. Device according to one of claims 4 to 8, characterized, that the burner provided on the spray drying chamber is fed with light oil, heavy oil or gas.   10. The device according to one of claims 4 to 9, characterized, that the exhaust gases emerging from the spray drying chamber with an appropriate amount of the surrounding air mixes and be returned directly to the burner. 11. The device according to one of claims 4 to 10, characterized, that the air emitted by the spray dryer, which with What steam is saturated, initially by a gas / gas Heat exchanger system is led to the water vapor to condense and withdraw from the system. 12. The device according to claim 11, characterized, that the exhaust gas components protected against water vapor escape to the burner directly or via a preheating system leads. 13. The device according to one of claims 4 to 12, characterized, that the water condensate separated in the heat exchanger is passed through a decarbonator or vent the water from its high content of dissolved carbondi rid of oxides.