AT403997B - Filter, particularly for desalination of seawater by means of reverse osmosis - Google Patents

Abstract

The invention relates to a filter 1,2,3 for desalinating seawater by means of reverse osmosis, comprising a base rod 1 which is provided on its circumference with segment strips 2. The invention is characterized in that both the base rod 1 and the segment strips 2 are made of the same seawater- resistant metal, where the base rod has a somewhat larger coefficient of thermal expansion than the segment strips 2, in that the difference in the coefficients of thermal expansion is achieved during the production of the two components 1,2 by means of differences in the production process, for example by different heat treatment or profile drawing, and in that, after assembly of the components 1,2, the faces 4 of the segment strips 2 are pressed together by gauge drawing and after heating to the temperature of the medium to be filtered, i.e. the seawater, filter slits of appropriate size, in the region of 10 - 10 m, are formed, with the medium to be filtered, i.e. seawater, serving as energy carrier for heating. <IMAGE>

Description

AT 403 997 B

The invention relates to a filter for the desalination of sea water by means of reverse osmosis, consisting of a base rod which is provided with segment strips on its circumference.

The sea water contains an average of 3.5% dissolved salts, especially NaCI. Ca, Mg and HCO3 &quot; are also represented. The drinking water should not contain more than 0.05% NaCI and 0.1% dissolved compact substances. The removal of appropriate amounts of salts from the sea water by means of ion exchange devices is not economical.

According to the prior art so far, multi-stage expansion evaporation is in the foreground when it comes to drinking water production and also water for irrigation purposes. The sea water is in several (up to 45!) Successive stages at 90 * C to max. Evaporated at 120 * C. The sea water that is introduced into the system and heats up serves as cooling water for the condensation of the steam that forms; part of the cooling water flows back into the sea, which causes a significant loss of energy. The second part of the preheated water mixes with the water concentrated by the evaporation and flows into the drain. The rest of the concentrate is also drawn off, causing further energy loss.

Certain requirements are placed on the quality of drinking water. In addition to the removal of coarse mechanical and biological contaminants, the components that cause an increased content of Ca and Mg ions must be eliminated or stabilized.

CaCOa and Mg (0H) 2 are deposited on unpurified sea water on the heat exchange surfaces and CO2 is released, which places a heavy burden on the performance of stills. It is possible to prevent the increased excretion of Ca and Mg ions with an H2SO4 addition, which results in MgSO * and CaSO *, which are relatively easy to dissolve. The necessary amount of H2SO «. is of course not to be neglected and is difficult to use at the site of desalination plants. In addition, the dosage must be very precise, because the addition of an insufficient amount leads to incrustation and the overdosage leads to corrosion.

Recently, polyphosphate or derivatives of polymaleic acid have been used for stabilization. At temperatures above 120 * C, CaSCU is excreted as an anhydride and no technically usable process exists for these conditions. Another process is now beginning to gain ground for the production of drinking water from saline water: reverse osmosis. With the help of external pressure and a semi-permeable membrane, a less concentrated solution is excreted through the membrane from concentrated solution. The pressure required depends on the content of the salt in the solution. To achieve a usable amount of water, the pressure applied must be significantly higher than the equilibrium with the osmotic pressure. For example, the equilibrium pressure of a solution with a salt content of 0.5% at 350 kPa, but the pressure required for water production is 4 to 7 MPa.

With higher pressure on the side of the raw water, the flow of the water is increased, but also the salt content in the product water is increased because the membranes do not completely retain the salt. In such cases, several stages are used. The membranes are made of acetyl cellulose or better polyamide. Because the pressures are high but the membranes are thin, this technical solution is very expensive.

Chemical preparation of the raw water is just as necessary as for evaporation. It is very advantageous to take the raw water from wells that are located near the shore. The operating costs for the production of drinking water from sea water depend to a large extent on the energy price; in any case, the operating costs are significantly higher than for the production of drinking water from fresh water. Reverse osmosis requires only 50% of the energy required for evaporation to produce water (8 to 10.6 kWhnrT3, based on the amount of fresh water, with a capacity of 19,103m3 d_1).

The object of the present invention is a filter system, especially for seawater desalination, consisting of a new type of metal filter for reverse osmosis; it is characterized in that both the base rod and the segment strips consist of the same seawater-resistant metal, the base rod having a somewhat larger coefficient of thermal expansion than the segment strips, that the difference in the coefficient of thermal expansion in the manufacture of the two components is due to differences in the manufacturing process, for example, different Heat treatment or profile drawing is achieved, and that after assembly of the components by calibration drawing the end faces of the segment strips are pressed together and after heating to the temperature of the filter medium, ie of sea water, form filter slots of appropriate size, in the range of Ä, the filter medium, i.e. Sea water, serves as an energy source for heating.

An advantage of such a filter system is a process flow without a change in the state of the sea water with lower investment and operating costs and with elimination of some of the chemical problems described above, which burden all previous processes. 2nd

AT 403 997 B

According to the invention, this is made possible in the case of a reverse osmosis of the above type, as described in the previous section, when two seawater temperatures of day and night period and average climatic temperatures interact, mainly in relation to the largest water consumption for irrigation purposes in the harvest period. In order to manage the circulation of the water in the above-mentioned desalination process and to rewind the water with an increased salt content, only the energy for pump operation is required.

In the following the invention is explained in more detail using an example and with reference to the accompanying drawings, wherein

Fig. 1 shows in enlarged scale an inventive filter in cross section, and

Fig. 2 in plan view, partially in longitudinal section, the filter which is attached according to the invention in the pressure vessel (Fig. 3).

Fig. 3 shows the pressure vessel on a smaller scale, partly in section.

1 shows parts 1 and 2 of the filter rods according to the invention. These two parts are pushed onto each other with little tolerance. Axial drainage channels 3 are left free between the rod core 1 and the push-on segment 2. After parts 1 and 2 have been assembled, the entire rod is drawn through a round caliber in such a way that the end faces 4 of the slide-on segments 2 are pressed into tight contact with one another without play.

After heating by the filter medium (sea water), longitudinal slits (in the A-area, about 1 (T10 m)) are formed between the end faces 4 in the contact area, the size of which changes with the heating.

To achieve this differential thermal expansion effect (because there are very minimal differences, on the order of λ), the two parts 1 and 2 are made of the same seawater-resistant metal, with only minor differences in the processing technology, e.g. during heat treatment or when drawing profiles, whereby a small difference in the coefficient of thermal expansion can be achieved.

For example, when using high-alloy austenitic, stainless steels one obtains for part 1: Ä, = 0.0000110 / 1 * 0, using one of the technological variants mentioned for part 2: Ä2 = 0.0000109 / 1 * C; This means that a difference of 0.8 Ä can be achieved in slot 4: for 1 Ä = 1 / 0.8 = 1.25, i.e. with a heating of the medium (sea water) by 1.25 * C a slit of 1 Ä. This means that a 6.25'C temperature increase is required for the filtration of molecules and elements that are larger than 5 Å. At temperatures increased by 12.5 * C, the slots are opened or enlarged, which facilitates backwashing to remove concentrated salt content and clearing out between the filter rods (1, 2) of the overpressure container (Fig. 3).

The following seawater-resistant alloys and pure metals are of metals which are suitable according to the invention:

Stainless steels: - Highly alloyed Cr, Ni, Mo (Ti) austenitic steels.

Aluminum alloys: - Lantal, Silumin, Hydronalium.

Bronze: - Al bronze 8 hard, - Delta metal.

Pure metals: - Tantalum (Ta), Titan (Ti), Nickel (Ni 99 hot rolled).

The sea water is a mild electrolyte with an alkaline characteristic (pH 7 to 8).

In the following, the conditions of the sea and the climate of the Adriatic are taken as a basis for the considerations.

Even in the winter months, the sea water temperature is still above 12 * C and the air temperature is above 8 * C. The small temperature difference for operations of filter systems in winter with corresponding drinking water consumption out of season can be compensated, e.g. using solar panels to compensate for 3

Claims (2)

AT 403 997 B small temperature differences and for the preparation of desalination. 2 shows a filter rod in side view and partly in section, the upper end of the filter rod being closed by means of welding 5; the lower end is provided with an extension 6. The filter rod is inserted in a common support and sealing plate 7 and tightly fixed by means of welds 8 and 9, as a result of which the filtered water only through the locking slits 4, the drainage channels 3 (Rg. 1), cavity 10, cross grooves 11, collecting channels 12 and 13 can flow to the center of the plate 7 and to the drain pipe 22 (Fig. 3). In Fig. 3, an overpressure container is shown on a smaller scale than Rg. 1 and 2, in side view and partially in section. It has a body 14 and a reinforced cover 15 in the upper part. Furthermore, an inflow pipe 16, a fixed bottom 17 and a drain pipe 22. A mounting auxiliary jacket 18 made of thin sheet metal rests on a support and sealing plate 7 for holding the filter rods 1, 2 together during assembly. The bottom 17 and the plate 7 are sealed together from above and from the side by means of a seal 19 and from below by means of an O-ring 20. The seals 19, 20 and the bottom 17 are pulled together by means of screws 21. For easier heat regulation, the overpressure container is equipped with thermal insulation 23. The entire container rests on three solid posts 24. The entire filtration is carried out in such a way that the sea water to the Rltrier pressure container (Rg. 3) from a heat-insulated reservoir 25 with cooler sea water from the night period and from a reservoir of the same type 26 with warmer Sea water from the day period flows in the heat-insulated mixture storage container 27 with the desired, set temperature for the filtration. A prefiltration 28 was carried out and then the pressure was applied by means of a high-pressure pump 29 (without lubrication medium). The overpressure in the pipeline is secured by a safety valve 30 including a manometer 31. The medium is passed through the inflow pipe 16 into the filter pressure vessel. Through a first stage of filtration (at 5 Ä slot size), in which the major part (approx. 80%) of the salts (NaCI etc.) is removed, the water with the remaining content of smaller molecules and elements reaches tank 32. The backwashing for removal of higher salt content from the space between the filter sticks (1, 2) is carried out by reflux of low-salt water 32 (from the second stage of the filtering through smaller slots) through the pipeline 22 and the high-pressure pump 29; through the now further (over 5 Å) slots of the filter rods 1, 2, the backwash water is pressed onto the upper surface of the filter rods and passed through the pipe 16 to the container 33 for the water with a higher salt content for further processing. The drinking water is obtained by filtering through smaller slits of filter sticks 4, leaving important salts and elements (CaC03, Mg, K, F, J) in the drinking water, or, in other desalination systems (by evaporation), these are added as an additive to maintain healthy drinking water. 1. Filter (1,2,3) for desalting sea water by means of reverse osmosis, consisting of a base rod (1), which is provided on its circumference with segment strips (2), characterized in that both the base rod (1) and the segment strips (2) consist of the same seawater-resistant metal, the base rod having a somewhat larger coefficient of thermal expansion than the segment strips (2), that the difference in the coefficient of thermal expansion in the manufacture of the two components (1, 2) is due to differences in the manufacturing process, for example different ones Heat treatment or profile drawing is achieved, and that after assembly of the components (1,2) by calibration drawing the end faces (4) of the segment strips (2) are pressed together and after heating to the temperature of the filter medium, ie of the sea water, form filter slots of appropriate size, in the range of 10 ~ 1 ° m, whereby the filter medium, i.e. Sea water, serves as an energy source for heating. 2. A method for backwashing a filter according to claim 1, characterized in that a medium with a higher temperature than that which is desalted is used for backwashing, so that the slots between the end faces (4) enlarge, which facilitates backwashing. 4 AT 403 997 B Including 2 sheets of drawings 5