FI89901C - purification method - Google Patents

Description

! 89901

The present invention relates to a process for the purification of process waste solutions resulting from the production of titanium dioxide based on sulphate process 5. The invention also relates to a process for the preparation of titanium dioxide using this purification process.

10 In the production of titanium dioxide by the sulphate process, a titanium-containing mineral used as a raw material, such as ilmenite or titanium slag, and sulfuric acid react to form a solid reaction cake. The reaction cake is dissolved in water and dilute acids circulating in the process. The solid in solution is separated and some of the iron is separated by crystallization as ferrous sulfate. The purified solution is concentrated, after which the titanium in it is precipitated as titanium hydroxide by hydrolytic heating of the solution. The precipitated slurry is filtered and the filter cake 20 is washed thoroughly to remove impurities therein. The purified titanium hydroxide mass is calcined at about 1000 ° C to titanium dioxide. The calcined product is ground to form an uncoated titanium dioxide pigment. This pigment can be coated with a precipitate of 25 bar on the surface of pigment crystals with various metal hydroxides and oxides. The coated slurry is filtered and the water-soluble salts formed during coating are washed out of the filter cake using deionized water. The washed pigment mass is dried and ground to form a coated titanium dioxide pigment.

In the precipitation of titanium hydroxide, the sulfuric acid bound to titanium is released into the mother liquor. The acidic filtrate is called waste acid and contains sulfuric acid 18-22% by weight, iron 4-5 35% by weight and other metals such as Ti, Mg, Al, Mn, Cr and V. Some waste acid remains in the filtrate. -tinkakkuun. In the so-called pre-wash step, the cake is washed with the filtrate and / or wash water 2 89901 obtained in the post-wash step or with chemically purified water. At the beginning of the pre-washing stage, the waste acid in the filter cake is displaced by the wash water, whereby the sulfuric acid content of the leaving wash water is initially almost as high as the sulfuric acid content of the waste acid, 5 so this fraction is also called waste acid. The waste acid, which typically contains about 20% by weight of sulfuric acid, can be fed to a multi-stage waste acid concentration unit where it is concentrated to about 70-80% by weight of sulfuric acid, which is recycled back to the initial stage of the process.

Gradually, as the washing progresses, the sulfuric acid content of the wash water leaving decreases, while the amount of wash water passing through the cake increases sharply as its viscosity decreases. The pre-washed cake is slurried in the post-wash filtrate 15 and / or wash water, the trivalent oxidized iron therein is reduced and the slurry is passed to a post-wash step where it is filtered and washed using chemically purified water. Some of the water leaving the post-wash can be utilized as described above in the pre-wash-20 step. Sulfuric acid from the prewash, washing water containing ferrous and other metal sulphates, in addition to waste acid, can be used to dissolve the reaction cake. However, in both the pre- and post-washing steps, such a large amount of dilute sulfuric acid and metal sulfate removal water is generated that not all of it can be utilized in the process as described above.

Waste acid and wash water pose a characteristic environmental problem for the production of titanium dioxide, for which various methods have been proposed.

A method is known in which the waste solution streams resulting from the production of titanium dioxide are neutralized using limestone and calcium hydroxide. A disadvantage of this method is that it requires considerable amounts of neutralizing agent. As a result, a large amount of solid waste is generated and the purified waste solution is not suitable for reuse in the titanium dioxide process because it is saturated with calcium-1.

3,39901 for sulfate (Trees W.E. et al. Journal Water Pollution Control, 1979, Vol. 51, No. 1, pp. 158-162).

EP-A-0 368 203 also discloses a process in which sulfuric acid is recovered from waste solutions from a titanium dioxide plant using an electrodialysis process. The disadvantage of this method is that the acid is only partially recovered.

A process is also known in which the waste solution resulting from the production of titanium dioxide is concentrated using vacuum evaporation. This method is suitable for the concentration of waste acid, but its use in the treatment of wash water results in unreasonably high investment and operating costs (Tillmanns, U., Umwelt, 15 10/88, pp. 510-511).

A steam compression method is also known in which the energy consumption of evaporation can be substantially reduced by utilizing the heat of condensation contained in the volatile steam.

20 This method is used to prepare pure water from seawater (Chem. Eng. Handbook, 5th edition, paragraph 11, p.

32). In order to achieve substantial energy savings with this method, the rise in the boiling point of the concentrated solution should be as low as possible, not more than about 10 ° C.

25

It is an object of the present invention to provide a process for purifying waste solutions from titanium dioxide production in a cost-effective manner, in particular from dilute sulfuric acid washing waters in titanium hydroxide washing, without the disadvantages described above and so that the purified water can either be reused in titanium dioxide production or water and that the acid separated in the purification can be returned to the process economically.

It is a further object of the invention to provide a process for the production of titanium dioxide in which the waste solutions from the washing of titanium hydroxide 4,89901 can be purified so that the purified water can be reused in the production of titanium dioxide and the acid separated in the purification can be economically returned to the process.

5

The main features of the invention appear from the appended claims.

In a particularly preferred embodiment of the invention, the sulfuric acid-containing waste solutions or portions thereof resulting from the titanium hydroxide wash are evaporated using a steam compression method to obtain very pure condensate which is returned to the process for reuse mainly as wash water and further concentrated. for use in the process as sulfuric acid required in the process.

When determining the dependence of the boiling point of the 20 waste solutions generated in the production of titanium dioxide on the sulfuric acid content of the solution, it was found that the boiling point at normal pressure was as follows: Boiling point 25 of the waste solution

3.2% at 100 ° C

10.1% 101 ° C

12.5% 102 ° C

14.7% 103 ° C

17.1% 104 ° C

19.8% 106 ° C

21.0% 107 ° C

The results show that the increase in the boiling point remains so low that the use of a steam compression method is preferred up to an acid concentration level of up to 21% by weight.

5,89901

In the process according to the invention, the wash water obtained from titanium hydroxide washes typically contains 1-200 g / l of sulfuric acid, 0.01-4 g / l of iron and in addition other metal sulphates, and this wash water is evaporated to a concentration of 5-21% by weight, preferably 15-20 % by weight utilizing the steam compression method. The sulfuric acid content of the concentrated waste solution thus obtained corresponds to the sulfuric acid content of the waste acid and thus can be passed together with the waste acid to a waste acid concentration unit for further concentration.

According to the invention, the evaporation can be carried out in one step or in several steps, preferably in series.

The principle of the steam compression method is based on the fact that the pressure of the volatile vapor 15 is raised by a fan or otherwise higher than the pressure prevailing on the evaporation side. The evaporated steam, the pressure of which has been increased as described above, is passed as heating steam to the heating side of the evaporator heat exchanger, where it condenses an amount of heat corresponding to the condensing heat. This released heat is transferred through the heat surface of the heat exchanger to the evaporation side. The pressure on the boiling side of the evaporator can be between 0.05 and 1.00 bar. The need to increase the vapor pressure depends on the evaporation pressure, the rise in the boiling point and the temperature difference in the heat exchanger and is an optimization task.

The invention will now be described in more detail with reference to the accompanying drawings, in which Figure 1 schematically shows an apparatus suitable for carrying out the method according to the present invention, and Figure 2 schematically shows an apparatus suitable for carrying out the method according to the present invention.

Figure 35 is the evaporator 1 by the reference numeral 1. The evaporator - - 1 comprises an evaporation side and lauhtumispuolen, which are separated by a heat transfer surface. The waste solution 11 from the titanium dioxide process is passed through preheaters 3 and 4 to the evaporator side of the evaporator 1. If necessary, the waste solution 11 can be filtered as a filter 10 to separate solids. The pressure of the evaporated steam is raised by the fan 2 and is led to the condensing side of the evaporator 1 5, where it condenses. The condensed steam 13 is very clean and is removed by means of a pump 6 from the condensing section through the preheater 3, where it dissipates heat. The concentrated solution 14 is similarly discharged by means of a pump 7 through a preheater 4. The solution 10 12 to be concentrated is circulated to the heat transfer surface of the evaporator 1 by means of a pump 8. If necessary, the recyclable solution 12 can be filtered as a filter 5 to prevent contamination of the heating surface. The vacuum is maintained in the system by means of a vacuum pump 9.

15

The water evaporated from the waste solution as condensate 13 in the evaporator is very pure and can be used in many different applications. Such applications include e.g. its use in the treatment washing stage to replace ion-20 exchanged water or its use as further purified boiler water in a power plant, if necessary. Water can, of course, be used to replace chemically purified water in various applications or it can be safely discharged into water bodies.

25

The acid solution 14 concentrated in the evaporator can be fed together with the waste acid to a waste acid concentrator for further concentration.

Figure 2 shows a preferred embodiment of the invention, in which the evaporation is carried out in several, in this case three, series-connected evaporator units 15, 16 and 17. Each evaporator unit is similar in operation to the steam compression device 35 shown in Figure 1. The waste solution 11 from the titanium dioxide process is passed through preheaters 3 and 4 to the first evaporation unit 15. The concentrate 14a leaving the first evaporation unit 15 is led to the second evaporation unit 7 39901 to 16, from where the leaving concentrate 14b is passed to The condensed steam 13a, 13b and 13c from each evaporation unit is combined and removed via the preheater 3 as condensate 13. This

10

The invention is described in more detail below by way of example. Example

The titanium dioxide plant, which produces titanium dioxide-15 dipigment using the sulphate process for 230 t per day, generates, in addition to waste acid, a waste water stream with the following volume and composition: volume 5000 t / d 20 density 1 kg / dm3 H2SO4 1.5% by weight

Fe 0.1 wt% solids 0.02 wt% other metals 50 50 t / d of this wastewater was fed to the three-stage steam compression apparatus described above (Figure 2). The result was a purified condensate of 45 t / d and a concentrated sulfuric acid solution of 5 t / d with a sulfuric acid content of 15 to 30% by weight. The condensate was passed to the factory treatment wash wash water and the concentrated acid solution was passed to a waste acid concentrator where it was further concentrated to 70% and returned to the mill.

Claims (11)

A process for the purification of process waste solutions resulting from the production of titanium dioxide based on the sulphate process, characterized in that the sulfuric acid-containing waste solutions or part thereof generated in the titanium hydroxide washing are evaporated using a steam compression process to form a pure condensate and sulfuric acid solution. Process according to Claim 1, characterized in that the condensate obtained is returned to the process for reuse as washing water. Process according to Claim 1 or 2, characterized in that the resulting sulfuric acid-concentrated waste solution is further concentrated in a waste acid concentration unit and returned to the process for use as sulfuric acid required in the process. Process according to one of the preceding claims, characterized in that the sulfuric acid content of the waste solutions to be purified is from 1 to 200 g / l. Process according to one of the preceding claims, characterized in that the sulfuric acid content of the waste solution obtained by evaporation is 2 to 21% by weight, preferably 15 to 20% by weight. Method according to one of the preceding claims, characterized in that the evaporation is carried out in several steps, preferably in series. 7. A process for producing titanium dioxide by the sulphate process, in which a titanium-containing mineral or concentrate 35 is treated with sulfuric acid, the product obtained is dissolved in water, a solid is separated, some iron is separated by crystallization as ferrous sulphate, and titanium in solution is precipitated as titanium hydroxide. , to give waste acid as a filtrate, the titanium hydroxide mass is washed several times with washing water to remove impurities and then the washed titanium hydroxide mass is calcined to titanium dioxide, characterized in that the sulfuric acid-containing waste solutions or , and a sulfuric acid-10 delta concentrated waste solution. Process according to Claim 7, characterized in that the resulting sulfuric acid-concentrated waste solution is concentrated together with the waste acid in the waste acid concentration unit 15 and returned to the process for use as the sulfuric acid required in the process. Process according to Claim 7 or 8, characterized in that the sulfuric acid content of the waste solutions to be purified is 1 to 200 g / l. Process according to one of Claims 7 to 9, characterized in that the sulfuric acid content of the waste solution obtained by evaporation is from 2 to 21% by weight, preferably from 15 to 20% by weight. Process according to one of Claims 7 to 10, characterized in that the evaporation is carried out in several steps, preferably in series. 30 ίο 2 9901