NL8300459A - PROCESS FOR THE PROCESSING OF WASTE WATER FROM THE FLUE-GAS DESULFURATION - Google Patents

Description

»Λ. f * -1-ir.o. 51608 <* Method for processing waste water from flue gas desulphurisation .........- ......

Flue gases, in particular from power plants for the generation of electrical energy by burning fossil fuels, contain known sulfur dioxide, which must be removed from these flue gases before these flue gases are released into the atmosphere. In order to remove the sulfur dioxide, the flue gases can be brought into intimate contact with an aqueous solution of a certain pH value, whereby the dissolved sulfite is oxidized with oxygen from the air. The sulphate ions formed herein can then be precipitated as gypsum with aqueous suspensions of finely ground limestone or calcined lime, which is separated from the aqueous phase and fed to a technical application.

A newer method for this is known, for example, from 33E-Offenlegungsschrift 2,944 * 536. According to this method, the flue gas is introduced into a reaction tower with two reaction zones - namely a quench reaction, oxidation zone and an absorption zone - which are flowed through the flue gas one after the other in the order indicated. In countercurrent flow with the flue gas, streams of absorption liquid recycled in the separate reaction towers outside the tower are introduced as finely divided as possible, collected at the foot of each reaction zone and recycled back through the storage vessel. In addition, there is also a connection between the two storage vessels of the two cycles, whereby the overflow from the absorption zone into the liquid cycle of the quenching zone is introduced. An aqueous suspension of very finely ground limestone or of calcium oxide or calcium oxide is used as the absorption liquid according to this method on the absorption cycle.

hydroxide supplied. The slurry of 30 gypsum (CaSO 2 · 2 2 2 O 3) in water resulting from this in the known method, in particular in the quenching zone, is removed from the quenching cycle and the gypsum is separated from the liquid phase.

The aqueous phase separated from the gypsum forms the waste water from the flue gas desulphurisation, which for its release into natural water consists of the finely divided solids contained therein, which consists essentially of very fine gypsum crystals and the impurities brought along with the aforementioned calcium compounds, should be liberated as much as possible.

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According to a Marquardt publication in Energie3 Energie- und Yerfahrenstechnik GmbH, pages 34 to 35? this wastewater is first neutralized with a sodium hydroxide solution.

The wastewater thus pretreated is then transferred to a flocculation vessel in which iron (III) chloride and flocculation aids are supplied to the wastewater. Hit the iron (III) chloride to form iron (III) hydroxide, which precipitates as sparingly soluble, voluminous precipitate, which encloses the finely divided solids present in the wastewater. In addition, all sodium-precipitable components can be precipitated from the waste water by the sodium hydroxide. The flocculating agent effects a faster sedimentation of deposits thus obtained.

The waste water is then fed to a thickener, in which the sludge is deposited at the bottom and is removed there. The waste water freed from the sludge is led from the overflow of the thickener into a waste water pipe, which leads to a drainage channel.

According to the known method, the separated suspension is dewatered in chamber filter presses into a stab-proof cake, which must then be brought as the last deposit at separate landfills. The aqueous cloudy mass draining from the chamber filter presses is fed back to the neutralization step of this process.

From this the problem emerges to possibilities.

25 to clean up the slurry desulphurisation obtained from the flue gas desulphurisation remaining after the waste water has been separated from the gypsum, without this slurry having to be deposited for final storage.

A process for processing waste water from the flue gas desulfurization by means of an aqueous suspension of very finely ground alkaline calcium compounds, by neutralization with alkali metal resp. alkaline earth metal hydroxide and with addition of iron (III) chloride and a flocculant and separating the resulting sludge in a thickener. According to this process, the thickened sludge is recycled into the aqueous phase of the oxidation stage of the flue gas desulfurization device.

The thickened sludge can advantageously be suspended for this purpose in the aqueous suspension of the finely-divided calcium compounds before this suspension is introduced into the oxidation stage of the flue gas desulfurization unit.

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However, it may also be expedient to subject the thickened sludge to a dewatering step for the return to the aqueous phase of the ozyation stage of the flue gas development.

As already mentioned, the waste water separated from the gypsum of flue gas desulphurisation contains 0.1 to 2% by weight of finely divided solids, which consist largely of very small gypsum crystals and very small particles of the calcium compounds used.

This waste water is obtained with a pH value of 4 to 8 and in dissolved form contains the impurities introduced with the calcium compounds used. If finely ground limestone or calcined ualcium ozide is used as the calcium compound for flue gas desulfurization, the waste water from the gypsum separation partly contains the impurities of the limestone, such as, for example, the silicate-like impurities of iron, aluminum and magnesium and, for example, the impurities of copper and zinc.

The further processing of such waste water according to the method of the invention is neutralized with a sodium hydroxide solution, this advantageously to a pH value between 7 and 9. At the same time, iron-20 (ill) chloride in this waste water is amount of about 0.02 to 0.05 wt% based on the amount of wastewater - in the form of an aqueous solution and a known flocculant, such as, for example, a polyelectrolyte in an amount of 0.0001 to 0.0005 wt. é stirred.

As a result of these measures, a voluminous iron (III) hydroxide precipitate is formed in the waste water, which encloses the solids and contains the aforementioned precipitation products. The pre-egg mixture is then placed in a clarifier, in which the precipitate as a suspension with a solids content of 50 sediments of about 1 to 20% by weight and is deposited on the bottom of the clarifier. In the above aqueous phase, which is discharged and supplied to a drainage channel, respectively. is sunk in layers of the substrate suitable for water absorption, approximately 1 to 5% by weight of the amount of solids originally present remain.

According to the invention, the sludge withdrawn from the bottom of the clarifier is returned without further treatment to the flue gas desulfurization stage, in which the gypsum is formed, i.e. mainly in the oxidation stage of the flue gas desulfurization stage. Advantageously, the sludge is stirred for this purpose in the absorption liquid, 8300459-4- before it is introduced into the oxidation stage of the flue gas desulfurization. It may be expedient to dehydrate the suspension prior to the return line.

Studies have shown that the solid particles of this sludge are incorporated into the gypsum crystals that form during this stage of the flue gas desulfurization, without changing their external shape and grain distribution. Nor do these solid particles of the introduced sludge cause any disadvantages in the discharge of the gypsum from the flue gas desulfurization via the usual dewatering and drying devices according to the usual methods. Also the further processing of this plaster into technically valuable products according to the known methods is in no way disturbed or adversely affected. These surprising findings and results apparently are based on the fact that the solids and impurities introduced into the gypsum with the recycled sludge are also in natural gypsum, for the further processing of which these known processes have been developed into technically valuable products.

Incidentally, the loading of the gypsum of the flue gas desulphurisation with foreign substances is very small, because the amount of sludge that has been recycled, based on the amount of the gypsum formed, is small and the sludge that is recycled already mainly consists of very fine gypsum crystals, which act as seed crystals in flue gas desulfurization.

The invention therefore solves the problem of the disposal of the sludge, which is obtained from the waste water remaining after the gypsum separation of a flue gas desulfurization carried out with calcium compounds, by working up in a very simple manner without dewatering and subsequent deposition is necessary.

Yoorbeeld I (invention)

In a ready vessel with stirrer, 55 tons of waste water, which is obtained as a filtrate of the gypsum separation from a flue gas sulfur sulfur at a temperature of 45 ° G and a pH value of 6, are obtained, and 20 kg of solids as suspended solids as well as each Contains 0.05 kg of dissolved copper and zinc, 2 kg of iron (III) chloride dissolved in water and 0.01 kg of flocculation aid are stirred. A sodium hydroxide solution is then stirred in this mixture until the pH value of the mixture has risen to 9. In this process, a 40-voluminous precipitate precipitates, which quickly stirs up to 8300459 when the mixture is stirred

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-5- The bottom of the ready vessel is deposited and discharged from there. 440 kg of sludge with a solids content of 22 kg are obtained, bit of sludge is returned to the oxidation stage of the flue gas development by means of conveying pumps, the aqueous phase above contains only 0.5 hg of solids and 0, 01 kg of dissolved copper and 0.01 kg of dissolved zinc. This aqueous phase is then led into a waste water channel.

The recycled sludge, containing 72.5 wt.% Calcium sulfate dihydrate, 18.1 yr.% Silicates, carbonates and hydroxides, 3.0 wt.% Iron (11¾ 10 hydroxide and 0.4 wt.% Precipitated copper and zinc) is enclosed in the flue gas plaster and thus removed from the process.

Example II (comparison)

The waste water is treated according to example I and the sedimented sludge is dewatered in a chamber filter press before it is finally deposited at a waste landfill.

The characteristic data of the waste water, the suspension and the flue gas gypsum are summarized in the following table: 8300459 -6-Table column 1 column 2 waste water waste water "treatment" treatment with return of the sludge pipe back the sludge. ..

(invention) (comparison.) wastewater v <$ <Sr pre-precipitation amount kg / h 10,000 10,000 temperature C 45 45 pï-value 6 6 solid kg / h 20 20 dissolved copper kg / h 0.05 0.05 dissolved zinc kg / h 0.05 0.05 iron (III) chloride kg / h 2 2.

addition of waste water after preoipentation amount kg / h 9 * 560 10,000 solid kg / h 0.50 0.50 dissolved copper kg / h 0.01 0.01 dissolved zinc kg / h 0.01 0.01 pE value 9 9 sludge precipitated kg / h 440 440 solid kg / h 22.08 22.08 sludge returned kg / h 440 - - solid kg / h 21.58 - sludge composition calcium sulphate dihydrate% 72.5 silicates, carbonates wt.% 18.1 - hydroxides iron (11l) hydroxide wt.% 9> 0 - precipitated copper and zinc wt.% 0.4 gypsum composition moisture ·% 10% calcium sulfate dihydrate wt% in no in silicates, carbonates, wt% 10.02, hydroxides of iron (III) hydroxide, wt.% 0.02, copper and zinc, wt.%, traces, amount kg / h 10,000 10,000 8300459 * * -; - -7-.

Figures 1 and 2 show the results of the microanalysis with the scanning electron microscope of a flue gas gypsum obtained by means of the invention, figure 1 clearly showing the incorporation of silicates and i 2 z (III) hydroxide, while figure 1 2 recognizes the incorporation of zinc in this flue gas plaster.

Figure 3 shows the results of such a micro analysis of a flue gas gypsum, which was obtained without recycling the sludge according to example 2.

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Claims (3)

4 -s- * 1. Process for processing waste water from flue gas desulphurisation by means of aqueous suspensions of very finely ground, alkaline acting calcium compounds, by neutralization with alkali metal resp. alkaline earth metal hydroxides and with the addition of iron (III) chloride and a flocculation aid and separating the sludge formed in a thickener, with the kerum being returned to the thickened sludge in the aqueous phase of the oxidation stage of the flue gas desulfurization device. 2. Process according to claim 1, characterized in that the thickened sludge is suspended in the aqueous suspension of the finely divided calcium compounds before this sludge is introduced into the oxidation stage of the flue gas desulfurization device. 3. Process according to claims 1 and 2, characterized in that the thickened sludge subjects the dewatering step of the oxidation stage of the oxidation stage of the flue gas desulphurisation device to a dewatering stage. * 8300459