DE3001910C2 - Method and device for separating dust from the waste gases of the aluminum smelting electrolysis - Google Patents

Description

The invention relates to a method and a device for separating dust from the Waste gases from the aluminum smelting electrolysis.

Modern plants for the extraction of aluminum have completely air pollution control reasons encapsulated electrolysis cells to capture the process exhaust gas as completely as possible. The cleaning of the Exhaust gases then mostly take place in wet scrubbers or, more recently, with dry cleaning systems through adsorption of aluminum oxide.

However, together with the fluorides and the alumina, there are also carbon and the compounds of phosphorus, vanadium, titanium, iron, silicon and sulfur separated from the exhaust gas, which in the ίο complete return to the electrolysis bath.

In this way, these impurities accumulate and lead to a reduction in the current yield and a deterioration in the quality of the metal.
It is therefore advisable to separate all of the raw gas dust before treatment in wet scrubbers or dry cleaning systems.

The fluorine content contained in this dust makes it cost-intensive to dispose of on a hazardous waste dump necessary. In addition, valuable raw materials such as cryolite and clay are lost as a result.

One way of recovering at least the fluorine content from this waste is in the DE-OS 24 03 282.4.

The object of the present invention is the separation of dust from the flue gases of the aluminum smelting electrolysis in such a way that the fluoride and the debris is largely returned and the impurities together with the carbon can be separated to a residual content of about 5%.

As a solution, it is proposed that a slurry of the dust is subjected to flotation, the buoyant foam with the impurities carbon, phosphorus, vanadium, titanium, iron, silicon and sulfur compounds being separated off and cryolite, chiolite and aluminum oxide as sediment is obtained which, after drying, is used again in the aluminum smelting flow electrolysis.
The mixture of chiolite, cryolite and aluminum oxide obtained in this way contains so few disruptive impurities that it can be used again in the melt flow electrolysis process after dewatering and drying. The much smaller proportion of foam in terms of quantity, in which the impurities are contained, can either be incinerated or disposed of.

In a special application of the invention Procedure is provided that the cleaning ■ ο the exhaust gases in a two-stage wet washing process at a flow rate of 2 to 10 liters of wash water per cubic meter of exhaust gas and a solids content of 5 to 35 g of solids per liter takes place and the washing water is fed through nozzles in countercurrent to the exhaust gas Packing bed made of plastic moldings is sprayed.

This method has the advantage that the dust can be separated without any special additives can.

The invention is explained in more detail below with the aid of two exemplary embodiments. It shows

1 shows a method for separating raw gas dust from aluminum electrolysis by wet washing,

Fig. 2 shows a method for separating the raw gas ¹ ) dust by flotation with a collector-foamer combination.

In the one- or two-stage wet scrubber 1 according to FIG. I is extracted from the electrolysis by means of fan 2

cells sucked off electrolysis waste gas washed in countercurrent with water. The washing water is with the Pump 3 circulated and finely divided by a nozzle system 4.

The separation of the acidic exhaust gas component HF and the dusts now takes place within the two dynamic packing beds 5 and f> through the most intimate contact with the washing water. Hollow spheres made of polypropylene with a diameter of less than 50 mm serve as fillers, which swirl in the ascending gas flow, are wetted by the wash water trickling down in countercurrent and thus form a large phase interface for the exchange of substances, which is constantly torn and renewed by the collision of the spheres. As a result, a very good absorption capacity is achieved and so much air is entrained in the running wash water 7 that a buoyant foam 8 is formed on the surface of the reservoir, which consists of carbon and the aforementioned impurities. If this foam by means of Stranlsaugern 9, such. B. injectors, sucked off and removed from the system, only aluminum oxide, cryolite and chiolite remain in the circulating wash water, provided that the flotation and filling conditions are ideally maintained by adding NaOH and AI (OH) 310 in a suitable amount.

These boundary conditions can be described as follows:

pH value: between 0.5 and 6, before

assigned between 1 and 3;
Fluoride concentration: 0.5 to 20 g F / l;
Sulphate concentration: 0.5 to 40 g SO4 / I;
Solids content: 5 to 35 g solids / l;

Amount of washing water: 2 to 10 l / m ^J exhaust gas.

So that the concentrations remain in equilibrium, the deposited amounts must correspond Fluoride and solids are discharged via the program-controlled valve 11. The further treatment this branched off partial flow consists of thickening 12, filtering 13 and drying 14, the resulting Product contains chiolite, cryolite and clay and can be returned to the electrolysis furnace will.

From the thickener 12, the solids-free clear runoff can through line 18 in the first stage of the wet scrubber be returned. A partial flow from the vacuum drum filter 13 is passed through line 19 into the thickener 12 returned and another partial flow through line 20 as fluorine-free exhaust air with the vacuum pump removed. From the dryer 14, which is shown here as a rotary kiln, can be used as exhaust gas via line 32 to Washer can be derived. The clay is via line 33 possibly via a silo of the electiolysis in Circulation fed.

After neutralization 15 and thickening 16, the extracted foam can also be filtered 17 and then incinerated or landfilled.

The solid-free clear runoff is produced from the thickener 16 entered via line 33 into the first stage of the wet scrubber. The vacuum drum filter 17 becomes a Partial flow returned to the thickener via line 34 and a further partial flow via line 35 removed from the vacuum pump as fluorine-free exhaust air. Line 36 leads to the landfill.

The method according to FIG. 2 can be described as follows:

The raw gas from the electrolytic furnace 21 is in dedusted in an electrostatic precipitator or in a fabric filter and then in a dry gas cleaning system 23 adsorbed the hydrogen fluoride gas on AhOj.

The raw gas dust from the dust pre-separation 22 is slurried with the flotation medium 24 in a mixer 37 and this pulp with a solids content of 50 to 200 g / l is fed into the flotation system 25. The propellers 26a to 26e ensure a very fine-bubble entry of the sucked in or forced air. With these air bubbles and by adding the Sarnmle · foamer combination 27, the impurities are floated out together with the carbon on the surface.

The liquor 29 is withdrawn via the discharge chute 28, while the cleaned liquor is via the outlet 30 Sediment is discharged.

The valuable ingredients in the sediment such as chiolite, cryolite and aluminum oxide (clay) can after the dewatering and drying 31 are returned directly to the electrolysis furnace.

The flotation medium is characterized by the following composition:

Fluoride content:

Sulphate content:

PH value:

0.5 to 20 g / l 0.5 to 40 g / l 0.5 to 6, preferred

to X

The collector-foamer combination - also known as a flotation aid - consists of one Mixture of butanol and decanol with additions of 2-ethylhexanol and Hcptanol isomerism. This resource is added in an amount of 0.1 to 5 g / l of the pulp in order to separate it into sediment and liquor to accelerate.

Normal water can be used as fresh water in both processes to supplement the evaporation losses Domestic water can be used. If the domestic water is very dirty, it is advantageous to use the To improve flotation according to claim 4 by adding a collector-frother combination. this expediently takes place in a downstream cell.

For this purpose 2 sheets of drawings

Claims (10)

Patent claims: ! Process for the separation of dust from the waste gases of the aluminum smelting electrolysis, characterized in that a slurry the dust is subjected to a flotation, the buoyant foam with the impurities carbon, phosphorus, vanadium, titanium, iron, silicon and sulfur compounds is separated and is obtained as a sediment cryolite, chiolite and aluminum oxide, which after the Drying is used again in the aluminum smelting electrolysis. 2. The method according to claim 1, characterized in that the flotation pulp has a pH between 0.5 and 6, a fluoride concentration between 0.5 and 20 g / l and a sulfate concentration between 0.5 and 40 g / l. 3. The method according to any one of the preceding claims, characterized in that the pH is between 1 and 3. 4. The method according to any one of the preceding claims, characterized in that for To accelerate the separation, a collector-foamer combination is used, consisting of branched alcohols from butanol to decanol with additions of ethylhexanol and heptanol isomers in an amount between 0.01 to 10 g / l of pulp. 5. The method according to claim 4, characterized in that the solids content of the pulp is between 50 and 200 g / l. 6. The method according to any one of the preceding claims, characterized in that for precipitation the double salts cryolite and chiolite from the washing water caustic soda or soda solution as well Aluminum hydroxide is added. 7. The method according to any one of claims 1 to 4, characterized in that the cleaning of the Exhaust gases in a two-stage wet washing process at a flow rate of 2 to 10 liters of washing water per cubic meter of exhaust gas and a solids content of 5 to 35 g of solids per liter and that Wash water through nozzles in countercurrent to the exhaust gas on a packed bed made of plastic molded parts is sprayed. 8. The method according to claim 7, characterized in that the floating in the reservoir Foam is sucked off with gas jet pumps and then incinerated or landfilled. 9. Device for performing the method according to one of claims 1 to 5, characterized characterized in that the flotation troughs are made of plastic, wood or rubberized steel. 10. Apparatus for performing the method according to claim 8, characterized in that a dynamic packing bed with hollow plastic balls is used.