SU778181A1 - Method for purifying effluents from heavy metal ions - Google Patents

Abstract

1, A METHOD FOR CLEANING WASTE WATER FROM HEAVY METAL ions, including the precipitation of metals in the form of hydroxides at pH 8.7 5 - 9.25, followed by separation of the sediment and neutralization of the effluent to pH 8.5, about 100% of the sediment that, in order to reduce the residual concentrations of metals, wastewater is additionally treated with iron hydroxide. 2, the method according to claim 1, about tl and h and rout and and the fact that iron hydroxide is administered in an amount of 50-250 mg / l.

Description

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The invention relates to methods for cleaning waste water from heavy metal ions and can be used in the treatment of galvanic effluents and non-ferrous metallurgy enterprises.

; Lime. A method of cleaning waste water from heavy metal ions by precipitating heavy metals in the form of hydroxides at pH 7-8.5 f).

The disadvantage of this method is the low quality of purification, since a significant part of heavy metal ions cannot be converted to hydroxides in the pH range; 7-8.5. units.

Also known cleaning method. wastewater from heavy metal ions by precipitating metals as hydroxides at a pH of 8.75 to 9.25, separating the hydroxides from water, and neutralizing the flow to a pH of 8.5.

With the simultaneous presence in water of ions of nickel, zinc, chromium and copper, which are most often encountered in practice, the pH range of 8.75-9.25 is optimal for water treatment, since in this range a more complete transfer of all of these ions to hydroxide formula. .

However, in this method, as a rule, high quality cleaning is not achieved.

The aim of the invention is to reduce the residual concentrations of heavy metal ions. The goal is achieved by the fact that when precipitating metals in the form of hydroxides, the effluent is additionally treated with iron hydroxide. Preferably, iron hydraoxide to enter in the amount of 50-250 mg / l (in terms of iron).

According to the proposed method, the effluent is treated, which contain non zinc, copper, nickel, hexavalent and trivalent chromium. The main difficulty in the neutralization of heavy metal ions by converting metals into insoluble hydroxide forms is that ions of various heavy metals can be most fully converted to hydroxide form at different pH values. For this reason, such a pH range cannot be selected, at which simultaneously the complete conversion of all heavy metal ions to the form of insoluble hydroxides is ensured. The most appropriate pH range at which more complete precipitation of all metals is achieved is pH 8.75-9.25 units. When it is below 8.75, the healer remains in the drains. However, in the pH range of 8.5–9.25 units in the effluent, heavy metal ions still remain in amounts that in most cases exceed the maximum permissible concentrations in the effluent.

Ferrous oxide of iron, additionally introduced into the stock during neutralization, expands the range of pH values at which the deepest and most complete precipitation of each of the individual types of heavy tracts is achieved. Due to this, practically complete precipitation is achieved in the pH range of 8.759, 25 units. At the same time, all heavy metal ions: nickel, zinc, copper, and chromium are precipitated. In addition, in the presence of hexavalent chromium ions in water, iron hydrous oxide ensures the conversion of these ions into a trivalent form.

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Thanks to this, when using the proposed method, hexavalent chromium containing effluents can be treated together with effluents containing ions of other t 5 yellow metals, and the need to pre-reduce chromium to the trivalent form is eliminated. Research has also shown that hydraoxide} crome improves the sedimentary properties of metal hydroxides, which makes it easier to separate the metal hydroxides by settling. After the metal hydroxide is separated from the treated water, the effluent 5 is neutralized to a pH of 8.5. .

The amount of iron hydroxide, which is introduced into the stock, is chosen taking into account the concentration of contaminants in the effluent, in particular, the concentration of hexavalent chromium. amount

0 Iron hydroxide is chosen in the range of 50-250 mg / l (in terms of iron), the lower limit is chosen at low concentrations of contaminants. AT

In this case, at least 50 mg / l of iron hydroxide is added to water to improve settling and. achievements

deep cleaning. For large con-.

wastewater concentration centers

0 up to 250 mg / l of iron hydroxide is introduced into the treated water.

PRI me R. The process according to the proposed method is subjected to electroplating wastewater with three, j and various contamination compositions.

 For comparison, the same effluent is also processed by a known method. .

In all three cases, purification was carried out in a 6.2 m reactor.

0 When processing by a known method

part of the galvanic workshop effluent containing hexavalent chromium ions,.

The chromium-containing part of the runoff of the galvotseh is mixed with the remaining drains of the workshop. In the reactor for processing comes mixed stock.

When processing by the proposed method, a separate processing of the chromoscale drain is not required and the reactor enters the drain containing chromium in hexavalent form.

In all three cases, the treatment in the reactor was carried out for 0.5 hours. The pH was adjusted with sodium hydroxide. ; In the first case, the initial pH of a hundred: galvanic shop was 6.2; in the second - 5.20 in the third -4.2. i Processing according to the proposed and known methods is carried out at

same pH. The pH at which the precipitation of heavy metal hydroxides occurs is, in the first case, 9.2; in the second - 9 and in the third - 8.75.

When processing by the proposed method, in the first case, iron hydroxide in the amount of 50 mg / l is introduced into the reactor, in the second case 100 mg / l, and in the third 250 mg / l.

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In all three cases after the separation of hydroxides by settling, the water is neutralized to a pH of 8.5, 15 The results of the treatment according to the known and according to the proposed methods are presented in the table.

2 3: 1 11.3 12.5 15.3 18 2.3 2.3 2.8 225 34.7 17.3 17.3 20.1 3.5 2.9 362.4 41.8 18.9 28.2 1.2 3.7

As can be seen from the data obtained in the table, during the treatment of 1 according to the proposed method, Ic is fully depleted of water from chromium, zinc, copper and nickel ions. This eliminates the need for purification, which requires the use of expensive methods, such as the ion exchange method. Use -. The proposed method provides in comparison with existing methods 10 11 12 13

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bami the following main advantages. The quality of wastewater purification from heavy metal ions is improved, and the need for special treatment of chromium containing compounds to convert hexavalent chromium ions into the trivalent form is eliminated. In addition, the absence of the need to clean up simplifies the instrumentation process and reduces the cost of cleaning. 4.3 O: 0 O 00 6.3 1.1 O O 6 O 9.2 O O O 00

Claims (2)

1, METHOD FOR SEWAGE TREATMENT FROM HEAVY METAL IONS, including the deposition of metals in the form of hydroxides at a pH of 8.7 5 - 9.25, followed by separation of the precipitate and neutralization of the effluent to a pH of 8.5; I mean that, in order to reduce residual concentrations of metals, wastewater is additionally treated with iron hydroxide. 2. The method according to p. m m 00