SU1698191A1 - Method of cleaning sewage water from organic matter - Google Patents

Abstract

The invention relates to wastewater treatment technology using reagent methods and can be used for the treatment of domestic and industrial wastewater, in particular, at textile enterprises in dyeing and finishing workshops. In order to increase the degree of purification of wastewater containing dyes and surfactants, reagent is introduced into wastewater at a pH above 10.7, which is a regeneration discharge of sodium-cation-exchange filters with the following content of components, mg / l: MgCl2 360- 1200; CaCfc 1200-4000; FeCIa 0.1-1, while the waste water is mixed with the reagent in a volume ratio of 1. (0.001-1), and the resulting precipitate is separated. The method allows to increase the degree of wastewater treatment by COD compared with the known method from 73 to 94% and the degree of purification in terms of color is 91-99%. 1 з p. F-ly, 4 tabl.

Description

The invention relates to wastewater treatment technology using reagent methods and can be used to clean household or industrial wastewater, in particular, at textile enterprises in dyeing and finishing workshops.

The aim of the invention is to increase the degree of purification of wastewater containing dyes and surfactants.

In order to carry out the proposed process, the flow waters of the dyeing and finishing shop of a textile enterprise introduce reagent containing magnesium chloride (360-1200 mg / l of water), calcium chloride (1200-4000 mg / l of water) and ferric chloride (0.1-1 mg / l of water), and the reagent is administered per unit volume of wastewater 0.001-1 volume

regeneration discharges of sodium-cation-exchange filters and purification are carried out at a pH of 10.7. After some time necessary for settling, the precipitate formed is separated.

The reagent is formed during regeneration with a solution of sodium chloride sodium-cation-exchange filters used to soften water. The values used for the concentration of the components and the amount of reagent are optimal.

Carrying out the purification process at a pH below 10.7 does not give good results, and using a sorbent per unit volume of wastewater in an amount greater than one is impractical because the sorbent consumption increases, which makes it difficult to use the method in industrial production conditions, and salt content of wastewater

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Wastewater treatment from a mixture of various dyes and surfactants by the proposed method is carried out on model solutions in which the concentration of dyes and surfactants exceeds their content in real wastewater, and in real wastewater from the dyeing and finishing factory.

To ensure a pH above 10.7, if necessary, lime is added to the mixture of wastewater and sorbent.

Example 1. A mixture of advanced and direct dyes and a surfactant sulfamol was used to prepare the wash solution. The following values were obtained: pH 8.2; COD 651.9 mg / l; optical density 3.5. 1 liter of the prepared model-4 solution was poured into a glass cylinder with a height of 0.5 m, and simultaneously with continuous stirring, 50 ml of sorbent containing 4000 mg / l of water, MgCl2 (1200 mg / l of water) and FeCIa (1 mg / l water) and having a pH of 7.5. 3 ml of milk of lime was added to the resulting mixture, so that the process took place at a pH of 11.5. The mixture was allowed to settle for 30 minutes and the precipitate was separated. The COD and the optical density of the purified water were then measured. The values obtained were: COD 43.7 mg / l; optical density is 0.049, m, e, the degree of wastewater treatment by COD is 93.3%, and by color is 98.6%, the resistivity of the formed sediment is 12.44-1010 cm / h.

The results of the experiments carried out with the model solution at other pH values of the process, the ratios of the sorbent and the model solution, and the ratios of the components in the sorbent are presented in Table 1.

From Table 1 it can be seen that the best values of the degree of purification both in COD and in color are obtained for the proposed values of the ratios of the components in the sorbent and the ratios of the sorbent and waste water (experiment No. 2, 4-12, 14, 15). In this case, a high degree of purification is provided at pH values of the process above 10.7.

In the experiment Ms 13, purified waste water was obtained with a salt content of 13.6 g / l, which exceeds the allowable rate.

Example 2. 1 liter of waste water taken from the factory dye shop, with a pH of 11.5. COD954.3 mg / l and an optical density of 4.1 were poured into a glass cylinder, while simultaneously with continuous stirring 50 mg of sorbent containing CaCl2 (4000 mg / l of water), MgCl2 (1200 mg / l of water) and FeCl2 (1 mg / l of water) and mixed to pH 7.5. The process took place at pH 11.5. The mixture was allowed to settle for 30 minutes and the precipitate was separated. The COD and the optical density of the purified water were then measured. The values obtained were: COD 57.3 mg / l; optical

density 0.09, i.e. the degree of sewage treatment by COD is 94.0%, and by color is 97.8%.

The results of experiments carried out with waste water at other pH values of the process, the ratios of the sorbent and the waste water, and the ratios of the components in the sorbent are presented in Table 2.

From Table 2 it can be seen that the best values of the degree of purification both in COD and in color are obtained for the proposed ratios of the ratios of the components in the sorbent and the ratios of the sorbent and wastewater (experiment N 2, 4-12, 14,15). The results obtained are similar to the results of experiments with a model solution,

0 High reagent efficiency is associated not only with the known properties of reagents (Mgd2, CaCia,), but also with the result of their combined use.

5B table 3 presents data on the separate use of these reagents and with their joint action,

An additional effect arises, exceeding the sushi effects from the separation of each reagent. The exclusion of one of the reagents (table 4) also leads to a decrease in the cleaning effect.

 The effect of wastewater treatment by the proposed method is higher than in the case of the application of freshly precipitated hmdratirovannyh sediments and hardness salts, which is confirmed by the examples below.

Example 3. 50 mg of a reagent containing CaCl2 (4UOO mg / l), MDSL (1200 mg / l) and

0 (1 mg / l), was introduced a 1 l of waste water, after which the alkaline reagent was introduced to a pH of 11.2. After settling and separation of the precipitate, the purification effect by chromaticity was determined:, b%.

5 Example 4. In 50 ml of a reagent containing (4000 mg / l), MgCl2 (1200 mg / l) and (1 mg / l) were injected with the same amount of alkaline reagent as in Example 3 After formation and separation of its sediment

0 was injected into 1 liter of wastewater. After settling and separating the suspension, the purification effect was determined by chromaticity:, 9%.

The invention allows to increase the degree of sewage treatment by COD to 94% (in

5 of the known method, this value does not exceed 73%), and the degree of purification in color is 91-99%.

In addition, the use of regeneration discharges as a reagent creates significant savings, since cleaning costs eliminate the cost of purchasing reagent consumed, and recycling of previously discharged and environmentally contaminated waste contributes to environmental improvement.

Claims (2)

Claims 1. A method for purifying wastewater from organic matter, including treating in an alkaline medium with a reagent obtained by softening water, and separating the precipitate formed, characterized in that, in order to increase the degree of purification 0 five wastewater containing dyes and surfactants, treatment is carried out at, 7, and as a reagent use regeneration discharge of cation-resin filters with the following content of components, mg / l: CaC 21200-4000 MgCIa360-1200 FeCI20,1-1,0 2. A method according to claim 1, characterized in that the wastewater and regeneration discharges are used in a volume ratio of 1; (0.001-1). Table 1 table 2 Table3 Table 4