RU2156741C1 - Coagulating agent for treatment of water from paint and varnish materials - Google Patents

Abstract

FIELD: physical-chemical treatment of sewages. SUBSTANCE: invention relates to treatment of sewages from coloring plants, in part, to reagents used for extraction of paint and varnish materials diluted in water and organic solvents from water. Activated bentonite, anionic poly-electrolyte (molecular mass is from 5 000 000 to 15 000 000 Da, content of anionic groups is 5%, not less) and sodium carbonate are added additionally to coagulating agent used for treatment of sewages and based on bi- and trivalent metal chlorides or sulfates or their mixtures and cationic polyelectrolyte in the following ratio of components, wt.-%: bi- and trivalent metal chloride or sulfates or their mixtures, 30-55; activated bentonite, 3-65; cationic poly-electrolyte, 1-2; anionic polyelectrolyte, 1-2 and sodium carbonate, the balance. Claimed coagulating agent enhances effectiveness of sewage treatment from paint and varnish materials up to 98-99.4%, broadens spectrum of effect and decreases consumption by 6-7 times. EFFECT: enhanced effectiveness of agent. 3 cl, 3 tbl, 11 ex

Description

 The invention relates to the field of physico-chemical wastewater treatment of paint industries, in particular to reagents for extracting water- and organo-diluting paints and varnishes from materials based on acrylic, melamine, polyurethane, nitrocellulose, epoxy and alkyd film-forming, and can be used in woodworking, engineering, automotive and other industries.

 Known powdery coagulant containing 5-60 wt.% Aluminum sulfate, 10-35 wt.% Sodium carbonate, 10-40 wt.% Sodium hydroxide, 5-25 wt. % sodium silicate, 10-25 wt.% sodium phosphate and 1-5 wt.% aluminum hydroxide, for the extraction of paints based on melamine-alkyd resins from water (Pat. RF N 95109054, class C 02 F 1/52, stated 02.06. 95, publ. 06/20/97).

 A disadvantage of the known coagulant is the low clarification effect of the treated water, due to the presence in the coagulant of up to 75 wt.% Alkaline components (carbonate and sodium hydroxide), creating an alkaline environment in which emulsification of paint and varnish impurities occurs, and the narrow scope of the coagulant (only for the extraction of melamine-alkyd paint and varnish materials).

 Known aqueous coagulant for water purification from paints and varnishes, which includes 15-20 wt. % Zn-phosphate sludge, 20-26 wt.% Nitric acid and 0.3-0.5 wt.% Boric acid, 1-3 wt.% Triethanolamine, 1 wt. % polyacrylamide and the rest is water (Pat. RF N 2006482, class C 02 F 1/58, claimed 25.02.93, publ. 30.01.94).

 A disadvantage of the known coagulant is its high corrosivity and the need for additional neutralization of treated wastewater.

 Known coagulant for purifying water from suspended solids and oil products containing bentonite and a flocculant copolymer of acrylamide and sodium acrylate in the ratio (20-100): 1 (Pat. RF N 2064445, CL 02 F 1/56, claimed 10.05.89 published on July 27, 1996).

 A disadvantage of the known coagulant is the low efficiency of the extraction of paints and varnishes from wastewater.

Closest to the claimed technical essence and the achieved effect is a coagulant for the treatment of industrial and domestic wastewater, containing:
chlorides and sulfates of divalent and trivalent metals - chloride, oxychloride, aluminum hydrochloride and polychloride, ferric chloride or sulfate, chlorides and sulfates of calcium and magnesium, as well as mixtures of these compounds in an amount of 0.05-10 wt.%;
cationic polyelectrolyte - copolymers of acrylamide with dimethylaminoethylmethacrylate, copolymers based on methacrylamide with N, N ¹ -dimethylaminoethylacrylate hydrochloride, homopolymers of dimethylaminoethylmethacrylate, quaternized acrylamide amyloidomide amide 10-100 mg, with a molecular weight ratio of 200 mg. up to 10 million cu in an amount of 0.001-2 wt.%;
buffering additive — sodium carbonate and hydrogen carbonate, or sodium acetate and acetic acid, or potassium hydrophthalate and hydrochloric acid, or triethanolamine and hydrochloric acid or sodium hydrogen phosphate and dihydrogen phosphate, in an amount of 0.05-10 wt.%;
water is the rest.

 The pH of the coagulant is 0.1-2.75 (Pat. RF N 2114068, class C 02 F 1/56, claimed 29.09.97, publ. 27.06.98).

The disadvantages of the known coagulant are:
low efficiency of the coagulant for extracting various types of paints and varnishes from water (70-74%);
high corrosion activity of the coagulant (pH 0.1 - 2.75);
low content of the main substance in the coagulant;
the complexity of the application, transportation and storage at low temperatures due to the high water content in the coagulant (up to 99.9%);
low content of buffering additives in the coagulant, which requires additional surgery to adjust the pH of the treated water.

 The technical result from the use of the inventive coagulant is to increase the efficiency of wastewater treatment from paints of various types, expanding the spectrum of action of the coagulant and reducing the consumption of coagulant.

The technical result is achieved by the fact that activated bentonite, an anionic polyelectrolyte with a molecular weight of 5 to 15 million grams, is additionally introduced into the coagulant for wastewater treatment based on chlorides or sulfates of divalent and trivalent metals or their cationic polyelectrolytes. E. and the content of anionic groups of at least 5%, and sodium carbonate in the following ratio of ingredients, wt.%:
Chlorides or sulfates of 2- and 3-valent metals or mixtures thereof - 30-55
Activated Bentonite - 3-65
Cationic Polyelectrolyte - 1-2
Anionic Polyelectrolyte - 1-2
Sodium Carbonate - Else
As the cationic polyelectrolyte are used copolymers of acrylamide with methyl chloride or benzyl chloride, dimethylaminoethyl methacrylate, copolymer of acrylamide with N-trimetilammoniyetilmetakrilatmetilsulfatom, acrylamide copolymers with dimethylaminoethyl acrylate hydrochloride or acetate dimethylaminoethyl polidimetilaminoetilmetakrilat acetate, polidimetilaminoetilmetakrilat hydrochloride, poly-N-trimetilammoniytilmetakrilatmetilsulfat and poly-N- trimetilammoniyetilmetakrilatbenzolsulfonat.

 As the anionic polyelectrolyte, copolymers of acrylamide or methacrylamide with sodium acrylate and methacrylate, hydrolyzed polyacrylamide, sodium polyacrylate are used.

 Only the combined use of chlorides or sulfates of divalent and trivalent metals or mixtures thereof, cationic and anionic polyelectrolytes, activated bentonite and sodium carbonate in a coagulant for wastewater treatment with the proposed ratio of ingredients provides the technical result: increasing the efficiency of wastewater treatment from paints of various types to 98-99.4%, expansion of the spectrum of action of the coagulant and a decrease in the consumption of the coagulant by 6-7 times.

 Data indicating the advantages of the proposed coagulant compared with the known, are presented in table 1.

 From table 1 it follows that the implementation of the proposed coagulant can increase the efficiency of industrial wastewater treatment from paints and varnishes from 70-74% to 98-99.4%, reduce coagulant consumption by 6-7 times. The content of coatings in purified water decreases from 198-270 mg / l to 5-17 mg / l, and the consumption of coagulant decreases from 2.5-3.5 g / l to 0.35-0.6 g / l.

 The achieved result can be explained as follows.

 The use of activated bentonite in the proposed coagulant, which has increased adsorption and coagulating ability due to changes in the structure and chemical composition of the activation process, increases the efficiency of water purification from paint and varnish impurities.

 The use of activated bentonite in the proposed coagulant together with chlorides or sulfates of divalent and trivalent metals or their mixtures leads to its additional activation, coagulation of contaminants and helps to increase the efficiency of water purification and reduce the consumption of coagulant.

 The use of sodium carbonate in the proposed coagulant contributes to an increase in the rate of hydrolysis of aluminum or iron salts at low temperatures, additional activation of bentonite and the maintenance of an optimal pH, which leads to an increase in the efficiency of water purification and a decrease in the consumption of coagulant.

 The use of the anionic polyelectrolyte in the proposed coagulant leads to the formation of polymer complexes with a cationic polyelectrolyte, which contributes to the formation of large, easily detachable flocs of contaminants and increase the efficiency of water purification.

 Data indicating the optimality of the selected intervals of the ingredients of the proposed coagulant are presented in table. 2.

 From table 2 it follows that when the content of chlorides or sulfates of divalent and trivalent metals or their mixtures in the composition is below 30%, their activating ability with respect to bentonite decreases, the number of hydrolysis products decreases, and the efficiency of purification from paints and varnishes decreases. The content of coatings in purified water increases from 8 to 35-43 mg / l, i.e. 4-5 times (Table 2, lines 3,13,15).

 When the content of chlorides or sulfates of divalent and trivalent metals or their mixtures is more than 55%, their hydrolysis results in a decrease in pH below the optimum and the content of coatings in purified water increases by 3-3.7 times, from 10 to 30-37 mg / l (table .2, lines 4.14).

 When the content of activated bentonite in the coagulant is lower than 3%, the adsorption capacity of the coagulant decreases and the content of coatings in purified water increases by 3.8 times, from 10 to 38 mg / l (table 2, line 6).

 An increase in the content of activated bentonite in the coagulant of more than 65% is economically disadvantageous, since the cleaning efficiency remains practically unchanged (Table 2, line 5), and the volume of the formed precipitate increases.

 A decrease in the content of cationic polyelectrolyte in the coagulant below 1% leads to a decrease in the flocculation activity of the coagulant and an increase in the content of coatings in purified water from 10 to 45 mg / l, i.e. 4.5 times (Table 2, line 7).

 An increase in the content of cationic polyelectrolyte above 2% causes a stabilizing effect with respect to coagulated particles of paints and varnishes, their poor separation from water and reduced cleaning efficiency. The residual content of coatings in purified water increases 5 times, from 8 to 40 mg / l, (table 2, line 8).

 A decrease in the content of anionic polyelectrolyte below 1% leads to a decrease in the number of polymer complexes that bind coagulated contaminant micro flakes and an increase in the content of coatings in purified water from 10 to 56 mg / l, i.e. 5.6 times (Table 2, line 9).

 An increase in the content of anionic flocculant above 2% causes a stabilizing effect with respect to coagulated particles of paints and varnishes and leads to an increase in the content of coatings in purified water from 8 to 50 mg / l, i.e. 6 times (Table 2, line 10).

 A decrease in the content of sodium carbonate below 1% leads to a decrease in pH, a decrease in the degree of hydrolysis of the coagulant, and an increase in the content of coatings in purified water from 8 to 34 mg / l, i.e. 4 times (Table 2, line 11).

 An increase in the content of sodium carbonate above 40% leads to the creation of an alkaline medium, dissolution of the products of hydrolysis of metal salts and an increase in the content of coatings in purified water by 3.9 times, from 10 to 39 mg / l (Table 2, line 12).

The proposed coagulant for cleaning paintwork materials is obtained by mixing the individual ingredients: chlorides or sulfates of divalent and trivalent metals or mixtures thereof, cationic and anionic polyelectrolytes, activated bentonite and sodium carbonate in the ratio of ingredients (wt.%):
Chlorides or sulfates of divalent and trivalent metals or mixtures thereof - 30-55
Activated Bentonite - 3-65
Cationic Polyelectrolyte - 1-2
Anionic Polyelectrolyte - 1-2
Sodium Carbonate - Else
The resulting coagulant is introduced into the treated water in the form of a powder or 5-10%, for example, 8% suspension with vigorous stirring for 7-10 minutes and the resulting flocs of contaminants are separated by settling, flotation or filtering. The efficiency of industrial wastewater treatment from varnish and varnish materials of various types is 98-99.4%.

Example 1
0.45 g of a coagulant containing 0.2475 g (55%) of aluminum sulfate, 0.0135 g (3%) of activated bentonite, 0.0045 g (1%) of a cationic polyelectrolyte copolymer of acrylamide with dimethylaminoethyl methacrylate methyl chloride, 0.0045 g (1%) of an anionic polyelectrolyte copolymer of acrylamide with sodium acrylate, and 0.18 g (40%) of sodium carbonate are added with stirring to 1 liter of wastewater containing 0.9 g / l of water-based acrylic paint material. Then the ink-containing water is stirred for 7 minutes and sedimented for 5 minutes. The residual content of paints and varnishes is 10 mg / l. The cleaning efficiency of the paint material is 98.9%.

Example 2
The process is carried out analogously to example 1: 0.45 g of a coagulant containing 0.135 g (30%) of aluminum sulfate, 0.2925 g (65%) of activated bentonite, 0.009 g (2%) of a cationic polyelectrolyte - a copolymer of acrylamide with dimethylaminoethyl methacrylate methyl chloride, 0.009 g (2%) of an anionic polyelectrolyte copolymer of acrylamide with sodium acrylate, and 0.0045 g (1%) of sodium carbonate are added with stirring to 1 liter of wastewater containing 0.9 g / l of water-based acrylic paint material. The residual content of paints and varnishes is 8 mg / l. The cleaning efficiency of the paint material is 99.1%.

Example 3
The process is carried out analogously to example 1: 0.45 g of a coagulant containing 0.18 g (40%) of aluminum sulfate, 0.1575 g (35%) of activated bentonite, 0.00675 g (1.5%) of a cationic polyelectrolyte-acrylamide copolymer with dimethylaminoethyl methacrylate methyl chloride, 0.00675 g (1.5%) of an anionic polyelectrolyte copolymer of acrylamide with sodium acrylate, and 0.099 g (22%) of sodium carbonate are added with stirring to 1 l of waste water containing 0.9 g / l of water-based emulsion acrylic paintwork material. The residual content of paints and varnishes is 9 mg / l. The cleaning efficiency of the paint material is 99%.

Examples 4-11
The process is carried out analogously to example 1. Coagulant in an amount of 0.45 g, containing 0.2475 g (55%) of chloride or sulfate of divalent and trivalent metals or mixtures thereof, 0.0135 g (3%) of activated bentonite, 0.0045 g (1%) of cationic polyelectrolyte, 0.0045 g (1%) of anionic polyelectrolyte and 0.18 g (40%) of sodium carbonate are added with stirring to 1 liter of waste water containing 0.9 g / l of water-based acrylic paint material. Then the ink-containing water is stirred for 7 minutes and sedimented for 5 minutes.

 Data on the composition of coagulants and the effectiveness of water purification during their use (according to examples 4-11) are given in table. 3.

 The proposed coagulant in comparison with the known one provides an increase in the efficiency of wastewater treatment from paints and varnishes based on acrylic, melamine, polyurethane, nitrocellulose, epoxy and alkyd film-forming from 70-74% to 98-99.4%, expanding the spectrum of action of the coagulant and reducing the consumption of coagulant 6-7 times. The content of coatings in purified water decreases from 198-270 mg / l to 5-17 mg / l, and the consumption of coagulant decreases from 2.5-3.5 g / l to 0.35-0.6 g / l.

Claims (2)

1. Coagulant for wastewater treatment from paints and varnishes based on chlorides or sulfates of divalent and trivalent metals or their mixtures and cationic polyelectrolytes, characterized in that it contains activated bentonite, anionic flocculant with mol.m. from 5 to 15 million cu and the content of anionic groups of at least 5% and sodium carbonate in the following ratio of ingredients, wt.%:
Chlorides or sulfates of 2- and 3-valence metals or mixtures thereof - 30 - 55
Activated Bentonite - 3 - 65
Cationic Polyelectrolyte - 1 - 2
Anionic Polyelectrolyte - 1 - 2
Sodium Carbonate - Else
2. The coagulant according to claim 1, characterized in that the cationic polyelectrolyte is used copolymers of acrylamide with methyl chloride or benzyl chloride, dimethylaminoethyl methacrylate, copolymer of acrylamide with N-trimetilammoniyetilmetakrilatmetilsulfatom, acrylamide copolymers with dimethylaminoethyl acrylate hydrochloride or acetate dimethylaminoethyl polidimetilaminoetilmetakrilat acetate, polidimetilaminoetilmetakrilat hydrochloride, poly-N trimethylammonium ethyl methacrylate methyl sulfate, poly-N-trimethyl ammonium ethyl methacrylate benzene sulfonate.  3. The coagulant according to claim 1, characterized in that the copolymers of acrylamide or methacrylamide with acrylate and sodium methacrylate, hydrolyzed polyacrylamide, sodium polyacrylate are used as the anionic polyelectrolyte.

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