RO121862B1 - Crust and corrosion inhibitor based on macromolecular compounds - Google Patents

Abstract

The invention relates to crust and corrosion inhibitors based on macromolecular compounds, having also microbiological effect, used for conditiong the industrial water used in the recirculated water cooling systems. According to the invention, the inhibitor comprises 1...3% acrylic acid polymers, having a molecular mass of 1500-30000 g/mole, polydispersity index ranging between 1.05 and 1.2 and comprising zinc, copper and ammonium ions, 1...30% potassium or sodium bromide, 2...45% compounds based on inorganic phosphorus, 0...20% compounds comprising organic phosphorus, 0.2...15% amines, 0...20% sodium or magnesium lignosulphonate, 0...15% sodium sulphite, 0...15% sodium dinaphthylmethansulphonate, 0...25% sodium silicate, 0...30% zinc chloride or sulphate, 0...50% copper sulphate, 40...75% water.

Description

The present invention relates to a crust and corrosion inhibitor, based on macromolecular compounds, also having microbiological action, used to condition the industrial water used in the cooling systems with recirculated water.

In recent years, according to the new technological requirements, the need for complex treatments has emerged, which aim at an efficient control of the crust, corrosion and microbiological agents found in the industrial systems of recirculated water cooling.

Firms involved in the manufacture of crust and corrosion inhibitors have adopted various variants, producing inhibitors based on organic phosphorus (phosphonates / phosphines) in combination with inorganic phosphates and water-soluble polymers, inhibitors that provide good corrosion protection.

Also known are various inhibitors based on organic or inorganic zinc compounds, or various salts of heavy metals such as molybdate, which form, in the presence of the water-soluble polymer, films of highly soluble complexes with anticorrosive protection effect.

From RO patent 111792, a crust and corrosion inhibitor is known, for the conditioning of industrial water, which contains 0 ... 7% organic compounds with phosphorus, 4 ... 45% inorganic phosphorus compounds, 0.1 ... 10 % amines, 1 ... 30% water-soluble polymers, such as polycarboxylic acids or sodium and / or ammonium salts, these being homopolymers of acrylic or methacrylic acid, or copolymers thereof with acrylamide, 0-12% sodium or magnesium lignosulfonate. , 0 ... 15% sodium sulphite, 0 ... 10% sodium dinaftilmethanesulfonate, 0 ... 20% sodium silicate, 0 ... 10% zinc chloride or sulphate, 45 ... 75% water.

The technical problem, which the invention aims to solve, is to obtain a product with a dispersive, non-flocculating character, and capable of inducing the electrochemistry of the water to be treated, so that it can provide superior corrosion protection, concomitantly with a good biocidal action.

The solution of the technical problem is to create a crust and corrosion inhibitor based on macromolecular compounds, which contains 1 ... 30% polymers of acrylic acid, having a molecular mass of 1500 - 30000 g / mol, polydispersity index between 1.05 and 1,2, and containing zinc, copper and ammonium ions, 1 ... 30% potassium or sodium bromide, 2 ... 45% compounds based on inorganic phosphorus, 0 ... 20% compounds containing organic phosphorus, 0.2 ... 15% amine, 0 ... 20% sodium or magnesium lignosulfonate, 0 ... 15% sodium sulfite, 0 ... 15% sodium dinaftilmethanesulfonate, 0 ... 25% silicate sodium, 0 ... 30% chloride or zinc sulphate, 0 ... 50% copper sulphate, 40 ... 75% water.

The polymers of the acrylic acid of the composition of the inhibitor according to the invention are obtained at a temperature of 5 ... 20 ° C, by a redox initiation system, consisting of 0.1 .2% sodium, potassium or ammonium persulfate, 0, 1 ... 4% hydroperoxides of the type cumene hydroperoxide, iron-butyl hydroperoxide or hydrogen peroxide, 0.01 ... 0.2% percarbonates of the type 2-ethyl tert -butyl monoperoxide carbonate Ihexyl or 0.1 ... 2% ascorbic acid, in the presence of 0.01 ... 0.05% copper sulphate and neutralization with 1 ... 20% ammoniacal complex of zinc and / or hexamethylentetraamine, the percentages being related to the monomer.

Inorganic phosphorus compounds are selected from alkaline phosphates, mono- or disodium orthophosphate, sodium hydrophosphate, potassium phosphite or tripolyphosphate, and compounds containing organic phosphorus are selected from phosphoric hydroxyethylidene, polyisopropyl phosphoric acid, phosphine or derivative.

The amines are selected from 1-naphthylamine, hexaamine, trioxazoline, oxazoline or hexamethylenetraamine, guandinine, polyamines derived from higher fatty acids or quaternary ammonium salts such as alkyltrimethylammonium chlorides or amino acids of the serine or glutamic acid.

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Due to its composition, the inhibitor according to the invention achieves the decarbonation of water 1, the anodic and cathodic protection of the metallic surfaces in contact with a water with high salinity, an efficient control of the microbiological developments found in surface waters 3 and which develop at higher temperatures. of 25 ° C, in the presence of the different contaminants existing in these systems, as well as preventing the inorganic and biological fulling. 5

The crust and corrosion inhibitor based on macromolecular compounds for treating industrial water according to this invention has the following advantages: 7

- allows to obtain very good results in combating corrosion, by the concomitant presence of phosphate, zinc, copper and ammonium ion, which favorably modifies the electrochemical potential of water;

- has a superior dispersing effect, thus removing the crust deposits, by the presence of the polymer having a molecular mass of 1500-30000 and weak zinc bonds;

- is biocidal in nature, due to the presence of copper sulphate and potassium bromide, 13 which activates hypochlorite in water;

- allows the use of surface or deep water having alkalinity, hardness and 15 different conductivities, in cooling systems with recirculated water, with or without prior treatment for clarification or decarbonation. 17

The product according to the invention acts efficiently in the treatment of industrial waters, due to its composition and synthesis method. Thus, by its synthesis, a form of 19 precomplexing of the soluble components in aqueous medium is achieved. They react with Ca ²⁺ , Mg ²⁺ or even Fe ions, resulting in complexes forming a protective film on the surface 21 of the metal to be protected and stable suspensions due to the dispersing character of the polymer. By its composition, the inhibitor has anti-corrosive, anti-fouling action, as well as action against 23 microbiological developments.

In the following, 9 embodiments of the invention are presented. 25

Example 1. A crust and corrosion inhibitor, based on macromolecular compounds, was obtained with the following composition: 15 parts of zinc and ammonium polyacrylate, obtained 27 by cold acrylic acid polymerization (5 .., 20 ° C). , by a redox initiation system, consisting of: 1 ... 30% acrylic acid, 0.1 ... 2% potassium sodium or ammonium persulfate, 0.1 ... 4% 29 hydroperoxides of the hydroperoxide type cumene, tert-butyl hydroperoxide or hydrogen peroxide, 0.01 ... 0.2% percarbonates of the tert-butyl monoperoxide carbonate type 2-ethylhexyl or 0.1 ... 2% 31 ascorbic acid, in the presence of 0.01 ... 0.05% copper sulphate, 17 parts by weight sodium tripolyphosphate, 3 parts by weight hexamethylenetetraamine, 5 parts by weight sodium lignosulfonate 33 or magnesium, 2 parts by weight sodium sulphite, 1 part in weight zinc sulphate, 53 parts by weight water. 35

The resulting inhibitor has a pH between 7 and 9, and the consumption in g / m ³ , which ensures the optimum protection against corrosion and anti-crust, is 40 g / m ³ water having a hardness of 3d 37 and 60 g / m water with the hardness greater than 10 ° d.

Example 2. A crust and corrosion inhibitor was obtained, with the following composition: 39 parts of zinc and ammonium polyacrylate, obtained by cold acrylic acid polymerization (5 ... 20 ° C) through a redox formation system, formed of: 1 ... 30% acrylic acid, 0.1 ... 2% persulfate 41 sodium, potassium or ammonium, 0.1 ... 4% hydroperoxides of the type cumene hydroperoxide, tea / t-butyl hydroperoxide or oxygenated water, 0.01 ... 0.2% percarbonates of the tert-butyl monoperoxide carbonate type 43 2-ethylhexyl or 0.1 ... 2% ascorbic acid, in the presence of 0.01 ... 0 , 05% copper sulfate, 18 parts by weight sodium tripolyphosphate, 5 parts by weight sodium or magnesium lignosulfonate, 2 45 parts by weight zinc chloride, 65 parts by weight water.

The obtained inhibitor has a pH between 1 and 4, and the consumption in g / m ³ , which provides 47 optimal corrosion protection and anti-crust protection, is 30 g / m ³ water having a hardness of 3-6 ° d and 55 g / m ³ water having a hardness> 10 ° d. 49

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Example 3. A crust and corrosion inhibitor was obtained, with the following composition: 20 parts of zinc and ammonium polyacrylate, obtained by polymerization of cold acrylic acid (5, .. 20 ° C) through a redox initiation system, formed of: 1 ... 30% acrylic acid, 0.1 ... 2% sodium, potassium or ammonium persulfate, 0.1 ... 4% hydroperoxides of the type cumene hydroperoxide, tertiary-butyl hydroperoxide or hydrogen peroxide , 0.01 ... 0.2% percarbonates of the iron-butyl monoperoxide carbonate type 2-ethylhexyl or 0.1 ... 2% ascorbic acid, in the presence of 0.01 ... 0.05% sulfate copper, 5 parts by weight sodium tripolyphosphate, 5 parts by weight sodium or magnesium lignosulfonate, 5 parts by weight quaternary ammonium salts, 65 parts by weight water.

The obtained inhibitor has a pH 7-8, and the consumption in g / m ³ , which ensures the optimum protection against corrosion and anti-crust, is 25 g / m ³ water which has a hardness of 3-4 ° d and 55 g / m ³ water having a hardness> 10 ° d.

Example 4. A crust and corrosion inhibitor was obtained, with the following composition: 20 parts of zinc and ammonium polyacrylate, obtained by cold acrylic acid polymerization (5 ... 20 ° C), by a redox initiation sternum consisting of: 1 ... 30% acrylic acid, 0.1 ... 2% sodium, potassium or ammonium persulfate, 0.1 ... 4% hydroperoxides such as cumene hydroperoxide, tert-butyl hydroperoxide or water oxygenated, 0.01 ... 0.2% tert-butyl monoperoxide carbonate type 2-ethylhexyl or 0.1 ... 2% ascorbic acid, in the presence of 0.01 ... 0.05% copper sulphate, 5 parts by weight sodium tripolyphosphate, 5 parts by weight sodium or magnesium lignosulfonate, 7 parts by weight hexamethylenetra- amine, 63 parts by weight water.

The obtained inhibitor has a pH of 6-8, and the consumption in g / m ³ , which ensures the optimum protection against corrosion and anti-crust, is 35 g / m ³ water having a hardness of 3-5 ° d and 55 g / m water having hardness> 10 ° d.

Example 5. A crust and corrosion inhibitor was obtained, with the following composition: 10 parts of zinc and ammonium polyacrylate, obtained by cold acrylic acid polymerization (5 ... 20 ° C), by a redox initiation system, consisting of: 1 ... 30% acrylic acid, 0.1 ... 2% sodium, potassium or ammonium persulfate, 0.1 ... 4% hydroperoxides such as cumene hydroperoxide, tert-butyl hydroperoxide or water oxygenated, 0.01 ... 0.2% tert-butyl monoperoxide carbonate of 2-ethylhexyl carbonate or 0.1 ... 2% ascorbic acid, in the presence of 0.01 ... 0.05% copper sulphate, 20 parts by weight sodium tripolyphosphate, 15 parts by weight sodium silicate, 5 parts by weight zinc chloride, 50 parts by weight water.

The obtained inhibitor has a pH of 4 - 6, and the consumption in g / m ³ , which ensures the optimum protection against corrosion and anti-crust, is 10 g / m ³ water having a hardness of 0,5-1 ° d and 50 g / m ³ water having a hardness> 5 ° d.

Example 6. A crust and corrosion inhibitor with biocidal action was obtained, with the following composition: 30 parts of zinc and ammonium polyacrylate, obtained by cold acrylic acid polymerization (5 ... 20'C), by a system of redox initiation, consisting of: 1 ... 30% acrylic acid, 0.1 ... 2% sodium, potassium or ammonium persulfate, 0.1 ... 4% hydroperoxides such as cumene hydroperoxide, turf hydroperoxide -butyl or oxygenated water, 0.01 ... 0.2% percarbonates of the type 2-ethylhexyl carbonate tert-butyl monoperoxide or 0.1 ... 2% ascorbic acid, in the presence of 0.01 ... 0.05% copper sulphate, 20 parts by weight sodium or potassium bromide, 5 parts by weight quaternary ammonium salts, 45 parts by weight water.

The obtained product ensures the optimum protection against corrosion and against microbiological developments, at a consumption, in g / m ³ , of 20 g / m ³ water.

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Example 7. A crust and corrosion inhibitor, with biocidal action, was obtained with 1 following composition: 30 parts of zinc and ammonium polyacrylate, obtained by polymerization of cold acrylic acid (5 ° -20 ° C) by a system of redox initiation, consisting of: 1 ... 30% 3 acrylic acid, 0.1 ... 2% sodium, potassium or ammonium persulfate, 0.1 ... 4% hydroperoxides such as cumene hydroperoxide, fertile hydroperoxide -butyl or hydrogen peroxide, 0.01 ... 0.2% 5 percarbonates of the tert-butyl monoperoxide carbonate type 2-ethylhexyl or 0.1 ... 2% ascorbic acid, in the presence of 0.01. .0.05% copper sulphate, 30 parts by weight sodium bromide 7 or potassium, 5 parts by weight hexamethylenetetraamine, 40 parts by weight water. The obtained product ensures the optimum protection against corrosion and against microbiological developments, at 9 a consumption, in g / m ³ , of 15 g / m ³ water.

Example 8. A corrosion and microbiological inhibitor was obtained, with the following 11 composition: 10 parts of zinc and ammonium polyacrylate, obtained by cold acrylic acid polymerization (5 ... 0 ° C), by a redox initiation system , consisting of: 1 ... 30% acrylic acid, 13 0.1 ... 2% sodium, potassium or ammonium persulfate, 0.1-4% hydroperoxides such as cumene hydroperoxide, tert-butyl hydroperoxide or water oxygenated, 0.01..0.2% percarbonates of type 15 tert-butyl monoperoxide carbonate of 2-ethylhexyl or 0.1-2% ascorbic acid, in the presence of 0.01-0.05% copper sulphate, 80 parts by weight quaternary ammonium salts, 10 parts by 17 weight water.

The obtained product ensures the optimum protection against corrosion and against the 19 microbiological developments, at a consumption, in g / m ³ , of 10 g / m ³ water.

Example 9. A crust and corrosion inhibitor, with biocidal action, was obtained with 21 following composition: 30 parts of zinc and ammonium polyacrylate, obtained by cold acrylic acid polymerization (5 ... 20 ° C), by a redox initiation system, consisting of: 1-30% 23 acrylic acid, 0.1 ... 2% sodium, potassium or ammonium persulfate, 0.1 ... 4% hydroperoxides such as cumene hydroperoxide, tertiary hydroperoxide -butyl or hydrogen peroxide, 0.01 ... 0.2% 25 tert-butyl monoperoxide carbonate type 2-ethylhexyl or 0.1 ... 2% ascorbic acid, in the presence of 0.01. .0.05% copper sulphate, 45 parts by weight copper sulphate, 27 5 parts by weight hexamethylenetetraamine, 20 parts by weight water.

The obtained product ensures optimum protection against corrosion and against 29 microbiological developments, at a consumption, in g / m ³ , of 20 g / m ³ water.

Claims (6)

1. Crust and corrosion inhibitor, based on macromolecular compounds, characterized in that it contains 1 ... 30% polymers of acrylic acid, having a molecular mass of 35 1500-30000 g / mol, polydispersity index between 1, 05 and 1,2, and containing zinc, copper and ammonium ions, 1 ... 30% potassium or sodium bromide, 2 ... 45% compounds based on 37 inorganic phosphorus, 0 ... 20% compounds containing phosphorus organic, 0.2 ... 15% amines, 0 ... 20% sodium or magnesium lignosulfonate, 0 ... 15% sodium sulfite, 0 ... 15% sodium dinaftilmethanesulfonate, 0 ... 25 % sodium silicate, 0 ... 30% chloride or zinc sulphate, 0 ... 50% copper sulphate, 40 ... 75% water. 41 2. Inhibitor according to claim 1, characterized in that the acrylic acid polymers are obtained at a temperature of 5 ... 20 ° C, by a redox initiation system, consisting of 43 0.1 ... 2% sodium persulfate. , potassium or ammonium, 0.1 ... 4% hydroperoxides of the type cumene hydroperoxide, tert-butyl hydroperoxide or hydrogen peroxide, 0.01 ... 0.2% percarbonates of type 45 RO 121862 Β1 1 tert-butyl monoperoxide carbonate of 2-ethylhexyl or 0.1 ... 2% ascorbic acid, in the presence of 0.01 ... 0.05% copper sulphate and neutralization with 1 ... 20% ammoniacal complex and / or zinc 3 hexamethylenetraamine, the percentages being related to the monomer. An inhibitor according to claim 1, characterized in that the compounds based on 5 inorganic phosphorus are selected from alkaline phosphates, mono or disodium orthophosphate, sodium hydrophosphate, potassium phosphite or tripolyphosphate, and compounds containing organic phosphorus are selected from 7 phosphoric hydroxyethylidene acid, polyisopropyl phosphoric acid, phosphine or phosphonium derivatives. An inhibitor according to claim 1, characterized in that the amines are selected from 9 1-naphthylamine, hexaamine, trioxazoline, oxazoline or hexamethylentetraamine, guandinine, polyamines derived from higher fatty acids or quaternary ammonium salts of the chloride type 11 alkyltrimethylammonium or amino acids such as serine, glutamic or asparagic acid.