UA92962U - Inhibitor complex protection recycling water supply systems from corrosion, salt deposits and bio-fouling - Google Patents

Abstract

Inhibitor complex protection recycling water supply systems from corrosion, salt deposits and bio-fouling contains sodium tripolyphosphate, pyrophosphate acid, water and organic additive. As organic additive used polyhexamethyleneguanidine phosphate and monoethanolamine.

Description

The proposed useful model relates to the protection of metal heat exchange surfaces of water circulation systems from corrosion, salt deposition and biofouling and can be used in chemical, oil refining, machine building, food and other industries. For such applications, the most promising are inhibitors of complex action, the use of which simultaneously achieves the protection of the heat exchange equipment of water circulation systems from corrosion, salt deposition, and bi-fouling. During this, along with increasing the efficiency and resource of the heat exchange equipment, the technologies and cost of water circulation water treatment are significantly simplified, which in general gives a significant saving of energy and material resources.

Known inhibitor for corrosion protection of heat exchange equipment of circulating water supply systems |11. The inhibitor contains cationic polymer 2-methyl-5-vinylpyridine (mol. mass 50-500 thousand) and sodium hexametaphosphate in the ratio 1:(1-4), respectively. The disadvantage of this inhibitor is its narrow functional focus, namely: it effectively protects metal surfaces from corrosion, but is not very suitable for preventing salt deposition and biofouling on the surfaces of heat exchange equipment.

A known compound for the prevention of salt deposition and corrosion in circulating water supply systems, which contains a phosphonate inhibitor (0.1-30 wt. 95), a phosphate inhibitor (0.1-70 wt. 95) and water (2). In addition, the composition contains a water-soluble polymer with a molecular weight of 3000-20000 (1-7 wt. 95) and an inhibitor of the azole series (3-10 wt. 95). The working concentration of the inhibitor in circulating water at a total salinity of 1.8 g/l is 60 mg/l. The disadvantage of the inhibitor is a decrease in its effectiveness when the temperature of the circulating water rises to 80-90 "С.

The main reason for this is the biological destruction of phosphonates at such temperatures and the loss of stability of the inhibitor, which in general leads to a decrease in its effectiveness, especially the function of preventing salt deposition. The composition is not effective for protecting heat exchange equipment from biological deposits.

The method of protecting water circulation systems from corrosion, salt deposition and biofouling is described in the patent of the Russian Federation). According to the patent, the protection of water circulation systems is achieved by introducing a polymer derivative of hydroxyethylidenediphosphonic acid into the water, namely: hydroxyethylidenediphosphonate polyhexamethyleneguanidine (p-10-100). The compound was obtained by the reaction of hydroxyethylidenediphosphonic acid on the basis of polyhexamethyleneguanidine in

From the equivalent ratio in the water environment. The disadvantage of the inhibitor is a decrease in its effectiveness and stability when the content of salts in the circulating water is more than 0.1 g/l and Ca? ions are more than 0.01 g/l. At the same time, the function of protecting the equipment against salt deposition decreases most significantly.

The closest to the proposed useful model is a complex action inhibitor for reversible water supply systems, which contains sodium tripolyphosphate, pyrophosphate acid, isopropylamine salt of M-phosphonomethyl-glycine and water in the ratio of components (wt. 95), respectively: 30-40; 21-26; 5-8; the rest |41. The inhibitor of complex action is designed to protect cooling water circulation systems from corrosion, salt deposits and biofouling at the temperature of the circulating water up to 60-70 "С and the total salt content up to 1.5 g/l and the content of Ca? up to 0.3 g/l. The disadvantage of the described inhibitor is the loss of stability at circulating water temperatures of 85-90 "С, for example, when used in water heating (heating) systems. The reduction of the function of protecting equipment from biofouling is especially significant. A decrease in the effectiveness of the inhibitor at elevated temperatures requires an increase in its concentration in circulating water , which under such conditions leads to a significant overspending of reagents.Therefore, in general, the use of such an inhibitor in water circulation systems becomes economically unprofitable.

Therefore, the urgent task of a useful model is to create an effective inhibitor of complex protection of heat exchange equipment against corrosion of salt deposits and biofouling at elevated temperatures and increased salt content in circulating water to expand the range of its protective capabilities and areas of use.

The task is solved by the fact that in the inhibitor of complex protection of metal surfaces of heat exchange equipment of circulating water supply systems against corrosion, salt deposition and biofouling, which contains sodium tripolyphosphate, pyrophosphate acid and an organic additive, polyhexamethyleneguanidine phosphate and monoethanolamine are used as an organic additive, with the following ratio of components, mass . Fo: sodium tripolyphosphate 25-42 pyrophosphate acid 20-28 polyhexamethyleneguanidine 6-10 phosphate monoethanolamine 3-5 water the rest.

The declared set of features is not contained in any of the objects of the existing level of development of inhibitors for comprehensive protection of heat exchange equipment of water circulation systems.

A new solution for inhibitors of circulating water systems is proposed in the utility model, which is that in the inhibitor of complex protection of circulating water supply systems against corrosion, salt deposition and biofouling, containing sodium tripolyphosphate, pyrophosphoric acid and an organic additive, polyhexamethyleneguanidine phosphate and monoethanolamine are used as organic additives , with the following ratio of components, wt. Fo: sodium tripolyphosphate 25-42 pyrophosphate acid 20-28 polyhexamethyleneguanidine 6-10 phosphate monoethanolamine 3-5 water the rest.

Therefore, a feature that is not found in any of the analogues in the inhibitor of complex protection of circulating water supply systems against corrosion, salt deposition and biofouling, which contains sodium tripolyphosphate, pyrophosphate acid and an organic additive, polyhexamethyleneguanidine phosphate and monoethanolamine are used as an organic additive, with the following ratio of components, mass . 9: sodium tripolyphosphate 25-42 pyrophosphoric acid 20-28 polyhexamethyleneguanidine 6-10 phosphate monoethanolamine 3-5 water the rest.

Industrial use of the proposed model does not require special technologies and materials, its implementation is possible at existing chemical enterprises that manufacture reagents and inhibitors.

The effectiveness of the inhibitor of complex protection against corrosion, salt deposition and biofouling was determined in model water with a total salinity (Ma", Ca, Maye", SG, 5042, MOz) up to 2 g/l and a content of Ca" up to 0.4 g/l. The study of the properties of the inhibitor was carried out at a water temperature of 60-90 "C and a flow rate of 0.3-0.6 m/s for 280 hours. The concentration of the inhibitor was varied in the range of 20-100 mg/l in terms of pure substances.

The weight method was used to determine the rate of corrosion and salt deposition. Samples of size 80 x 35 x 2 mm made of steel Z were prepared according to known methods (cleaning, grinding, degreasing, washing) and placed in a flow of model water, the speed of which was 0.5 m/s. The rate of corrosion and salt deposition and the effectiveness of the protection of metal samples were determined in model water without the addition of an inhibitor and with the addition of inhibitors (proposed and prototype). At the same time, the biocidal properties of inhibitors were determined according to the well-known TTS test by estimating the number of bacteria in 1 cmU. The results of studies of the effectiveness of the inhibitor of complex protection of metal surfaces against corrosion, salt deposition and biofouling are shown in the table.

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Table

Properties of the inhibitor of complex protection of metal surfaces against corrosion, salt deposition and biofouling at different temperatures and concentrations in circulating water (total salt content in water - 2 g/l, Ca concentration - 0.4 g/l, water movement speed - 0, 5 m/s) in Concentration Velocity m Effectiveness Deposition Effectiveness of bacteria in water, "C inhibitor, mg/l | corrosion, mm/year | protection, 95 | salt, g/m protection, 90 sMU 60 | yush50 | 0040 | 970 | 4 | 980 | t 750 | yushschL50 | 0048 | 962 | 8 | 964 | t 80 | yush50 | 0080 | 938 | 18 | 923 | 1 80 | yuyu 20 | this | 863 | 40 | 822 | 1 80 | yuschyusch, RMO | o0lho | 908 | 24 | 898 | t 80 | юЮющМ,/70 | 0070 | 946 | 717 | 927 | 1 80 | yush85 sh | 0080 | 938 | 719 | 919 | t 60 | 7122 | 0 | 212 1 yush 0 | 1 non-inhibitor | 129 | 0 | 228 | BYUD 0 | 10 80 | 7181 Her 0 11 236 | that | 1 60 | 0048 | 960 | 8 | 962 | 1 90

The results of the studies given in the table show that the effectiveness of protecting metal surfaces from corrosion and salt deposition at the optimal concentration of the proposed inhibitor of 50 mg/l and the temperature of the circulating water is 97 and 98 95, respectively. When the water temperature is increased to 90 "С, the effectiveness of protection against corrosion decreases by -3.2 95, and protection against salt deposition by 5.0-5.595. At the same time, the biocidal properties of the inhibitor at high water temperatures (907) remain high - the number of bacteria per cm3 does not exceed 102.

Along with this, when using the prototype complex inhibitor under similar conditions, the effectiveness of protection against corrosion decreases by 35 95, against salt deposition - by 42 95. Under such conditions, the prototype inhibitor practically does not protect the equipment from biofouling - the number of bacteria per cm3 is equal to 107.

Therefore, the proposed inhibitor of complex protection of metal surfaces of heat exchange equipment of water circulation systems against corrosion and salt deposition at a water temperature of 90 "С and a total salt content of 2 g/l has a significantly higher efficiency compared to the prototype.

The positive effect is achieved due to the synergistic strengthening of the inhibitory properties of the composition compared to equivalent amounts of the constituent components. Organic additives of the inhibitor contain amino groups, which are competitively adsorbed on the active centers of the metal and, in general, significantly increase the protective properties of the inhibitor. The presence of a mechanism of competitive adsorption and enhancement of inhibitory properties allows the proposed complex protection inhibitor to be used in waters with elevated temperature and elevated total salinity.

The proposed inhibitor will find practical application for effective protection against corrosion, salt deposition, and biofouling of heat exchange equipment of water-circulating cooling and heating systems in various industries: chemical, energy, oil refining, engineering, hydraulic engineering, food, etc. The use of the proposed complex protection inhibitor will allow to increase the service life of the heat exchange equipment, improve the ecological indicators of the environment, and also obtain

To save fuel and energy resources.

Sources of information: 1. Patent VO Mo 2038420, IPC C23ZE 11/00. A method of corrosion inhibition in water systems. /P.T. Poluzktov, E.I. Kryvosheeva, A.V. Molodka, G.V. Krashchenko, N.A. Matveeva,

E.V. Vorobyov - Publ. 27.06.1995. 2. Patent SHA Mo 42519, IPC СО2Е 5/00. Compound to prevent salt deposits and corrosion. L.V. Boyko, O.O. Boyko - Publ. 15.10.2001.

Z. Patent VO Mo 2100294, IPC СО2Е 5/14. A method of protecting water circulation systems from corrosion, salt deposition and biofouling. /V.P. Tomin, A.F. Babikov, E.M. Kolivanova, V.S.

Voytyk, S.S. Horyavin, N.A. Korchevy - Publ. 27.12.1997. 4. Patent OA Mo 81348, МПК С2ЗЕ 14/00. Inhibitor of complex action for the circulating water cooling system. / Yu.V. Voloshchuk, I.V. Okhotsk - Publ. 06/25/2013.

Claims (1)

USEFUL MODEL FORMULA An inhibitor of complex protection of circulating water supply systems against corrosion, salt deposition and biofouling, containing sodium tripolyphosphate, pyrophosphate acid, water and an organic additive, which is characterized by the fact that polyhexamethyleneguanidine phosphate and monoethanolamine are used as an organic additive, with the following ratio of components, by weight. 9: sodium tripolyphosphate 25-42 pyrophosphoric acid 20-28 polyhexamethyleneguanidine 6-10 phosphate monoethanolamine 3-5 water the rest.