RU2581347C1 - Method of removing scale-corrosion sediments from metal surfaces of carbon non-alloyed steels - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: method includes etching of sediments with a purification solution, which has pH of 4-5 and contains g/l: 10-15 hydrochloric acid, 10-15 orthophosphoric acid, not less than 3-5 complexon in the form of ethylenediaminetetraacetic acid (EDTA) or 1-hydroxyethylidene diphosphonic acid (HEDP), 0.5-1 UCP urotropin condensation product and ethanolamine with chlorine benzine, 0.4-1 alizarin oil, and the remaining part - water.

EFFECT: effective removal of sediments from the metal surface and the invariability of initial physical-chemical properties of the metal surface, reduction of corrosion loss and increase of ecological safety of processing.

3 cl, 5 dwg

Description

The invention relates to the field of chemical treatment of metals, in particular to a method for cleaning metal surfaces of products from carbon unalloyed steels from carbonate and iron oxide deposits, is intended primarily for the implementation of cleaning washing operations during repairs and / or during operation of heat power equipment, for example, steam and hot water boilers , heat exchangers, heavily contaminated heating systems, and can also be used to clean other metal Cereal variety of configurations.

A known method of removing scale-corrosion deposits when cleaning heat power equipment (RU 2218533 C2, 2001), based on the sequential use of the first spent weakly acidic solutions with periodic replenishment with acute hydrochloric acid at a concentration of 20-28% with inhibitors, then aqueous 5-8% alkali solutions with a temperature of 50-80 ° C. The method involves washing the cleaned surface with a hot medium with a temperature of 50-70 ° C before and after passivation by 1% soda solution or 2% ammonia solution. The disadvantage of this method is the use of high concentration hydrochloric acid solutions and the multi-stage cleaning process, due to the need to neutralize the washing solution, passivation of the surface and washing equipment.

There is a method of removing scale deposits from heat exchange equipment - a locomotive’s water cooling system (RU 2449234 C2, 2010), in which a thermal imaging examination of the internal surfaces of the system is carried out first, after which it is first kept under a solution of 4% hydrochloric acid, 1.5% urotropine , 0.5% magnesium silicate for an hour with repeated circulation of the solution inside the system, and after washing the system with water and neutralizing the residual solution, the system is also kept under the solution for an hour (pH 2-3), containing 8.8% phosphoric acid, providing multiple circulation of the solution and completing the cleaning process of the system by washing and neutralizing the residual solution. This method is characterized by a multi-stage process and a length of time, due to the use of highly aggressive reaction media, and requires significant economic costs, as a result of which it has a limited scope.

Known methods for cleaning metal surfaces from scale-corrosion deposits, in which the disadvantages of the above analogues are eliminated by reducing the concentration of mineral acids and increasing the pH of the solution by introducing chelating agents into the cleaning solution.

So there is a known method of cleaning the inner surfaces of blast furnace refrigerators from scale deposits (RU 2154109 C1, 1999), when an aqueous solution containing complexon 24-26 kg / m ³ , ascorbic acid is pumped within 1-3 hours 1-3 kg / m ³ and sodium salts of sulfosalicylic acid 1-44 kg / m ³ . The discharge of the spent solution in this method does not require additional purification and chemical treatment, however, the use of high concentrations of expensive components: complexones and sodium salts of sulfosalicylic acid should be attributed to the disadvantage of this analogue.

The closest analogue (prototype) of the invention is a method for cleaning metal surfaces from scale-corrosion deposits, including etching the deposits with a cleaning aqueous solution containing HEDP complexone, a reaction mixture with hydrochloric and oxalic acids and ethylene glycol, at constant pH and temperature, and subsequent washing of the flow surface water (RU 2507312 C1, 2012), in which sediment is etched at a temperature of 50-80 ° C and a pH of 2-3 cleaning solution having the following ratio of components: ethylene stake 90-150 g / l, hydrochloric acid 15-25 g / l, 1-hydroxyethylidene diphosphonic acid (HEDP) 10-15 g / l, oxalic acid 15-25 g / l.

The disadvantages of the prototype include the increased content in the composition of the cleaning solution as a surfactant of a toxic substance of ethylene glycol in quantities that do not allow the possibility of draining the spent solution without additional cleaning and chemical treatment into the sewer. In addition, during prolonged storage of the spent solution containing hydrochloric acid and ethylene glycol, the formation of polymer resins is inevitable, which further deteriorates the quality of treatment.

The problem solved by the invention is aimed at eliminating the disadvantages of the prototype and developing an environmentally safe method for removing scale-corrosion deposits from metal unalloyed steel from carbon unalloyed steels, which will allow to abandon large quantities of toxic ethylene glycol using low-hazard alizarin oil as a surfactant without loss of efficiency , when it becomes possible to drain the spent solution into the sewer.

The technical result obtained by the implementation of the invention is to increase environmental safety while maintaining the efficiency of removing deposits without increasing the number of stages of the cleaning process and the economic costs of its implementation.

To achieve a technical result in a method of removing scale-corrosion deposits based on calcium, iron, magnesium, iron oxides and hydroxides from metal surfaces of carbon unalloyed steels, including etching of the deposits with a cleaning solution containing complexon and an acid mixture containing hydrochloric acid, at constant pH and temperature, and subsequent washing of the surface with running water, according to the invention, the etching is carried out in a solution containing additional inhibitors to of acid corrosion: PKU - the condensation product of urotropine and ethanolamine with gasoline chloride - and alizarin oil in a slightly acidic environment and phosphoric acid in a mixture of acids and having a pH of 4-5, while the components of the solution are taken in the following ratio, g / l:

hydrochloric acid 10-15 orthophosphoric acid 10-15 complexon no less 3-5 in the form of ethylenediaminetetraacetic acids (EDTA) or 1-hydroxyethylidene diphosphonic acids (HEDP) PKU 0.5-1 alizarin oil 0.4-1 water rest

In particular cases of the invention, the etching is carried out in the bath with stirring of the cleaning solution or by pumping the cleaning solution inside the washing circuit.

The use of a reactive mixture of hydrochloric and phosphoric acids as the basis for the cleaning solution contributes to the efficiency of deposit removal, since, as is known, the rate of dissolution of deposits on the surface of carbon unalloyed steels depends on the concentration of hydrogen ions in the solution, and the presence of complexon (EDTA or HEDP) in the solution due to the formation soluble chelate complexes of the composition CaHY ^- and CaHY ^o on the surface of the steel allows you to maintain the achieved level of removal efficiency of deposits in less aggressive conditions (at pH 4-5), favorable for the manifestation of such properties of alizarin oil as improving the wettability of the surface of deposits and a decrease in surface tension. Alizarin oil also inhibits the corrosion rate of carbon unalloyed steels.

It is known that as a result of the removal of deposits by etching with a cleaning solution using mineral acids and complexones, a juvenile steel surface is obtained, which has a reduced resistance to aggressive environments and is subject to destruction. In the proposed method, to increase the corrosion resistance of the surface, the condensation product of urotropine and ethanolamine with gasoline chloride, PCU, which even in small amounts (up to 1%) creates a blocking mechanism and prevents the contact of hydrogen ions with the steel surface, is introduced into the composition as an acid corrosion inhibitor.

The selected optimal operating temperature range of 50-80 ° C favors the course of this process, as the process goes in the kinetic region (activation energy 70 kJ / mol). A further increase in temperature is impractical due to the increase in the cost of the process.

Due to the presence in the composition of a cleaning solution of phosphoric acid in the proposed method, along with the removal of carbonate deposits, surface phosphating occurs due to the formation of a Ca ₃ (PO ₄ ) ₂ film.

The essence of the method is explained in the attached graphs, where: in FIG. Figure 1 shows a plot of the logarithm of the rate of dissolution of calcite on pH; in FIG. 2 is a graph of the dependence of the rate of mass loss of steel 10 on the concentration of EDTA and PKU at pH 5; in FIG. 3 is a graph illustrating the effect of the concentration of alizarin oil on the corrosion rate of steel 10 in distilled water; in FIG. 4 is a graph illustrating the effect of pH on the corrosion rate of steel 10 in a solution containing alizarin oil; in FIG. 5 - isotherm of the surface tension of alizarin oil.

To implement the method using technological equipment, a washing composition is fed into the tank (bath) or inside the cleaned circuit of the product with a strict ratio of reagents, pH, and temperature to maintain the existence of autocatalytic complexonate forms of calcium (CaHY ^- , CaHY ^o ), with the possibility of forced pumping, mixing (or without it) of the supplied solution. To ensure the effective impact of the etching process of deposits based on calcium, iron, magnesium carbonates, iron oxides and hydroxides, based on the thickness of the deposits on the surface to be cleaned and depending on the type of deposits, the following specific process parameters are assigned from the prescribed ranges:

- etching time - within 60 minutes;

- pH of the solution is 4-5;

- solution temperature - 50-80 ° C;

- mass ratio of reagents, g / l:

hydrochloric acid 10-15 orthophosphoric acid 10-15 complexon not less than 3-5 in the form of ethylenediaminetetraacetic (EDTA) or 1-hydroxyethylidene diphosphonic acid (HEDP) PKU 0.5-1 alizarin oil 0.4-1 water rest

with a ratio of (HCl: H ₃ PO ₄ ) 1: 1 by weight.

At the end of the etching process, the surface to be cleaned is washed with running water.

In the course of the research, washing was carried out from scale deposits of a specific steel product 10. Etching was carried out by immersing the product in a bath with a cleaning solution containing 10 g / l hydrochloric and 10 g / l phosphoric acid, 3 g / l EDTA, 0.5 g / l PKU, 0.4 alizarin oil, at a pH of 4-5 and a temperature of 70 ° C and constant stirring of the solution for one hour.

As a result, the steel surface to be cleaned, exposed to the specified washing composition, after complete removal of deposits did not change its physicochemical parameters while increasing the protective properties.

It is established that the value of the mass index of steel corrosion st. 10 at 70 ° C in the above solution was 1 g / m ² h. Without the use of PCUs and alizarin oil, the corrosion rate increases to 25 g / m ² h.

From the graph (Fig. 1) it follows that the intensive dissolution of calcite (the main component of deposits in thermal power equipment) occurs in an acidic environment. The use of complexones, in particular EDTA, also makes it possible to efficiently carry out the dissolution process under more benign conditions (pH 4-5).

From the graph (Fig. 2) it follows that the additives of the acid corrosion inhibitor PKU reduce the rate of mass loss during corrosion in a mixture of hydrochloric and phosphoric acids containing complexones.

From the graph (Fig. 3) it is seen that with an increase in the concentration of alizarin oil, the corrosion rate of steel 10 decreases sharply. The minimum protective concentration for alizarin oil is 0.4 g / l.

Alizarin oil as an effective corrosion inhibitor acts only in slightly acidic, slightly alkaline and neutral environments. As is known, a decrease in pH, leading to the formation of a hydrolysis form of alizarin oil, reduces the initial form in the solution, which leads to a sharp increase in the corrosion rate.

The change in the protective effect of alizarin oil depending on pH is shown in the graph (Fig. 4). The graph shows that alizarin oil reduces the corrosion rate in the pH range 4-5.

From the graph (Fig. 5) it is seen that the surface tension decreases with an increase in the concentration of alizarin oil: with its concentration from 0.4 g / l to 0.5 g / l, a sharp decrease in surface tension is observed with an increase in the concentration of surfactants. Then, at an oil concentration of 0.5 g / l to 1 g / l, a smooth decrease in surface tension is observed, and starting from a concentration of 1 g / l, the addition of a surfactant changes the surface tension slightly.

Distinctive features of the method provided by the presence of complexones, an acid corrosion inhibitor and a surfactant are:

- the ability to effectively carry out the process of removing deposits from unalloyed carbon steels in the pH range of 4-5 while minimizing the amount of inorganic acids and improving the wettability of deposits by additives of alizarin oil;

- reduction of risks of corrosion losses when using PKU;

- the formation of soluble complexes of EDTA (or HEDP) with calcium, iron (II, III), magnesium ions in the process of removing deposits, accelerating the cleaning process of the metal surface.

Claims (3)

1. A method of removing scale-corrosion deposits based on calcium, iron, magnesium, iron oxides and hydroxides from metal surfaces of carbon unalloyed steels, including etching the deposits with a cleaning solution containing complexon and an acid mixture containing hydrochloric acid at constant pH and temperature and subsequent washing of the surface with running water, characterized in that the etching is carried out in a solution containing additional acid corrosion inhibitors in the form of a condensate tion hexamine and ethanolamine chloride gasoline (PKU) and alizarin oil in a weakly acid medium, and phosphoric acid and acid mixture having pH 4-5, with the components of the solution taken in the following ratio, g / l:
hydrochloric acid 10-15 orthophosphoric acid 10-15 complexon not less than 3-5 in the form of ethylenediaminetetraacetic acids (EDTA) or 1-hydroxyethylidene diphosphonic acids (HEDP) PKU 0.5-1 alizarin oil 0.4-1 water rest 2. The method according to p. 1, characterized in that the etching is carried out in the bath while stirring the cleaning solution. 3. The method according to p. 1, characterized in that the etching is carried out when pumping the cleaning solution inside the washing circuit.

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