RU1813800C - Agent for metallic surface cleansing - Google Patents

Abstract

Usage: cleaning of metal surfaces, in particular tanks of steel and aluminum alloys from oil pollution and tar deposits. The inventive composition for cleaning contains, wt.%: Alkali metal hydroxide 12-22, sodium phosphate 6-12, sodium carbonate 25-56, nonionic surfactant 5-9, polyacrylamide 0.5-1.5 and dry residue sulfate runoff production of FFA to 100. 1 tab.

Description

The invention relates to detergents used to clean a metal surface, in particular tanks of steel and aluminum alloys, from oily contaminants and tar deposits.

The purpose of the invention is to increase the washing ability of an agent.

The addition of a mixture of polyacrylamide with sodium sulfate (containing 6% of unidentified products of heat treatment of sodium salts of low molecular weight acids) in combination with other components provides an increase in the washing ability of the composition. In addition, the electrostatic charge of droplets in the vapor-air smsi resulting from the cleaning of oil tanks is reduced.

The metal surface cleaning agent contains, wt.%: Alkali metal hydroxide 12-22, sodium phosphate 6-12, sodium carbonate 25-56, nonionic surfactant 5-9, polyacrylamide 0.5-1.5, dry residue sulphate runoff production of FFA to 100.

The claimed tool differs from the known one by the introduction of new components - the dry residue of sulfate runoff from the production of FFA and polyacrylamide at a certain ratio of all components.

The dry residue of sulfate runoff produced by FFA - granular sodium sulfate (TU 38.10742-78) is characterized by the following composition, wt.%:

ioo

I-

CA 00 O

ABOUT

Sodium sulfate 33.0 Sodium carbonate 3.0 Sodium chloride 1.6 Water 1.0 Unidentified residue 6.0 Polyacrylamide (TU 6-16-2531-81) - a white powder, readily soluble in water.

The addition of polyacrylamide and sodium sulfate in combination with other components reduces the electrostatic charge of droplets of the vapor-air mixture formed during the jet cleaning of oil tanks and also increases the washing action of the solution.

Example 1. To prepare a metal surface cleaning agent, a mixture is prepared containing 5 wt.%, Neonol AF 9-12, 12 wt.% Sodium hydroxide, 6 wt.% Sodium tripolyphosphate, 25 wt.% Sodium carbonate, 0.5 wt.% polyacrylamide, up to 100 wt.% dry residue sulfate runoff production of FFA.

The mixing of the components is carried out in the following order:

sodium carbonate, dry sulphate effluent from FFA production, polyacrylamide and sodium phosphate are charged into the mixer. The components are mixed, alkali metal hydroxide is added and, while mixing is continued, a non-ionic surfactant is supplied through a spray nozzle. A free-flowing white powder is obtained with interspersed granules of dark brown color.

The proposed composition is recommended to be used in the form of 2% aqueous solutions at a temperature of 20-80 ° C using jet-type machines, as well as submersible-type machines.

In order to test the plates with the size of 10 mm diameter of aluminum alloy Amg 2 or steel St.Z, a gear oil of grade 3 is applied (nigrol, TU 38.101-521-75). The prepared plates are cleaned in a laboratory jet washing machine with 2% aqueous solution at 80 ° C for 5 s. The washing ability (in mg / cm2. S) is determined by the formula

Rnach - RKON

S-5

where is rnach. - mass of the plate with pollution before cleaning, mg;

Rcon. - the mass of the plate after cleaning, mg;

S is the surface area of the plate,

cm

Additionally, the oil tank (V 200 m3) is cleaned with a 2% solution of detergent using an MN-2/11 jet washer. The jet length of the washing solution at constant pressure and the intensity of the electrostatic air-vapor mixture are determined by the method of the Central Research Institute of the Marine Fleet.

The test results of the proposed tool:

jet length 16 m, electrostatic field strength 600 V / m. Positive results were also obtained when cleaning plates from steel of the grade St.Z.

Examples 2-6. The preparation of the metal surface cleaning agent and its testing are carried out under the conditions of Example 1, changing the ratio of components in the composition.

The results are shown in the table.

Example 7 (known prototype composition). The composition and test results are shown in the table.

From the data given in the table it follows that, with an optimum ratio of components, the inventive product surpasses the known detergency. In the process of cleaning the tank with the MN-2/11 washer, it was noted that the transition to a turbulent regime of jet expiration occurs at a higher rate

sti of supply of the washing solution. At

With the same pump performance, the inventive tool provides the formation of a more compact jet, which is expressed in an increase in jet length (see

0 table), the separation of pollution from the surface of the tank is facilitated, and the efficiency of pumps and flow parts of technological equipment is increased.

5 The intensity of the electrostatic field of the vapor-air mixture generated during the cleaning of the tank behind the detergent solution is two times lower than during the cleaning with the known solution, which ensures the safety of the cleaning technology. surfaces, reduce the energy consumption of the process of cleaning tanks from

5 residues of petroleum products. In addition, the composition of the proposed product includes up to 30% of the dry residue of sulfate runoff, which is a waste product of the production of synthetic fatty acids and which does not currently have qualified use.

Form of invention

A tool for cleaning the metal surface of predominantly steel and aluminum alloy tanks from oil pollution and tar deposits, containing alkali metal hydroxide, sodium phosphate, sodium carbonate and a nonionic surfactant, characterized in that, in order to increase the washing ability, it additionally contains polyacrylamide and a dry residue of sulfate runoff

production of synthetic fatty acids (FFA) in the following ratio of components, wt.%:

Alkali metal hydroxide Sodium phosphate Sodium carbonate Nonionic surfactant Polyacrylamide Solids sulphate runoff produced by FFA

12-22

6-12

25-56

5-9 0.5-1.5

Up to 100

Comparative test data for the compositions