RU2530883C2 - Washing composition for purification of surfaces of various solid bodies - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: claimed invention relates to a washing composition for purification of the surface of various bodies, which contains sodium metasilicate pentahydrate, sodium tripolyphosphate, sodium hydroxide, sodium carbonate and SAS, and the composition additionally contains active polyelectrolyte - adduct of prop-2-enamide with sodium prop-2-enate 0.07-2.5 wt %, and as SAS applied is cocamidopropyldimethylamine oxide with the following component in terms of dry residue, %: sodium methasilicate pentahydrate 21.5-29.92; sodium carbonate 20.0-21.0; sodium hydroxide 25.0-35.0; sodium tripolyphosphate 12.0-20.0; cocamidopropyldimethylamine oxide 2.0-12.0; adduct prop-2-enamide with sodium prop-2-enate 0.07-2.5.

EFFECT: extension of spheres of the washing composition application for various different solid surfaces, increase of the washing ability, possibility of regeneration and re-application, as well as an increase of ecological safety with the application of the claimed washing composition.

8 ex, 3 tbl

Description

The invention relates to production processes where detergents with cleaning properties are used: to eliminate soot, dirt, protein grease, scaling on work surfaces in the food, textile, automotive industries, in the field of medicine and veterinary medicine, the removal of conservation oil and lubricating components in the oil refining, aviation - and engineering industries, scaling of various types in the field of chemistry.

Known detergent for cleaning metal surfaces containing a nonionic and / or anionic surfactant, complexing agent and activator of the washing action in the ratio (0.41-1.09) :( 0.11-0.40) :( 1) [ RU 2200188 dated 2000.10.09]. As anionic surfactants, alkyl sulfates, alkyl sulfonates, alkyl phosphates, fatty alcohols with the addition of ethylene oxide and propylene oxide, wetting agents are used. As an activator of the washing action, compounds from a number of borates, silicates, alkali metal carbonates are used.

The disadvantages of the known detergent are limited use - only for cleaning metal surfaces, insufficient washing ability for high molecular weight preservative oils and lubricants, as well as a small possibility of reuse of solutions, which requires their complete replacement.

Known detergent for cleaning a metal surface [RF Patent No. 2291894, 07/07/2005] containing sodium hydroxide, sodium carbonate, sodium metasilicate, sodium tripolyphosphate, ethoxylated monononylphenol based on propylene trimers with 9-12 moles of ethylene oxide and a flocculant in an amount of 0, 1-2.0% wt. The flocculant is a polymer of prop-2-enamide with N, N, N-trimethyl-3 - [(1-oxo-2-propenamino) -propanamine chloride].

The disadvantage of this detergent is the use of an inorganic component of a non-inogen surfactant (with changes in the amount in the composition as above in the above inventions) and a flocculant, which refers to cationic polymers. Cationic products have a greater bactericidal effect than detergents, and are used in most cases as bactericidal agents (Brief chemical encyclopedia "Soviet Encyclopedia", Moscow, 1964, p. 355; chemical encyclopedia, "Big Russian Encyclopedia", M. 1992, p. 1166). Oxyethylated mononylphenol based on propylene trimers with 9-12 moles of ethylene oxide is a carcinogen; in addition, if it enters the environment, it can accumulate in soil, water bodies and affect flora and fauna, cause fish death, disrupt oxygen exchange in water bodies and adversely affect on vegetation in nearby areas.

The closest in technical essence technical solution is a detergent for cleaning a metal surface [RF Patent No. 2134719, 01/08/1998], containing inorganic components, g / l: 6.44-11.04 sodium hydroxide; 1.26-2.16 sodium tripolyphosphate; 5.74-9.84 soda ash; 0.42-0.72 sodium metasilicate; 0,084-0,144 of ethoxylated monoalkyl phenol based on propylene trimmers containing 12 moles of hydroxyethylene in the molecule; 0.056-0.096 oxyethylated monoalkylphenol based on propylene trimers containing 9 moles of oxyethylene in the molecule; and water to one liter.

The disadvantages of the detergent according to this invention are both insufficient washing ability for high molecular weight preservation oils and lubricants, as well as a small possibility of reuse of solutions, which requires their complete replacement. In addition, they are designed to clean metal surfaces. The ethoxylated mononylphenol used in this detergent based on propylene trimers with 9-12 moles of ethylene oxide is a carcinogen, it is not safe for the environment (if it enters the environment, it can accumulate in soil, water bodies and affect flora and fauna, cause fish death, disrupt oxygen metabolism in water bodies and adversely affect vegetation in coastal areas).

The aim of the present invention is to expand the scope of application of detergent compositions for various heterogeneous hard surfaces, increase washing ability, the possibility of regeneration and reuse, as well as improving environmental safety when using this washing composition.

The proposed new detergent composition contains pentahydrate sodium metasilicate, sodium tripolyphosphate, sodium hydroxide, sodium carbonate, cocamidopropyl dimethylamine oxide and anionic adduct of prop-2-enamide with prop-2-enoate of sodium in an amount of 0.07-2.5 wt. %, The total composition of the detergent composition in terms of dry residue is as follows:

5-Sodium Metasilicate  21.5-29.92% Sodium carbonate  20.0-21.0% Sodium hydroxide  25.0-35.0% Sodium Tripolyphosphate  12.0-20.0% Cocamidopropyl Dimethylamine Oxide 2.0-12.0% The prop-2-enamide adduct with sodium prop-2-enate 0.07-2.5%

In this composition, instead of the cationic product of oxoethylated mononylphenol based on propylene trimers containing 9-12 moles of hydroxyethylene and a cationic polymer of prop-2-enamide with N, N, N-trimethyl-3 - [(1 oxo-2-propenamino) -propanamine chloride] , a highly active polyelectrolyte is used - the adduct of prop-2-enalide with prom-2-sodium eonate in an amount of 0.07-2.5 wt.%. The use of a smaller (0.07% wt.) Amount of polyelectrolyte in the composition does not give a high detergent effect, the use of more than 2.5% wt. quantity becomes economically impractical.

The use of this adduct gives a complete and clear separation of the height of the soluble product of the solution and dirt and allows the solution to be decanted and separated from the substandard (dirty, unnecessary) product, followed by its disposal, while the working solution returns to the cycle, increasing its total time work. In physical properties, the anionic component has a lower bulk density and dynamic viscosity than the cationic one. We believe that a lower bulk density increases mass transfer in the solid-solid system, and low dynamic viscosity increases the interface in the liquid-solid system. Cocamidopropyl dimethylamine oxide is proposed as a surfactant. The ratio of the components of the optimal washing composition in terms of a solution (1.2-1.5 wt.% Water), wt.%:

Sodium pentas metasilicate  19.7 Sodium hydroxide  20.7 Tripolyphosphate  19,4 Sodium carbonate  21,2 Cocamide propyl dimethylamine oxide  1.8 Sodium prop-2-enamide-2-enate adduct  1,5 The rest is water  Up to 100

The following examples illustrate the invention, but do not limit it.

Example 1

157.6 kg of pentahydrate sodium metasilicate are loaded into a mixing reactor equipped with a belt-vane conveyor with stirring 89.8 kg of sodium tripolyphosphate, 157 kg of sodium hydroxide, 118 kg of sodium carbonate, 37.3 kg of cocamidopropyl dimethylamine oxide (surfactant), 98, 5 kg of water and 2.2 kg of polyelectrolyte. After stirring for 5 minutes, the reaction mass is discharged into a washer (bath with a circulation of the reaction mixture along the circuit using a centrifugal pump of the TsNG type) with a capacity of 3.2 m ³ . Pipes from the Pervouralsk Pipe Plant with canned oil and lubricants are placed in the washing machine. The results are shown in table 1.

Example 2

152 kg of sodium pentas metasilicate, 101 kg of sodium tripolyphosphate, 169 kg of sodium hydroxide, 112 kg of sodium carbonate, 27 kg of surfactant, 98 kg of water and 1 kg of polyelectrolyte are loaded into the mixing reactor. After mixing, the contents of the reactor are loaded and sent to a washer. The results are summarized in table 1.

Example 3

142 kg of pentahydrate sodium metasilicate, 68 kg of sodium tripolyphosphate, 187 kg of sodium hydroxide, 118 kg of sodium carbonate, 45 kg of surfactant, 7 kg of polyelectrolyte are loaded into the mixing reactor, mixed and sent to the washer after mixing. These results are presented in table 1.

Example 4

165.6 kg of sodium pentas metasilicate, 70 kg of sodium tripolyphosphate, 142.8 kg of sodium hydroxide, 114 kg of sodium carbonate, 68.6 kg of surfactant, 10 kg of electrolyte and 89 kg of water are loaded into the mixing reactor. Stirred and after mixing sent to the washer. These results are presented in table 1.

Example 5

128 kg of sodium pentas metasilicate, 114.8 kg of sodium tripolyphosphate, 177.7 kg of sodium hydroxide, 114 kg of sodium carbonate, 26 kg of surfactant, 12 kg of electrolyte and 88 kg of water are loaded into the mixing reactor. Stirred and the reaction mass is sent to the washer. These results are presented in table 1.

Example 6

The reactor-mixer is charged with 143 kg of pentahydrate sodium metasilicate, 86 kg of sodium tripolyphosphate, 190 kg of sodium hydroxide, 121 kg of sodium carbonate, 20.8 kg of surfactant, 14 kg of polyelectrolyte and 86 kg of water. After stirring, the contents of the reactor are sent to a washer. The data are summarized in table 1.

Example 7

132 kg of sodium pentas metasilicate, 100 kg of sodium tripolyphosphate, 157 kg of sodium hydroxide, 114.8 kg of sodium carbonate, 56.6 kg of surfactant, 0.46 kg of polyelectrolyte and 86 kg of water are loaded into the mixing reactor. After stirring, the contents of the reactor are sent to a washer. The data are summarized in table 1.

Example 8

163 kg of sodium pentas metasilicate, 78.6 kg of sodium tripolyphosphate, 162.8 kg of sodium hydroxide, 117 kg of sodium carbonate, 39.6 kg of surfactant, 0.55 kg of polyelectrolyte and 86 kg of water are loaded into the mixing reactor. After stirring, the contents of the reactor are sent to a washer. The data are summarized in table 1.

Washing from oil and lubricants from the Pervouralsk Pipe Plant was carried out at OJSC “Surgutneftegas”.

The results of the above examples in table 1.

Table 1

No. of an example of a payment order The volume of the washing machine, m ³ The concentration of the solution, wt.%. The temperature of the solution in the machine, ° C The number of loaded pipes, pcs. Washing time, min The total operating time of the solution until it is completely replaced, hour one 3.2 1,5 70/60 fourteen 12 98 2 3.2 1,5 70/60 fourteen eleven 95 3 3.2 1,5 70/60 fourteen eleven 96 four 3.2 1,5 70/60 fourteen eleven 96 5 3.2 1,5 70/60 fourteen eleven 98 6 3.2 1,5 70/60 fourteen 10.5 98 7 3.2 1,5 70/60 fourteen 13 97 8 3.2 1,5 70/60 fourteen eleven 96 prototype 7.6 1.8 70 12 15-20 40-82

From the analysis of the results it is clear that the present invention is superior to the prototype, i.e. the use of a cationic product with a washing ability of 1.36-1.82 times and the total operating time of the detergent 1.15-1.20 times. The optimal amount of polyelectrolyte = 0.07-2.5 wt.%.

At JSC Halopolimer, work was carried out to determine the washing ability of the anionic adduct with the prototype to compare the washing properties. The tests were carried out by washing sludge from polyethylene pipes in the sewer of a mixture of hydrofluoric, hydrochloric acids, salts of fluoride and sodium chloride. The tests were carried out by dipping in a closed system. For testing, solutions of anionic detergent compositions with a concentration of 8 g / l and cationic detergent with a concentration of 10 g / l were prepared. Rinsing of polyethylene pipes by dipping with stirring with compressed air was carried out for 10 minutes. At a temperature of anionic composition 40-45 ° C, cationic (prototype) at a temperature of 60-65 ° C. Surface cleanliness was determined by the gravimetric method. The test results are summarized in table 2.

table 2 No. p / p The name of indicators Anionic composition Cationic composition one Appearance Clear liquid Clear liquid 2 Concentration, g / l 8 10 3 PH 12.7 12.7 four Flushing method Stir dipping Stir dipping 5 Flushing temperature 40-45 60-65 6 Surface cleanliness, ml / cm 0.002 0.005

Mixing was carried out by sparging with dry air under a layer of liquid. Tests have shown that the anionic detergent composition has a better detergency than a cationic detergent.

Also, OJSC Halopolimer tested polypropylene filters from liquid hydrogen fluoride pipelines to remove mechanical impurities (rust, scale, oxidation products, etc.) before feeding it into the reactor. The tests were carried out in a closed system with stirring with compressed nitrogen. Data on filter cleaning according to the methodology of VNIIPKNeftekhim (fingerprint method) are summarized in table 3.

Table 3 No. p / p Test Composition Concentration Filter Appearance one Anionic composition 3 g / l 1 filter -6 red spots ø <1 mm 5 red spots ø> 1 mm
2 filter -1 red spot ø <1 mm 5 red spot ø> 1 mm 2 Anionic composition 5 g / l 1 filter -3 red spots ø <1 mm 1 red spot ø> 1 mm
2 filter - 2 red spots ø <1 mm 5 red spots ø> 1 mm 3 Anionic composition 7 g / l On two filters, 3 red ø> 1 mm each four Anionic composition 10 g / l No lesions 5 Cationic composition 10 g / l 1 filter - 4 red spots ø> 1 mm
2 filters - 6 red spots ø> 1 mm 6 Cationic composition 20 g / l No lesions

The table shows that the washing ability of the anionic composition is higher than that of the cationic one.

Thus, the proposed composition in its washing ability is superior to known. The ratio of the components of the optimal washing composition in terms of a solution (1.2-1.5 wt.% Water), wt.%:

Sodium pentas metasilicate  19.7 Sodium hydroxide  20.7 Tripolyphosphate  19,4 Sodium carbonate  21,2 Cocamide propyl dimethylamine oxide  1.8 Sodium prop-2-enamide-2-enate adduct  1,5 The rest is water  Up to 100

Claims (1)

Detergent composition for cleaning the surface of various solids, containing sodium pentasodium metasilicate, sodium tripolyphosphate, sodium hydroxide, sodium carbonate and surfactant, characterized in that the composition further comprises an active polyelectrolyte - adduct prop-2-enamide with prop-2-enate sodium 0, 07-2.5 wt.%, And cocamidopropyl dimethylamine oxide is used as a surfactant in the following ratio of components, calculated on the dry residue,%:
5-Sodium Metasilicate 21.5-29.92 Sodium carbonate 20.0-21.0 Sodium hydroxide 25.0-35.0 Sodium Tripolyphosphate 12.0-20.0 Cocamidopropyl Dimethylamine Oxide 2.0-12.0 The prop-2-enamide adduct with sodium prop-2-enate 0.07-2.5