RU2502794C1 - Mixed solvent for cleaning apparatus for airless spraying of polyurethane and polyurea mastic compounds - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: described is a mixed solvent which contains a mixture of aromatic hydrocarbon solvents - toluene and/or xylene and/or solvent and organochlorine solvents - trichloroethylene and/or perchloroethylene, and additionally as a detergent and simultaneously passivating (anticorrosion) additive - fatty acids of tall oil or plant oil, having acid number less than 170 mgKOH/g, with the following ratio of ingredients, wt %: toluene and/or xylene and/or solvent - 40-45; trichloroethylene and/or perchloroethylene - 45-50; fatty acids of tall oil or plant oil - 5-10.

EFFECT: obtaining an incombustible mixed solvent with high efficiency of detergent action when removing remains of highly viscous components of polyurethane and polyurea mastic compounds, having preservation action on carbon steel.

1 cl, 4 tbl

Description

To apply a number of high-viscosity paints, varnishes, and sealants to the protected objects, the method of "hot" airless application is widely used, for which high-pressure installations (P up to 30 MPa) are used for airless spraying of one- or two-component compositions manufactured by GRACO (USA ) and WIWA (Germany).

Installations for airless spraying of two-component materials (polymer base + hardener) contain independent material paths for each of the components for their supply to the spray device (paint sprayer). Each path includes a feed pump, a hose for supplying and circulating a component, a material pump of a unit with a flow heater, containing channels and cavities, a high pressure hose (sometimes up to 50 m long) that provides a heated component (up to 60-80 ° C) directly to spray gun nozzle [1].

At the end of work and after changing the sprayed paint and varnish material, the internal paths of the airless spraying unit are cleaned of residual components, which is carried out, as a rule, by pumping through them an organic solvent recommended by the technological regulations [1, p. 88; 2], and in some cases, with a long shutdown of the installation, it is canned.

Polyurethane and polyurea two-component mastics consist of a polymer base - an urethane prepolymer with terminal NCO-groups - and an amino-hydroxyl-containing hardener, fed through separate paths and mixed in a spray gun in the chamber immediately in front of the nozzle.

The present invention relates to compositions of technical detergents based on organic solvents intended for cleaning the internal paths of airless spraying plants of high viscosity polyurea and polyurethane mastics with separate supply of components used for corrosion protection of various structures and structures.

Individual organic solvents of almost any chemical nature are ineffective when cleaning equipment from residues of components of polyurethane and polyurea paint systems, especially from residues of highly viscous polar urethane prepolymers, since the latter are poorly soluble in them and require a long exposure time, which is difficult to implement when washing airless spraying plants . Therefore, as a rule, mixed organic solvents are used to clean equipment from residues of urethane materials. So, it is known to use the mixed organic solvent R-189 (TU 6-10-1508-75) for the removal and dissolution of polyurethane and uralkid paints and coatings [3, p. 71]. This solvent contains the following ingredients, wt.%:

ethylene glycol acetate 37.0 methyl ethyl catone 37.0 xylene 13.0 butyl acetate 13.0

However, the known mixed solvent is ineffective for dissolution with the aim of subsequent removal of high-viscosity urethane prepolymers from equipment containing internal channels and cavities of great length. In addition, the R-189 solvent is flammable, has a flash point of less than 10 ° C, which classifies it as a flammable liquid (LVH).

Closest to the claimed technical essence and formulation is the mixed solvent R-14 (TU 6-10-1509-75), designed to dissolve polyurethane resins containing equal amounts of toluene (50%) and cyclohexanone (50%) [4, p.186, prototype].

The prototype composition, as the previous mixed solvent, belongs to the category of flammable liquids, which imposes certain requirements and limitations on the technology of its use. It is also ineffective when removing the highly viscous components of polyurethane mastics from the equipment with a large length of internal channels and cavities by the flow method.

The problem to be solved within the framework of the present invention is the creation of a non-combustible mixed solvent formulation that efficiently cleans the residues of high-viscosity urethane prepolymers of an airless spraying unit by the flow method, while simultaneously acting as a preservative of this equipment during its long-term storage.

This task / result is achieved due to the fact that the proposed mixed solvent, intended for cleaning airless spraying units from the remains of polyurethane and polyurea mastics, contains a mixture of aromatic hydrocarbon solvents - toluene and / or xylene and / or solvent and organochlorine solvents - trichlorethylene and / or perchlorethylene and additionally as a detergent additive - tall oil fatty acids (GLC) or vegetable oil fatty acids (LCFM) with an acid number of at least 170 mg KO / G, acting as preservative equipment simultaneously, with the following ratio between the solvent ingredients wt.%:

toluene and / or xylene and / or solvent 40-45 trichlorethylene and / or perchlorethylene 45-50 tall fatty acids or vegetable oils 5-10

Hydrocarbon aromatic solvents use technical qualifications in accordance with existing standards:

toluene oil according to GOST 14710-78 xylene according to GOST 9949-76 oil solvent according to GOST 10214-78

Chlorine-containing solvents - trichlorethylene and perchlorethylene also use technical qualifications according to GOST 9976-94 and TU 6-01-956-86, respectively.

ZhKTM and ZhKRM are used in accordance with the requirements of GOST 14845-79 and TU 9145-003-70316851-2007, while fatty acids having an acid number (r.h.) of less than 170 mg KOH / g are of little use due to the low washing efficiency actions as part of a mixed solvent.

The claimed amounts of ingredients in the composition of the mixed solvent are optimal and determined experimentally. The use of less than 45% three chlorethylene and perchlorethylene transfers the proposed mixed solvent from the class of non-combustible liquids to the class of combustible liquids (GF) and a flash point of more than 61 ° C.

The amount of GIT and LCRM is less than 5% ineffective, and more than 10% is impractical due to a decrease in the solubility of the solution composition with respect to the highly viscous components of polyurethane and polyurea systems.

The production of a mixed solvent can be carried out on standard chemical equipment of a capacitive type with a mechanical mixing device at ambient temperature by the usual mixing of all components to obtain a transparent homogeneous solution.

Due to the low volatility (volatility) and the passivating effect of the GIT and LCRM in relation to carbon steel, thin wall films of fatty acids are formed on the inner surfaces of the material tracks of airless plants when they are washed with a solvent, which impede the access of atmospheric moisture to the metal, thereby preserving it.

Comparison of the proposed mixed solvent formulation with known analogs allows us to conclude that it meets the criterion of "Novelty", as a new set of ingredients has been compiled. Although the use of individually aromatic hydrocarbons and chlorine-containing solvents for the cleaning of machines and mechanisms is known, their composition in the claimed range of component concentrations in combination with those used to increase the washing effect of GIT and LCM is proposed for the first time.

The combination of these innovations led to positive effects - the production of a non-combustible mixed solvent with high washing efficiency when removing residues of highly viscous components of polyurethane and polyurea mastics, which, among other things, has a preservative effect in relation to carbon steels. The above indicates that the proposed technical solution meets the criterion of "Inventive step".

All components of the mixed solvent are of domestic production, the technology for its preparation is simple and affordable and is based on the use of standard chemical equipment. This allows you to make a reasonable conclusion about the conformity of the proposed technical solution to the criterion of "Industrial applicability".

The technical nature and advantages of the proposed mixture composition is illustrated by the following examples.

EXAMPLE 1

Table 1 shows the formulations of the prototype solvent and the variants of the proposed mixed solvent, and table 2 shows the comparative results of determining their washing efficiency with respect to the Forpol-NCO urethane prepolymer (TU 2458-095-20504464-2005) with a viscosity of 9 8 Pa · s at (20 ± 1) ° C. The solvent washing efficiency was evaluated by the photocolorimetric method using an FEK-M photoelectric colorimeter for the completeness of dissolution of the prepolymer in solvents, determined by the turbidity spectrum by comparing the light transmission coefficients of pure solvents (T,%), and prepolymer solutions: pure solvents and true polymer solutions are transparent and have visible transmittance close to 100%. Colloidal solutions of incompletely dissolved polymers are turbid and such a suspension has a light transmission coefficient of less than 100% up to 0% [5].

Table 1 Component Name The content of the solvent, wt.% Prototype Composition one 2 3 four 5 6 7 8 9 10 Toluene fifty 40 - - twenty twenty - fifteen fifty - 23 Cyclohexanone fifty - - - - - - - - - - Xylene - - 45 - twenty - 22.5 fifteen - 45 - Solvent - - - 45 - twenty 22.5 fifteen - - twenty Trichlorethylene - fifty - - 25 thirty 25 twenty 40 - 45 Perchlorethylene - - fifty 45 25 twenty 25 25 - 52 - GIT with c.h. = 190 mg KOH / g - 10 - - 10 - 5 - - - 12 ZhKRM with k.ch. = 172 mg KOH / g - - 5 10 - 10 - 10 10 3 -

table 2 №№ Solvent compositions from table 1 The transmittance of the solutions of the urethane prepolymer "Forpol-NCO", (T),% Flash point in a closed crucible, ° C Prototype Composition 46.2 +13.9 (LVH) one 98.1 Incombustible 2 99.5 Incombustible 3 97.8 Incombustible four 99,2 Incombustible 5 99.0 Incombustible 6 98.3 Incombustible 7 98.7 Incombustible 8 96.0 +161 (GJ) 9 84.0 Incombustible 10 97.5 Incombustible

EXAMPLE 2

Table 3 shows the amount of solvents used to flush the ForpolOil prepolymer path (TU 2458-125-20504464-2009) of the WUWA DUOMTX-230 airless spray unit (feed hose length 30 m). The completeness of the washing of the installation was controlled refractometrically using an IRF-454B2M refractometer: when the refractive index (nD 20) of the spent solvent became equal to the value nD 20 of the initial mixed solvent, the equipment cleaning process was considered completed.

Table 3 №№ Solvent compositions from table 1 The amount used for washing the mixed solvent, DM ³ Prototype Composition 118 * one twenty 2 17 3 22 four twenty 5 21 6 eighteen 7 22 8 31 9 fifteen 10 28

Note: The prototype composition did not completely remove the remains of the urethane prepolymer from all the cavities of the internal duct of the DUOMIX-230 installation: traces of the prepolymer remained on the valves and in the inaccessible cavities on the surface, which eventually polymerized under the influence of air moisture to form an insoluble polychole, which can only be removed mechanically or thermally.

EXAMPLE 3

Metal plates 150 × 70 × 0.8 mm in size made of carbon steel St.3 with a ≈ 1 mm thick layer of the Forpol-NCO prepolymer layer were subjected to cleaning by washing using a number of mixed solvents, the composition of which is given in Table 1. After that, the cleaned plates were placed in a desiccator at a temperature of (20 ± 1) ° С, the atmosphere of which had 100% relative humidity. Table 4 shows the data on the change in the appearance of the plates (visually) at various exposure times.

Thus, as can be seen from the experimental data given in Tables 2-4, the inventive formulation of the mixed solvent due to the optimization of the component composition and the use of new detergents that exhibit non-obvious properties of the preservative of metal surfaces (passivation), allowed to obtain non-combustible (fire and explosion safe when used) a mixed solvent having higher efficiency in the process of cleaning airless spray units from residues and traces of highly viscous components (urethanes th prepolymers) polyurethane and polyurea mastics.

Information sources

1. Gots V.L., Larin A.V. Modern paint and varnish equipment. Spraying methods. Practical Guide. - M.: Publisher "Paint Media", 2005. - 174 p.

2. Bedrik B.G., Chulkov P.V., Kalashnikov S.I. Solvents and compositions for cleaning machines and mechanisms. Directory. - M .: Chemistry, 1989 .-- 176 p.

3. Drinberg S.A., Itsko E.F. Solvents for paints and varnishes. Handbook-L .: Chemistry, 1986. - 208 p.

4. Popilov L.Ya. Advice to a factory technologist. Reference manual. - L .: Leniz-dates, 1975. - 264 p. (Prototype).

Claims (1)

A mixed solvent for cleaning airless spraying systems of polyurethane and polyurea mastics, containing a mixture of aromatic hydrocarbon solvents and organochlorine solvents, characterized in that it contains toluene and / or xylene and / or solvent as an aromatic hydrocarbon solvent, and trichloethylene as an organochlorine solvent and / or perchlorethylene, and additionally as a detergent and preservative, it contains tall oil fatty acids or fatty acids grows edible oils having an acid number of more than 170 mg KOH / g, in the following ratio between components, wt.%:
toluene and / or xylene and / or solvent 40-45 trichloethylene and / or perchlorethylene 45-50 tall fatty acids or vegetable oils 5-10