EA008025B1 - Composite decorative-protection coating - Google Patents

Abstract

The invention relates to building and industrial production and can be used as finishing material for interior and exterior finishing of buildings and structures, as well as for protection of ground, water and air transport means and different technological and auxiliary equipment.Composite decorative-protection comprises aqueous polymer dispersion as a binder and structured filler as hollow vacuum microspheres. According to invention the coating comprises a filler from sodium/potassium/borosilicate glass or metal oxides and amounts to 3.0-74.0 vol. %. The microspheres have the outer diameter 5.0-10.0 mkm with wall thickness 0.25-10.0 mkm and vacuumized to 0.1-0.15 atm.The microspheres comprise alumina, silicon, zirconium or molybdenum oxides as metal oxides and have bulk density 0.1-1.0 g/cm.The coating comprises acrylic copolymer or emulsion, or butadiene-styrene emulsion, or polyvinyl acetate dispersion.

Description

Application area

The invention relates to the field of construction and industrial production and is intended for use as a finishing material for interior and exterior decoration of buildings and structures, as well as for protecting surfaces of land, water and air vehicles and various technological and auxiliary equipment.

State of the art

Known thermoplastic composition for marking the roadway (1). The composition includes a film-forming solid polyester resin, a plasticizer based on a complex of polyester (C ₄ or more) aliphatic dibasic acids and (Cz-C5) aliphatic glycols with an acid number from 0 to 80 mg / KOH, titanium dioxide, anti-sedimentation additive, glass beads mineral filler (for example, silica sand, crushed glass, carbonates, etc.) and additionally one or more synthetic waxes in an amount of 0.02-1.5 wt.h. per 100 parts by weight composition, parts by weight:

Polyester Resin 15.0-30.0

Plasticizer 2.0-8.0

Titanium dioxide 4.0-10.0

Anti-sedimentation supplement 3.0-10.0

Glass beads 0-30.0

Mineral filler Else

In a known composition, glass beads are made whole, which increases the density and thermal conductivity of the coatings and does not allow them to be used as protective thermal insulation elements of building structures or other industrial facilities.

Known building structure with a protective coating to reduce heat loss (2). The building construction system contains a porous, well-permeable water vapor coating on both sides. The coating structure includes an aqueous acrylic emulsion filled with ceramic-based microspheres. Such a coating is not prone to surface swelling (bubble formation) and prevents the direct penetration of moisture into the pores of the building element and the manifestation of the associated heat loss from evaporation of moisture.

A composition for a thermal protective coating based on a translucent polyorganosiloxane resin (3) is also proposed. The composition contains:

A: 100 vol. polyorganosiloxane resin;

B: 1.0-10.0 vol.h. the composition has at least one halogen atom selected from the group of bromine and chlorine;

C: from 10 to 100 vol.h. glass microspheres having an average size of from 5.0 to 100 microns.

The weight ratio of the described mixture to glass particles (microspheres) ranges from 0.05 to 4.0.

The composition is intended for external coating of building materials in order to protect against heating by solar radiation.

Known energy-saving paint "TNEKMO-8N1ESH", which is selected as a prototype (4, 5). The paint is prepared on an aqueous dispersion of a polymer of acrylic resin as a binder, into which a filler of glass or ceramic hollow microspheres is introduced, as well as pigments and other components inherent in the paint (stabilizers, plasticizers, etc.). The microspheres is a free-flowing powder consisting of thin-walled (0.5-2.0 μm) spherical particles with a diameter of 10-150 μm with a bulk density (0.2 g / cm ³ ). The surface of the coating has an increased roughness, and its structure is characterized by high vapor permeability and can reduce heat loss by 30%.

A disadvantage of the known coating is a narrow scope due to the use of exclusively acrylic resin polymer and low heat-shielding properties due to the low quality of the structured filler, which is due to its dispersion, the chemical composition of the material of the microspheres (low-grade glass) and their physical condition.

The aim of the invention is to expand the range of coatings and increase their heat-shielding characteristics.

The technical result of the invention is to increase the range of coatings through the use of a wider range of binders and microspheres from other materials - from metal oxides, as well as improving the technical characteristics of protective coatings by imparting a compound based on microspheres with improved optical properties in the range of 5-75 microns.

Disclosure of invention

This goal is achieved in that the composite decorative protective coating containing an aqueous dispersion of a polymer as a binder and a structured filler in the form of hollow evacuated microspheres, according to the invention, contains filler of potassium borosilicate glass or metal oxides in an amount of 3.0-75.0 vol. %, while the microspheres are made with an outer diameter of 5.0-200.0 μm with a wall thickness of 0.25-10.0 μm and are evacuated to a pressure of 0.1-0.15 atm.

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Microspheres as metal oxides mainly contain oxides of aluminum, or silicon, or zirconium, or molybdenum.

The microspheres are made with a bulk density of 0.1-1.0 g / cm ³ .

As an aqueous dispersion of the polymer contains an acrylic copolymer or emulsion, or styrene-butadiene emulsion, or polyvinyl acetate dispersion (PVA dispersion).

Brief description of the figure

The invention is illustrated by the drawing, which shows the structure of the composite decorative protective coating.

The coating, after application to the base 1 (wall or surface of technological equipment) and curing, consists of microspheres 3, evenly distributed in a matrix of polymer binder 4, has a rough surface 2 and a characteristic average thickness ά.

The best embodiment of the invention

The invention is implemented as follows. One or another composition of the composition is prepared depending on the necessary indicators for a specific application area of the coating (for example, for indoor painting, for applying to the outer surfaces of structures, etc.). The cooking technology is applied standard using traditional equipment used in the paint and varnish production. Microspheres 3 are prefabricated with specified parameters, then they are mixed in an amount by volume from 3 to 75% with a polymer binder 4, and the appropriate particle size distribution is selected to ensure a given radiation pattern from the surface of the protected object. The finished composition is applied with a roller or brush to the surface of the substrate 1, for example, walls and dried in the mode according to the technical requirements for this type of binder. After curing, the coating is ready for use.

The technical result is achieved due to the fact that the properties of the components of the composition suppress the radiation component of heat loss by more than 50%, which is on average 20% higher than that of the prototype. This effect is achieved by optimizing the optical and thermophysical characteristics of the coating components by appropriate combination of the type of binder and filler in the composition, namely, by choosing the material of the microspheres and their parameters (diameter, shell thickness, degree of evacuation, bulk density, particle size distribution), which provides predominant reflection and scattering of low-temperature infrared radiation. So, with an average diameter of microspheres of 35 μm and their concentration in the composition layer I = 2.5-10 ¹² m ^-3 with a distance between particles of ~ 40 μm, the emissivity of the wall surface coated with the composition on a clear, windless night at a temperature of T _a = -20 ° C is ε „= 0.35. The most significant decrease in the radiation flux (ceteris paribus) is observed when there is an energy exchange between the coating and directly with the sky. In this case, the quantitative heat-shielding effect of the composite decorative protective coating, due to the physical principle of its operation, substantially depends on the optical properties of the substrate (for example, wall material), the environment, and the temperature regime of operation. So, the integral reflection coefficient ρ on a horizontal platform in the range of 0.37-0.76 μm, in a closed environment, taking into account the daily visibility function of a standard observer in shares of a light source, reaches ρ = 66%. The use of such a coating, for example, in a room with a window, provides a general increase in illumination in the room of about 4%, while the thermal resistance of the ceiling is increased by ~ 0.5 m ² - ° K / W.

A distinctive feature of the new coating is a low coefficient of water absorption and good vapor permeability. Such properties provide quick drying of structures protected by such a coating, and keep them in this state throughout the heating period, which leads to a significant reduction in heat loss (up to 9%).

Energy saving, depending on the type of coating used, ranges from 16.7% (cardboard base) to 27.7% (foam base).

Industrial applicability

The table shows data on the effect of the type of coating applied to different types of substrates on the integrated reflection coefficient of the surface to be protected, illustrating the technical result and industrial applicability of the invention.

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No. p / p Type of coating Integral reflection coefficient,% Uncoated Base The content of microspheres in the coating,% 3 fifty 75 one 2 3 4 5 6 one. Uncoated base: - Styrofoam 1 - 2 cm thick - Cement-sand mortar (with capillary moisture of masonry 2 - 6%) - Ceramic brick (density 1750.0 kg / m ³ ) - Silicate brick (density1990.0 kg / m ³ ) - cellular concrete (density - 570, Okg / m ³ ) - cardboard, 1 mm thick 6.0-8.0 6.0 8.0 8.0 8.0 - - - 2. Filling: mycosophas from sodium potassium borosilicate glass Binder: acrylic copolymer or emulsion + other components - the rest Base: cement-sand mortar - 12 65 55 3. Filling: mycosophas from sodium potassium borosilicate glass Binder: butane-styrene emulsion + other components - the rest; coating thickness - 0.3 mm Base: polystyrene, thickness. 1 cm nine 62 53 4. Filling: mycosophas from sodium potassium borosilicate glass Binder: PVA dispersion + other components - the rest Basis: silicate brick - 12.5 66 57 5. Filling: MikoosPheoi from alumina Binder: acrylic copolymer or emulsion + other components - the rest Basis: cellular concrete - 7 60 fifty 6. Filling: MikoosPheoi from silicon oxide Binder: butane-styrene emulsion + other components - the rest Basis: cardboard - 12.5 64 57 7. Filling: MikoosPheoi from zirconium oxide Binder: PVA dispersion + other components - the rest Basis: cardboard - 10 49 41 8. Filling: MikoosPheoi from molybdenum oxide Binder: PVA-dyspeosia + other components - the rest Basis: ceramic brick - 8.4 46 39

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From the data given in the table, it can be seen that the composite decorative protective coating significantly improves the thermal protective properties of the base by increasing the integral reflection coefficient, good vapor permeability, and preventing the penetration of droplet moisture into the substrate structure from the atmosphere, and the technical solution meets the criteria of patentability.

The production of the developed coating was mastered at the applicants' enterprise and successfully passed tests in industrial production.

Information sources

1. Ki patent No. 2216564 C1, IPC ⁷ C 09Ό 167/02; Е 01Р 9/04, (22) 08.22.2002, (46) 20.11.2003. Bull. No. 32, (54) "Thermoplastic composition for marking the roadway."

2. Application EP 1111144 A1 200110627, IPC ⁷ E 04B 1/76, (54) “Building construction to reduce heat loss in the premises”.

3. Patent ϋδ No. 4404305, IPC ³ С 08Ь 83/04, (22) 02.16. 82, (54) “Iasha geDagbap! ro1uog§apogyohape gegsh eoshrozyyupz ".

4. M.L. Herman, P.S. Grinchuk “Mathematical model for calculating the heat-shielding properties of the composite coating“ Ceramic microspheres - a binder ”, IFZh, t. 75, No. 6, p. 43.

5. Energy-saving ThermoShield paints. Promotional brochure ICHUPP “Thermoceramic systems” (Belarus), Tek-Si Trading House, © 2004, p. 1-8. (prototype).

Claims (4)

CLAIM 1. Composite decorative protective coating containing as a binder an aqueous dispersion of the polymer and structured filler in the form of hollow vacuum microspheres, characterized in that it contains a filler of sodium kali borosilicate glass or metal oxides in the amount of 3.0-75.0%, with This microsphere is made with an outer diameter of 5.0-200.0 μm with a wall thickness of 0.25 to 10.0 μm and evacuated to a pressure of 0.1-0.15 atm. 2. Composite decorative protective coating according to claim 1, characterized in that the microspheres as metal oxides mainly contain oxides of aluminum, or silicon, or zirconium, or molybdenum. 3. Composite decorative protective coating according to claim 1, characterized in that the microspheres are made with a bulk density of 0.1-1.0 g / cm ³ . 4. Composite decorative protective coating according to claim 1, characterized in that as the aqueous dispersion of the polymer contains an acrylic copolymer or emulsion, or a butadiene styrene emulsion, or a polyvinyl acetate dispersion.