RU2490234C1 - Method of heat-insulating plaster mixture - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention relates to field of construction and can be used as dry plaster mixture, intended for heat-insulating covering of external and internal sides of walls of building constructions. Composition of heat-insulating plaster mixture contains, wt %: slack lime 3-7, expanded perlite 2-4, limestone powder 20-28, foam glass 15-25, methylcellulose 0.1-0.2, foaming agent based on sodium lauryl sulfate 0.015-0.045, water-soluble additive based on modified starch ester 0.03-0.08, polypropylene fibres 0.02-0.1, redispersible powder of copolymer of vinylacetate and ethylene 2-5, Portland cement 30-36, quartz sand 10-20.

EFFECT: increased efficiency of heat protection, ensuring stability of thermophysical and physicomechanical parameters of plaster layer for is entire guaranteed service term.

Description

The invention relates to the field of construction and can be used as a dry plaster mix intended for thermal insulation coatings of the external and internal sides of the walls of building structures.

Modern dry plaster mixes are not just a mixture of cement with sand, but a product of high technology, the use of which allows not only to significantly increase labor productivity, but also to obtain completely different qualitative results, unattainable in the case of using traditional cement-sand mortar mixes. In the composition of modified dry mixtures, four main groups of components can be distinguished: mineral binders, inert fillers, additives for obtaining special properties, including water retention, as well as polymer binders, which work together with mineral binders, but have a completely different mechanism of action. Portland cement (white and gray), quick-hardening high-aluminate cements, various types of gypsum, as well as combinations of these substances are most often used as a hydraulic mineral binder. As fillers in the known dry plaster mixes, marble or limestone flour and quartz sand are most often used. The composition of known heat-insulating stucco mixtures also includes porous fillers, such as expanded clay, perlite and vermiculite, and in some cases granular, pre-expanded polystyrene foam. Currently, dry building mixes, which include such porous fillers as, for example, expanded perlite or foam glass, are of greatest relevance. The properties of such porous fillers when incorporated into dry plaster mixes provide a significant reduction in the thermal conductivity of the plaster layer, as well as its bulk weight. The quality of heat-insulating plaster mixes depends not only on the particle size distribution of the filler / fillers, but also on the content of other additives, the presence of which significantly affects the final result. The composition of the known dry stucco mixtures also includes modifying additives that contribute to the production of certain technical and technological characteristics of the mixtures, for example, the retention of water in the closed solution after its application. For example, the addition of an insignificant amount (0.02-7%) of water-soluble cellulose ethers to cement-sand mixtures leads to a significant increase in open time and provides a more complete and uniform hydration of cement throughout the volume of the solution, and also provides a significant increase in adhesion to the base and improvement surface quality. As already established in this technical field, the greater the thickness of the required cement slurry layer, the less methyl cellulose is required to provide the necessary degree of initial hydration. It is also known to use additives such as dispersion powders, which, in contrast to water-soluble cellulose derivatives, when mixing mixtures with water, do not form solutions, but two-phase systems consisting of polymer particles (based on copolymers of vinyl acetate and ethylene, vinyl chloride, styrene acrylate, etc. .) dispersed in water. The addition of these compounds also allows you to actively influence the characteristics of dry mixes and provides results that are unattainable when using only traditional mineral binders.

Formulation of dry plaster mixes is a complex and lengthy process, impossible without the participation of qualified personnel and the use of high-quality equipment, including the availability of a modern laboratory for analysis and testing of samples, which is probably why some of the compositions of modern plaster mixes known from published materials cannot only provide the advantages voiced in them, but also raise doubts about their suitability for use.

So, in patent RU 2394006 C2, publ. 07/10/2010, the composition of the heat-insulating stucco mixture for external and internal works is described, which contains, wt.%:

expanded perlite 15-45, cellulose 1-10, sand 5-30, slaked lime powder 5-25, kaolin 5-15, microvolastonite 1-10, foam glass 15-50, sodium oleate 1-5, zinc stearate 1-5, optibent 1-5, guilty flux 1-5, plasticizer 1-5, Elotex 511 10-40, blowing agent 1-5, technocel 150 1-5, Opagel SMT 1-5, ufapor 2-10, diatomite 2-10, cement rest.

It should be noted that providing the advantages and technical results claimed in RU 2394006 C2 is not possible, since the quantitative values of some additives indicated in the patent are several times higher than those acceptable for use in stucco mixtures, which has been studied and is widely known in this area. So, for example, the permissible amount of Elotex 511 is exceeded 5-6 times, and the permissible amount of methylcellulose and blowing agent is 50-10 times. The overestimated values of the marked additives in the stucco mixture lead to negative consequences, for example, the amount of blowing agent specified in RU 2394006 C2 will cause uncontrolled pore growth when mixing the stucco composition with water, which will subsequently lead to rapid destruction of the stucco layer. And the stucco mortar prepared on the basis of the plaster mortar described in patent RU 2394006 C2 cannot be normally applied to the surface to be treated due to the lack of wetting effect, because all water will be retained inside the plaster and the plaster, therefore, will not have any adhesion to the treated surface. Those. we can conclude that the stucco mixture described in patent RU 2394006 C2 not only cannot provide the technical results described in this patent, but also causes great doubts about its use as a stucco mixture.

You can also pay attention that the dimensions of thermal conductivity (BT / mChS 1), water absorption coefficient (kg / m ² -Tg), vapor permeability (mg / mg-Pa) specified in this patent are neither standardized nor generally accepted, they are not explained and in the description of the patent, which also raises doubts about the possibility of both realizing the mixture as a plaster, and the possibility of providing it with the technical results specified in patent RU 2394006 C2.

The proposed heat-insulating stucco mixture is aimed at eliminating the aforementioned disadvantages of the above-mentioned known stucco mixtures and provides a technical result, which consists in increasing the efficiency of thermal protection, in ensuring the stability of the thermophysical and physico-mechanical properties of the stucco layer applied to the treated surface for the entire guaranteed period service.

This technical result is ensured by the fact that the proposed heat-insulating stucco mixture contains slaked lime, expanded perlite, limestone flour, foam glass, methylcellulose, blowing agent, Portland cement, silica sand, polypropylene fiber, polymer binder, starch ether in the following ratio of starch mass. %:

slaked lime 3-7 expanded perlite 2-4, limestone flour 20-28, foam glass 15-25, cellulose 0.1-0.2 Sodium Lauryl Sulfate Frother 0.015-0.045, modified starch ester water soluble additive 0.03-0.08 polypropylene fiber 0.02-0.1 redispersible vinyl acetate-ethylene copolymer powder  2-5 Portal cement 30-36 quartz sand 10-20

The presence of slaked lime in the proposed composition improves the application of plaster on the surface, since slaked lime has plasticizing properties in cement mortars, and is an air binder. In addition, slaked lime reduces the bulk density of cement mortars due to the formation of a closed structure during their hardening.

Limestone flour in the proposed composition of the mixture provides a denser packaging of the resulting stucco solution at the micro level. In addition, due to the fact that the particles of limestone flour have a sufficiently high porosity relative to quartz sand, a decrease in the volumetric weight of the hardened plaster mortar is provided. In the plaster composition according to the invention, it is preferable to use limestone flour with a fraction of 0.01-0.15 mm.

Foam glass (or “foam glass”) is a porous material with closed cells rolled into spheres, obtained from a mixture of finely ground glass and a foaming agent, reminiscent of solid soap foam in structure. The use of the foam glass mixture in the proposed composition is necessary to give the plaster high thermal insulation properties. It is preferable to use foam glass with a fraction of 0.5-4 mm, a bulk density of 140-150 kg / m ³ in an amount of 15-25% of the total weight of the dry stucco mixture.

Methyl cellulose in the proposed mixture is used as a water-retaining additive, because it is a water-soluble thickener, which causes the following effects in cement-based mortar mixtures: strong water retention, which ensures more complete hydration of the cement, thickening of the solution, giving the solution thixotropic properties, which increases the resistance of solutions to sliding from vertical surfaces, the uniformity of the drying of the solution , which helps to reduce the likelihood of shrinkage cracks. As you know, cellulose ethers vary in degree of modification, in the proposed mixture intended for the manufacture of lightweight plasters, it is preferable to use medium-modified cellulose ethers in an amount of 0.1-0.2% of the total weight of the dry stucco mixture. In the proposed mixture can be used methyl cellulose, for example, grades МЦ-100, МЦ-16, МЦ-СБР and others described in TU-2231-107-05742755-96, or methyl cellulose, grades МЕС company SE TULOSE, for example, MHS 150003P4, or cellulose grades Culminal S.

The foaming agent based on sodium lauryl sulfate in the proposed composition is used as a water-soluble air-entraining additive, as causes a strong foaming effect in mortar cement-based mixtures, involving air bubbles in the solution, which contributes to the formation of closed spherical pores during hardening of the solution, which in turn increases the thermotechnical properties of the plaster layer, reduces its shrinkage and reduces the risk of cracking in it. In the prior art, such blowing agents are known and are available, for example, under the trademarks of Berolan Vertriesgesellschaft (Austria), for example Berolan LP-W1, or under the trademarks of Hostapur OSB, see Appendix 3. However, experiments show that overdosing of blowing agents in dry stucco mixtures leads to a sharp decrease in the strength of the stucco layer, which occurs in the known mixture according to patent RU 2394006 C2.

The water-soluble additive based on modified starch ether used in the mixture causes a weak thickening effect in the mortar plaster mixture, while the processability of its application to the treated surface is significantly improved, especially with machine application. The specified water-soluble additive improves the distribution of aggregates (especially light), because also has air-entraining properties due to the formation of closed spherical pores during hardening of the solution. However, the experiments showed that the noted positive properties of the presence in the stucco mixture of a water-soluble additive based on modified starch ether are provided with a small amount of it in the total weight of the dry mixture, in the proposed mixture - 0.03-0.08%. An overdose, as shown by experiments, leads to a sharp decrease in the adhesion of the plaster layer to the surface on which it is applied. Modified starch esters are known and are available, for example, under the trademarks of BEROLAN (for example, BEROLAN ST-500), under the trademarks of SE Tyiovis GMBH & Co. KG), for example, Tyiovis SE 72.

Polypropylene fiber is used in the proposed plaster mixture for volume micro-reinforcement, because Having high tensile strength and high corrosion resistance, polypropylene fiber significantly improves the strength characteristics of hardened plaster, applied to the surface, i.e. its tensile and bending strength, which reduces the risk of microcracks in the thickness of the plaster layer, also has a positive effect on the indicators of frost resistance and impact strength. In the proposed plaster mix, it is preferable to use polypropylene fiber with a diameter of 40 μm with a fiber length of not more than 10 mm, in an amount of 0.02-0.1% of the total weight of the dry mix. In the proposed mixture, any polypropylene fiber can be used, known, for example, under the brand name PB EUROFIBER, manufactured by P.Baumhuter, GmbH, or under the brand name PANACEA R dry, manufactured by LAMBDA FURTHERANCE B.V.

Redispersible powder based on a copolymer of ethylene and vinyl acetate is used as a polymer binder, because as a result of redispersion in water, a reactive polymer dispersion is formed, which, when hardening the mortar plaster mixture, forms its own 3-D polymer structure in the pores of the solution, reinforcing the solution and giving it properties that are not characteristic of the well-known widely used plaster mixtures. The polymer 3-D structure significantly increases the tensile and bending strength of the plaster layer, reduces the risk of cracking in it, improves the manufacturability of applying the plaster layer to the treated surface, and increases the impact strength of the applied plaster layer. Polymer binders are manufactured by Wacker Polymer Systems GmbH & Co. KG "under the brand name Vinnapas, for example, Vinnapas RE 5010 N, or Vinnapas RE 5028 N, etc.

Thus, the proposed dry plaster mixture provides a plaster layer applied to the surface to be treated with low bulk weight and high thermal performance (λ = 0.1), which are combined with high physical and mechanical properties (compressive strength and bending), and also provides good adhesion in various types of machined surfaces, which allows the use of the proposed composition for repair and protection of facades of various types with high thermal protection of the building . At the same time, the plaster layer (plaster) obtained from the proposed mixture has low shrinkage, has internal reinforcement with microfiber, which allows it to be used without additional reinforcement, and it can be applied both manually and mechanically to a thickness of 50 mm in one pass. In addition, the plaster from the proposed mixture has high thermal resistance and vapor permeability, and the use of polymer redispersion additives gives it strong hydrophobic properties, which dramatically reduces the absorption of water by the stucco layer during operation, thereby ensuring the stability of thermophysical and physico-mechanical properties throughout life time.

It should also be noted that the physico-mechanical characteristics of the proposed dry mix make it possible to use it not only as a stucco mixture, but also for the manufacture of various building products, such as heat-insulating panels and blocks of various configurations and sizes, decorative products for energy-efficient facade systems. The experiments showed that the stucco mixture based on the proposed dry mix is also effective when sanitizing surfaces that have traces of old stucco, because it has high adhesion to any heterogeneous surfaces.

Claims (1)

The composition of the heat-insulating stucco mixture containing slaked lime, expanded perlite, limestone flour, foam glass, methyl cellulose, blowing agent, cement, silica sand, characterized in that it additionally contains polypropylene fiber, redispersible powder, starch ether, in the following ratio of components, wt.%:
slaked lime 3-7 expanded perlite 2-4 limestone flour 20-28 foam glass 15-25 cellulose 0.1-0.2 sodium lauryl sulfate blowing agent 0.015-0.045 water based soluble additive modified starch ester 0.03-0.08 polypropylene fiber 0.02-0.1 redispersible powder copolymer of vinyl acetate and ethylene 2-5 Portal cement 30-36 quartz sand 10-20