RU2072378C1 - Chalk spackling - Google Patents

Abstract

FIELD: building materials production. SUBSTANCE: proposed spackling contains organic polymer binder having molecular weight 1000-2000 (content of alkoxy and acetoximoxy groups in it being 30-45 mass % and 3-8 mass % respectively). EFFECT: improves quality of desired product.

Description

 Light water-based putty materials widely used in construction are prepared by mixing ground chalk (or its mixture with sand, gypsum or gypsum-cement binder), water and a polymeric binder of natural or synthetic origin (animal glue, CMC methyl carboxycellulose sodium salt and (or) synthetic latexes rubbers Sometimes, to improve the rheological properties of putties, polymer emulsions, drying oils and soap are introduced into their composition (see table 1).

When putties are applied to the defective surface of concrete or other inorganic material (with the goal of leveling it) after 4 hours of exposure of the leveled layer, a material is formed that has a certain mechanical strength, retains its original shape, has adhesion to the base and has low density (1.4 -1.6 g / cm ³ ) due to the high content in it of a light filler of chalk (up to 85 wt. In terms of dry cured material). The high porosity of the cured dry putties contributes to the subsequent fixing on their surface of the paintwork needed to complete the finishing work.

 Among the normative indicators of putties, according to the technical specifications for finished products, such as color, degree of grinding, hardening time, consistency, workability, shrinkage, etc. are indicated. however, such important indicators as water resistance and biostability are not presented.

 So, it is known that the high hygroscopicity of cured dry putties of the brands Pomelax, Water Lily, Emulsin, latex-chalk composition, etc. as well as the solubility in water of their adhesive base (actually CMC glue) after curing of the putties can lead to complete destruction of the leveling layer based on them during their operation (for example, in contact with water during leaks).

 On the other hand, the use of decoration materials in indoor areas characterized by high humidity (kitchen facilities, bathrooms, laundries, basements, etc.) is associated with a high probability of mold damage. The susceptibility to damage by putrefactive bacteria of many putties (for example, the widespread oil-glue putty) also determines their short shelf life (15-30 days) after preparation.

где m (n 6-12) 1-2 R¹ -CH₃, -С₂Н₅ -изо-С₃Н₇; R² -СН₃,-С₂Н₅, -СНСl₂, -CH₂Cl, -CH= CH₂; R³ -CН₃, -С₂Н₅, изо-С₃ Н₇; R⁴ -CH₃; R⁵ -CH₃ и -C₂H₅ с содержанием звеньев -О-N-CR⁴R⁵ от 3 до 8 мас.These shortcomings of putties (water solubility of some and susceptibility to infection by molds of others) are eliminated by the addition of a molecular weight modifying additive oligoorganoalkoxysiloxane in the range of 1000-2000 cu containing 30-44 wt. alkoxy groups and from 3 to 8 wt. acetoxyxy groups, in the amount of 6% by weight of the initial putty. The following formula of the proposed additives more clearly reflects its chemical composition and structure:

where m (n 6-12) 1-2 R ¹ -CH ₃ , -C ₂ H ₅ -iso-C ₃ H ₇ ; R ² -CH ₃ , -C ₂ H ₅ , -CHCl ₂ , -CH ₂ Cl, -CH = CH ₂ ; R ³ —CH ₃ , —C ₂ H ₅ , ISO-C ₃ H ₇ ; R ^{4 is} CH ₃ ; R ⁵ —CH ₃ and —C ₂ H ₅ with a content of —O — N — CR ⁴ R ⁵ units of from 3 to 8 wt.

The proposed additives are mobile transparent, from light yellow to brown liquids with a viscosity of 15 to 40 cst, which have a high impregnating ability (penetration depth into building materials from 1 to 8 mm, depending on the porosity of the processed material). Due to their chemical composition (namely, the presence of reactive groups of a different nature at the silicon atom) and adjusted density (d 1.00 ± 0.02 g / cm ³ according to the requirements of the Technical conditions for these products), the proposed additives, although they do not mix with water but they form a mobile emulsion with water, without the involvement of high-speed mixers and without the participation of surface-active substances, the stability of which allows it to be stably distributed in the mass of water-based building material, in this case putty. The method of infrared analysis proved the interaction of the additive substance with the hardened inorganic binder of the building material. The additive does not form a varnish film on the surface of the material. The formation of strong chemical bonds of the Si — O — Si additive with the base (during the reaction of the Si — OH base with — Si – ONCR ⁴ R ⁵ additives) prevents the additive from being washed out from the pores of the material during prolonged contact of the samples with water.

 It is shown that the introduction of the proposed additive in the amount of putties in an amount of 5-6 by weight of the starting components does not affect the rheological properties and other standard parameters of the material in accordance with the requirements of TU, but significantly increase their water resistance, especially in combination with additional surface treatment of the same additive cured material. This allows you to significantly improve the consumer properties of finishing materials to increase their durability, to expand the scope.

 It was also found that some of the proposed additives but the proposed solution have fungicidal properties and, being introduced into the composition of putties in an amount of 6%, they can significantly increase the fungus resistance of the surface treated by them. So, oil-glue putty, which is initially not resistant to putrefactive bacteria and molds, can be stored for at least six months after it is added without adding any putrefactive odor and mold to the surface of the material. At the same time, other normative indicators of these materials (hardening speed, workability, etc.) remain unchanged.

 In addition, it was shown that the use of additives according to the proposed solution in the composition of putties, including drying oil in the initial formulation, allows you to replace the drying oil with the additive without losing its quality according to TU. At the same time, this allows to reduce the costs of natural raw materials (sunflower oil) in the production of putties.

 Additives proposed in this solution are new products, final documentation has been developed for them, and experimental work on their production has begun at Russian enterprises. It is important that previously unused waste products of the organosilicon sub-industry can be used as raw materials for their production, which completely removes the question of the scarcity of these products.

В описание заявки введены примеры использования этого продукта к шпаклевки в качестве контрольных опытов. В литературе не найдено сведений о применении жидкости 136-41 для повышения водостойкости шпаклевок и ее влиянии на грибостойкость защищаемых ею материалов.Since it is known that in order to hydrophobize building materials (concrete, brick, natural stone, mortar), the most effective is the treatment of their surface (or introduction into their volume) with dilute solutions or aqueous emulsions of organosilicon liquid 136-41:

The application description contains examples of the use of this product as a putty as a control experiment. No information was found in the literature on the use of liquid 136-41 to increase the water resistance of putties and its effect on the mushroom resistance of materials protected by it.

 The following examples illustrate the advantages of the proposed technical solution compared to the prototype.

 A. Protection of putties from erosion by water by introducing additives into their composition according to the proposed solution.

Example 1 (prototype). Oil-glue putty (see table 1), including animal glue as an adhesive, after curing upon contact with water retains the shape of an even coating and has water absorption (an increase in the weight of a cured putty sample when it is held for 3 hours in water, referred to to its original weight) equal to 34.4%
Example 2. Putty "Pomelax" (see table 1), which includes CMC glue as an adhesive, even after curing it is absolutely non-waterproof: when it comes in contact with water, it erodes, and the formed level layer is destroyed. Such coatings under operating conditions in rooms with possible leaks, even when protected by water-emulsion coating compositions, inevitably exfoliate. In addition, in the conditions of the production of ready-made sanitary cabins and other products by the enterprises of the construction complex, their dismantling in the open air with defects puttied with such putty is impossible.

 Example 3 (control). Putty "Pomelax" after introducing into its composition an additive of an aqueous emulsion of liquid 136-41 in an amount of 6% (based on the main substance) to the mass of all putty components shows an increase in water resistance in the hardened state by 4.7% compared with the material in example 1 (water resistance 32.8%), while the water absorbed into the putty does not violate the integrity of the layer.

 Example 4. Putty "Pomelax" after the introduction of additives in its composition, according to the proposed solution, oligoorganoalkoxysiloxane with a molecular weight of 1037, a content of ethoxy groups of 43.4% and a content of acetoxyoxy groups of 5.4% (its formula is given below), in an amount of 6% in relation to the components in the initial putty, after curing, gives the cured putty an increased resistance to water: the material does not melt and has a water absorption of 19.40%. Thus, the water resistance of the material increased by 43.6% compared to the material according to claim 1. Putty with this additive has good portability (it easily sticks to concrete and does not reach for the putty knife), dries for 3 hours, and does not give shrinkage cracks during hardening.

 Example 5. The combination of putty "Pomelax" with the addition of oligoorganoalkoxysiloxane of molecular weight 647, the content of ethoxy groups 42.2% and acetoxy hydroxy groups 10.4% (formula below) with a total content of 6% in the mixture with putty causes gelation of the additive with the formation of lumps of jelly, violating the homogeneity of the mixture and preventing the formation of a flat surface on defective concrete.

Example 6. The introduction of an additive, similar to that specified in example 4, in the putty "Pomelax" in an amount of 4% prevents the curing of the material from erosion by water, but increases its waterproof properties slightly: water absorption is 33.6%
Example 7. The introduction of an additive similar to that described in example 4, in the putty "Pomelax" in an amount of 7% increases the water resistance of the cured and dried material (the putty after curing does not melt upon contact with water, its water absorption is 16.5%), but at the same time one of the important normative indicators deteriorates the workability of the material: the mixture begins to adhere poorly to the concrete base. An undesirable consequence of introducing an additive in the specified amount into the putty composition is also the poor compatibility of the surface of the cured putty with the water-emulsion composition intended for painting the repaired surface.

 B. Protection of putties from erosion by water by surface treatment of hardened material with an organosilicon additive.

Example 8 (control). A day after the curing of the Pomelax putty, its surface was treated with an additive liquid 136-41 in the form of a 100% substance. The consumption of the additive was about 170 g / m ² . The penetration depth of the additive in the putty was 0.8 mm. After holding the impregnated layer for 6 hours, the sample was placed in water for 3 hours. As a result, the material exfoliated along the thickness of the impregnation with an additive and the other material was washed out.

Example 9 (control). After daily curing of the cured putty "Pomelax" its surface was treated with an additive liquid 136-41 in the form of a 50% aqueous emulsion. The consumption of the additive was about 250 g / m ² due to the high viscosity of the additive. After 6 hours of exposure, the processed putty sample was placed in water for 3 hours. As a result of the interaction of the processed putty with water, the top layer of the putty is peeled off about 0.3 mm thick (the thickness of the putty is impregnated with the additive) and the remaining mass of the putty material initially hardened is eroded.

Example 10 (control). After a daily exposure to the Pomelax putty, its surface is treated with an additive liquid 136-41 in the form of a 10% solution in an organic solvent (kerosene). The penetration depth of the additive in the material is 1 mm, and the consumption of the additive is 120 g / m ² . After holding the material for 6 hours, it is placed in water. After a few minutes, the material begins to spread throughout the entire volume.

Example 11 (control). After daily exposure, the cured putty "Pomelax" is treated with a control additive in the form of a 10% aqueous emulsion. The consumption of the additive is 120 g / m ² , the impregnation depth is 0.5 mm. Immediately after immersion of the sample in water, putty, previously dried in air for 6 hours, begins to blur, losing shape and dissipating in water.

Example 12. After daily exposure, Pomelax putty was treated with an additive according to the proposed solution with an oligoorganoalkoxysiloxane of molecular weight 1780 with an ethoxy content of 35.4% and an acetoxy hydroxy group of 6.3% (the formula of the additive is given below). The penetration depth of the additive into the material is 1 , 4 mm, and the consumption of the additive is 120 g / m ² . The additive was used as a 100% substance. 6 hours after the putty was impregnated, its samples were placed in water. It was found that a sample of the material treated with the additive does not swell in water, is not washed out by water, and does not lose its shape.

Example 13. Putty "Pomelax" after daily exposure is treated with the additive according to the proposed solution oligoorganoalkoxysiloxane with a molecular weight of 1960 cu the content of isopropoxy groups of 30% and the content of acetoxyxy groups of 2.9% with a total additive consumption of 120 g / m ² and an impregnation depth of 1.5 mm. The additive in this example was also used as a 100% substance. When the treated substance is placed in water after 6 hours of exposure to air, the sample does not swell, is not washed out by water, and does not lose its shape.

 Example 14. Processing putty "Pomelax" with the addition of oligoorganoalkoxysiloxane, similar to that described in example 12, taken in the form of a 10% solution in kerosene, does not lead to a noticeable increase in the hardness of putty, when it comes into contact with water, it swells noticeably and becomes very friable and fragile.

Олигометилэтоксисилоксан с включением ацетоксимоксигрупп молекулярной массой 647, содержанием этоксигрупп 42,2% и содержанием ацетоксимоксигрупп 10,4% по примеру 5:

Олигоэтилэтоксисилоксан с включением ацетоксимоксигрупп молекулярной массы 1780 у.е. содержанием этоксигрупп 35,4% и ацетоксимоксигрупп 6,3% по примеру 12:

Олигохлорметил(изопропокси)силоксаны с включением ацетоксимоксигрупп молекулярной массы 1960 у.е. содержанием изопропоксигрупп 30,1% и ацетоксимоксигрупп -2,9% по примеру 13:

В. Фунгицидная защита негрибостойкой шпаклевки добавкой по предлагаемому решению.The following are the formulas of additives (oligoorganoalkoxysiloxanes with inclusions of acetoxyoxy groups) used in various examples illustrating the proposed technical solution:
Oligomethylethoxysiloxane with a molecular weight of 1037, with a content of ethoxy groups of 43.4% and acetoxyoxy groups of 5.4% according to example 4:

Oligomethylethoxysiloxane with the inclusion of acetoxyxy groups with a molecular weight of 647, a content of ethoxy groups of 42.2% and a content of acetoxyoxy groups of 10.4% according to Example 5:

Oligoethylethoxysiloxane with the inclusion of acetoxyoxy groups of molecular weight 1780 cu the content of ethoxy groups of 35.4% and acetoxyoxy groups of 6.3% according to example 12:

Oligochloromethyl (isopropoxy) siloxanes with the inclusion of acetoxyoxy groups of molecular weight 1960 c.u. the content of isopropoxy groups of 30.1% and acetoxyoxy groups of -2.9% according to example 13:

B. Fungicidal protection of non-fungal putty with an additive according to the proposed solution.

The tests were carried out in accordance with GOST 9.048-75 / 4 / The essence of the method consists in keeping the samples infected with mold spores under conditions optimal for their development (T = 29 ± 2 ^o C and relative humidity more than 90%). Suspensions of fungal spores were prepared, usually developing on walls inside residential premises:
Penicillium cyclopium westling,
Aspergillus niger van Tiegem,
Aspergillus versicolor (Vuill) Tiroboschi,
Verticillium lateritium Berkeley,
Trichoderma viride Pers. ex Fr.

 Penicillium chrisogenium Thom.

 Putty samples were applied to slides with a smear of 2-3 mm thickness. The number of parallel samples in each experiment was 4. The test was performed on both putty samples (protected and unprotected by the additive) without coating, and putty samples, coating with a layer of water-based paint, respectively, with and without the additive. After exposure of the samples under conditions of infection for 75 days, the results were evaluated using the six-point system shown in table. 2. 2 Example 15 (the behavior of mushroom-resistant putty). Putty "Pomelax" (as a binder includes polymers of synthetic origin) without additives and coating with an aqueous emulsion composition shows a fungus resistance score of O, that is, it is mushroom-resistant. However, according to example 2, it is absolutely non-water resistant.

 Example 16 (same). Putty "Pomelax" without additives, coated with a water-based composition VDVA-224, when tested, shows a fungus resistance score of O, that is, it is mushroom-resistant. However, when in contact with water, as shown in example 2, the paint layer peels off and the putty is eroded.

 Example 17 (1-4) (prototype). Oil-glue putty, in the formulation of which animal glue without additives and without coating with an aqueous emulsion composition was used as an adhesive, gives a score of 5, i.e. it is non-fungal, although it is, according to example 1, relatively waterproof.

 Example 18 (1-4) (control). Oil-glue putty with introduced into its composition before application to the base with the addition of liquid 136-41 in the form of an aqueous emulsion with a concentration of 50% with a total amount of additive 4% after testing showed a mushroom resistance rating of 5.

 Example 19 (1-4) (control). Oil-glue putty with the addition of liquid 136-41 (taken in the form of a 50% aqueous emulsion) in the amount of 6% introduced into its composition before application to the base gives a test point of mushroom resistance 5.

 Example 20 (1-4) (control). Oil-adhesive putty with the addition of 136-41 fluid in an amount of 10% introduced into its composition before application to the base and taken as a 50% aqueous emulsion, when tested for mushroom resistance, shows a score of 5.

 Example 21 (control). Oil-glue putty with 136-41 liquid added to it before application on the base (taken as a 50% aqueous emulsion) in an amount of 6% of the basic substance and coated with VDVA-224 water-based paint, including 6% of the same additive, with fungus test shows a score of 3.

 Example 22 (parallel to example 21). Score 2.

 Example 23 (parallel to example 21). Score 4.

(молекулярная масса 1186, содержание изопропоксигрупп 9,9% бензилоксигрупп 54,1%), взятой в виде 100%-ного вещества, после испытания на грибостойкость показывает балл 5.Example 24 (1-4). Oil-glue putty, including 4% additives according to the proposed composition solution

(molecular weight 1186, the content of isopropoxy groups 9.9% benzyloxy groups 54.1%), taken in the form of a 100% substance, after a test for mushroom resistance shows a score of 5.

 Example 25 (1-4). Oil-glue putty with the additive added to it before application onto the base, similarly to that used in example 24, in the amount of 6% (the additive was taken as a 100% substance), after testing for mushroom resistance it is rated 5.

 Example 26 (1-4). Oil-adhesive putty, comprising 10% of an additive similar to that used in example 24, taken as a 100% substance, as a result of mushroom resistance tests, shows a score of 5.

 Example 27. An oil-glue putty with an additive introduced into it before curing, similar to that used in example 24, in an amount of 6% in combination with an aqueous emulsion composition of VDVA-224 and also with the addition of the same substance in an amount of 6% after a fungus resistance test, is rated 1 .

 Example 28 (parallel to example 27). Score 2.

 Example 29 (parallel to example 27). Score 3.

 Example 30 (1-4). An oil-glue putty, including an additive similar to that used in example 4, applied in the form of a 100% substance in an amount of 4% after testing for mushroom resistance, shows a score of 5.

 Example 31 (1-4). Oil-glue putty with an additive similar to that taken for example 30, in the amount of 6% (in the form of a 100% substance), when tested for mushroom resistance is rated 5.

 Example 32 (1-4). Oil-glue putty with an additive similar to that used in example 30, taken as a 100% substance in an amount of 10% after testing for mushroom resistance is rated 5.

 Example 33. Oil-glue putty, including an additive similar to that specified in example 30, taken in the form of 100% liquid in an amount of 6% introduced into the putty before applying it to the base, and coated on top after curing with VDVA-224 water-based paint, also including the addition of the same substance in an amount of 6% when tested for mushroom resistance gives a score of 2.

 Example 34 (parallel to example 33). Score 2.

 Example 35 (parallel to example 33). Score 1.

 Thus, based on the requirements of GOST, as can be seen from the above data, the final (i.e., the maximum of the three values), the mushroom resistance score of the prototype is 5, with an additive of control 4, and for two putties with additives according to the proposed solution 3 and 2 respectively. Therefore, the use of these additives is effective for increasing the fungus resistance of initially non-fungal hard putties.

 The results in examples 1-35 are summarized in tables 3, 4 and 5.

Claims (1)

 Cretaceous putty, including an organic polymer binder and a modifying additive, characterized in that it contains oligoorganoalkoxysiloxane mol. m. 1000 2000 cu with alkoxy groups 30 45 wt. acetoxyxy groups 3 8 wt. in the amount of 6% by weight of the initial putty.

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