RU2176705C2 - Method for reconstruction of heat insulation and anticorrosive treatment of buildings and structures - Google Patents

Abstract

FIELD: construction engineering. SUBSTANCE: method is used in operation and repair of buildings and structures suffering wall temperature difference from minus 30 to plus 30 C and in recovery of operating characteristics of buildings including their heat insulating and anticorrosive ones. Method involves cleaning of outer wall surface of buildings and structures by mechanical methods: sand-blasting of wall surfaces or by cooling building surface with compressed air. Polyurethane foam layer is evaporated onto clean surface immediately after mechanical cleaning A:B proportion of ingredients being from 1:1 to 1:2; evaporation is made by means of small-size movable evaporating plant PENA; mentioned layer is foamed and hardened at temperature of 18-30 C in absence of surface moistening sources; layer thickness of polyurethane foam is 20-50 mm. Anticorrosive varnish layer is sprayed onto hardened polyurethane surface. EFFECT: reduced repair time, cost, labor consumption; improved heat insulating and anticorrosive characteristics. 4 tbl, 2 ex

Description

The invention relates to the field of construction, operation and repair of buildings, which are characterized by a significant temperature difference on the wall - from -30 to +30 ^o C, and can be used to restore the operational characteristics of buildings, including their heat-insulating and anti-corrosion properties.

 Known methods of reconstruction and repair of industrial buildings and structures [1].

 The restoration and strengthening of reinforced concrete structures by building up, arranging clips or shirts consists in preparing the surface of old concrete by mechanical methods and manually, applying polymer glue to the cleaned surface, applying cement and polymer concretes and mortars [1, p. 48-61]. The disadvantage of this method is the inability to improve the thermal insulation characteristics of the walls of the building, since the thermal conductivity of the materials used for repair is equal to the thermal conductivity of the walls of the building, significant labor costs and a significant increase in the mass of the building (5-10%).

 The closest in technical solution is the method of corrosion protection and waterproofing of reinforced concrete structures with compositions based on bitumen, organosilicon and organic polymers [1, p. 134-153], which consists in preparing the surface by mechanical methods and manually, preparing the composition, heating the composition to a predetermined temperature, applying the composition by spraying from non-standard nutrient containers using a pneumatic nozzle and a device for supplying compressed air and material through flexible hoses, drying the layer, applying the following layer. The disadvantages of this method is the inability to improve the thermal insulation characteristics of the walls of the building, since the thermal insulation characteristics used for the repair of materials and walls of the building are equal, significant labor costs due to the need to use manual labor and applying several layers of the composition, increasing the mass of the building by 5-10%.

 The objective of the invention is to develop a method of restoring thermal insulation and corrosion protection of buildings and structures.

 EFFECT: restoration and improvement of heat-insulating and anticorrosive characteristics of buildings and structures, reduction of repair time, reduction of labor costs, reduction of material costs.

The specified technical result in the implementation of the invention is achieved by the fact that in the known method of restoring thermal insulation and anticorrosive protection of buildings and structures, they perform mechanical cleaning of the outer surface of buildings and structures, the peculiarity is that immediately after mechanical cleaning of the surface of the building at a temperature of 18-30 ^o C and the absence of sources of surface wetting by spraying, followed by foaming and curing, a layer of polyurethane foam is applied with a thickness of 20 to 50 mm at a ratio of x components for producing polyurethane foam: A (mixture of oligoesters, chain extenders, water, catalysts, stabilizers, pigments or dyes): B (di- or polyisocyanates) [4, p. 234] from 1: 1 to 1: 2, then a paint coating is applied to the cured layer of polyurethane foam.

 The method is as follows: the external surface of the walls of the building is cleaned by mechanical methods — by sandblasting the surface of the building or by blowing the surface of the building with compressed air at a pressure of 0.2-0.5 MPa to remove damaged sections of the surface of the walls of the building. On a cleaned surface in the absence of sources of surface moistening, a layer of polyurethane foam is applied by spraying followed by foaming and curing [2, p. 10-16] a thickness of 20 to 50 mm with a ratio of the starting components to obtain A (mixture of oligoesters, chain extenders, water, catalysts, stabilizers, pigments or dyes): B (di- or polyisocyanates) from 1: 1 to 1: 2 using a portable small-sized installation for spraying polyurethane foam "Foam", consisting of heated containers for components, gear pumps and a spray gun with a stirrer. The consumption of polyurethane foam is determined in accordance with the dimensions of the building, the thickness of the applied layer, the apparent density of the foamed and cured polyurethane foam. Foaming and curing of the composition occurs within a few seconds [3, p. 246]. A spray paint layer is applied to the cured surface of the polyurethane foam by spraying, which is resistant to acids and alkalis [1, p. 153-170].

Example 1
Possible defects causing a decrease in thermal insulation characteristics, violation of the state and stability of the load-bearing structures of a reinforced concrete building, using the example of a mine pile as follows:
- The destruction of the solution monolithic joints of the panels with the loss of it from the mouths;
- Destruction of the protective paint layer;
- Destruction of the protective layer of concrete.

 To repair the destroyed surface layer of the copra reinforced concrete building, to ensure the strength of the connection of the protective heat-insulating coating of polyurethane foam with the surface coating of the panels, the surface of the plates is cleaned by sandblasting or, at least, using compressed air to remove surface contaminants, damaged areas of the paintwork or protective layer concrete.

A layer of polyurethane foam grade PPU-17N-1 or PPU-17N-2 [2] is applied to the cleaned surface in the absence of sources of surface wetting, followed by foaming and curing immediately after cleaning the surface in dry weather at an air temperature of at least 18 ^o C using "Foam".

The starting components for the production of polyurethane foam:
PPU-17N-1 - component A-A1-17N-1 and A2-17H, component B - polyisocyanate grade B or grade D.

 PPU-17N-2 - component A-A1-17N-2 and A2-17H, component B - polysocyanate grade B or grade D.

 The ratio of the starting components to obtain polyurethane foam A: B is 1: 1.1.

 The volume of the insulation layer will be equal to the product of the lateral surface area of the copra building, multiplied by the layer thickness (assumed to be 50 mm).

V = 2 (A + B) HS,
where V is the volume of the insulating layer, A, B, H are the width, length and height of the copra, respectively, S is the thickness of the foam layer.

A = 24 m, B = 21 m, H = 105 m, S = 0.05 m
Then V = 2 (21 + 24) • 105 • 0.05 = 472.5 m ³ .

The area to be coated is:
F = 2 • (21 + 24) • 105 = 9450 m ² .

 The mass of the insulation layer and the consumption of raw materials for a layer thickness of 50 mm will be at a coefficient of consumption of raw materials Kr = 1.5 (see table. 1).

 Data analysis table. 1 shows that the increase in the mass of the copra building when applying the heat-insulating coating does not exceed 2% (the mass of the copra is 3300 tons), the consumption of raw materials for producing a polyurethane foam coating with a thickness of 50 mm is almost equal to the consumption for obtaining a coating with a thickness of 1-3 mm from compositions based on bitumen, organosilicon and organic polymers [1, p. 134-153].

The performance of applying the PUF coating is 6 kg / min (Foam-0.4-6 installation), which with an 8-hour working day will be:
3B = (V • ρ / (n • 8 • 60),
where 3B - time spent on work; V is the volume of the applied polyurethane foam layer, m ³ , p is the installation capacity, kg / min; ρ is the apparent density of the foam, kg / m ³ .

3B = (472.5 m ³ • 70 kg / m ³ ) / (6 kg / min • 8 • 60) = 11.5 days
The calculation of the time spent is made under the condition of using one unit operating in one shift.

 The data presented in Table 2 show that the applied layer of polyurethane foam can significantly improve the thermal insulation characteristics of the building, since the thermal conductivity of reinforced concrete is 1.5 W / (m K), which is more than forty times higher than the thermal conductivity of polyurethane foam, to obtain a relatively durable and waterproof coating weatherproof, the heat resistance of which depends on the brand of the selected polyurethane foam.

 To enhance the anti-corrosion characteristics of the coating, a layer of anti-corrosion paint is applied to the cured layer of polyurethane foam by spraying.

Example 2
To repair a brick building and ensure the strength of the connection of the protective insulating coating of polyurethane foam with the surface of the walls of the building, cleaning is carried out using sandblasting or, at least, using compressed air to remove surface contaminants, damaged areas of the paintwork or protective layer of concrete or mortar.

A layer of Izolyan-6 polyurethane foam (TU 6-05-221-635-82) is applied to the cleaned surface in the absence of sources of surface wetting, followed by foaming and curing immediately after cleaning the surface in dry weather at an air temperature of at least 18 ^o C using installations "Foam"; the ratio of components A (A2 Isolan-6): B (polysocyanate grade B or grade D) from 1: 1.5. Foaming and curing of the composition occurs almost instantly, within a few seconds [3].

 The volume of the insulation layer will be equal to the product of the lateral surface area of the building, multiplied by the thickness of the layer (assumed to be 30 mm).

V = 2 (A + B) HS,
where V is the volume of the insulating layer, A, B, H are the width, length and height of the copra, respectively, S is the thickness of the foam layer:
A = 24 m, B = 21 m, H = 15 m, S = 0.03 m
Then V = 2 (21 + 24) • 15 • 0.03-40.5 m ³ .

The area to be coated is:
F = 2 • (21 + 24) • 15 = 1350 m ²
The mass of the insulation layer and the consumption of raw materials for a layer thickness of 30 mm will be at a coefficient of consumption of raw materials Cr = 1.5 (see table. 3).

 Data analysis table. 3 shows that when applying a layer 30 mm thick, the consumption of raw materials is less than when obtaining a coating 1-3 mm thick from compositions based on bitumen, organosilicon and organic polymers [1, p. 134-153], the mass of the layer does not exceed 2% of the mass of the building.

The performance of applying the PUF coating is 6 kg / min when using the "Foam 0.4-6" installation, which with an 8-hour working day will be:
3B = (V • ρ) / (n • 8 • 60),
where 3B - time spent on work;
V is the volume of the applied polyurethane foam layer, m ³ ;
p - installation capacity, kg / min;
ρ is the apparent density of the foam, kg / m ³ .

3B = (40.5 m ³ • 60 kg / m ³ ) / (6 kg / min • 8 • 60) = 0.844 days
The calculation of the time spent is made under the condition of using one unit operating in one shift.

 The resulting coating has the characteristics contained in the table. 4.

 Given in the table. 4 data show that the applied layer of polyurethane foam can significantly improve the thermal insulation characteristics of the building, since the thermal conductivity of reinforced concrete is 1.5 W / (m K), i.e. almost forty times the thermal conductivity of polyurethane foam, get a fireproof, relatively durable and waterproof coating that is resistant to weathering.

 To enhance the anti-corrosion characteristics of the coating, a layer of anti-corrosion paint is applied to the cured layer of polyurethane foam by spraying.

 A distinctive feature of the proposed method for restoration of thermal insulation and anticorrosive protection of buildings and structures is the almost complete restoration and improvement of the thermal insulation characteristics of the walls of the building, protection of the damaged outer layer of the walls from external influences, low laboriousness when performing repairs, a slight increase in the mass of the building compared to other methods, and high productivity method.

Sources of information
1. Recommendations for ensuring the reliability and durability of reinforced concrete structures of industrial buildings and structures during their reconstruction and restoration / Kharkov Promstroyproekt. -M .: Stroyizdat, 1990.-176 p.

 2. Foamed plastics. Catalog. Cherkasy. 1988 - 38 p.

3. Technology of plastics. / Ed. V.V. Korshak, ed. 2nd, rev. and additional - M.: Chemistry, 1976. -608 s
4. Chemistry and technology of polymer film materials and artificial leather: Textbook for universities Part 1. / G.P. Andrianova et al. - 2nd ed., Rev. and add. - M: Legprombytizdat, 1990 .-- 304 p.

Claims (1)

A method of restoring thermal insulation and corrosion protection of buildings and structures, including mechanical cleaning of the outer surface of the walls of buildings and structures, applying a layer of material by spraying, applying a layer of paint and varnish coating, characterized in that polyurethane foam with a ratio of components A: B from 1: 1 is used as a sprayed material up to 1: 2, a layer of polyurethane foam is sprayed, foamed and cured immediately after mechanical cleaning of the outer surface of the walls at a temperature of 18-30 ^o C in the absence of sources of moisture surface, and the thickness of the layer of polyurethane foam is 20-50 mm

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