RU117467U1 - THERMAL INSULATION COATING BASED ON FOAM GLASS - Google Patents

Abstract

1. Thermal insulation coating using foam glass blocks made in the form of a flattened prism, characterized in that liquid ceramic thermal insulation is used to attach the foam glass blocks to the base of the protected structure and to each other, while at least the surface of the base of the protected structure is applied to one layer of liquid ceramic thermal insulation, on which, for a time not exceeding the time of its complete polymerization, blocks of foam glass with at least one layer of liquid ceramic thermal insulation preliminarily applied on their side edges are laid in a continuous layer, while the blocks are aligned with the base of the protected structures and with each other tightly, without the formation of air cavities in the liquid ceramic insulation between the lower edges of the blocks and the base of the protected structure, as well as between the lateral edges of adjacent blocks, while on the outer surface of the layer formed by the foam glass blocks, at least one layer liquid th ceramic thermal insulation. ! 2. Thermal insulation coating according to claim 1, characterized in that at least two layers of liquid ceramic thermal insulation are applied to the outer surface of the layer formed by blocks of foam glass, while the outer layer of liquid ceramic thermal insulation is applied after complete polymerization of the material of the underlying layer. ! 3. Thermal insulation coating according to claim 1 or 2, characterized in that a protective layer of finely dispersed material is applied to the outer layer of the ceramic thermal insulation after its hollow polymerization by the method of gas-dynamic spraying.

Description

The utility model relates to the field of construction, more specifically to methods of protecting building structures and can be used, in particular, for heat and waterproofing walls, partitions, floors, ceilings and roofs of buildings and structures.

It is known that foamed glass or foam glass is a lightweight porous material, with pore (cell) sizes ranging from fractions of a millimeter to a centimeter, insoluble in water, resistant to most acids and organic solvents, and able to withstand high temperatures (http: //www.tutteplo. ru). Due to its cellular structure, foam glass is a tough and non-shrink material. The material does not contain organic compounds, environmentally friendly, not combustible. The chemical resistance of foam glass, along with its stiffness, incombustibility and low density, make it possible to use it as a heat and waterproofing material in various, including aggressive, environments. Blocks and boards made of foam glass are widely used, for example, for heat and waterproofing walls, roofs, ceilings, floors, pipelines, etc.

A typical thermal insulation option, for example, a concrete coating using foam glass blocks, is shown in the figure (Fig. 1) (http://penosteklo.org/index.php?pid=6). A layer of hot bitumen 3 is applied to a concrete slab 1, previously treated with a primer on a bitumen base 2, and foam glass plates are laid on it 4. Then, a layer of hot bitumen is applied to the foam glass plates and the first layer of roofing is laid 5. The roofing is usually laid in several layers, while on each underlying layer of the roof coating a layer of hot bitumen is applied. A layer of adhesive emulsion 6 and a layer of mineral chips 7 are applied to the top layer of the roofing.

For fixing blocks of foam glass to the base of the roof, cement-sand and cement-lime mortars are also used. However, as a rule, all currently widely used constructive options for using foam glass as a heat-insulating material are low-tech, are associated with the consumption of a large number of additional materials and do not provide the necessary quality and service life. In addition, when using adhesive materials based on bitumen, the fire resistance of building structures is reduced.

A known building block (Patent RU No. 94249, IPC E04C 1/42, 05/20/2010), having the shape of a parallelepiped made of foam glass with pores formed by glass partitions of the following composition: SiO2 - 70-73.8%, A ₂ O ₃ - 4-5%, CaO - 6-7%, MgO - 3-3.8%, K2O + Na20 - 13-14%, Fe ₂ O ₃ - not more than 0.2%, while the pores have a closed loop, their transverse size is 0.3-1.0 mm, and the thickness of the partitions does not exceed 1/3 of the transverse size of the pores they form.

The block is characterized by high strength, low water absorption and density, however, it is not technologically advanced when used as a heat-insulating material, for example, for roofs or partitions, since it is impossible to securely fasten it to structural elements of the base of the roof or partition without violating the integrity of the block, and violation of the integrity of the block leads , in turn, to reduce the quality and service life of the roof and partitions.

The task to which the utility model is directed is to create a technologically advanced heat-insulating coating based on foam glass, which makes it possible to fully use the qualitative characteristics of the starting materials.

At present, liquid ceramic thermal insulation is increasingly being used as a thermal insulation material. Known, for example, is liquid ceramic thermal insulation RE-TERM manufactured by Innovative Technologies LLC, Russia (http://www.re-term.ru), which is a liquid thermal insulation material in the form of a suspension of ceramic and silicone microspheres, which forms after application on the surface to be treated, a polymer coating having high heat and waterproofing properties. The material has high adhesion to any building materials; has a working temperature range from -60 ° C to + 250 ° C (special modifications up to + 1000 ° C); resistant to mechanical and weathering; fireproof and environmentally friendly. When using this material, special preparation of the processed surface and the use of special equipment are not required. The material can be applied to the surface with a regular brush or roller.

High adhesion of liquid ceramic thermal insulation in combination with very low thermal conductivity allows it to be used as an adhesive material for fastening sheets, panels, blocks or slabs of various thermal insulation materials to the bases of insulated structures (walls, partitions, ceilings and coatings of buildings and structures).

A known method of manufacturing a heat-insulating multilayer composite coating (RU 2352467 C2, IPC VV 27/02, 04/20/2009). The method consists in sequentially applying to the possibly preheated surface of the coating layers, first a liquid-ceramic coating of a polymer composition containing a binder, a mixture of hollow microspheres, differing in size from 10 to 500 microns and bulk density from 650 to 50 kg / m ³ , and auxiliary target additives, then one or more layers of fiberglass are applied to a coating that has not yet dried, and then one or more layers of a liquid-ceramic coating are applied to the surface of the fiberglass, then carry out the final drying of the coating. Using this method, the qualitative and technological characteristics of the resulting coatings are significantly improved, however, it does not allow to obtain the values of the coating parameters that are achieved when using foam glass blocks.

The technical result achieved by the claimed utility model is to reduce the thermal conductivity and water absorption of the coating, to increase the resistance of the coating to the effects of aggressive environmental conditions, to increase the fire resistance of building structures, to preserve the integrity of the foam glass blocks, to increase the service life of building structures, and the processability of the coating.

The specified technical result is achieved in that as the main heat-insulating material using blocks of foam glass 3, made in the form of a flattened prism. At the same time, as shown in the figure (Fig. 2), at least one layer of liquid ceramic thermal insulation 2 is preliminarily applied to the surface of the base of the protected structure 1 (walls, partitions, ceilings, coatings - roofs). Then, on the layer of liquid ceramic thermal insulation over a period of time not exceeding the time of its complete polymerization, foam glass blocks are laid in a continuous layer, having previously applied at least one layer of liquid ceramic thermal insulation to their side faces. In this case, the blocks are combined with the base of the protected structure and with each other tightly, without the formation of air cavities in the layers of liquid ceramic insulation between the lower face of the block and the base of the protected structure, as well as between the side faces of adjacent blocks. Then, at least one layer of liquid ceramic thermal insulation 4 is applied to the outer surface of the foam glass block layer 4. After the outer layer of liquid ceramic thermal insulation is fully polymerized, the coating is ready for use, while the integrity of the foam glass blocks is not compromised and there is no need to use them to fix the basis of the protected design of special tools.

One of the possible options for a thermal insulation coating based on foam glass blocks using liquid ceramic thermal insulation is shown in the figure (Fig. 3), where on the surface of the base of the protected structure 1 there is a layer of foam glass blocks 3, bonded to the base surface and to each other with a layer of liquid ceramic thermal insulation 2. Liquid ceramic thermal insulation is also applied to the outer surface of the foam glass blocks.

Due to the properties of liquid ceramic thermal insulation and foam glass, maintaining the integrity of the foam glass blocks and the structure to be protected, the parameters of thermal conductivity and water absorption of the thermal insulation coating made in this way are significantly improved, the fire resistance of the coating is increased, as well as the operational characteristics of the building structures protected by this coating as a whole. The absence of the need to use for fixing blocks of foam glass on the basis of the protected design of special means determines the manufacturability of the thermal insulation coating obtained by this method.

To increase the resistance of the thermal insulation coating made by this method to the effects of an aggressive external environment and improve its consumer qualities, as shown in the figure (Fig. 4), on the outer layer of ceramic thermal insulation 4 after full polymerisation of liquid ceramic thermal insulation by gas dynamic spraying using currently known technologies and equipment, for example, DIMET® technology and equipment of the company Obninsky Powder Spraying Center LLC (OTPN) Russia (http://www.amazonit.ru/ocpn/in dex0.html), apply a protective layer 5 of finely dispersed material, for example, metal.

Claims (3)

1. A heat-insulating coating using foam glass blocks made in the form of a flattened prism, characterized in that liquid ceramic thermal insulation is used to fasten the foam glass blocks to the base of the protected structure and between each other, at least at least one layer of liquid ceramic thermal insulation, on which, over a period of time not exceeding the time of its complete polymerization, blocks of foam glass with a preliminary coating on them are laid in a continuous layer side faces with at least one layer of liquid ceramic thermal insulation, while the blocks are aligned with the base of the protected structure and with each other tightly, without the formation of air cavities in the liquid ceramic insulation between the lower faces of the blocks and the base of the protected structure, and also between the side faces of adjacent blocks, while on the outer surface of the layer formed by the blocks of foam glass, applied at least one layer of liquid ceramic thermal insulation. 2. The heat-insulating coating according to claim 1, characterized in that at least two layers of liquid ceramic thermal insulation are applied to the outer surface of the layer formed by the foam glass blocks, while the outer layer of liquid ceramic thermal insulation is applied after the polymerisation of the underlying material is complete. 3. Thermal insulation coating according to claim 1 or 2, characterized in that a protective layer of finely dispersed material is applied to the outer layer of ceramic thermal insulation after its hollow polymerization by gas-dynamic spraying.