RU72242U1 - EXTERIOR WALL INSULATION SYSTEM - Google Patents

Abstract

1. The system of thermal insulation of external walls contains a multilayer effective insulation installed on the inner surface of the wall from the side of the heat-insulated room, at least one layer of which is made in the form of a low-conductivity high-compressive porous material, mounted directly on the inner surface of the wall from the side of the heat-insulated room, and the second layer is made in the form of heat and noise insulation material installed on top of the first layer of effective insulation and made containing at least one vapor-proof heat-reflecting screen facing the inside of the insulated room, the system comprises a heat-insulating layer made in the form of an air gap located between the vapor-tight heat-reflecting screen of the layer of heat and noise insulation material and the interior of the heat-insulated room, installed, in turn, on the fastener system placed on top of a multilayer effective insulation from the side of a heat-insulated room, while the materials of the first and the second layer of effective insulation is chosen so that the thermal conductivity coefficient λ (W / m ° C) of the first layer of effective insulation - a layer of low heat conductive compressive porous material - is less than the coefficient of thermal conductivity λ (W / m ° C) of the second layer of effective insulation - a layer of heat and noise insulation material, and their ratio κ = λ / λ, depending on operating conditions, lies in the range κ = 0.6-0.87, and the vapor permeability coefficient ρ (mg / m · h · Pa) of the second layer of effective insulation

Description

The utility model relates to the technology of construction and repair and can be used to increase heat-shielding properties and insulation of the outer walls of building structures, as well as horizontal surfaces - floors, ceilings of buildings, etc.

The closest analogue is known from the prior art — a prototype — of the claimed utility model — an external wall insulation system having load-bearing elements fixed to the wall, an efficient insulation installed on the wall surface, mounting profiles and facing plates fixed to them, a waterproofing layer located between the facing plates and an effective heater, and a vapor barrier layer located between the outer surface of the wall and an effective heater (see Russia, patent No. 45745, Е04В 1/74, 2004).

The achievement of the required technical result in the prototype is hindered by the complexity of the design, the inability to use it for insulation from inside insulated rooms, as well as insufficient thermal resistance, which does not allow to achieve the required characteristics of insulation.

The task to which the claimed utility model is directed is the creation of a thermal insulation system for the external walls of building structures, which allows for the implementation of work on the insulation and decoration of heat-insulated rooms from the inside of the premises.

The technical results obtained by implementing the claimed utility model include simplification of the design,

increasing its reliability, increasing the thermal resistance of the system, and, as a result, improving the thermal insulation of the room.

The problem is solved, and the technical result is achieved by the fact that the thermal insulation system of the external walls contains a multilayer effective insulation installed on the inner surface of the wall from the side of the heat-insulated room, at least one layer of which is made in the form of a low heat-conducting, highly compressive porous material mounted directly on the inner surface of the wall from the side of the insulated room, and the second layer is made in the form of heat-vapor-noise insulation material, installed on top of the first layer of effective insulation, and made containing at least one vapor-tight heat-reflecting screen facing the inside of the insulated room, the system contains a heat-insulating layer made in the form of an air gap located between the vapor-tight heat-reflecting screen of the layer of heat-vapor-noise insulation material and the inner decoration of a heat-insulated room, installed, in turn, on a fastener system placed on top of a multi-layer effective eplitelya from the thermally insulated space, the materials of the first and second layers efficient insulation are chosen so that the thermal conductivity coefficient λ ₁ (W / m ° C) of the first layer effective insulation - layer of low thermal conductivity, high compression of the porous material - is less than the thermal conductivity coefficient λ ₂ (W / m ° C) of the second layer of effective insulation - a layer of heat-vapor-noise insulation material, and their ratio κ = λ ₁ / λ ₂ depending on operating conditions lies in the range κ = 0.6-0.87, and the coefficient of steam paucity ρ ₂ (mg / m ^x h ^x Pa) of the second layer of effective

insulation - a layer of heat-vapor-noise-insulating material - less than the vapor permeability coefficient ρ ₁ (mg / m ^x h ^x Pa) of the first layer of effective insulation - a layer of low heat conductive, highly compressive porous material, and their ratio μ = ρ ₂ / ρ ₁ in depending on operating conditions lies in the range μ = 0.056-0.067, moreover, the ratio of the thicknesses of the first α and second β layers of the effective insulation δ = α / β and lies in the range δ = 0.25-0.33, and the minimum thickness of the heat-insulating layer in the shape of the air gap is determined from the relation μ = ε / τ, where ε is the thickness effective insulation, and τ is the thickness of the air gap, depending on the value of the coefficient μ, determined by the calculation-practical method, and lying in the range μ = 0.3-0.375.

The thermal insulation system of the external walls can be equipped with an additional vapor-proof heat-reflecting screen located between a layer of low heat-conducting, highly compressive porous material and a layer of heat-vapor-noise insulation material.

In the system of thermal insulation of external walls, a vapor-tight heat-reflecting screen can be made in the form of a foil surface of a layer of heat-vapor-noise insulation material, for example, from aluminum.

In the system of thermal insulation of external walls, a layer in the form of a low heat-conducting, high compressive porous insulation can be made of a material with a density of 28-45 kg / m ² , compressive strength at 10% linear deformation of at least 0.25 MPa, tensile strength under static bending depending on the thickness of 0.4-0.7 MPa and an elastic modulus of 15-18 MPa.

A layer in the form of a heat-vapor-noise-insulating material can be made of a material with a coefficient of thermal reflection of the surface, at least 90%, a coefficient of optical reflection of the surface, at least 97%, a heat transfer coefficient (for a period of 24 hours) of 0.45-0 , 51 W / m ² ° C and specific heat of 1.95-2.0 m ² ° C / W.

The utility model is illustrated in the drawing, where Fig. 1 shows a system of thermal insulation of external walls in a lateral section.

The thermal insulation system of the outer walls 1 contains a multilayer effective insulation installed on the inner surface of the wall 1 from the side of the insulated room 2 with a clip to the surface of the wall 1.

At least one layer 3 of effective insulation is made in the form of a low heat conductive, high compressive porous material, mounted directly on the inner surface of the wall 1 from the side of the insulated room 2.

The second layer 4 of effective insulation is made in the form of heat-vapor-noise insulation material installed on top of the first layer 3 of effective insulation, and made containing at least one vapor-proof heat-reflecting screen 5, facing the inside of the insulated room 2.

The system contains a heat-insulating layer made in the form of an air gap 6 located between the vapor-tight heat-reflecting screen 5 of the layer 4 of the heat-vapor-noise-insulating material and the interior finish 7 of the heat-insulated room, installed, in turn, on the fastener system 8, placed on top of the multilayer effective insulation with sides of the insulated room 2.

The materials of the first 3 and second 4 layers of effective insulation are selected so that the thermal conductivity coefficient λ ₁ (W / m ° C) of the first layer 3 of effective insulation - a layer of low heat conductive compressive porous material - is less than the coefficient of thermal conductivity λ ₂ (W / m ° C) the second layer 4 of effective insulation - a layer of heat-vapor-noise insulation material, and their ratio κ = λ ₁ / λ ₂ depending on operating conditions lies in the range κ = 0.6-0.87, and the vapor permeability coefficient ρ ₂ ( mg / m ^x h ^x Pa) second layer 4 effective of the heater — a layer of heat-vapor-noise-insulating material — is less than the vapor permeability coefficient ρ ₁ (mg / m ^x h ^x Pa) of the first layer 3 of effective insulation - a layer of low heat-conducting high compressive porous material, and their ratio μ = ρ ₂ / ρ ₁ in depending on operating conditions lies in the range μ = 0.056-0.067.

The ratio of the thicknesses α of the first 3 and β of the second 4 layers of the effective insulation is δ = α / β and lies in the range δ = 0.25-0.33, and the minimum thickness of the heat-insulating layer in the form of an air gap 6 is determined from the ratio μ = ε / τ, where ε is the thickness of the effective insulation, and τ is the thickness of the insulating layer in the form of an air gap 6, depending on the value of the coefficient μ, determined by the calculation-practical method, and lying in the range μ = 0.3-0.375.

In some cases, the system may be equipped with an additional vapor-proof heat-reflecting screen (not shown) located between the layer 3 of low heat-conducting, highly compressive porous material and layer 4 - heat-vapor-noise insulation material.

The vapor-proof heat-reflecting screen 5 or 9 can be made in the form of a foil-coated surface of a layer of heat-vapor-noise insulation material, and the foil-coated surface of a vapor-tight heat-reflection screen 5 of layer 4 of a heat-vapor-noise insulation material can be made, for example, of aluminum.

Layer 3 in the form of low heat conductive, high compressive strength porous insulation can be made, for example, from a material with a density of 28-45 kg / m ² , compressive strength at 10% linear deformation of at least 0.25 MPa, tensile strength under static bending depending on the thickness of 0.4-0.7 MPa and an elastic modulus of 15-18 MPa.

Layer 4 in the form of heat-vapor-noise insulation material can be made, for example, of a material with a thermal reflection coefficient of the surface of at least 90%, an optical reflection coefficient of the surface of at least 97%, and heat transfer coefficient (for a period of 24 hours) 0 , 45-0.51 W / m ² ° C and specific heat 1.95-2.0 m ² ° C / W.

The system operates as follows.

Being mounted on the wall 1 from the inside - from the side of the insulated room 2 - in the declared sequence - layer 3 of low heat conductive, high compressive porous material - layer 4 of heat-vapor-noise insulation material - vapor-proof heat-reflecting screen 5, facing the inside of the insulated room 2 - heat-insulating layer in the form of an air gap 6 - interior decoration 7 of the heat-insulated room 2, the system provides the required characteristics of insulation by increasing the overall thermal sky resistance of the whole system.

Cold air of the external environment acts on the outer wall 1, cooling it by an amount determined by the thermal conductivity of the material of the wall 1 and the temperature of the outside air.

From the side of the heat-insulated room 2, the heat flux primarily interacts with the heat-insulating layer in the form of an air gap 6 behind the interior finish 7 of the heat-insulated room 2.

This first line of interaction prevents the access of warm room air directly to the elements of the insulation system having a lower temperature and, therefore, lowering its temperature, preventing direct contact.

Further, the heat flux of the heat-insulated room 2 interacts with the vapor-tight heat-reflecting screen 5 facing inside, providing reflection of up to 97% of radiant heat.

Directly behind the vapor-tight heat-reflecting screen 5 is a layer 4 of heat-vapor-noise insulation material. In fact, the surface of the layer 4 of heat-vapor-noise-insulating material facing the inside of the insulated room 2 is metallized - it forms a vapor-tight heat-reflecting screen 5.

Having at least one vapor-proof heat-reflecting screen 5 facing the insulated room, the combination of “layer 4 - screen 5” provides the system with the necessary heat and vapor insulation characteristics that persist throughout the entire period of operation. Due to the physical characteristics and characteristics of the material of layer 4 itself (heat transfer coefficient (for a period of 24 hours) 0.45-0.51 W / m ² ° С, specific

heat capacity of 1.95-2.0 m ² ° С / W), high noise insulation properties are also provided.

Due to its own characteristics of thermal conductivity, layer 4 of heat-vapor-noise insulation material in combination with a vapor-tight heat-reflecting screen 5 allows you to store heat in a heat-insulated room 2, preventing the interaction and cooling of the warm air of room 2 with cold surfaces.

In some cases, an additional vapor-tight heat-reflecting screen can be introduced into this combination, located between the layer of 4 heat-vapor-noise insulation material and layer 3 of low heat-conducting, highly compressive porous material. Under certain operating conditions, the introduction of an additional vapor-tight heat-reflecting screen increases the overall thermal resistance.

Further, in the thermal insulation system of the external walls, a layer 3 of low heat-conducting, highly compressive porous material is “connected” to the heat storage.

Having a thickness greater than the thickness of layer 4 of heat-vapor-noise insulation material, the thermal conductivity coefficient λ ₁ (W / m ° C) is smaller, and the vapor permeability coefficient ρ ₂ (mg / m ^x h ^x Pa) is larger, layer 3 is low heat conductive, high compressive porous material provides the final thermal insulation between the warm air of the insulated room 2 and the cold outer wall 1.

With the claimed combination of materials of the insulation layers, their thicknesses α and β, the thermal conductivity λ ₁ and λ ₂ and the vapor permeability coefficients ρ ₂ and ρ ₁ , as well as the thickness τ of the heat-insulating layer in the form of an air gap of 6 s

the formation of a multilayer and multi-level thermal insulation package, the so-called “Thermos effect”, in which the heat in room 2 persists for an arbitrarily long time.

The claimed combination of layers 3 and 4 of an effective heater, vapor-tight heat-reflecting screen 5 and air gap 6, which are sequentially located between the inner side facing the insulated room 2 side of the outer wall 1 and the inner finish 7 with the stated ratio of physical and thermal characteristics, reflecting the dependence of the thickness of the air gap from the thermal conductivity of the material of the layer of porous insulation, can significantly increase the overall thermal resistance of the entire system.

When creating and equipping the system of thermal insulation of external walls, well-known and widely used structural materials and means were used, therefore, the system can be manufactured both in mass production and in individual construction.

Claims (6)

1. The system of thermal insulation of external walls contains a multilayer effective insulation installed on the inner surface of the wall from the side of the heat-insulated room, at least one layer of which is made in the form of a low-conductivity high-compressive porous material, reinforced directly on the inner surface of the wall from the side of the insulated room, and the second layer is made in the form of heat and noise insulation material installed on top of the first layer of effective insulation and made containing at least one vapor-proof heat-reflecting screen facing the inside of the insulated room, the system comprises a heat-insulating layer made in the form of an air gap located between the vapor-tight heat-reflecting screen of the layer of heat and noise insulation material and the interior of the heat-insulated room, installed, in turn, on the fastener system placed on top of a multilayer effective insulation from the side of a heat-insulated room, while the materials of the first and the second layer of effective insulation is selected so that the coefficient of thermal conductivity λ ₁ (W / m ° C) of the first layer of effective insulation - a layer of low heat conductive compressive porous material - is less than the coefficient of thermal conductivity λ ₂ (W / m ° C) of the second layer of effective insulation - layer of heat and noise insulation material, and their ratio κ = λ ₁ / λ ₂ depending on operating conditions lies in the range κ = 0.6-0.87, and the vapor permeability coefficient ρ ₂ (mg / m · h · Pa) of the second layer of effective insulation - layer of heat transfer oizolyatsionnogo material - less vapor permeability coefficient ρ ₁ (mg / m · h · Pa) of the first layer effective insulation - layer nizkoteploprovodnogo high compression of the porous material, and the ratio μ = ρ ₂ / ρ ₁ depending on operating conditions lies between μ = 0.056-0.067, and the ratio of the thicknesses of the first α and second β layers of the effective insulation δ = α / β and lies in the range δ = 0.25-0.33, and the minimum thickness of the heat-insulating layer in the form of an air gap is determined from the relation μ = ε / τ, where ε is the thickness of the effective insulation, and τ - the thickness of the air gap, depending on the value of the coefficient μ, determined by the calculation and practical method and lying in the range μ = 0.3-0.375. 2. The system of thermal insulation of external walls according to claim 1, characterized in that it is equipped with an additional vapor-tight heat-reflecting screen located between a layer of low heat-conducting, highly compressive porous material and a layer of heat and noise insulation material. 3. The system of thermal insulation of external walls according to claim 1 or 2, characterized in that the vapor-tight heat-reflecting screen is made in the form of a foil surface of a layer of heat and noise insulation material. 4. The thermal insulation system of external walls according to claim 2, characterized in that the foil surface of the vapor-tight heat-reflecting screen of the layer of heat and noise insulation material is made of aluminum. 5. The system for thermal insulation of external walls according to claim 1, characterized in that the layer in the form of a low-conductivity high-compressive porous insulation is made of a material with a density of 28-45 kg / m ² , compressive strength at 10% linear deformation of at least 0, 25 MPa, tensile strength under static bending depending on the thickness of 0.4-0.7 MPa and an elastic modulus of 15-18 MPa. 6. The thermal insulation system of external walls according to claim 1, characterized in that the layer in the form of heat and noise insulation material is made of a material with a thermal reflection coefficient of the surface of at least 90%, an optical reflection coefficient of the surface of at least 97%, and heat transfer coefficient (for a period of 24 hours ) 0.45-0.51 W / m ² ° C and specific heat 1.95-2.0 m ² ° C / W.