RU220170U1 - THERMAL INSULATION FACADE PANEL - Google Patents

Abstract

The utility model relates to elements of building structures, in particular to thermal insulating facade panels, and can be used in the manufacture of thermal insulating panels at enterprises in the construction industry, as well as for thermal insulation of residential, public, administrative and domestic civil and industrial buildings. Thermal insulating facade panel contains outer and inner skins, glued with insulation located between them. The outer skin is made of a material with low moisture and vapor permeability and contains fasteners in the form of a tongue-and-groove lock. The inner lining is made of vapor-permeable material. The insulation is made in the form of lamellas made of heat-insulating material and contains cutouts of a trapezoidal cross-section shape, located with a smaller base towards the back side of the outer skin. The cutouts form ventilation channels with the back side of the outer skin. The inventive design of a heat-insulating facade panel has increased ventilation efficiency and makes it possible to provide more favorable operating conditions for the walls of buildings and structures compared to known panels for similar purposes. 1 salary f-ly, 5 ill., 4 ave.

Description

The utility model relates to elements of building structures, in particular, to thermal insulating facade panels, and can be used in the manufacture of thermal insulating panels at enterprises in the construction industry, as well as for thermal insulation of residential, public, administrative and domestic civil and industrial buildings.

A thermal insulation panel is known (international application No. WO2017144707, IPC B29C44/02, B29C44/32, E04C2/52; E04D3/35, publication date 08/31/2017), containing outer and inner skins connected to insulation located between them. The outer and inner cladding is made of thin sheet metal or non-metallic material. The insulation is made monolithic from polymer and/or mineral material and contains many holes oriented in the longitudinal direction parallel to the planes of the outer and inner skins. The holes can be made triangular, polygonal or circular in cross section. In addition, the holes can be spaced evenly across the width of the panel or at different distances from each other, or grouped into subgroups. The thickness of the outer and inner skins ranges from 0.5 to 1 millimeter. The thickness of the insulation is from 4 to 25 centimeters, preferably from 10 to 12 centimeters. The ratio of the total volume of insulation to the volume of holes is from 1:0.2 to 1:0.4. The holes in the insulation are intended for laying electrical, plumbing and other communications.

The disadvantage of the known technical solution is the relatively high complexity of manufacturing, due to the need to use form-building parts to make holes in a monolithic layer of insulation.

A heat-insulating facade panel is known (patent No. 94597, IPC E04F13/00, E04C2/292, publication date 05/27/2010), containing outer skin and two layers of insulation. The side end edges of the outer skin contain tongue-and-groove locks. The insulation layer adjacent to the back side of the outer skin contains cutouts that form ventilation channels of a rectangular cross-section. The insulation layer adjacent to the structure is sealing and is designed to compensate for unevenness on the surface of the walls of the structure and prevent air gaps with the facade panel. The material for external cladding can be plasterboard or thin galvanized metal with a polymer coating. Mineral wool, glass wool, polyurethane or expanded polystyrene slabs are used as insulation material. The outer skin and insulation are connected to each other using an adhesive composition.

The disadvantages of the known technical solution are:

reduction in ventilation efficiency due to a decrease in the cross-sectional area of ventilation ducts of rectangular cross-section as a result of their local “clogging” with the adhesive composition during the manufacture of facade panels;

reduction in thermal insulation characteristics due to uneven density of insulation as a result of the formation of gaps of different sizes at the joints of slabs during the manufacture of facade panels.

A heat-insulating facade panel is known (patent No. 170175, IPC E04F13/07, E04F13/075, publication date 04/18/2017), containing outer and inner skins glued with insulation located between them. The outer skin is made of a material with low moisture and vapor permeability, which is selected from sheet metal, polymer or composite material, plasterboard, plywood, oriented strand board, glass-magnesium sheet, high-pressure laminate or spray-on coating, such as cork. The side end edges of the outer skin contain tongue-and-groove locks. The internal lining is made of vapor-permeable material, which is selected from fiberglass, fiberglass, glass composite or sprayed materials. The insulation is made in the form of lamellas made of hydrophobized heat-insulating material, which is selected from mineral wool or glass wool with a density of 60 to 140 kg/m3. The fibers of the heat-insulating material in the lamellas are located perpendicular to the plane of the outer skin. In addition, the lamellas are located with their ends offset relative to each other in the longitudinal direction, which significantly improves the uniformity of the insulation layer. The lamellas, in addition to the end ones, contain cutouts that form rectangular-shaped ventilation channels with the back side of the outer skin. The internal surfaces of ventilation ducts can be treated with dust-removing agents. The vapor-permeable material of the internal lining is selected from fiberglass, fiberglass, glass compound or sprayed materials. The insulation is connected to the outer and inner skins using an adhesive composition. Making the insulation in the form of a set of lamellas makes it possible to improve the manufacturability of the facade panel design and eliminate the above-mentioned disadvantage associated with a decrease in thermal insulation characteristics.

The disadvantage of the known technical solution is a significant reduction in ventilation efficiency due to a decrease in the cross-sectional area of the rectangular ventilation ducts in cross-section as a result of local “clogging” with the adhesive composition during the manufacture of facade panels. As a result of this, the intensity of removal of condensate and construction moisture from adjacent areas of the walls of buildings is reduced, which leads to their increased humidity and, accordingly, a decrease in thermal resistance, accelerated damage and mold damage.

The utility model is based on the task of increasing the ventilation efficiency of a heat-insulating facade panel due to a different design of ventilation ducts.

The technical result of the implementation of this task is to ensure a stable flow area of ventilation ducts in the manufacture of heat-insulating facade panels by reducing the possibility of the adhesive composition flowing into the cavities of the cutouts on the lamellas.

The problem is solved by the fact that in a heat-insulating facade panel containing outer and inner skins, glued with insulation located between them, while the outer skin is made of a material with low moisture and vapor permeability and contains clamps in the form of a tongue-and-groove lock, the inner the sheathing is made of vapor-permeable material, and the insulation is made in the form of lamellas made of heat-insulating material and contains cutouts that form ventilation channels with the back side of the outer skin; according to the utility model, the said cutouts are made trapezoidal in cross-section and are located with a smaller base towards the back side of the outer skin.

In this case, it is advisable that the geometric dimensions of the cutouts on the lamellas and the number of ventilation ducts be selected taking into account the design features and purpose of the heat-insulating facade panel.

The improved design of the heat-insulating facade panel allows us to achieve the claimed technical result. In particular, making cutouts on lamellas of a trapezoidal cross-section shape, located with a smaller base towards the back side of the outer skin, makes it possible to increase the surface area of the insulation in the area of connection with the outer skin and thereby reduce the amount of pressure on it during the process of gluing them, which, with for its part, reduces the intensity of squeezing part of the adhesive composition inward. The location of the larger base of the cutouts, trapezoidal in cross-section, inside the body of the lamellas makes it possible to provide the calculated cross-sectional area of the ventilation ducts with a relatively small depth of the cutouts inside the lamellas. In addition, this arrangement of a larger base helps to increase the area of the vertical walls of the ventilation ducts, through which the main part of the moisture enters them from the vapor-permeable structure of the lamellas.

The essence of the proposed technical solution is illustrated in the presented drawings, where

in fig. Figure 1 shows a cross section of the panel (example 1);

in fig. 2 – cutout A in Fig. 1 (cross section of the ventilation duct);

in fig. 3 – cross section of the panel (example 2);

in fig. 4 – cross section of the panel (example 3);

in fig. 5 – cross section of the panel (example 4).

The thermal insulation facade panel contains an outer skin 1, an inner skin 2 and insulation 3 located between them. The outer skin 1 is made of a material with a low coefficient of moisture and vapor permeability. The side edges of the outer skin 1 are made with clamps 4 in the form of a tongue-and-groove lock. The inner lining 2 is made of vapor-permeable material. Insulation 3 is made in the form of lamellas made of heat-insulating material. The fibers of the heat-insulating material in the lamellas are located perpendicular to the plane of the outer skin 1, and the ends of the lamellas are offset relative to each other in the longitudinal direction. The lamellas have cutouts of a trapezoidal cross-section shape, forming, together with the back side of the outer skin 1, ventilation channels 5. In this case, the cutouts are oriented in such a way that the smaller base is located on the back side of the outer skin 1. The geometric dimensions of the cutouts, trapezoidal in cross-section, are characterized by their height h, the length of the smaller base a and the length of the larger base b (Fig. 2). The height h is chosen in the range from 15 to 40 mm. The ratio between the length of bases a and b can range from 0.2 to 0.5.

The specific geometric dimensions of the cutouts on the lamellas and the number of ventilation ducts are selected taking into account the design features and purpose of the heat-insulating panel.

The connection of the insulation 3 with the outer 1 and inner 2 skins is made using one- or two-component polyurethane glue.

A material with a low coefficient of moisture and vapor permeability for the outer skin 1 is selected from flat or corrugated sheet metal with a protective coating, for example, from metal with zinc or polymer coating or a composite material, or a high-pressure laminate. Strength, thermal, fire-resistant, climatic and other characteristics of the material for external cladding 1 must meet the requirements for facade panels for this purpose. Thermal insulation material for the lamellas is selected from hydrophobized mineral wool or glass wool with a density of 60 to 140 kg/m3. The vapor-permeable material for the inner lining 2 is selected from fiberglass or fiberglass.

Thermal insulating facade panels are manufactured at construction industry enterprises using well-known sandwich panel production technology. At the same time, to increase the reliability of ventilation ducts, their internal surfaces can be treated with a dust-removing agent. To protect against rodents, a protective mesh can be mounted on the end surface of the heat-insulating facade panel, blocking the entrance to the ventilation ducts.

Below are examples of specific implementations of thermal insulating façade panels with different numbers of ventilation ducts.

Example 1. Thermal insulating facade panel with 8 lamellas (Fig. 1, 2).

The thermal insulation facade panel contains an outer skin 1, an inner skin 2 and an insulation 3 located between them, consisting of two end lamellas 6, 7 and six intermediate lamellas 8-13. The outer skin 1 is made of flat sheet metal with a double-sided protective polymer coating. The inner lining 2 is made of fiberglass. Lamels 6-13 are made of hydrophobized mineral wool. The panel contains 6 ventilation channels 5, formed by double-sided cutouts of a trapezoidal cross-section shape on the lamellas 8, 9, 12 and 13, and one-sided cutouts on the adjacent lamellas 6, 10 and 11, 7. The height of the cutouts h is 20 mm, and the lengths of the bases a and b are 15 and 30 mm, respectively. The total area of the ventilation ducts is 54 ^cm2 .

Example 2. Thermal insulating facade panel with 6 slats (Fig. 3).

The thermal insulation facade panel contains an outer skin 1, an inner skin 2 and an insulation 3 located between them, consisting of two end lamellas 14, 15 and four intermediate lamellas 16-19. The outer skin 1 is made of flat thin-sheet galvanized metal. The inner lining 2 is made of fiberglass. Lamels 14-19 are made of hydrophobized glass wool. The panel contains 4 ventilation channels 5, formed by double-sided cutouts of a trapezoidal cross-section in the lamellas 16 and 19 and one-sided cutouts on the adjacent lamellas 14, 17 and 15, 19, respectively. The height of the cutouts h is 40 mm, and the length of the bases a and b, respectively, 20 and 30 mm. The total area of the ventilation ducts is 80 ^cm2 .

Example 3. Thermal insulating facade panel with 12 lamellas (Fig. 4).

The thermal insulation facade panel contains an outer skin 1, an inner skin 2 and an insulation 3 located between them, consisting of two end lamellas 20, 21 and ten intermediate lamellas 22-31. The outer skin 1 is made of flat composite material. The inner lining 2 is made of fiberglass. Lamels 20-31 are made of hydrophobized glass wool. The panel contains 6 ventilation channels 5, formed by one-sided cutouts of a trapezoidal cross-section shape on lamellas 21-27 and 29-31. The height of the cutouts h is 30 mm, and the lengths of the bases a and b are 25 and 35 mm, respectively. The total area of the ventilation ducts is 90 ^cm2 .

Example 4. Thermal insulating facade panel with 10 lamellas (Fig. 5).

The thermal insulation facade panel contains an outer skin 1, an inner skin 2 and an insulation 3 located between them, consisting of two end lamellas 32, 33 and eight intermediate lamellas 34-41. The outer skin 1 is made of high pressure flat laminate. The inner lining 2 is made of fiberglass. Lamellas 32-41 are made of hydrophobized mineral wool. The panel contains 4 ventilation channels 5, formed by one-sided cutouts of a trapezoidal cross-section shape on the adjacent surfaces of the lamellas 34 and 35, 36 and 37, 38 and 39, 40 and 41. The height of the cutouts h is 30 mm, and the length of the bases a and b, respectively, 30 and 40 mm. The total area of the ventilation ducts is 84 ^cm2 .

Thermal insulating facade panels are mounted on the outer surfaces of the walls of buildings and structures in a known manner using threaded fasteners, which are selected from facade anchor bolts, expansion dowels and self-tapping screws. The connection of adjacent heat-insulating facade panels to each other is carried out using clamps 4 in the form of a tongue-and-groove lock. To protect from atmospheric precipitation, the locations of fastening elements on the outer skin are covered with protective and decorative elements and/or extensions.

The proposed design of the heat-insulating façade panel has been tested under actual manufacturing and operating conditions. The test results confirmed an increase in the ventilation efficiency of the improved panel compared to known thermal insulation facade panels, which allows for more favorable operating conditions for the walls of buildings and structures when used.

Claims (2)

1. Thermal insulating facade panel, containing outer and inner skins, glued with insulation located between them, while the outer skin is made of a material with low moisture and vapor permeability and contains clamps in the form of a tongue-and-groove lock, the inner skin is made of a vapor-permeable material , and the insulation is made in the form of lamellas made of heat-insulating material and contains cutouts that form ventilation channels with the back side of the outer skin, characterized in that the said cutouts are made trapezoidal in cross-section and are located with a smaller base towards the back side of the outer skin. 2. The panel according to claim 1, characterized in that the geometric dimensions of the cutouts on the lamellas and the number of ventilation ducts are selected taking into account the design features and purpose of the heat-insulating facade panel.