CZ2018179A3 - Contact system to suppress thermal bridges in buildings - Google Patents

Abstract

A contact system for suppressing point and line thermal bridges in buildings consists of a layer of material with a thermal conductivity of at least 5 W.m. A layer of thermally conductive material is affixed to the substrate by a water vapor impermeable adhesive.

Description

Field of technology

The invention relates to measures for suppressing the negative effects of thermal bridges - places with increased heat flux in buildings, such as wetting of walls and the formation of mold.

Prior art

A thermal bridge is a place on the building envelope where, in comparison with other surfaces of the envelope, higher heat losses occur due to heat transfer. The share of these heat losses in the total loss of the house usually reaches 10% and in unfavorable cases up to 30%. In addition to the higher energy consumption for heating due to cooling in the places of thermal bridges, it is a very undesirable consequence of condensation of moisture on the inner face of the building envelope and possible subsequent formation of mold.

Thermal bridges are formed mainly in lines on edges, joints of building structures and in places of combination of different materials (geometric and material thermal bridge). In addition, however, point weak points can also arise, for example in the places of anchoring of suspended facades, roofs, in the places of connection of balconies, in the corners between the walls and the ceiling of the building, etc.

In order to suppress the effects of thermal bridges, ie to increase the internal surface temperature in given places, building structures are most often insulated with thermal insulation from the outside. For aesthetic reasons, it is usually necessary to make such an adjustment over the entire area of the facade (which is costly). Less often, various internal or external coatings are used, which work only to a very limited extent. The low thermal conductivity of the material is mentioned as a key feature, especially of interior coatings. Coatings must be applied in greater thickness and will have a negative effect on the interior. It is therefore an additional internal insulation, which, however, there is a risk of condensation under the coating.

For existing buildings and sometimes for new buildings, the owner is faced with the task of quickly removing the manifestations of thermal bridges, while insulation of the entire house is not immediately affordable.

The object of the invention is to provide a contact system for suppressing the effects of thermal bridges in buildings, the implementation of which is very fast, inexpensive and does not affect the outer shell of the building and interiors only to an acceptable extent.

The essence of the invention

This task is solved by a contact system for suppression of point and line thermal bridges in buildings, the essence of which lies in the fact that it consists of a layer of material with thermal conductivity of at least 5 Wm ťK ¹ covering the inner wall of the building with increased heat flux and exceeding at least 5 cm into its surroundings, the layer of thermally conductive material being attached to the substrate by a water vapor impermeable adhesive.

The layer of thermally conductive material covering the place with the increased heat flux at the intersection of the two walls and the ceiling extends into both walls and into the ceiling or floor.

The layer of thermally conductive material covering the place with increased heat flux at the intersection of two walls extends into both walls.

The layer of thermally conductive material overlying the location with increased heat flux along the window frame extends into the window lining.

- 1 CZ 2018 - 179 A3

The layer of thermally conductive material can be glued to the face of the wall or built under the plaster.

The layer of thermally conductive material can be formed by a metal sheet, a metal foil or a coating, in particular graphite or graphene.

The essence of the invention is therefore the use of the increased thermal conductivity of the surface layer applied on the interior side at the location of the thermal bridge. The surface layer brings thermal energy from the nearest warmer surface of the structure and thus increases the temperature of this critical point. A thin layer of thermally conductive material must extend beyond the place with the lowest surface temperature, up to areas where the temperature is already sufficient due to the thermal insulation properties of the wall. It is usually a few decimetres. The thickness of the layer is sufficient to be about 1 mm, and the layer must be vapor-tightly connected to the substrate-glued, either under the plaster or on the plaster. If the layer is not vapor-tightly bonded to the substrate, water vapor may condense and mold grow under the layer. At the end, the entire finish is painted over and is aesthetically acceptable without further major building modifications.

Explanation of drawings

The invention will be further elucidated by means of the drawing, in which Fig. 1 shows schematically the application of a thermally conductive layer to a place with increased heat flux in a corner between a ceiling panel and two wall panels under an attic superstructure or a wall. frame.

Examples of embodiments of the invention

The measure according to the invention for suppressing the negative effects of thermal bridges in buildings is realized by inserting, applying or applying a thin layer of thermally conductive material to the surface of the inner walls of buildings or just below the surface. The measure concerns both unsatisfactory existing buildings and new buildings with thermal bridges. This solution is most suitable for suppressing thermal bridges in cold vertical and horizontal corners of perimeter walls and also in corners under the roof. Another critical place where the solution can be used is the window lining. Here, the internal surface temperature decreases due to the geometric thermal bridge, while there is also a linear thermal bond due to the mounting of the frame in the lining and also due to the spacer frame.

The measure according to the invention was applied to a point thermal bridge in a corner formed by a ceiling and two walls under the roof of a building - see Fig. 1, and to a linear thermal bridge on a lining along a window frame - see Fig. 2. Aluminum templates S1 were glued to the wall to S3 on the side of the square, resp. width a. By this dimension, therefore, the layer of thermally conductive material exceeded the point, resp. linear thermal bridge.

The measure was performed both in the environment of a real residential building and in the simulated environment of mathematically modeled 3D thermal fields. The input and boundary data of both experiments, as well as their results, are shown in the following table.

-2EN 2018 - 179 A3

Authentication method measurement modeling Thermal bridge type 3D point / 2D line 3D corner 2D corner 3D corner 2D corner Foil material / thermal conductivity (W.m \ K J AI / 200 AI / 200 AI / 200 AI / 200 Adhesive material adhesive adhesive PUR PUR Foil thickness 1 mm 1 mm 0.6 mm 0.6 mm Wall / roof material holes. brick / concrete + TI holes. brick/- holes. brick / aerated concrete holes. brick/- Wall / roof heat transfer coefficient (W.nrťK ' ¹ ) 0.38 / 0.24 0.38 / - 0.70 / 0.80 0.70 / - Under plaster 10 mm Yes Yes No No Foil geometry a = 250 mm a = 250 mm a = 500 mm a = 500 mm Indoor air temperature 22.0 ° C 22.0 ° C 21.0 ° C 21.0 ° C Exterior air temperature -5.0 ° C -5.0 ° C -15.0 ° C -15.0 ° C Wall temperature in the warmest place 20.6 ° C 16.8 ° C 15.7 ° C 13.5 ° C The temperature of the wall in the coldest place 10.4 ° C 11.9 ° C 5.2 ° C 10.9 ° C Risk of condensation at an outdoor temperature of -15 ° C Yes Yes Yes Yes The temperature of the wall surface in the coldest place after installation 16.0 ° C 13.2 ° C 11.4 ° C 13.7 ° C Increase in surface temperature after treatment / risk of condensation 5.6 ° C / Sun. 1.3 ° C / sun 6.2 ° C / Sun. 2.8 ° C / sun

It is clear that the measure according to the invention in all monitored cases led to a significant increase in temperature in the area of the thermal bridge, which eliminates the risk of surface condensation of steam in this area.

In addition to the 1 mm thick aluminum foil used in the described experiments, it is possible to use sheets or foils of other metals with a high thermal conductivity, or coatings of a material with a high thermal conductivity. Here, for example, graphite (λ = 2000 Wm 'K ¹ ) or graphene (λ = 4500 Wm ^ K ¹ ) is available. When using less thermally conductive materials (eg stainless steel), a thicker layer must be inserted.

The thermally conductive layer can be applied by gluing under plaster, gluing to plaster or in the form of coating or spraying. For universal use for walls and ceilings, the size of the template a = 250 mm is usually sufficient, see Fig. 1. In the case of application to the lining of building fillings of openings, it is possible to apply a smaller layer size according to the geometric possibilities around the filling, see Fig. 2.

The surface temperature is further increased by the use of a thin thermal insulation and adhesive base layer, eg based on polyurethane foam. For the optimal solution of a more complex construction detail, it is necessary to use the calculation of three-dimensional heat conduction to determine the correct thickness and size of the template.

Claims (8)

PATENT CLAIMS 1. A contact system for suppressing the effects of point and line thermal bridges in buildings, characterized in that it consists of a layer of material with a thermal conductivity of at least 5 W.mťK ¹ overlying on the inner wall of the building a place with increased heat flux and exceeding by at least 5 cm to its surroundings, wherein the layer of thermally conductive material is attached to the substrate by a water vapor impermeable adhesive. -3 CZ 2018 - 179 A3 The system according to claim 1, characterized in that the layer of thermally conductive material covering the place with the increased heat flux at the intersection of the two walls and the ceiling on the interior side extends into both walls and into the ceiling or floor. The system according to claim 1, characterized in that the layer of thermally conductive material covering the place with the increased heat flux at the intersection of the two walls on the interior side extends into both walls. The system according to claim 1, characterized in that the layer of thermally conductive material covering the place with increased heat flux along the window frame on the interior side extends into the window lining. A system according to any one of claims 1 to 4, characterized in that the layer of thermally conductive material is adhered to the inner face of the wall. System according to any one of claims 1 to 4, characterized in that the layer of thermally conductive material is built in under the plaster. System according to any one of claims 1 to 6, characterized in that the layer of thermally conductive material is formed by a metal sheet or a metal foil. System according to any one of claims 1 to 6, characterized in that the layer of thermally conductive material is formed by a coating, in particular of graphite or graphene.