NL8203423A - Tightly rollable cavity wall insulation element - has aluminium foil sheets spaced at least 20 mm by foam strips when installed - Google Patents

Abstract

The insulating element is partic. intended for installation in the middle of a wall cavity as a barrier between the inner and outer portions of the cavity, comprises two or more sheets (1,2) of aluminium foil with spacing members (3) between them. These members are resilient, e.g. plastic foam strips, such that they are compressed with the sheets largely in mutual contact when the element is roller up, and on installation they hold the sheets at least 20 mm apart. At least the outer surfaces of the sheets may be provided with reinforcing wire mesh material (4) and/or covered by plastic, e.g. polythene, foil (5) over the mesh when applied.

Description

-1- 4 N.0. 31206

Sheet-shaped insulation material

The invention relates to a sheet-shaped insulating material consisting of two or more layers: each of which comprises aluminum foil on one or both sides and which are adhered to intermediate means, whereby the layers are kept essentially parallel to each other. Such an insulating material is known from Dutch patent application 7603863.

In particular, such a sheet-shaped insulating material serves for application in a cavity, either between vertical or between horizontal walls of a building, the material being placed approximately in the center of the cavity, so that approximately equal cavity widths remain on either side thereof. .

In the known insulating material, the intermediate; horizontal means formed by two air-cushion films which, with their surfaces where the air cushions protrude, are adhered to this film on either side of a flat film.

15 Based on Stefan Boltzmann's law, which teaches that a body with an absolute temperature T (° K.) And an emission coefficient L1 o cientE, radiates energy: E = £ OTW / m, where O - constant = - 8 2 4.

5.7. 10 "W / m K *, it can be calculated that the heat flow Q. ~ from a wall with a temperature and a reflection coefficient equal to 20 1 - € to a second wall with a temperature T ^ and a reflection coefficient equal to 1 -6 equals = e, 2; El, -ei £ 2, = - y * - t /} lf 6 + e -ee i_ + i_.

62

25 t - T

Q, Λ is also equal to 1 2, where R is the heat resistance due to R i. 1 T-T Ê + £ -i 2 1 2 C1 2 of radiation in m K / W, so that R = - = 7-r— - · V - a 30

However, the heat transfer between two walls does not only take place as a result of radiation, but also as a result of conduction and convection, whereas, in contrast to the heat transfer as a result of radiation, the heat transfer as a result of conduction and convection strongly depends - / ¾ '35 is the size of the cavity width and wd the greater this width, the greater the. heat transfer due to convection, but the smaller the heat transfer due to conduction, so the heat resistance is reduced. As a result of conduction increases, and the resistance due to convection [1! decreases with increasing cavity widths.

| Because the resistances due to radiation and ten; 5 connected in parallel due to convection and conduction, the total

| heat resistance D D

g + C x RSTR

KT0T _ R + RCT1J *

I g + c STR

The thermal resistance Rg + C as a result of conduction and convection has an optimum value I i p 10 equal to 0.7 m K / W for a cavity width of 20 mm or more. For a construction consisting of two walls made of bricks where the brick has an emission coefficient e 2

of c = 0.9, the resistance due to radiation is equal to 0.23m K / W

2 so that the total heat resistance Ryg-p 0.17m K / W.

In such a cavity now becomes a sheet-shaped insulating material.

15 of the type known from the aforementioned application is then applied, this value is Rygy = 1,3m2K / W.

The object of the invention is to provide a sheet-shaped insulating material, with which an even greater increase of the Rjq-j- | value can be obtained, and which nevertheless has the same advantageous properties as the known sheet-shaped insulating material, namely easy handling and the possibility of being stored and transported in rolls.

This object is achieved in that in the sheet-shaped insulating material according to the invention the intermediate means are formed by a number of spaced apart bodies of such dimensions and of such an compressible elastic material, that by a slight pressure on the layers, for example a pressure generated when the sheet-like insulating material is rolled up, the layers largely abut, and when this pressure is removed, the material returns to its original shape, whereby the layers are spaced apart. kept at least 20mm.

When the material according to the invention is arranged in a cavity between two walls, this cavity is divided into three parts, namely a first part between one wall and a first aluminum foil of the material, a second part enclosed between the two. aluminium-! foils of the material, and a third part between the second aluminum foil 1 8203423 r -3-! ! I of the material and the other wall, preferably these parts having the same J width of 20 mm, so that the cavity must have a width of 60 mm. For an aluminum foil, £ = 0.1, so that for the first and third cavity parts 2 2; Rjqj- = 0.51 m K / W and for the second cavity part Rtq-j- = 0.67 m K / W, so that for ; 5th whole cavity R-j-qj = W x 0.51 + 0.67 = 1.69 m K / W.

! This value can even be increased to = 2.0, if for one of the layers the known sheet-shaped insulating material is: | used.

Because the spaced-apart bodies consist of a compressible elastic material, the insulating material according to the invention can be stored and transported in rolls, the bodies being compressed in such a way that the layers come to rest against each other for the most part. so that such a roll of insulating material has a relatively small volume. As the material 15 rolls down, the bodies expand again, resulting in the two layers of the material; automatically brought parallel to each other at the aforementioned distance, and can easily be placed in a cavity in this condition.

i!

Advantageously, the bodies are formed by a plurality of spaced parallel strips, each extending over the entire width of the material. After such an insulating material is placed in a vertically running cavity, the strips run horizontally, dividing the part located between the two layers into sections by the strips, thereby further improving the heat resistance due to convection.

The material of which the bodies consist is preferably a foamed plastic, while instead of strips the bodies may also consist of cubes.

! i

Since cavities in which the sheet-like insulating material is preferably used are often moist and are in an alkaline medium, the aluminum foils can corrode. To prevent this, at least the outer sides of the aluminum foils can be provided with a covering film, which preferably consists of polyethylene, so that the reflection is not affected.

When using single aluminum foils, at 1:35, a reinforcement network is preferably adhered to the foils.

j

The invention is further described with reference to the drawing, in which Figure 1 shows a perspective view of part of a sheet-like '8203423

0KC /? 1-C

-4-

j I

| insulating material according to the invention, and I | Figure 2 shows the sheet-shaped insulating material according to i | ! Figure 1 shows placed in a cavity.

); ; "I! As shown in Figure 1, the sheet-shaped | 5 insulation material two aluminum foils 1 and 2, which are at a distance

Are held parallel to each other by the strips 3, which consist of a compressible elastic material, such as a foam material, and which ί; | are bonded to the aluminum foils 1 and 2 at two opposite sides. A reinforcement mesh k \ 10 is adhered to the aluminum foils 1 and 2, and a covering film 5 of, for example, polyethylene i is applied over the aluminum foils.

In figure 2 a cavity 6, between two, is made of stone raised walls 7 and 8 are shown. In this cavity, in the middle! thereof, is the sheet-shaped insulating material, consisting of the aluminum; 13: films 1 and 2 and strips 3 interposed therebetween, so that the cavity 6 is divided into three parts 6 ', 6 ", 6"' of equal widths.

! I

! The sheet-shaped insulating material is fixed in the cavity 6 relative to the walls 7 and 8 by means of the wall anchors 9, and the spacers 10 and the clamping discs 11.

20 Instead of clamping discs and spacers j!, Bodies can also be mounted on the outer sides of the films 1 and 2 | J which are of the same type as the bodies 3.

i - j:; ! ; j! i j ί j; : j | ί i: j ί ':; 8 2 0 3 42 3

Claims (3)

Insulation material according to claim 1, characterized in that the bodies are formed by a number of strips running parallel to each other at a distance, each of which extends over the entire width of the material. Insulation material according to claim 1 or 2, characterized in that the material of which the bodies consist; is a foam plastic. 120 | 4 ·. Insulating material according to claims 1-3, with; : the feature that at least the outer sides of the aluminum foils are provided with a covering film. Insulation material according to claim 4, characterized in that the covering film consists of polyethylene. Insulation material according to claims 1-5 with! characterized in that a reinforcement network is adhered to one or both aluminum foils. | | i: Ι ί i; ]; ! I! ! 8203423! | i