FR2597573A3 - Thermal insulation panel - Google Patents

Abstract

Thermal insulation panel with parallel air strips which are sufficiently thin to avoid any convection movement and thus to benefit from a high thermal resistance. According to the invention, the panel is composed of a relatively rigid envelope 12 inside which there are arranged and fixed thin partition walls 13 delimiting the parallel air strips 13a. Application to thermal insulation in the building industry.

Description

THERMAL INSULATION PANEL
The invention relates to a thermal insulation panel using a gas of low thermal conductivity as an insulating material, in particular air; the panel according to the invention is above all remarkable for its lightness and the fact that its overall thermal resistance can be adjusted to any predetermined value.

 Thermal insulation materials have become widely used in various fields of technology, particularly in the building sector, to meet the need for savings in heating. The most used materials are expanded polystyrene and glass wool, for example as one of the constituents of a composite panel intended to line the walls and ceilings of the shell. In this case, glass wool or expanded polystyrene is attached to at least one plasterboard or of wood, of small thickness. The invention relates to a panel structure capable, among other things, of fulfilling a similar function but exploiting the low conductivity of a gas such as air or carbon dioxide (0.024 W / mOC for air and 0.014 W / mOC for carbon dioxide) when kept stationary in the form of thin strips.

 In this spirit, the invention essentially relates to a thermal insulation panel characterized in that it consists of a relatively rigid envelope inside of which is disposed at least one thin partition wall, preferably a plurality of such parallel partition walls, limiting between it and the envelope substantially independent gas blades inside said envelope.

 In other words, the invention consists in exploiting the low thermal conductivity mentioned above, when the gas is not animated by any convection movement, by creating a juxtaposition of air layers or carbon dioxide gas. thick enough to limit said convection movement likely to increase this conductivity. For this purpose, the thickness of each gas plate is preferably between 8 and 10 mm.

 With such a structure, it suffices to juxtapose as many air spaces, of a predetermined unitary thermal resistance, as necessary to obtain a chosen overall thermal resistance. Thus, a 10 mm air gap can reach a thermal resistance of 0.45 m20C / W.

taking into account the inherent thermal resistance of the material or materials constituting the envelope and the thin partition walls as well as that of the surface contacts. For example, the juxtaposition of only five 10 mm air layers leads to an overall thermal resistance of approximately 2.25 m 2 C / W, that is to say the equivalent of 8.7 cm of expanded polystyrene.

The gain in thickness is therefore of the order of 40 Z.

 According to another characteristic of the invention, the envelope can be made of glass or any other transparent synthetic material and the partition walls can be made of transparent film, so as to constitute glazing elements with a thermal resistance unknown to date. .

The invention will be better understood and other advantages thereof will appear more clearly in the light of the following description of several embodiments of thermal insulation panels in accordance with the principle, given solely by way of example and made with reference to the accompanying drawing in which
- Figure 1 is a partial cross-sectional view of a thermal insulation panel according to the invention
- Figure 2 illustrates a foldable variant for transport and / or storage
- - Figure 3 illustrates the implementation of panels according to the invention, in particular according to Figure 2, # along a wall or floor to be insulated;
- Figures 4 and 5 illustrate two variants using the principle of the invention in the production of insulating glazing.

 Referring more particularly to FIG. 1, the panel 11 essentially consists of a relatively rigid envelope 12, substantially in the shape of a rectangular parallelepiped, inside which are arranged and fixed several parallel partition walls 13, delimiting gas blades 13a (usually air) also parallel and substantially independent, inside-the envelope. The air thus trapped is practically not subject to any convection movement if the air knives are sufficiently thin, for example of the order of a centimeter.

 The material of the envelope depends on the implementation envisaged.

it is chosen to have sufficient rigidity relative to its destination. it may be an insulating material itself, such as cardboard or plastic, but this is not essential. A metal envelope may also be suitable since most of the qualities of thermal insulation of the panel result from the confinement of the parallel air spaces inside the envelope.

 In the case of a cardboard or plastic envelope, for example, the envelope 12a can have the deformable parallelepiped structure of FIG. 2, defined by two plates 14 each comprising a longitudinal fold 15 and assembly edges 16, also longitudinal, opposite along a diagonal of a cross section of the panel and joined to one another, for example by gluing. This structure makes it possible to fold the envelope 12a provided internally with the partition walls 13, in order to facilitate transport and / or storage.

 On site, the panel is deployed so as to constitute approximately a rectangular parallelepiped see Figure 3) and the thin partition walls then naturally resume the desired spacing. Once set up and fixed to the wall, one next to the other, the panels, advantageously of floor height, are protected by an interior partition if they do not naturally have the necessary mechanical resistance.

 The partition walls 13 can be flexible sheets (membranes or flexible films or resistant paper of the “Kraft” paper type) slightly stretched between at least two opposite fields of the envelope. Thus, if the panels are intended to be "storey height", it is sufficient to fix the partition walls by their short side, respectively high and low. The walls can also be fixed by their longitudinal edges. In the latter case, the panel can be cut to any length.

 The partition walls can also have a configuration suitable for giving them a certain rigidity. One can for example provide walls with ribs or having embossings or any other similar structure.

 To minimize the risk of convection inside the air space, it is also possible to use relatively rough partition walls or fitted with a rough coating, this in order to maximize the thickness of the "boundary layers" linked to the walls by friction. A similar result will be obtained by using partition walls made of material perforated with a multitude of pores. We know for example a paper of the "Kraft" type called "micropore" capable of giving good results in this application.

 As mentioned above, the invention also applies to the development of transparent panels, which opens up the possibility of making constructions (walls and openings) of great thermal uniformity, that is to say of which all the walls, opaque or transparent, have the same given and significant thermal resistance, at no additional cost. Figures 4 and 5 thus illustrate two possible variants of glazing according to the invention. The envelope 12b or 12c is essentially made of rigid transparent material, for example glass. The partition walls 13b are made of transparent flexible film, for example of the "mylar" type or similar. In the example of FIG. 4, the casing 12b has a bowl face 17 determining the thickness of the panel and assembled at its periphery to a flat wall 18.

 According to the embodiment of Figure 5, the casing 12c comprises a frame 19 made of a profile, for example of rigid plastic material, comprising both recess grooves for the glass plates constituting the large parallel faces of the envelope, as well as attachment ribs for the partition walls 13b.

 The embodiments of FIGS. 4 and 5 lend themselves well, inter alia, to the production of an envelope which is sufficiently tight so that it is possible to envisage replacing the air with carbon dioxide having the lower thermal conductivity, indicated below. above. This possibility is not however reserved for transparent panels forming glazing, it entirely depends on the qualities of the envelope.

Claims (11)

 1 - Thermal insulation panel characterized in that it consists of a relatively rigid envelope (12) inside which is disposed at least one thin partition wall (13), preferably a plurality of such walls of parallel separation, delimiting between it and the envelope of the gas blades (13a), substantially independent inside said envelope.  2 - Thermal insulation panel according to claim 1, characterized in that said relatively rigid envelope (12a) is essentially of cardboard.  3 - Thermal insulation panel according to claim 1 or 2, characterized in that the or each partition wall (13) is a sheet, membrane or film, stretched between at least two opposite fields of said envelope.  4 - Thermal insulation panel according to claim 1 or 2, characterized in that the or each partition wall (13) has a configuration capable of giving it a certain rigidity, such as for example ribs, embossing or the like.  5 - Thermal insulation panel according to one of the preceding claims, characterized in that the faces of the or each partition wall are rough or provided with a rough coating.  6 - thermal insulation panel according to one of claims 1 to 4, characterized in that the or each partition wall (13) is made of material perforated with a multitude of pores, for example a "Kraft" paper of the type "micropore".  7 - thermal insulation panel according to claim 1, characterized in that said envelope (12b, 12c) and the partition wall (s) (13b) are essentially made of transparent material, for example glass or the like for the envelope and in flexible film of the "mylar" type for the partition wall (s).  8 - Thermal insulation panel according to claim 7, characterized in that the envelope (12b) comprises a wall in a bowl (17) determining the thickness of said panel.  9 - thermal insulation panel according to claim 7, characterized in that said envelope (12c) comprises a frame (19) made of a profile having ribs for attachment of the partition wall (s) (13b).  10 - Thermal insulation panel according to one of claims 1 to 6, characterized in that said envelope substantially forms a deformable parallelepiped (Figure 2) so that it can be folded for storage and / or transport.  it - thermal insulation panel according to one of claims 1 to 10, characterized in that the spaces (13a) defined inside said envelope are filled with air.  12 - Thermal insulation panel according to one of claims 1 to 10, characterized in that said envelope is sealed and filled with carbon dioxide.