WO2015121090A1

WO2015121090A1 - Device for thermally insulating a building wall from the outside, and method for implementing such a device

Info

Publication number: WO2015121090A1
Application number: PCT/EP2015/051983
Authority: WO
Inventors: Jacques Pigerre; Albert Vandebroeck
Original assignee: Jacques Pigerre; Albert Vandebroeck
Priority date: 2013-03-03
Filing date: 2015-01-30
Publication date: 2015-08-20
Also published as: PL2775062T3; US20170247889A1; EP2775062A1; EP2775061A1; EP2775062B1

Abstract

The invention relates to a device (2) for thermally insulating a building wall (1) from the outside, being applicable in particular to walls and roofs, comprising, starting from said wall, a layer (3) of impermeable rigid insulation, spacers (4) and a perforated rigid facing sheet (6) at a distance from the layer (3) of rigid insulation so as to form an air gap (7) between said facing sheet and the layer (3) of rigid insulation. A layer (8) of granular insulation (9) in divided form is contained in synthetic textile bags (10) placed in the air gap (7). The invention also relates to a method for implementing such a device.

Description

DEVICE FOR THERMALLY INSULATING OUTSIDE A BUILDING WALL AND METHOD FOR IMPLEMENTING SUCH A DEVICE

The invention relates to a thermal insulation device from the outside of a building wall, in particular applicable to walls and roofs, and more particularly to such a device that also makes it possible to protect the wall and the insulation against deterioration by climatic aggressions such as sun, wind, snow, rain, etc. The invention also relates to a method for producing and implementing such a thermal insulation device.

There are two main techniques for insulating a building. The first is to provide on the inner face of the walls or roof of the building the laying of insulating materials such as glass wool, in greater or lesser thickness for the desired coefficient of thermal insulation. However, it is advisable to leave an air gap between the inner face of the wall or roof and the layer of insulation, and to cover this layer of insulation, on its inward side of the room to be insulated, by a coating such as plasterboard to maintain the insulation and ensure a proper finish of the wall. In this case, the thickness of the insulation device encroaches on the living space of the parts to be insulated.

The second technique is to isolate the walls of the building from the outside, that is to say to apply and fix on the outside walls and roofs a layer of insulating material. However, in this case, the insulation is subjected to climatic aggressions which can deteriorate it quickly.

The present invention therefore aims to provide an insulation device from the outside of the walls of a building that has improved resistance to climatic aggressions.

The invention also aims to provide such a thermal insulation device which is adapted to isolate walls or roofs without major modification of the device. The invention also aims to provide such a thermal insulation device that can be installed over or instead of an existing roof.

The invention further aims to provide such a thermal insulation device which has a high thermal inertia.

The invention also aims to provide such a thermal insulation device which has an improved ecological impact.

To do this, the invention relates to a thermal insulation device from the outside of a building wall comprising:

a rigid and impervious insulating layer comprising a first face, said contact face, adapted to be fixed on said wall, and a second face, said external face, opposite to the contact face,

a rigid and perforated facing plate,

spacers fixed on said outer face and adapted to maintain said facing plate away from the outer face and to provide an air gap between said facing plate and the outer face of the rigid insulation layer,

a layer of granular insulation between the rigid insulation layer and the facing plate,

characterized in that the granular insulator is in divided form and contained in at least one synthetic textile bag.

The insulation device according to the invention uses a rigid and impermeable insulating layer formed for example of polystyrene or expanded polyurethane plates, of thickness calculated as a function of the desired thermal resistance, itself dependent on the location of the the work. This insulating layer may be made in one or more thicknesses made integral by gluing, for example, when the wall to be covered has asperities where the first thickness of insulation allows to equalize the surface and the second to achieve a continuous coverage . The insulating layer is fixed by its contact face on the wall to be insulated, directly or after interposition of a vapor barrier according to the nature of the wall to be insulated, if necessary fixed on battens nailed, glued or screwed on this wall. The installation of a rigid and perforated facing plate, for example one or more plates of perforated metal sheet remote from the outer face of the insulating layer can protect it from major climatic hazards. A perforated sheet metal plate allows the surrounding air to circulate on either side of the plate and maintains a much lower surface temperature than that of a solid plate when exposed to direct sunlight. In addition, by choosing a sheet having a rate and appropriate perforation dimensions, the insulating layer is shaded and subtracted from the influence of direct sunlight. For example a perforation rate of the order of 20% allows sufficient air circulation while retaining 80% of the surface of the insulator in the shade. In addition, depending on the latitude of the location of the structure and the exposure of the wall to be insulated, it is possible to calculate the optimum distance between the perforated wall plate and the insulation so as to limit the time continuous exposure of each point of the surface of the insulation layer. For example, a face plate with perforations of 5 mm and placed at 150 mm from the outer face of the insulating layer limits the continuous exposure of the insulator for a horizontal wall to 7 minutes. level of the equator.

Thus, a rigid and perforated facing plate makes it possible to limit the degradation of the insulating layer under the effect of exposure to the sun. It also allows, thanks to its rigidity, to protect the layer of insulation against wind energy and the direct impact of rain or hail. The perforated siding plate is a protective layer in the event of snow by supporting the weight of the layer of snow, minimize the risk of slipping it while allowing the evacuation of meltwater.

According to the invention, the thermal insulation device further comprises a layer of a granular insulator, in divided form, between the insulating layer and the facing plate. According to an advantageous characteristic, the granular insulator is a porous granular insulator, for example consisting of expanded clay balls or pumice gravel. By adding a layer of granular insulator in divided form between the insulating layer and the perforated facing plate, the path of penetrating water through the perforations of the facing plate is modified. Direct runoff on the insulating layer is minimized and the time taken by the water to join the storm drainage system is increased, minimizing the risk of waterlogging and the risk of overflowing and waterlogging. flood that could result. Thanks to this layer of granular insulator in divided form, and particularly when it is a porous granular insulator, the thermal insulation device according to the invention allows a regulation of the water flow rates by promoting a retention of water in the granular insulating layer without adversely affecting the performance of the rigid and impermeable insulating layer that supports it. In addition, the delayed release of the amount of water retained in the granular insulating layer, whether by runoff or evaporation, contributes to maintain a moderate temperature on the outer walls of a construction thus equipped and, particularly under Tropical climates with fast alternations of precipitation and strong sunshine, allows a natural air conditioning of the environment of the structure. The layer of granular insulation also contributes, depending on its nature, to fix certain pollutants contained in the precipitation water and improves the quality of the discharged water. Even when used in dry climates, the granular insulating layer makes it possible to increase the overall thermal inertia of the insulation device according to the invention and therefore to improve its performance. Preferably, the granular insulator in divided form used comprises expanded clay beads which may have, depending on their finish, either a good porosity or an impermeable surface. In addition, the density of the expanded clay balls is relatively low, of the order of 500 kg / m ³ , which makes it possible to use them on the roof without excessively increasing the coverage, and exempts, subject to certain reservations, consolidation or modification. the existing support structure. Alternatively, Volcanic materials such as pumice or pozzolana can be used in the form of grains or gravel.

Advantageously and according to the invention, the granular insulator is contained in at least one synthetic textile bag. The synthetic textile has the advantage of being rotproof and therefore of resisting in time and against the elements (rain, snow, etc.) and thus of preventing the granular insulator in divided form from spreading.

Advantageously and according to the invention, the synthetic textile is a nonwoven synthetic textile, in particular a needle-punched geotextile. In order to be able to hold the granular insulating layer in position, in particular on vertical walls such as walls or having a non-zero slope such as roof panels, the insulation device according to the invention provides for the use of synthetic imputrescible textile, woven or non-woven, for example polypropylene needled geotextile felt, which have the advantage of being naturally porous and can be easily made in many dimensions by folding and heat-sealing the edges between them. Of course, any other textile whether woven or not can be used, as long as it can be closed by sewing, gluing, thermo welding, etc. Similarly, if it is preferable that the textile used is naturally porous, an impervious textile may be used by producing on its surface perforations allowing the entry of water to the granular insulation. Advantageously and according to the invention, each bag has a substantially cylindrical shape, with an axis defining an installation orientation and a diameter less than or equal to the distance between the outer face of the insulation layer and the facing plate. . The simplest form for bags containing the granular insulating layer is in the form of substantially cylindrical strands obtained by folding a textile rectangle along its length and welding its long edges between them. One of the short edges is then closed by heat sealing and the bag is then filled with granular insulation. Preferably, the bag is only 80% filled to allow it to be crushed against the rigid insulating layer during placement. Advantageously and according to the invention, each bag has a substantially parallelepipedal shape and comprises partitions, said partition walls, rectangular, parallel and regularly spaced whose long edges define an installation orientation and are attached to the main faces of each bag so to maintain between said main faces a distance less than or equal to the distance between the outer face of the insulation layer and the facing plate. In this embodiment, the bags are in the form of rectangular cushions whose thickness is maintained substantially constant by interlayers. The bags are made from two rectangles between which are welded partition walls forming parallel cells and which is welded to the edges parallel to the partitions and one of the perpendicular edges. The bags are then filled with the edge perpendicular to the partitions not yet welded so as to distribute substantially equally granular insulation in the cells and the bag is closed by heat-sealing the last edge.

Advantageously and according to the invention, at least a portion of the textile walls of each bag is perforated. Although the geotextile felt used to make the bags is naturally porous, it is preferable to provide additional perforations to promote the entry of precipitation waters in the granular insulating layer. Preferably, it is the face of the bag facing the facing plate which is perforated in the case of a parallelepiped bag.

Advantageously and according to the invention, each bag is fixed on the rigid insulating layer so that its installation orientation is orthogonal to a line of greater slope of the insulating layer. In order to avoid excessive settlement of the granules of the insulator under the effect of gravity, the bags are fixed on the rigid insulation layer so that their largest dimension is orthogonal to the slope line of the wall . Thus, for a wall or a roof, the axis of the cylindrical bags or the direction of the partition walls of the parallelepiped bags is generally horizontal to avoid settling of the granular insulation at one end of the bag. Advantageously and according to the invention, the rigid insulating layer comprises on its outer face an anti-depression coating on which the spacers are fixed. In order to avoid punching of the rigid insulation layer, either by the weight transmitted by the spacers or by the manipulations and movements of the workers during the installation of the insulation device according to the invention, it is preferable to provide an anti-sinking coating on the surface of the insulation of the rigid insulation layer. Such a coating is often integrated from the manufacture of the insulation that is delivered glued on one side to a rigid plate ensuring the rigidity and protection against depressing insulation. In the case where the anti-sinking coating is not originally part of the rigid insulation layer, it may be added in the form of a plate of sheet metal, preferably solid, or plywood bonded to it. insulation to form the rigid insulation layer.

Advantageously and according to the invention, the spacers are fixed on the rigid insulating layer with a predetermined pitch along parallel lines. The spacers are attached along orthogonal lines to a line of greater slope of the insulation layer. The spacers are preferably made in the form of rectangular parallelepipeds in folded perforated sheet metal, possibly comprising a main face partly open. The spacers are placed evenly spaced, in parallel lines, orthogonal to the line of greatest slope of the wall on which the rigid insulation layer is fixed. In general, for vertical walls or roof panels, the spacers are aligned horizontally.

Advantageously and according to the invention, on each line, the spacers are offset by half a step between two adjacent lines. They are fixed by their longest side face on the anti-sinking coating of the rigid insulation layer by any appropriate means, for example by gluing, screwing, riveting or any combination of these means.

Advantageously and according to the invention, the spacers of the same line are interconnected by U-shaped beams to cap said spacers. According to an advantageous characteristic, the facing plate is fixed on the U-shaped beams. In order to maintain the facing plate away from the rigid insulation layer and to reinforce the resistance of the insulation device according to the invention, the spacers are made integral with each other by means of U-shaped beams, preferably made of folded perforated sheet and having two wings separated by a core of an inner width adapted to allow the two wings of the U to cap each spacer. The minimum length of the beams is adapted so that each beam can at least partially cover a spacer at each end of the beam. The mounting of the beams is preferably without overlapping so that the outer face of the core of each beam is in a common plane for each wall. It is thus possible to put the perforated facing plates on the beams and fix them in a simple manner, for example by means of blind rivets passing through the perforations of the facing plate and the beam.

Advantageously and according to the invention, the facing plate is adapted to receive roofing accessories adapted to be fixed on said facing plate. The rigid and perforated facing plates make it possible to fix devices such as solar photovoltaic panels or fluid circulation panels directly on the roof panels and / or on the walls and to guide their cables or connecting ducts. Similarly, fluid circulation coils can be simply hung on the perforated facing plates, for example by means of collars, so as to constitute a heating network to accelerate the melting of a layer of snow deposited on the siding. Other accessories, for example networks of light spots can thus be arranged on the vertical walls to form display elements and / or lighting.

The invention also relates to a method of thermal insulation of a wall implementing the device. According to this method:

a first face, referred to as the contact face, is fixed on said wall with a layer of rigid and impermeable insulation, spacers are fixed on a second face, called the external face, of the rigid insulating layer opposite to the contact face, with a predetermined pitch along lines parallel and orthogonal to a line of greater slope of the wall;

the spacers of one and the same line are connected together by U-shaped beams, so that said beams come to cover the spacers, and

a rigid and perforated facing plate is fixed on said beams so as to provide an air gap between said facing plate and the external face of the rigid insulating layer,

characterized in that, before fixing the facing plate, is fixed between each line of spacers, on the outer face of the rigid insulation layer, granular insulating bags in divided form.

Advantageously and according to the invention, the spacers are offset by half a step between two adjacent lines. Thanks to this shift, the air circulation in the roof is improved.

Advantageously and according to the invention, each bag is arranged in such a way that its largest dimension is parallel to the lines of spacers.

The invention also relates to a method and a thermal insulation device characterized in combination by all or some of the characteristics mentioned above or below.

Other objects, features and advantages of the invention will become apparent from the following description and the appended drawings in which:

- Figure 1 is a sectional view of the isolation device according to the invention;

FIG. 2 is a perspective view showing the placement of the spacers and beams of an isolation device according to the invention;

FIG. 3 is a perspective view showing the placement of granular insulation bags according to the invention; - Figure 4 is a perspective sectional view of a granular insulating bag according to one of the variants of the invention.

The thermal insulation device 2 shown in FIG. 1 is intended to isolate a wall 1 of a building, (wall, sloped roof or terrace, etc.) by an applied fixture on the face of this wall facing outside the building. The device 2 comprises a layer 3 of rigid and impermeable insulation fixed on the wall 1 by a contact face 31. The layer 3 of rigid and impermeable insulation is for example constituted, in its thickness, at least one stratum 33 of insulating material such as expanded polystyrene or expanded polyurethane. These materials are generally in the form of closed cell foam making them impermeable to water. They also have good intrinsic rigidity, even if they are sometimes fragile. Depending on the desired thermal resistance and / or, as described below, the nature of the wall 1, the thickness of the insulating material is variable and may be formed of several layers of insulating material bonded together.

The rigid insulation layer 3 also has an anti-sinking coating 34 in the form of a plywood plate or sheet metal, preferably solid. This coating 34 is generally bonded in the factory on one side of the thickness of the insulating material to allow it to have additional resistance to bending and to prevent the insulating material from being damaged during site manipulation. In the opposite case, the coating 34 can be glued on the layers of insulating material on the site. It can be used for this a prepainted steel sheet with a thickness of 0.75 to 1 mm or a sheet of plywood 8 to 12 mm thick. The layer 3 of rigid insulation may consist of a plurality of rectangular plates juxtaposed to cover the surface of the wall 1. These plates may comprise on their edge assembly means such as a bouvetage.

Depending on the wall to be insulated, three main cases can be envisaged: the thermal insulation device 2 is fixed on a vertical wall such as an outer wall, or on a sloping wall such as a roof pan. In the latter case, it is possible to use the isolation device according to the invention directly on the frame or on a roof already made when it is sheet metal, for example formed of steel tanks.

In the case of attachment to a vertical wall, the layer 3 of rigid insulation is preferably adhered to the wall by adhesive beads, for example expansive foam if necessary assisted by anchors. Other attachment methods known to those skilled in the art for external insulation may also be employed as long as they allow sufficient insulation to be held on the wall. When the insulation device according to the invention is placed on the roof, it is necessary to remove the cover if it does not allow laying flat (tiles, corrugated sheet, etc.). In this case, it is preferable to place a vapor barrier directly on the existing framework and for example to maintain it by nailed battens. The layer 3 of insulation is then glued on the battens. In some cases, it is possible to keep the existing roof, for example when it consists of flat sheets having at regular intervals stiffeners trapezoidal section (steel tanks). In this case, it is possible to bond between the stiffeners a first layer of insulating material, a thickness substantially equal to the height thereof to form a flat surface. The laying of the layer 3 of rigid insulation is then completed by bonding to this layer of a second layer of insulating material comprising the coating 34 antipoinçonnement.

Once the layer 3 of rigid insulation attached to the wall 1 is fixed on its outer face 32 (which is also the outer face of the coating 34 antipoinçonnement) spacers 4 of generally parallelepiped shape (rectangular parallelepiped). These spacers 4 are made for example of lacquered perforated sheet and formed by folding and riveting. These spacers 4 are fixed for example by bonding and / or riveting and / or screwing on the coating 34 antipoinçonnement, interposing where appropriate a reinforcing plate 13 (Figure 2).

The spacers 4 are fixed on their face corresponding to the thickness and the length of the parallelepiped, regularly spaced according to a pitch P, in alignment along the length of the spacer along lines orthogonal to the slope of the wall 1. Thus, for straight walls or regular roof panels, the spacers 4 are aligned in horizontal lines they - even regularly spaced between them.

For example, the spacers 4 are 250 mm long,

150 mm wide and 70 mm thick. They are arranged in a 600 mm pitch on a horizontal line and offset by half a step on the adjacent lines. The spacing between strut lines is also of the order of 600 mm without this being a necessity, these dimensions being able to vary according to the calculations of resistance and the regulation Snow and Wind applicable to the building.

The spacers 4 are made integral along the lines of spacers by beams 5 having a core 5a and two wings 5b folded orthogonally to the core to form a U-shaped profile. The width of the core 5a of each beam is adapted so that it can come to cap the face of the spacers opposite to the attachment face thereof and that the flanges 5b of the beam extend towards the attachment face by flanking the spacer. The length of the beams 5 is preferably equal to an integer number of pitch P, generally two or three, with a tolerance by a lower value so as to avoid any overlap of a beam on the adjacent beam. The length of the beams must also be sufficient so that each end covers the spacer which it caps on at least 50 mm. The beams are fixed on the spacers by blind rivets placed through the flanges of the beams and the main faces of the spacers they cover so as not to create roughness on the surface of the souls of the beams in order to fix a plate 6 rigid facing and perforated at a predetermined distance from the layer 3 of rigid insulation corresponding to the width of the spacers 4.

The facing plate 6 is preferably made by means of lacquered perforated sheet metal plates placed in abutment on the beams 5 and fixed on them by means of blind rivets. Preferably, there is a rivet on each spacer and a rivet on the core of the beam between each pair spacer. The facing plate 6 is rigid enough to withstand forces exerted by a possible layer of snow (mainly on the roof) or by the wind (particularly on the walls). The facing plate 6 is also perforated so as to allow the passage of air through the perforations to prevent heating such as can be encountered on solid sheets.

In addition, the use of a rigid perforated facing plate 6 allows the precipitation water to flow at least partly through the plate and also allows the perforations to be used to simply attach accessories 17 to this plate. . Examples of accessories that can be easily fixed include solar panels, photo voltaic or hot water (solar water heater) and their cables or connecting pipes. In cold climates where the plates 6 are likely to be covered with snow, it is possible to attach snow guards to prevent falling snow flakes around the roofs or coils circulating a heat transfer fluid to accelerate snow removal. Other accessories can also be easily put in place, such as for example light strings or light emitting diodes forming an advertising display screen.

According to an advantageous characteristic of the thermal insulation device according to the invention, a layer 8 of granular insulating material 9 in divided form, for example in the form of balls, grains, gravel, not bonded together, is interposed between the outer face 32 of the rigid insulation layer 3 and the facing plate 6. Preferably, the thickness of this layer 8 of granular insulation is limited to two thirds of the gap existing between the outer face 32 of the rigid insulation and the facing plate 6 to leave a free space to maintain a air knife 7 under the plate 6 of facing.

The granular insulator 9 may preferably be composed of expanded clay beads, porous or not, or pumice granules or pozzolan granules. In order to maintain this granular insulator in place, it is placed in preferably parallelepipedic bags 10 made of synthetic nonwoven fabric, for example made of polypropylene geotextile needle felt. Such a textile presents the advantage of being naturally porous and to be assembled by thermo welding. Of course, any other textile whether woven or not can be used, as long as it can be closed by sewing, gluing, thermo welding, etc. Similarly, if it is preferable that the textile used is naturally porous, an impervious textile may be used by producing on its surface perforations allowing the entry of water to the granular insulation.

Such a bag 10 is illustrated in perspective cut by a median plane in FIG. 4 and comprises two rectangular main faces 14a and 14b placed facing one another and whose respective edges are heat-sealed together to form a bag closed. The main face 14a is further perforated so as to allow direct entry of the precipitation water. Between the main faces 14a and 14b, rectangular partition walls 11 are placed parallel to each other and welded to the two main faces by a flap 15 formed on their long edge to define cells 16. The width of the partition walls 11 is provided to maintain substantially constant the thickness of the layer 8 of granular insulator 9. The filling of the cells 16 of the bag 10 is effected by one of the orthogonal edges to the partition walls and the edge is closed by thermo welding of edges facing the main faces.

The dimensions of the bags 10 are provided to be multiples of the pitch P for the length so as to lay them parallel to the lines of spacers 4 resting on at least two spacers and to correspond to the spacing between two lines of spacers for the width. The bags 10 are fixed on the outer face of the layer 3 of rigid insulation by adhesive beads 12, parallel to the lines of spacers. The bags 10 are arranged such that the direction of the partition walls 11, which also defines the largest dimension of the cells 16, is parallel to the lines of spacers 4 (and therefore perpendicular to the line of greatest slope of the wall on which the isolation device is placed) so that the length of the cells 16 is also orthogonal to this line of greater slope (see Figure 3). For example, the dimensions of a bag 10 adapted to the thermal insulation device whose dimensions have been given further are of the order of 600, 1200 or 1800 mm long, 600 mm wide and the constant thickness maintained by the partition walls 11 is of the order of 100 mm.

Alternatively, the bags 10 may be made in a single cell formed of a cylindrical envelope obtained by folding on itself a sheet of geotextile felt and welding of its edges so as to form a cylinder with a length of one , two or three steps P and a diameter substantially equal to the distance between the outer face 32 of the layer 3 of rigid insulation and the facing plate 6. In order to protect the air space 7 beneath it, the cylindrical bag is only filled to 80% of its capacity, allowing it to be crushed on at least two strips of adhesive 12 to obtain an oblong section of which the small diameter corresponds to the desired thickness of the layer 8 of granular insulation. In this variant embodiment, the cylindrical bags are arranged in such a way that the axis of the cylinder (which corresponds to the largest dimension of the single cell) is parallel to the lines of spacers 4, several bags being used to fill the gap between two lines of spacers. Of course, the bags 10 may be arranged in parallel or staggered rows, each bag resting on two other bags.

Due to the presence of this layer of granular insulation, the thermal inertia of the insulation device and therefore of the insulated building with this thermal insulation device is improved. In addition, the precipitation waters reaching the facing plate 6 through at least in part through its perforations and reaches the layer 8 of granular insulation in which it is temporarily trapped. Precipitation runoff is thus slowed down, minimizing the risk of clogging rainwater evacuation. In addition, in case of rapid alternation of precipitation and sunshine, the evaporation of trapped water creates a local air conditioning phenomenon.

Of course, this description is given as an illustrative example only and the skilled person can bring many modifications without departing from the scope of the invention, such as for example to modify the dimensions and the arrangement of spacers and bags of granular insulation to adapt to the geometry of the building to be insulated. Similarly, the accessories that can be attached to the facing plate 6 are not limited to the devices described above, the perforations of the facing plate may also allow to fix a thatch roofing for example.

Claims

1 / - Device (2) for thermal insulation from the outside of a wall (1) of a building, particularly applicable to walls and roofs, comprising:

a layer (3) of rigid and impervious insulation comprising a first face, said contact face (31) adapted to be fixed on said wall, and a second face, said external face (32), opposite to the face of contact,

a plate (6) of rigid and perforated facing,

spacers (4) fixed on said outer face and adapted to maintain said facing plate away from the outer face and to provide an air gap (7) between said facing plate (6) and the outer face (32). ) of the layer (3) of rigid insulation,

a layer (8) of a granular insulator between the rigid insulation layer (3) and the facing plate (6),

characterized in that the granular insulator (9) is in divided form and contained in at least one synthetic textile bag (10).

21 - Insulating device according to claim 1, characterized in that the synthetic textile is a nonwoven synthetic textile, in particular a needle-punched geo-textile.

3 / - Insulating device according to any one of claims 1 or 2, characterized in that the granular insulator (9) is a porous granular insulator.

4 / - Insulating device according to any one of claims 1 to 3, characterized in that each bag (10) has a substantially cylindrical shape with a diameter less than or equal to the distance between the outer face (32) the rigid insulation layer (3) and the facing plate (6).

5 / - Insulating device according to any one of claims 1 to 4, characterized in that each bag (10) has a substantially parallelepiped shape and comprises partitions, said partitions (11), rectangular, parallel and regularly spaced whose long edges are attached to the main faces (14a, 14b) of each bag to maintain between said main faces a distance less than or equal to the distance between the outer face (32) of the layer (3) of rigid insulation and the facing plate (6).

6 / - Insulating device according to any one of claims 1 to 5 characterized in that at least a portion of the textile walls of each bag (10) is perforated.

Il - Insulating device according to any one of claims 1 to 6, characterized in that the layer (3) of rigid insulation has on its outer face (32) a coating (34) anti-depression on which are fixed the spacers (4).

8 / - Insulating device according to any one of claims 1 to 7, characterized in that the spacers (4) are fixed on the layer (3) of rigid insulation with a predetermined pitch (P) along parallel lines .

91 - Insulating device according to claim 8, characterized in that the spacers are offset by half a step between two adjacent lines.

10 / - Insulating device according to any one of claims 8 or 9, characterized in that the spacers (4) of the same line are interconnected by beams (5) in the form of U to cap said spacers .

11 / - Insulating device according to claim 10, characterized in that the plate (6) facing is fixed on the beams (5) U-shaped.

12 / - isolation device according to any one of claims 1 to 11, characterized in that the plate (6) facing is adapted to receive accessories (17) cover adapted to be fixed on said facing plate.

13 / - Method of thermal insulation of a wall (1) of building from the outside, according to which:

a first face, referred to as the contact face (31), is fixed on said wall (1) with a layer (3) of rigid and impermeable insulation, spacers (4) are fixed on a second face, referred to as the outer face (32), of the layer (3) of rigid insulation opposite to the contact face, with a predetermined pitch (P) along parallel and orthogonal lines. at a line of greater slope of the wall,

the spacers (4) of the same line are connected together by U-shaped beams (5), so that said beams come to cover the spacers, and

a rigid and perforated facing plate (6) is fixed on said beams (5) so as to provide an air gap (7) between said facing plate (6) and the outer face (32) of the layer ( 3) rigid insulation,

characterized in that, prior to fastening the facing plate (6), there is fixed between each strut line (4), on the outer face (32) of the rigid insulation layer (3), bags (10), ) Granular insulation (9) in divided form.

14 / - Insulation method according to claim 13, characterized in that the spacers (4) are offset by half a step between two adjacent lines.

15 / - Insulating method according to any one of claims 13 or 14, characterized in that each bag (10) is arranged in such a way that the largest dimension of the cell or cells forming it is parallel to the lines of spacers.