FR2935407A1 - Isolating panel for interior or exterior isolation in e.g. residential building, has set of superimposed webs, in which each web is constituted by juxtaposition and connection of textile pieces by sewing - Google Patents

Abstract

The panel has a set of superimposed webs (N1, N2, N3), in which each web is constituted by juxtaposition and connection of textile pieces by sewing. The pieces are formed from pieces generated during tailoring work, fragments of clothes or used linen pieces. The webs are arranged to delimit compartments. The compartments are filled with materials such as reclaimed textile fibers, mineral materials e.g. rock wool, vegetal material e.g. cellulose fibers, or animal matter e.g. sheep wool.

Description

The invention relates to a material for the insulation of buildings and buildings for residential use and / or activities. It also relates to the method of manufacture and implementation of this material. It applies to all buildings and especially those built in regions with a harsh climate, particularly cold or particularly hot. It can also find applications in the field of industry, for the insulation of pipes and pipes, as well as for the insulation of crankcases, ovens or enclosures. It is known to produce insulating materials from fibers, including mineral, vegetable, or synthetic fibers agglomerated in the form of panels or rollers. It is also known to produce insulators in the form of a plurality of superimposed plasticized or metallized films. This family of insulators, known by the generic name of thin insulators has interesting properties compared to the bulk but can sometimes be poorly adapted in terms of hygrometric regulation of the premises. In general, insulation used in the building must have good resistance to the propagation of heat flux, good mechanical strength, and, for some applications properties, non-flammability and fire resistance. These insulators must also let water vapor pass from the inside to the outside of buildings. The most used insulators are those made from mineral wool, known as glass wool or rockwool. These insulators, particularly effective and with good fire resistance, however, have the disadvantage of requiring a very large amount of energy for their manufacture: the glass must indeed be heated to very high temperature (several hundred degrees) to be transformed into filaments. It has also been proposed to produce insulators based on plant fibers, typically flax or hemp. However, this type of implementation requires large cultivable areas, and involves a significant consumption of fertilizers and fuels. Finally, it has been proposed to manufacture insulators based on textile fibers, for example scrap manufacturing or frayed used clothing whose fibers are interconnected by heat-sealing fibers so as to form a panel.

In general, all fiber-based insulators may have insufficient rigidity. Moreover, all fibrous materials can diffuse over time fibers in the atmosphere, which presents a significant potential nuisance. In particular, insulants made from mineral fibers can emit small particles, for example following a gradual oxidation of the glass. These defects of fibrous insulation are particularly troublesome when one seeks to achieve buildings with high energy performance, for example buildings with parietodynamic insulation systems in which the air introduced into the premises is circulated in the buildings. spaces separating the partitions or facings of the insulators themselves. In addition, the known insulators are often difficult to implement, whether in the context of an insulation from the inside or the outside. In most cases, there is a gradual settlement of panels or insulating rolls made of agglomerated fibers, whether mineral, vegetable or animal fibers. Infrared photographs of buildings built more than a year ago frequently show a zone of significant losses at the top of walls and at the level of wall / roof junctions. Finally, it can be seen that there is practically no insulation adapted to the particular problem of the insulation of high-volume, high-rise buildings, for example warehouses or logistics buildings, factories, workshops or supermarkets. sale. Most often, these buildings are built in simple metal walls, these simple walls being sometimes made using material including an insulating core. When these buildings are built in double walls, fibrous insulation is placed between the inner wall and the outer wall. In addition to the fact that the implementation of these insulators is relatively delicate, there is a settling phenomenon of these fibrous materials, so that the insulation performance is degraded over time. The invention proposes to solve these difficulties and to achieve a particularly efficient insulation, easy to implement and a price is particularly low. An essential objective is to propose an insulation whose manufacture, the implementation, the use and the end of life have environmental impacts as low as possible. A complementary objective is to provide an insulator and a method of insulation from the inside and / or outside whose cost is particularly low. Another objective is to propose a powerful solution to the particular problem of the insulation of large buildings, for example business buildings,

3 warehouses or supermarkets. A complementary objective is to propose an insulator perfectly adapted to the dynamic insulation techniques, that is to say, not risking in any way to emit fibers or particles likely to be driven by a flow of air circulating tangentially to the surface of this insulation. Among the objectives of the invention, it will be noted that it is also a question of proposing insulating materials which make it possible to let water vapor pass from the inside to the outside of the building, without the performance of insulation are substantially affected. These objectives and others which will appear on the following reading of the description of the embodiments and use of the insulators according to the invention are achieved by producing an insulator not from fibers agglomerated with each other but from pieces of fabrics or textiles reconstituted into webs and bound together by suitable means. To facilitate the implementation of these new insulators and to ensure the maintenance of insulation performance over time, while allowing breathing especially in relation to the steam flow of the buildings equipped, the invention proposes to provide the insulating panels according to the invention of attachment means with one or more neighboring panels or still and possibly cumulatively with the structure or a wall of the building. In an advantageous variant, the panels according to the invention will comprise a rigid outer face or semi spaced away from the insulating complex, this outer face will be waterproof and may be decorative so that one will obtain tiles or insulating cladding. The fact of juxtaposing a plurality of textile plies makes it possible to constitute a particularly effective barrier to the propagation of heat by conduction as by convection. The invention proposes to use as essential raw material either textile waste or unsold or used clothing, for example garments at the end of life recovered in the dump or selective collection companies. One of the difficulties comes from the shapes of textile pieces, to the extent that these will come from clothing. In practice, it will be enough to perform a sorting of clothes, to eliminate those which would contain unwanted materials (for example viscose, elastane or pieces of leather or PVC), to remove any metal parts (zippers) and to cut out these clothes in strips that will be juxtaposed and connected together by sewing to form tablecloths. In an advantageous embodiment, it will use pieces of cloths, for example sheets, blankets or towels to make some sheets and more particularly the outer layers. We can also keep the clothes in their original form and juxtapose them with partial overlap before binding them by sewing or

4 bonding to each other, these seams or collages being made at the overlaps, so as to achieve a kind of patchwork. In all cases, we will take the precaution of washing the clothes, dipping them in fungicidal baths and insecticides. Fire treatment may also be performed at this stage. Once the webs of textile pieces obtained, we can choose either simply superimpose them on each other and connect them by sewing to form a parallelepiped panel, or to reduce the weight without substantially impacting the performance of thermal insulation, to achieve, for example by cutting webs made as described above, textile strips of small width (for example of the order of 5 cm) and to insert several of these strips between the webs, while achieving the connecting connections to the right of these strips serving as spacers. These strips may be arranged either parallel to each other or perpendicular. This will provide empty spaces (hereinafter referred to as compartments) between the different layers, spaces in which the air will be prisoner which will improve the insulation performance. In an advantageous embodiment, these compartments will simply be empty or more precisely filled with air, which will provide a very effective insulation insofar as this air will be blocked by the presence of the textile walls delimiting the compartments. It is known that the performance of an insulator depends essentially on the quantity of air it traps and the material barriers that prevent the molecules of this air from transmitting energy, because of their molecular agitation, one side of the insulation board to the other. It will preferably be chosen to produce panels of approximate dimensions 60 x 120 cm; the dimension 60 cm is an interesting dimension because it corresponds to a standard spacing of the structural members. In this case, the spacers will be spaced about 15 cm, which will provide compartments of about 12 x 12 cm, a height of a few centimeters. The seams made at the spacers and allowing the connection of the different plies between them will preferably straight seams performed in two parallel rows; this arrangement will allow in the implementation of cutting panels between these two seams, so as to give them the desired dimensions without harming their cohesion. In an advantageous variant, all or part of these compartments may be filled with a substance having the property of changing state, that is to say of passing from the solid state to the liquid state, at a temperature close to the temperature that one wishes to maintain in the local or the isolated enclosure. For the building application, substances, for example paraffins (iso-paraffins or normo-paraffins) whose change of state occurs at temperatures close to the comfort temperature, ie approximately 20 ° C (range of between 15 ° C), will be selected. and 35 ° C) To isolate an oven or oven, choose substances whose change of state occurs around 60 ° C. It will also be chosen to place these substances in sealed and conductive pouches (for example an aluminized polypropylene sheet welded on itself), said pouches being placed in the compartments formed between the different layers of the insulating complex. In the case where one chooses to fill all or part of the compartments, this filling to be carried out floor by floor, the compartments of each floor being filled before the introduction, and the attachment by sewing to the right of the spacers, of the reconstituted sheet which constitutes the ceiling of the floor considered. In another variant, it will be chosen to place in all or part of the compartments of the sealed and rigid containers in which we have created an at least partial vacuum. These containers may for example be glass beads or capsules. In this embodiment, the insulation performance will be exceptionally high, without requiring a significant insulation thickness, so that the product will be particularly well suited to the realization of housing, buildings or appliances with very high energy performance. It may also be chosen to place a fibrous material in all or part of the compartments. Among the fibrous materials, it is possible to use frayed textile fibers, basalt fibers, cellulose wadding, wood fibers or even mineral fibers: considering that each compartment will be closed, the risks of spreading fibers in the environment and in the inhabited space will be considerably reduced or even eliminated, compared to insulating panels known to date. To improve the fire behavior of the proposed insulating complexes, all or part of the compartments may be filled with boron salts or with silica salts or with any other anti-fire material. These salts will, for example, be placed in leakproof pouches, typically non-woven fabrics. They will take care of the water they will disperse during a possible accidental temperature rise due to a fire, thus giving the product a fire behavior in accordance with the regulatory requirements. The use of boron salts or silica salt or antifoulant in insulants is known in itself, but heretofore it has been sufficient to mix these products with the agglomerated fibers together. experience

6 shows that the salts tend to sink in the insulating complexes under the effect of gravity and that consequently, after a few years, the salt or fire-fighting concentrations in the matrix being irregular, certain zones are insufficiently protected. The provisions of the invention and in particular the creation of a plurality of compartments equally distributed in the material make it possible to overcome this difficulty and to propose an insulating material that is durably and effectively protected against the propagation of a fire. It is known that the tightness of the insulating envelope of a building is an essential condition of its thermal performance, that is to say its ability to be heated or refreshed without requiring excessive energy expenditure. It is for this reason that the invention recommends providing the insulating panels with lateral flaps making it possible to form a connection between each panel and at least one neighboring panel. These flaps may be provided with hooking devices, for example simple buttonholes cooperating with buttons placed on the neighboring panel and recovered on the used clothes used to make the tablecloths, or claw devices known under the name velcro (trademark) or even self-adhesive tapes. Since the function of an insulator is to reduce heat losses (and summer contributions) by conduction, by convection and by radiation, it will be chosen to place at least one reflective film, for example a sheet of metallized polyethylene on or at place of one of the layers constituting the insulating complex. This metallic film will have the effect of returning infrared radiation to their original space, that is to say inside the building in winter and outside in summer. In a more expensive embodiment, it will be possible to choose to place several reflecting films, one of which is at the level of each main outer face of the insulating panels. This will provide a thermos bottle effect that will further improve insulation performance. These reflective films will not oppose the evacuation of water vapor to the outside of the building, insofar as they may be perforated and where the taps made to secure the various sheets together, including these films, allow a passage of water vapor. The invention will be better understood if one refers to the attached figures in which: Figure 1 shows a web reconstituted from cut clothing. Figure 2 shows a stack of reconstituted webs.

Figure 3 shows a panel according to the invention in top view. Figure 4 shows a panel according to the invention in side and perspective view. Figure 5 shows a method of fixing the panels according to the invention Figure 1 shows clothing juxtaposed and roughly sewn with each other, so as to form a generally flat web. It can be seen that garments of different shapes (1 and 2), once cleared of their possible metallic parts and, where appropriate, cut into pieces of preferentially rectangular shapes (3), are simply assembled in such a way that one obtains a large room approximately rectangular. This piece will then be cut into the shape of a large rectangle (4) whose thickness will be variable but generally between the equivalent of the thickness of one, two or three pieces of tissue and this in function partial overlays which will have proved necessary to join the different components together by stitching together. Figure 2 shows a stack of webs made as described in Figure 1 and stacked on top of each other. Three successive layers (N1, N2 and N3) are shown which are spaced apart from each other by spacers, which are for example simple strips of rectangular fabrics, for example cut from clothes or pieces of cloths from garment falls. or in used clothing recovered and washed. These spacers are superimposed on each other and they are placed in two perpendicular series. In the configuration shown, the stacking order of the component parts is as follows: reconstituted (N3), horizontal (H33), vertical (V33), horizontal (H32), vertical (V32), horizontal ( H31), vertical spacer (V31), reconstituted filament (N2), horizontal crisscross (H23), vertical spacer (V23), horizontal crisscross (H22), vertical spacer (V22), horizontal crisscross (H21), vertical spacer (V21) , reconstituted web (Ni). This description applies to the particular case where a complex is made comprising three main plies, two outer plies (N3 and N1) and an inner ply (N2). We understand that we can choose to make stacks of a large number of layers, up to twenty, as we can choose the number and thickness of spacers spreading the sheets of each other between Zero and twenty pieces of tissues. It is also understood that, the more spacers are numerous, thick and spaced, the compartments delimited by 2 plies and 4 stacks of spacers will be bulky, which will significantly reduce the weight of the insulating complex without degrading its performance in terms thermal insulation. Preferably, the

8 cohesion between the various components of the insulating complex will be obtained by sewing: it will achieve stitches (Dn) for example at the horizontal strut stackings (Hn) and vertical (Vn) so as to secure the sheets or the sheets and spacers between them.

Figure 3 illustrates an insulating complex according to the invention shown in plan view. We distinguish the upper layer and cross braces (H1 and V1). Which delimit compartments (C11, C12, C13, C21, C22, C23). At least one ply chosen from the lower ply and the upper ply of the complex is extended by flaps (R1 and R2), said flaps being provided with attachment devices (Al) capable of making connections either with a neighboring insulating panel or with the structure of the building or the isolated object. To improve the insulation performance of the panels, it will be chosen to double or replace at least one of the two outer layers by a metallized film having the property of reflecting the majority of infrared radiation. In an advantageous variant, it will also be chosen to double or replace at least one of the outer layers of the insulating panels with a vapor barrier film, for example a nonwoven fabric slowing the passage of water vapor. The insulating panels according to the invention are characterized in that they comprise several superimposed sheets (Nn), each sheet consisting of the juxtaposition with partial overlap and sewing connection of textile pieces (1, 2 and 3) originating from making or cutting used clothes or pieces of laundry and said sheets (Nn) being separated by spacers (Hn, Vn), said spacers being made using rectangular fabric strips of small width relative to lengthwise and also cut into textile scraps or used clothing or pieces of cloth.

Another characteristic of these insulating panels is that the superposed layers (Nn) cooperate with the spacers (Hn, Vn) to delimit several compartments (Cn) of approximately parallelepiped shape. To improve thermal performance, it will be chosen to double or replace at least one of the outer layers (N1 or Nn) component said panel by a metallized film reflecting infrared radiation. In order to perfect the behavior with respect to the transmission of the water vapor, it will be chosen to double or replace with a nonwoven material web having the property of slowing down without totally preventing the passage of the vapor of water. 'water. It is also possible to make the two outer layers (N1 and Nn) with one and the same piece of linen (by

9 example a drape or blanket) folded on itself and acting as an envelope for the insulation board. FIG. 4 is a perspective representation of an insulating complex according to the invention.

There are four successive reconstituted layers (N1, N2, N3 and N4) as well as stackings of vertical (V) and horizontal (H) spacers which delimit compartments (Cn). It is these compartments which can, according to an essential provision of the invention, be either occupied by a simple vacuum of air, or be filled totally or partially: to - by sealed capsules or sealed containers in which we have realized a relative vacuum, - by a material having a low weight and a very low thermal conductivity, for example frayed textile fibers, mineral materials (glass wool, rock wool, vermiculite, perlite, expanded glass beads, etc.) vegetable matter (cork, sphagnum, cellulose fiber, flax fiber, hemp fiber, straw ...) or animal materials (sheep's wool, horsehair, feathers or poultry flax ....) by conductive containers themselves filled with substance having the property of changing state, that is to say to pass from the liquid state to the solid state at a temperature between 15 ° C and 35 ° C. - with water-repellent salts s, for example boron salts or salts of silicas, capable of absorbing large amounts of water and relarger this water in case of significant and rapid rise in temperature. The above list is not limiting and one may choose other filling materials compartments (Cn) without departing from the scope of the invention. Figure 5 shows a partial sectional view of an insulated building by means of panels according to the invention. It can be seen that the wall and the frame are equipped with hooks (Ti to T6) to which insulating panels according to the invention are attached. In the configuration shown, these insulating panels are provided with vapor barriers on their inner face (N35 for the third panel shown from the bottom), said vapor barriers being extended by flaps and these flaps (Rn) being them themselves equipped with means of clashing. The insulation provided by the succession of reconstituted plies and

To the compartments will advantageously be complemented by the presence of facing pieces (Pn). These facing pieces will be spaced a few centimeters, typically 5 cm, relative to the outer layer (N31) of the insulating panels, so as to allow the circulation of a ventilated air gap between the insulation and the facing pieces. . This arrangement will be particularly advantageous for the realization of parietodynamic insulation in buildings with high energy performance. It is recalled here that the insulating panels according to the invention are particularly well suited to the realization of this type of insulation, insofar as, unlike most known insulating panels, they are not likely to escape fibers in the airflow flowing along their surface. Of course, the facing pieces (Pn) will be made of weather resistant materials and will preferably have a decorative appearance. They will overlap laterally and vertically so that the walls formed by their assemblies are sealed, including in cases of implantation on the roof. It will be possible either to fix the facing pieces to the fastening means (Tn) which will be fitted to the building or the object to be insulated, or to make each piece of facing secured to an insulating panel, the juxtaposition of the insulating panels. on a roof or a facade to create a double skin at once waterproof, aesthetic and high performance in thermal insulation. This leads to the concept of cladding or roofing made from textile waste agglomerated in reconstituted webs. These products will be particularly intended for industrial buildings and logistics warehouses, for which they will make a second insulating skin particularly powerful and cheap. The insulating panels according to the invention therefore advantageously comprise an outer facing piece (Pn), said outer facing piece being held at a distance of about 5 cm from the outer ply (Ni) of the insulating board, having good resistance qualities. weathering and ensuring, by covering with the outer facing parts of neighboring panels, a watertightness of the walls or roofs made by means of the assembly of several insulating panels.

Although the implantation illustrated in Figure 5 relates to the insulation from the outside of a house, the panels according to the invention can be indifferently arranged in internal insulation or external insulation, for residential premises or houses. business premises. They can also be used for insulation of indoor or outdoor piping, and even for fairing and insulation of industrial equipment, such as cold rooms, ovens, ovens or machines of all kinds.