FR2973812A1 - VEGETABLE WOOL FIBER TABLE IMPREGNATED WITH EPOXYDE VEGETABLE OIL - Google Patents

Abstract

The invention relates to a web of vegetable wool fiber impregnated with a reactive mixture composed of a partially or completely epoxidized vegetable oil and a hardener. It also relates to a panel comprising a sheet according to the invention. The invention also relates to a method of manufacturing a sheet or a panel according to the invention, comprising the following steps: • mixing an epoxidized vegetable oil and a hardener at a temperature greater than each of their temperatures melting and lower at each of their degradation temperatures, • depositing the mixture obtained on a set of vegetable wool fibers at a temperature above each of their melting temperatures and below each of their degradation temperatures.

Description

The announced depletion of oil resources has pushed industry players in the insulation sector to study the improvement and thermal insulation, including buildings, but also vehicles. The present invention is part of this field of thermal insulation, without it being possible, however, to consider that it is limited in its applications to this area alone. In particular, this invention may also be of interest in the context of sound insulation.

The present invention relates more particularly to a sheet of vegetable wool fibers, which can be used to thermally and / or phonically isolate a wall. In the remainder of the application, and for simplicity of reading, it will be sufficient to mention the thermal insulation, but it is understood that a large part of the sheets used for thermal insulation are also useful for sound insulation, and that, moreover, it is possible to use such plies in cases where only sound insulation is desired. Vegetable insulation wools can be considered as competitive products of mineral wools (glass, rock) for application, particularly in the field of eco sustainable housing. These mineral wools are mainly based on the use of synthetic polymeric materials thermosetting nature such as phenol-formaldehyde. FR2626597 discloses a thermal and acoustic insulation panel with a mineral wool bonded by a thermosetting melamine resin. Other variations of glass wool panels have examined the replacement of thermosetting matrices by thermoplastic polymer binders. FR2731243 discloses a thermal and acoustic insulation panel with a glass wool bonded with a thermoplastic, such as PVC. Another way has been to replace mineral wools petrochemical binders with a composition formed by a monosaccharide and / or polysaccharide with a polycarboxylic organic acid having a molar mass of less than 1000. Such an invention is detailed in FR2924719A1. Vegetable wool already marketed is very often based on hemp fiber or flax. A semi-crystalline thermoplastic polymer (polyethylene, polypropylene, polyethylene terephthalate) is used as inter-fiber binder to ensure their mechanical cohesion for the design of a sheet or even a plant wool insulation panel . But its petrochemical origin prohibits these tablecloths or insulation boards to display a natural or ecological product label. The mechanical and thermal performance of the vegetable wools are obviously a function of various factors, some of which are directly attributable to the nature of the fibers used. We can cite as such: - their chemical composition: each plant species is characterized by a specific proportion of cellulose-hemicelluloselignin - their form factor: this is the length-to-diameter ratio of the fibers used - their size distribution - their arrangement within the sheet: crocheted fibers or not. With regard to the polymeric binder, the majority of commercial applications using plant fibers use polyolefin (polyethylene, polypropylene) or polyester (polyethylene terephthalate) thermoplastic polymers. Due to their semi-crystalline nature, these polymers can melt during a rise in temperature, which allows them to diffuse within the fibrous network. After cooling to room temperature, these polymers cover a high mechanical rigidity to ensure inter-fiber cohesion required for the production of an insulating web.

Often the insulating plies are produced in the form of rigid or semi-rigid panels, which can be placed for example between a wall and a cladding, to improve the thermal insulation of said wall. They can also be used to insulate a non-flat wall, such as a car door. In this case, it is possible either to form a non-planar panel, for example by molding, or else to form the sheet directly on its support. To do this, one can prepare on one side the fibers, on the other the polymer. The polymer can then be deposited on the fibers and then project the assembly onto the wall to be covered. It is also possible to project at the same time, by a suitable projection device, the fibers and the polymer. The choice of the process will depend on the characteristics of the chosen polymers. In the present application, the term tablecloth will be used to describe a layer of fibers, bound by a binder, with any shape, flat or not, whether preformed to form a separate part, or whether it is formed at the time of being applied to the wall of which it must improve the thermal and / or sound insulation. In the description we will often use the term "panel", since the panel represents the most common application. But here too the variants described apply to any layers. The choice of a thermoplastic binder derived from petroleum has several disadvantages. Indeed, it is not possible to recycle these materials once mixed with the plant fibers. Moreover, because of their 100% petrochemical origin, these different classes of binders can in no way give the insulating material a "green" label. Finally, the mechanical characteristics close to the various types of thermoplastics used limit the variation of a wide range of plant wools. Beyond the factors inherent in the fibers described above, the relative proportion of polymer makes it possible to vary the physical properties of the fibrous panel. However, in order not to alter the thermal appearance of the insulating panel, the mass percentage of the thermoplastic matrix must not exceed 10 to 20%. This therefore strongly limits the use of this means to confer the desired properties to a panel. The manufacturing process can also be used to vary the physical properties of the panel. For example, the compaction pressure will impact in particular the density of the plant wool, but also at the same time its insulating nature. The mode of dispersion of the polymer matrix (in the form of powder or fibers) within the plant network is also another element of influence. The means of action are, however, extremely limited. The present invention proposes to remedy at least some of the aforementioned drawbacks and proposes to substitute the thermoplastic binder of petrochemical origin with a thermosetting polymer formulation derived from Green Chemistry. The latter is based on the reactive mixture of an epoxidized vegetable oil with a hardener. For this purpose, the invention relates to a web of vegetable wool fibers. This sheet is impregnated with an epoxidized vegetable oil and a hardener. The combination of epoxidized vegetable oil and hardener is a binder allowing the web of vegetable wool fibers to be a solid and consistent. This concept allows a wide range of formulations depending on the intrinsic chemical nature of its components, the composition of the mixture or the associated polymerization conditions (time, temperature). According to other characteristics: - the epoxidized vegetable oil can be an oil obtained from a plant on the list consisting of flax, sunflower, rapeseed, soya, olive, Tung wood, cotton, castor oil, cashew nut, peanut, grape seed; these oils have been identified as excellent components for the invention. They can be used pure or as a mixture of the above-mentioned oils. Any other oil with the particularity of being rich in unsaturated fatty acids may be considered a good candidate for the base of the present invention; the epoxidized vegetable oil may be an epoxidized linseed oil; this is particularly interesting because its proportion of unsaturated fatty acids exceeds 90% with in particular a high composition of linoleic and linolenic fatty acids; furthermore, since it is not edible, its recovery does not conflict with a production initially directed towards food - said epoxidized linseed oil may comprise from 2 to 6 epoxide groups; oils with few epoxide groups will be selected to obtain more flexible plies, and oils with more epoxide groups will allow to obtain more rigid plies. said hardener may be a compound carrying a plurality of primary or secondary amines (n greater than or equal to 2). In the general case, the said compound will be referred to as polyamine; it can be for example a diamine if n = 2 - said polyamine can be of biological origin, which makes it possible to produce the web entirely from biological components - said hardener can be an acid anhydride which can be mono or plurifunctional . Nevertheless, it should be noted that each anhydride ring may react with two epoxide units - said anhydride may be of biological origin, which enables the web to be produced entirely from biological components. The present invention also relates to a thermal insulation panel comprising a web according to the invention, wherein said epoxidized vegetable oil and said hardener form a binder so as to impart sufficient mechanical cohesion to said panel; such a panel can be used easily in construction.

Finally, the present invention relates to a method of manufacturing a sheet or a panel according to the invention comprising the following steps: - mixing an epoxidized vegetable oil and a hardener at a temperature greater than each of their temperatures of melting and lower at each of their degradation temperatures, - depositing the resulting mixture on a set of vegetable wool fibers at a temperature above each of their melting temperatures and below each of their degradation temperatures. According to other characteristics: said removal can be carried out according to a method of the list consisting of spraying, infusion, dispersion, spraying; a solvent can be added to said mixture before being removed, so as to make it less viscous; said fibers can being deposited on a conveyor belt, the oil / fiber ratio being regulated by the oil delivery rate and the running speed of the treadmill, preferably a suction of the mixture through the fibers being added so as to improve the penetration and the diffusion of the mixture through the fibers - said fibers can be placed in a horizontal rotor where they are brewed and dispersed, before the removal of said mixture by direct spraying - after removal of said mixture the web can be pressed, or through a rolling mill for regulating the thickness of the fibrous carpet, either by a mold formed by an impression / counter-cavity te, then subjected to a heat treatment to allow the crosslinking of the mixture. The advantage of the present invention is that the binder used is largely of biological origin and, according to some preferred embodiments, completely of biological origin.

Other features and advantages of the invention will emerge from the following detailed description relating to an exemplary embodiment given by way of indication and not limitation.

The understanding of this description will be facilitated with reference to the accompanying drawing, in which: Figure 1 shows an essential chemical formula in the process according to the invention; The present invention relates to a web of vegetable wool fibers. Such fibers are known for their insulating characteristics. Nevertheless, to be able to be formed into a sheet or even into a panel, it is necessary to add a binder. According to the invention, this binder consists of an epoxidized vegetable oil and a hardener.

A vegetable oil is a triglyceride unit: it is formed as three fatty acids grafted on a glycerol unit. Only the fatty chains carrying carbon-carbon double bonds (C = C) are qualified as unsaturated. The transformation of these double bonds (C = C) by peroxidation will allow the creation of epoxide groups and consequently the epoxidation of the oil. In other words, only vegetable oils containing unsaturated fatty acids can be epoxidized. This process serves as a basis for the synthesis of the binder according to the invention, which will be used in the manufacture of plant wool insulation panels. Some examples of unsaturated fatty chains are summarized in Table 1. The associated fatty acids are naturally present in the vegetable oils of flax, sunflower, soy, olive, Tung wood, cotton, castor oil, cashews, peanuts, pips. grapes which have therefore been identified as possible solutions for the invention. The oil can be used pure or as a mixture of the above-mentioned oils.

Fatty acid Chemical formula Palmitoleic acid CH3 (CH2) 5CH = CH (CH2) 7COOH Oleic acid CH3 (CH2) 7CH = CH (CH2) 7COOH Linoleic acid CH3 (CH2) 4CH = CH-CH2-CH = CH (CH2) 7COOH Acid linolenic acid CH3-CH2-CH = CH-CH2-CH = CH-CH2-CH = CH (CH2) 7COOH Eleoearic acid CH3- (CH2) 3-CH = CH-CH = CH-CH = CH (CH2) 7COOH Ricinoleic acid CH3- (CH2) 4CH-CH (OH) -CH2-CH = CH (CH2) 7COOH Table 1: unsaturated fatty acids

Among the various oils mentioned, that extracted from linseed is particularly interesting because it is very rich in unsaturated fatty acids (> 90%) with in particular a high proportion of linoleic and linolenic fatty acids (see Table 2). Moreover, being not edible, its valuation does not come into conflict with a production initially oriented towards food. Oil Fatty Acid Acid Acid Oleic linoleic linoleic unsaturated acids (%) (%) (%) (%) Flax - 90 12-34 17-24 35-60 Table 2: Typical composition of a linseed oil Epoxidation give access One of them, which will be as much as a linseed oil, allows, for example, a carrier molecule of 2 to 6 epoxide groups of groups which can react with groups of selection of the web by the anhydride or polyamine type. So the influence on the rigidity of the choice of the number of epoxy groups present: more hardener of the oil will there be epoxidized groups, the greater the rigidity of the web.

The invention encompasses two classes of hardeners. The first is formed by polyamines (molecules carrying several amine functions), the second by acid and acid anhydrides.

A primary amine is capable of opening two epoxide groups to form two covalent bonds. Thus, a diamine of standard chemical formula H2N-R-NH2 may react with four epoxide groups (NH2 is a primary amine end and R is the central block). This reaction can give rise to the formation of a three-dimensional polymer network if these two epoxide groups are carried by two different macromolecular chains. The transformation is called crosslinking. The schematic diagram is proposed in Figure 1.

In the context of our invention, the polyamine-epoxy reaction is carried out through the mixture formed by an epoxidized vegetable oil with a diamine hardener in order to produce a thermosetting formulation. For an oil-polyamine pair, the proportion of each compound in the reaction mixture can be selected according to the desired degree of crosslinking in order to adjust the stiffness material or its default hardener pepper if necessary. But for a total consumption of the reagents leading to a stable product, it is important to work in stoichiometric quantities.

For example, for an epoxidized linseed oil carrying 5.45 epoxide functions per triglyceride unit, the stoichiometry of the formulation is 1.36 moles of primary diamine per 1 mole of oil. The study of the reactivity can be carried out by differential scanning calorimetry by following the evolution of the heat released by the crosslinking reaction. Dynamic rheometry can also be used to determine the characteristics of the polymerization kinetics at a given temperature, such as its speed or the time to reach equilibrium of the reaction. This key information obtained at different temperatures is useful in order to determine the optimum factors of implementation (temperature and duration) necessary for the construction of the thermal cycle of implementation. A first generation of binders based on epoxidized vegetable oil can be developed by using polyamines from petrochemicals. Compared to the current thermoplastic solution, this type of binders already has the advantage of being based on a much higher renewable carbon content due to the presence of vegetable oil in the thermosetting formulation. The exact nature of the central block R of the polyamine makes it possible to modulate the properties of the final matrix, in particular in terms of mechanical or thermal properties. It is then possible to decline a wide range of plant wools depending on the desired flexibility or mechanical rigidity. The simplest case is represented by polyamines carrying two amine functions. We then speak of diamine. A diamine having a rigid central block R - that is to say based on cyclic or aromatic chemical units - must be favored for the production of "structural" binders. There may be mentioned, for example, p-phenylenediamine, isophorone diamine (also referred to as 5-amino-1,3,3-trimethylcyclohexanemethylamine), m-xylylenediamine. The binder derived from this type of polyamine is particularly suitable for the production of dense and rigid thermal insulation wool panels. It should be noted that certain aromatic diamines of the "methylene diamine" type must be discarded because of their health risk.

Conversely, a diamine displaying an aliphatic central block will allow the manufacture of more flexible binders. This same flexibility can be modulated by the length of the aliphatic unit, or even the presence of flexible chemical patches of ether types. Examples include ethylene diamine, 1,4-diaminobutane, hexamethylene diamine, bis (3-aminopropyl) amine, 1- (2-aminoethyl) piperazine, Jeffamines.

In this case, the flexibility of the binder allows the production of wool panels much more flexible and able to adapt to laying in areas of complex geometry. These same fibrous panels exhibit a much lower compression set after compression than that observed with rigid binder based panels. It is worth noting that the proportion of binder in the fibrous cluster nevertheless makes it possible to modulate the difference between the two types of hardeners. On the other hand, the reaction between an amine terminus and an epoxide group can also be conducted with an epoxide oil cured with a polyamine, i.e., a chemical compound having more than two amine functions. This solution is a new lever allowing the extension of the range of binders to meet in particular mechanical or thermal specific constraints. Several commercial polyamines can serve as a basis for this concept, such as diethylene triamine, triethylene tetramine, tetraethylene pentamine, T-Jeffamines. A second generation of vegetable wool binders can be obtained by reacting the epoxidized vegetable oil with diamines produced from biological sources. For example, the compound "1-4 diaminobutane" previously mentioned, can also be obtained by green chemistry including hydrolysis of animal proteins. Another compound that can be produced from biological components is 1,5-diaminopentane. In a different register, some amino acids carry several amine functions that allow them to satisfy the hardener function. For example, lysine, arginine, asparagine, glutamine. All these hardeners allow, like their counterparts from petrochemicals, to crosslink the epoxidized oil during an increase in temperature. The binders thus obtained allow the design of 100% thermal insulation panels of biological origin. This last point is interesting because this type of product is perfectly compatible with the expectations of the sustainable housing market.

The present invention also encompasses vegetable wools whose binder has been obtained by the polymerization of the epoxidized vegetable oil with an anhydride hardener. Various anhydride compounds have been tested to extend the range of binders assigned to vegetable wool. Some examples can be cited namely phthalic anhydride, maleic anhydride, succinic anhydride, hexahydrophthalic anhydride or methylhexahydrophthalic acid. Each of course requires the definition of suitable crosslinking temperatures to take into account the reactivity of the mixture. In all cases, the reaction rate of the anhydride hardener with respect to the oil is slower than that observed with the polyamine hardeners. This point is important in the context of industrial production, even if the crosslinking reaction can be catalyzed, in particular by the use of an amino derivative. The anhydride route can also be explored by Green Chemistry. For example, itaconic anhydride can be obtained by treatment of citric acid. Mixed with epoxidized vegetable oil, it allows the production of a new binder derived entirely from biological sources. The preparation of the binder consists in mixing the epoxidized vegetable oil and its hardener. If the latter is solid at room temperature, it may be heated beyond its melting point but below its vaporization and degradation temperature. The oil will of course be heated to the same temperature in order to avoid any crystallization of the hardener during the "oil / hardener" mixture. The stoichiometry of the mixture depends on the epoxidation rate of the oil (ie on the amount of epoxide groups per triglyceride group) but also on the functionality of the hardener (diamine, polyamine, acid anhydride, etc.). an amine group can react with two epoxide groups. The same 1: 2 ratio is observed with the reaction of an anhydride group on an epoxide group.

When the hardener is solid at room temperature, it is necessary to preheat the epoxidized oil alone at a temperature slightly above the melting temperature of said hardener. The oil is mechanically stirred by means of a blade mixer in order to homogenise its temperature. The hardener is then added gradually to allow easier incorporation into the mixture. The mechanical stirring is maintained at low speed for 5 to 10 minutes until a homogeneous color mixture is obtained. Degassing of the solution can be carried out in a vacuum chamber, in order to eliminate any trace of air bubbles in the mixture. All these manual steps can also be performed using a dosing / mixing machine. mixing an epoxidized vegetable oil and a hardener at a temperature where the two products are liquid in order to allow a better diffusion of the reactive units. However, it is advisable to choose this temperature below the degradation temperature of each product in order to avoid any thermal alteration of the reaction medium. - Removal of the mixture obtained on a set of vegetable wool fibers. The deposition temperature is chosen so as to maintain the entire reaction medium in the liquid state. It is therefore at least equal to the mixing temperature. It should not be operated at an excessive temperature at which the crosslinking process would occur too quickly. Indeed, a temperature too close to the reaction area can cause rapid gelation of the mixture and at the same time cause diffusion of the mixture into the web.

As a general rule, the viscosity of the "oil / hardener" mixture is sufficiently low to allow its vaporization on the vegetable fibers by means of nozzles. If necessary, it can be lowered by adding solvent, the choice of which must be defined according to the type of hardener used.

A wide range exists because the epoxidized oil is indeed soluble in a very large number of solvents: chloroform, ethyl acetate, certain alkanes (hexane, heptane), petroleum ether, diethyl ether, dichloromethane , toluene, THF or dioxane ... The wetting of the fibers can be operated by various methods. A first technique is to vaporize the thermosetting formulation on the fibers previously arranged on a conveyor belt. The spraying rate of the material and / or the running speed of the carpet make it possible to regulate the oil / fiber ratio. An aspiration of the resin through the fibrous network can be operated to allow better penetration and diffusion of the binder through the fibrous tissue. In the second technique, the previously dried plant fibers are placed in a horizontal rotor where they are brewed and dispersed. The impregnation phase with the oil / hardener mixture can then occur by direct spraying. Whatever the method of impregnation retained, the sheet of fibers thus moistened is then pressed either through a rolling mill to regulate the thickness of the fibrous mat, or by a mold formed by a set of imprints / counter- footprint. Then, the assembly is subjected to a heat treatment to allow the crosslinking of the "oil-hardener" mixture. The final heating step can be carried out by means of infrared emitting lamps, a hot air tunnel or by direct thermal contact. Once the polymerization of the binder has been carried out, the plant panel exhibits good mechanical cohesion. The binder become rigid gives the panel good tensile strength. The homogeneous diffusion of the binder within the fibrous mat ensures a regular color and a good dimensional stability. The vegetable wool panels thus produced can be used as thermal insulation elements for traditional construction as a substitute for mineral wool panels (glass or rock). Based largely or completely on products of biological origin, vegetable wools offer a very interesting alternative to lignocellulosic wools based on petrochemical binder especially in the context of sustainable habitat (timber frame house). It is important to note that, beyond the sole thermal aspect, vegetable wool panels also provide a soundproofing function. This makes it possible to obtain several advantages: Compared with mineral wools, vegetable wool is a high-performance and very light insulation material: this feature allows its arrangement in suspended partitions. - Vegetable wool based on a polymer binder derived in part or totally from Green Chemistry is perfectly in line with the expectations of sustainable eco housing whose market shares are growing in our modern society. In this sense, vegetable wool produced from a binder 100% of biological origin can claim to display an eco-label, which gives it an undeniable superiority over the currently marketed products based on binder. petrochemical polymer. The ecological image of this class of products opens a privileged application in the field of sustainable housing. The chemical synthesis of the green thermosetting binder is based on a chemistry in phase with the expectations of an industrial production. Beyond this sole ecological aspect, wool with a polymer binder derived from epoxidized vegetable oil will be much less subject to oil price fluctuations than materials based on the use of petrochemical polymers. - Moreover, because of its liquid state before polymerization, the oil-based binder disperses more easily in the plant network that petrochemical thermoplastic binders. The amount of product to use remains low. - The biosourced epoxy binder can be declined through very diverse chemical compositions. Each has specific properties (mechanical, thermal ...) that allow to decline a wide range of plant wools able to adapt to very different functions (rigid or flexible wool, wool with a low compression set ...). By its thermosetting nature, the biobased binder can be deposited on the constituent plant fibers of the thermal insulation wool by processes very different from those used for the thermoplastic petrochemical binder. Various methods that are very economical in terms of product can be used: spraying, infusion, dispersion, spraying ... - A biosourced vegetable wool is not synonymous with a product with a short shelf life since "biobased" is not synonymous with "biodegradable" ... - Thermal insulation wools are known to be more sensitive to moisture and fire than mineral wools. But, this point is in no way induced by the use of a binder derived from epoxidized vegetable oil. Although the invention has been described with respect to a particular embodiment, it is understood that it is in no way limited and that various modifications of shapes, materials and combinations thereof can be made. various elements without departing from the scope and spirit of the invention.

Claims (12)

REVENDICATIONS1. Vegetable wool fiber web characterized in that it is impregnated with a reactive mixture composed of a partially or fully epoxidized vegetable oil and a hardener. 2. Tablecloth according to the preceding claim, wherein the epoxidized vegetable oil is an oil rich in unsaturated fatty acids, in particular an oil obtained from a plant of the list consisting of flax, sunflower, soy, olive, wood of Tung, cotton, rapeseed, castor, cashew, peanut, grape seed. 3. Tablecloth according to the preceding claim, wherein said epoxidized linseed oil comprises from 2 to 6 epoxide groups. 4. Tablecloth according to one of the preceding claims, wherein said hardener is a polyamine or a diacid anhydride 5. Tablecloth according to the preceding claim, wherein said polyamine, respectively said anhydride is of biological origin. A thermal insulation panel comprising a web of any one of the preceding claims, wherein said epoxidized vegetable oil and said hardener form a binder so as to impart sufficient mechanical cohesion to said panel. 7. A method of manufacturing a web according to one of claims 1 to 5 or a panel according to claim 6, characterized in that it comprises the following steps: - mixing an epoxidized vegetable oil and d a hardener at a temperature above each of their melting temperatures and below each of their degradation temperatures; - depositing the resulting mixture on a set of vegetable wool fibers at a temperature above each of their melting temperatures; less than each of their degradation temperatures. 8. Method according to the preceding claim wherein said removal is performed according to a method of the list consisting of spraying, infusion, dispersion, projection. 9. Method according to one of claims 8 or 9, wherein a solvent is added to said mixture before removal, so as to make it less viscous. 10. Method according to one of claims 8 to 10, wherein said fibers are deposited on a conveyor belt, the oil / fiber ratio being regulated by the oil delivery rate and the running speed of the treadmill, preferably aspiration of the mixture through the fibers is added so as to improve penetration and diffusion of the mixture through the fibers. 11. Method according to one of claims 8 to 10, wherein said fibers are placed in a horizontal rotor where they are brewed and dispersed, before depositing said mixture by direct spraying. 12. Method according to one of claims 8 to 12, wherein after removal of said mixture the web is pressed, either through a rolling mill to regulate the thickness of the fibrous mat, or by a mold formed by a set impression / backstop, then subjected to a heat treatment to allow crosslinking of the mixture.