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    • 专利摘要:
    The present invention relates to a composite material comprising at least one superabsorbent polymer in a geopolymer matrix, its method of preparation and its uses in 3D printing, in the building or to prepare a macroporous and mesoporous geopolymer.
    公开号:FR3041630A1
    申请号:FR1559078
    申请日:2015-09-25
    公开日:2017-03-31
    发明作者:Arnaud Poulesquen;Adrien Gerenton;Fabien Frizon;Thomas Piallat
    申请人:Commissariat a lEnergie Atomique CEA;Commissariat a lEnergie Atomique et aux Energies Alternatives CEA;
    IPC主号:
    专利说明:

    SUPER-ABSORBENT POLYMER GEOPOLYMER,
    ITS PREPARATION METHOD AND USES THEREOF
    DESCRIPTION
    TECHNICAL AREA
    The present invention belongs to the technical field of geopolymers and, in particular, to the technical field of geopolymers used in 3D printing.
    More particularly, the present invention provides a material comprising at least one superabsorbent polymer embedded in a geopolymer matrix and this, to improve the properties in particular in terms of yield point, modulus of elasticity and adhesion properties and thus improving the ability of such a geopolymer material to be used in 3D printing.
    The present invention also relates to a process for the preparation of such a material and its various uses, in particular for preparing a macroporosity and mesoporosity geopolymer.
    STATE OF THE PRIOR ART
    Geopolymers are aluminosilicate materials synthesized from the alkaline activation of an alumino-silicate source such as, for example, metakaolin and fly ash [1]. These are mainly amorphous materials which typically have an intrinsic porosity of the order of 40-50% by volume relative to the total volume of material, with an average pore size of between 4 and 15 nm and a specific surface area. between 40 and 200 m2 / g depending on the alkaline activator used (sodium or potassium) [2].
    Geopolymers are reported to have good mechanical strength, good fire resistance and acid attack and can be used in various parts of the industry such as building for thermal insulation, nuclear for waste conditioning [3] or else chemistry for the trapping of toxic elements or other heavy metals [4]. Recently, the properties of geopolymers have also made them ideal materials for 3D printing. Indeed, in this field, the creation of objects or structures in geopolymer is an alternative much superior to plastics since in a carbon-free material, comparable to stone, fireproof and difficult to break and therefore of superior durability.
    However, when implemented in 3D printing, geopolymers may have certain disadvantages. For example, certain geopolymers, especially those whose aluminosilicate source is metakaolin, flow under their own weight because they have no yield point. In addition, their elastic modulus related to local interactions between particles is relatively low. These two characteristics are detrimental in 3D printing, especially when injecting the geopolymer paste through the nozzles of the 3D printers and in maintaining and holding the printed form.
    Finally, 3D printing may require reinforced adhesion properties between the printed form and the surface of the support on which 3D printing takes place, this surface being able to be hydrophobic.
    The inventors have therefore set themselves the goal of developing a geopolymer able to meet all or part of the constraints related to 3D printing.
    In parallel, superabsorbent polymers (or SAPs for "SuperAbsorbent Polymers") are materials that can absorb a large amount of water or aqueous solutions. One gram of these polymers can absorb and retain up to 1000-1500 g of water. Super absorbent polymers were developed in the late 1980s with the application of diapers. SAPs are cross-linked polyelectrolytes and the most common in the industry are sodium polyacrylates. When the SAPs are immersed in an aqueous solution, they swell by osmotic pressure whose intensity is proportional to the amount of ions present in the aqueous solution. The level of swelling also depends on the nature of the ions since the divalent (Ca 2+) or trivalent (A! 3+) ions act as additional crosslinkers thus reducing the adsorption and swelling capacity [5]. The use of SAP in the cement industry is only very recent since it began in the early 2000s. The hardened hydraulic cements are the result of the hydration of the finely ground materials of the cement mixture. The main purpose of adding SAP to a cementitious mixture is to provide water, which acts as a water reservoir, to control the hydration of the cement particles over time. and avoid self-drying and thus fracking. Improving the durability of concrete is also an issue of adding SAP. Indeed, since the water transport properties, which are at the origin of the early deterioration of the concretes, are facilitated by the presence of interconnected capillary pores, the fact of adding SAP allows a redistribution of this capillary water in filled macropores. of water, which is also beneficial for concrete resistance to the freeze / thaw cycle [6, 7].
    STATEMENT OF THE INVENTION
    The present invention overcomes, at least in part, the disadvantages and technical problems related to the use of a geopolymer in 3D printing. Indeed, the latter proposes a composite material in which one or more superabsorbent polymer (s) is / are dispersed, coated and / or incorporated into a geopolymer matrix.
    The work of the inventors has shown that geopolymers and superabsorbent polymers have good compatibility. This work has also shown that the addition of at least one superabsorbent polymer in a geopolymer makes it possible: ii) to increase the elasticity, the yield point and the rheofluidifying character of the composite material obtained and this, to give an injectable material and in particular to be able to inject it through 3D printer nozzles and so that the requested shape does not collapse; iii) to modify and control the properties of wettability of the mixture according to the intended application for the composite material thus obtained, such as injection under water, leakproof barrier, soil stabilization ... iv) modulate and in particular to reduce the setting time of the composite material thus obtained; and v) improving the adhesion properties of the resulting composite material.
    In view of the properties described above, the material according to the invention is particularly interesting in the field of 3D printing since it offers the possibility of developing custom products based on geopolymer which intrinsically has good mechanical properties, high specific surface areas as well as a monomodal and mesoscopic pore size distribution. Such products have the property of being injectable.
    However, by virtue of the properties described and in addition to the 3D printing aspect, it is also possible to envisage the use of the material according to the invention, as a filling coating, in the open air or immersed, as a seal or even as shotcrete given the drastic increase in rheological properties such as increasing elasticity, flow threshold and rheofluidifying character, as well as adhesion properties.
    It should be emphasized that the addition of SAP in the geopolymers had never been studied before the present invention and that the use of such polymers in the field of hydraulic cements including as a water reservoir as explained above did not suggest any advantages and properties obtained when using superabsorbent polymers in geopolymers.
    Thus, the present invention provides a composite material comprising at least one superabsorbent polymer in a geopolymer matrix.
    By "composite material" is meant, in the context of the present invention, an assembly of a geopolymer matrix and one or more superabsorbent polymer (s). This assembly can be in the form of an encapsulation of SAP by the geopolymer matrix, a microencapsulation of SAP by the geopolymer matrix and / or a coating of SAP by the geopolymer matrix.
    More particularly, the composite material which is the subject of the invention is in the form of a geopolymer (or geopolymer matrix) in which SAP nodules, and especially SAP micronodules and / or nanonodules, are coated. By "micronodule" is meant a mass of SAP whose characteristic dimension is between 1 and 1000 μιτι, in particular between 5 and 900 pm and, in particular between 20 and 800 μιτι. The term "nanonodule" is understood to mean a mass of SAP whose characteristic dimension is between 1 and 1000 nm, in particular between 10 and 900 nm and, in particular, between 20 and 800 nm. The micronodules and nanonodules of SAP present in the composite material according to the invention may have various forms such as oval, spheroidal or polyhedral shapes. It is these nanonodules and micronodules which participate, essentially, in the macroporous nature of the final geopolymer obtained after removal of the SAPs, giving in fact pores of various forms such as oval, spheroidal or polyhedral shapes.
    By "superabsorbent polymer" or SAP is generally meant a polymer capable, in the dry state, of absorbing spontaneously at least 10 times, advantageously at least 20 times its weight of aqueous liquid, in particular water and in particular distilled water. Some SAPs can absorb up to and even more than 1000 times or even more than 1500 times their weight of liquid. By spontaneous absorption is meant an absorption time less than or equal to 1:30 and in particular less than or equal to 1 h.
    The superabsorbent polymer used in the present invention may have a water absorption capacity ranging from 10 to 2000 times its own weight (ie 10 g to 2000 g absorbed water per gram of absorbent polymer), advantageously from 20 to 2000 times its own weight (ie 20 g to 2000 g absorbed water per gram of absorbent polymer), in particular still 30 to 1500 times its own weight (ie 30 g to 1500 g of water absorbed per gram absorbent polymer) and, more particularly, from 50 to 1000 its own weight (ie 50 g to 1000 g absorbed water per gram of absorbent polymer). These water absorption characteristics are understood under the normal conditions of temperature (25 ° C) and pressure (760 mm Hg or 100000 Pa) and for distilled water.
    The SAP of the composite material according to the invention may be chosen from poly (meth) acrylates of alkaline salts, starches grafted with a (meth) acrylic polymer, hydrolysed starches grafted with a (meth) acrylic polymer; polymers based on starch, gum, and cellulose derivative; and their mixtures.
    More precisely, the SAP that can be used in the composite material according to the invention can be, for example, chosen from: the polymers resulting from the polymerization with partial crosslinking of water-soluble ethylenically unsaturated monomers, such as acrylic, methacrylic polymers (especially those derived from the polymerization of acrylic and / or methacrylic acid and / or acrylate and / or methacrylate monomers) or vinyl monomers, in particular crosslinked and neutralized poly (meth) acrylates, in particular in the form of a gel; and the salts, in particular the alkaline salts such as the sodium or potassium salts of these polymers; starches grafted with polyacrylates; acrylamide / acrylic acid copolymers, typically in the form of salts, especially of alkaline salts and in particular of sodium or potassium salts; acrylamide / acrylic acid grafted starches, typically in the form of salts, especially of alkaline salts and in particular of sodium or potassium salts; the salts, in particular the alkaline salts and in particular the sodium or potassium salts, of carboxymethylcellulose; the salts, in particular the alkaline salts and in particular the sodium or potassium salts, of crosslinked polyaspartic acids; the salts, in particular the alkaline salts and in particular the sodium or potassium salts, crosslinked polyglutamic acids and their mixtures.
    In particular, it is possible to use as SAP in the composite material according to the invention a compound chosen from: - crosslinked sodium or potassium polyacrylates sold under the names SALSORB CL 10, SALSORB CL 20, FSA type 101, FSA type 102 ( Allied Colloids); ARASORB S-310 (Arakawa Chemical); ASAP 2000, Aridall 1460 (Chemdal); Kl-GEL 201-K (Siber Hegner); AQUALIC CA W3, AQUALIC CA W7, AQUALIC CA W10; (Nippon Shokuba); AQUA KEEP D 50, AQUA KEEP D 60, AQUA KEEP D 65, AQUA KEEP S 30, AQUA KEEP S 35, AQUA KEEP S 45, AQUA KEEP Al Ml, AQUA KEEP Al M3, AQUA KEEP HP 200, NORSOCRYL S 35, NORSOCRYL FX 007 (Arkema); AQUA KEEP 10SH-NF, AQUA KEEP J-550 (Kobo); LUQUASORB CF, LUQUASORB MA 1110, LUQUASORB MR 1600, HYSORB C3746-5 (BASF); COVAGEL (Sensient Technologies); SANWET IM-5000D (Hoechst Celanese); grafted starch polyacrylates sold under the names SANWET IM-100, SANWET IM-3900 and SANWET IM-5000S (Hoechst); acrylamide / acrylic acid copolymers grafted with starch in the form of the sodium or potassium salt sold under the names WATERLOCK A-100, WATERLOCK A-200, WATERLOCK C-200, WATERLOCK D-200, WATERLOCK B-204 (Grain Processing Corporation); acrylamide / acrylic acid copolymers in the form of the sodium salt sold under the name WATERLOCK G-400 (Grain Processing Corporation);
    carboxymethylcellulose sold under the name AQUASORB A250 (Aqualon); cross-linked sodium polyglutamate sold under the name GELPROTEIN (Idemitsu Technofine). It should be noted that superabsorbent polymers, in particular superabsorbent polymers (polyelectrolytes) which contain alkaline ions such as sodium or potassium ions, for example of the sodium or potassium poly (meth) acrylate type, are particularly suitable to use in a composite material according to the invention. Thus, in a particular embodiment, the superabsorbent polymer used in the context of the present invention is a sodium or potassium poly (meth) acrylate, ie it is chosen from the group consisting of a sodium polyacrylate, a polyacrylate of potassium, sodium polymethacrylate and potassium polymethacrylate.
    By "geopolymer" or "geopolymer matrix" is meant in the context of the present invention a solid and porous material in the dry state, obtained following the hardening of a mixture containing finely ground materials (ie the alumino-silicate source ) and a saline solution (ie the activating solution), said mixture being able to set and harden over time. This mixture may also be referred to as "geopolymeric mixture", "geopolymeric mixture", "geopolymeric composition" or "geopolymeric composition". The hardening of the geopolymer is the result of the dissolution / polycondensation of the finely ground materials of the geopolymeric mixture in a saline solution such as a high pH salt solution (i.e. the activating solution).
    More particularly, a geopolymer or geopolymer matrix is an amorphous aluminosilicate inorganic polymer. Said polymer is obtained from a reactive material containing essentially silica and aluminum (i.e. the aluminosilicate source), activated by a strongly alkaline solution, the solid / solution weight ratio in the formulation being low. The structure of a geopolymer is composed of an Si-O-Al network formed of silicate tetrahedra (SiO4) and aluminates (AlO4) linked at their vertices by oxygen atom sharing. Within this network, there is (s) one or more charge compensating cation (s) also called (s) compensation cation (s) which make it possible to compensate for the negative charge of the complex AIO4 '. Said cation (s) of compensation is (are) advantageously chosen from the group consisting of alkali metals such as lithium (Li), sodium (Na), potassium (K), rubidium (Rb ) and cesium (Cs); alkaline earth metals such as magnesium (Mg), calcium (Ca), strontium (Sr) and barium (Ba); and their mixtures.
    In a particular embodiment, when the superabsorbent polymer used in the context of the present invention is a sodium poly (meth) acrylate, the compensation cation used is advantageously sodium. In a variant, when the superabsorbent polymer used in the context of the present invention is a potassium poly (meth) acrylate, the compensation cation used will advantageously be potassium.
    The terms "reactive material containing essentially silica and aluminum" and "aluminosilicate source" are, in the present invention, similar and usable interchangeably.
    The reactive material containing essentially silica and aluminum that can be used to prepare the geopolymer matrix used in the context of the invention is advantageously a solid source containing amorphous aluminosilicates. These amorphous alumino-silicates are chosen in particular from natural alumino-silicate minerals such as illite, stilbite, kaolinite, pyrophyllite, andalusite, bentonite, kyanite, milanite, grovenite, amesite, cordierite, feldspar, allophane, etc .; calcined natural aluminosilicate minerals such as metakaolin; synthetic glasses based on pure aluminosilicates; aluminous cement; pumice; calcined by-products or industrial mining residues such as fly ash and blast furnace slags respectively obtained from the burning of coal and during the processing of cast iron ore in a blast furnace; and mixtures thereof.
    The saline solution of high pH also known, in the field of geopolymerization, as "activation solution" is a strongly alkaline aqueous solution which may optionally contain silicate components, especially chosen from the group consisting of silica, colloidal silica and vitreous silica.
    The terms "activation solution", "high pH saline solution" and "strongly alkaline solution" are, in the present invention, similar and interchangeably usable.
    By "strongly alkaline" or "high pH" means a solution whose pH is greater than 9, especially greater than 10, in particular greater than 11 and more particularly greater than 12. In other words, the Activation solution has an OH concentration greater than 0.01 M, in particular greater than 0.1 M, in particular greater than 1 M and more particularly between 5 and 20 M.
    The activation solution comprises the compensation cation or the compensation cation mixture in the form of an ionic solution or a salt. Thus, the activation solution is in particular chosen from an aqueous solution of sodium silicate (Na 2 SiC 3), potassium silicate (K 2 SiC 2), sodium hydroxide (NaOH) and potassium hydroxide (KOH ), calcium hydroxide (Ca (OH) 2), cesium hydroxide (CsOH) and their derivatives, etc.
    In the material which is the subject of the present invention, the superabsorbent polymer (s) is (are) incorporated into the geopolymer matrix up to an incorporation rate of 10% by weight relative to the total mass of said material. Advantageously, this degree of incorporation is between 0.1 and 5% and, in particular, between 0.2 and 3% by weight relative to the total mass of said material.
    The material which is the subject of the present invention may be in various forms, of small or large size, depending on the desired application and in particular structures of predetermined shape in the context of 3D printing. Thus, the material which is the subject of the present invention may be in the form of a fine powder, a coarse powder, grains, granules, pellets, balls, balls, blocks, rods, cylinders, plates, structures or mixtures thereof. These various forms can be obtained in particular thanks to the plasticity, before curing, of the geopolymer matrix of the material which is the subject of the present invention.
    The present invention relates to a formulation, or kit of elements, for the preparation of a composite material as defined above, comprising: an aluminosilicate source, especially as defined above; an activation solution, in particular as defined above, and at least one superabsorbent polymer, especially as defined above.
    The present invention also relates to a method for preparing a composite material as defined above. Said preparation process comprises a step of incorporating at least one superabsorbent polymer into a geopolymer mixture. In other words, the preparation process according to the present invention consists in mixing together the various elements of the formulation as defined above.
    In a first embodiment, the preparation method according to the present invention comprises the following steps: a) preparing an activation solution comprising at least one superabsorbent polymer, b) adding to the solution obtained in step (a) at least one alumino-silicate source, c) subjecting the mixture obtained in step (b) to conditions allowing the hardening of the geopolymer. Step (a) of the process according to the present invention consists in adding to an activating solution as defined previously, at least one superabsorbent polymer prepared beforehand. Prior preparation of the activation solution is a standard step in the field of geopolymers.
    As previously explained, the activation solution may optionally contain one or more silicated component (s), in particular chosen from the group consisting of silica, colloidal silica and vitreous silica. When the activation solution contains one or more silicated component (s), this or these latter (s) is (are) present in an amount of between 100 mM and 10 M, in particular between 500 mM and 8 M and, in particular, between 1 and 6 M in the activation solution.
    The superabsorbent polymer (s) is (are) added to the activation solution at once or in several times. Once the superabsorbent polymer (s) added to the activation solution, the solution or dispersion obtained is mixed using a kneader, a stirrer, a magnetic bar, an ultrasonic bath or a homogenizer. The mixing / kneading during the sub-step (a) of the process according to the invention is carried out at a relatively slow speed. By "relatively slow speed" is meant, in the context of the present invention, a rotational speed of the rotor of the mixer less than or equal to 250 rpm, in particular less than or equal to 200 rpm and, in particular, greater or equal to 20 rpm. Advantageously, this agitation is carried out using a magnetic bar. This agitation is rapidly stopped because of the gelation of the activation solution. Thus, following step (a) of the process according to the invention, an activation solution is obtained comprising at least one superabsorbent polymer in the form of a gelled solution in which the polymer nodules (s) superabsorbent (s) are evenly distributed or dispersed. Step (a) of the process according to the invention is carried out at a temperature of between 10 ° C. and 40 ° C., advantageously between 15 ° C. and 30 ° C. and, more particularly, at room temperature (ie 23 ° C. ± 5 ° C) for a period of less than 30 min, in particular less than 15 min, in particular between 15 s and 10 min and, more particularly, between 30 s and 5 min. Step (b) of the process according to the invention consists in bringing into contact the activation solution comprising at least one superabsorbent polymer and the aluminosilicate source as defined above.
    The alumino-silicate source can be poured in one or more times on the activating solution containing at least one superabsorbent polymer. In a particular embodiment of step (b), the alumino-silicate source may be sprinkled onto the activating solution containing at least one superabsorbent polymer.
    Advantageously, step (b) of the process according to the invention is carried out in a kneader in which the activation solution containing at least one superabsorbent polymer has been introduced beforehand. Any kneader known to those skilled in the art can be used in the context of the present invention. By way of non-limiting examples, mention may be made of a NAUTA® mixer, a HOBART® mixer and a HENSCHEL® mixer. Step (b) of the process according to the invention thus comprises a mixing or kneading of the activating solution containing the organic liquid and optionally a surfactant with the aluminosilicate source. The mixing / kneading in step (b) of the process according to the invention is carried out at a relatively high speed. By "relatively high speed" means, in the context of the present invention, a speed greater than 250 rpm, especially greater than or equal to 350 rpm. Step (b) of the process according to the invention is carried out at a temperature of between 10 ° C. and 40 ° C., advantageously between 15 ° C. and 30 ° C. and, more particularly, at room temperature (ie 23 ° C. ± 5 ° C) for a duration greater than 1 min, in particular between 2 min and 30 min and in particular between 4 min and 15 min. Those skilled in the art will be able to determine the amount of alumino-silicate source to be used in the context of the present invention based on their knowledge in the field of geopolymerization as well as the nature of the superabsorbent polymer (s) (s) ( s) implemented and the amount of polymer (s) super-absorbent (s) and activation solution implemented.
    Advantageously, in the process according to the present invention, the mass ratio activation solution / MK with activation solution representing the mass of activating solution containing one or more superabsorbent polymer (s) (expressed in g) and MK representing the alumino-silicate source mass (expressed in g) used is advantageously between 0.6 and 2 and in particular between 1 and 1.5. As a particular example, the ratio of activation solution / MK is of the order of 1.3 (i.e. 1.3 ± 0.1).
    In addition, besides the alumino-silicate source, sand, granulate and / or fines can be added to the activation solution during step (b) of the process according to the invention. .
    By "granulate" is meant a granular material, natural, artificial or recycled, the average grain size is advantageously between 10 and 125 mm.
    The fines also called "fillers" or "addition fines" is a dry product, finely divided, resulting from the size, sawing or work of natural rocks, aggregates as previously defined and ornamental stones. Advantageously, the fines have an average grain size of in particular between 5 and 200 μm.
    Sand, granulate and / or fines are (are) added to better regulate the temperature rise during step (b) of the process but also to optimize the physical and mechanical properties of the composite material obtained.
    The sand that may be added during step (b) may be calcareous sand or siliceous sand. Advantageously, it is a siliceous sand which makes it possible to achieve the best results with regard to the optimization of the physical and mechanical properties of the composite material obtained. In the context of the present invention, the term "siliceous sand" is intended to mean sand that is more than 90%, in particular more than 95%, in particular greater than 98%, and more particularly more than 99%. of silica (SiCh). The siliceous sand used in the present invention advantageously has a mean grain size in particular of less than 10 mm, in particular less than 7 mm and in particular less than 4 mm. By way of particular example, a siliceous sand having a mean grain size of between 0.2 and 2 mm can be used.
    When sand is added in addition to the alumino-silicate source to the activation solution, the mass ratio between sand and alumino-silicate source is 2/1 and 1/2, in particular between 1.5 / 1 and 1 / 1.5 and in particular between 1.2 / 1 and 1 / 1.2. Step (c) of the process according to the invention consists in subjecting the mixture obtained in step (b) to conditions allowing the geopolymer mixture to harden.
    Any technique known to those skilled in the art for curing a geopolymer mixture in which is / are present (s) or polymer (s) super-absorbent (s) is used during the curing step of the process.
    The conditions for curing during step (c) advantageously comprise a curing step optionally followed by a drying step. The curing step can be done in the open air, under water, in various hermetic molds, by humidifying the atmosphere surrounding the geopolymer mixture or by applying an impermeable coating on said mixture. This curing step can be carried out under a temperature of between 10 and 80 ° C., in particular between 20 and 60 ° C. and in particular between 30 and 40 ° C. and can last between 1 and 40 days, or even longer. . It is obvious that the duration of the cure depends on the conditions implemented during the latter and the skilled person will be able to determine the most suitable duration, once the conditions defined and possibly by routine tests.
    When the curing step comprises a drying step, in addition to the curing step, this drying can be carried out at a temperature of between 30 and 90 ° C, in particular between 40 and 80 ° C and, in particular, between 50 and 70 ° C and can last between 6 hours and 10 days, especially between 12 pm and 5 days and, in particular, between 24 and 60 hours.
    In addition, prior to the hardening of the geopolymer mixture in which there is present at least one superabsorbent polymer, the latter can be placed in molds or containers so as to give it a predetermined shape following or prior to this hardening.
    Likewise, the geopolymer mixture in which at least one superabsorbent polymer is present is entirely suitable, prior to its curing, for injection through the nozzles of the 3D printers and for holding and holding the shape printed.
    In a second embodiment, the method according to the present invention comprises the following steps: a ') adding to an activation solution at least one aluminosilicate source, b') adding to the mixture obtained in step ( a ') said at least one superabsorbent polymer, c') subjecting the mixture obtained in step (b ') to conditions permitting the hardening of the geopolymer. Step (a ') of the process according to the present invention consists in preparing an activation solution as defined above in which at least one aluminosilicate source as defined above is added. Such a sub-step is conventional in the field of geopolymers.
    All that has been previously described as to the activation solution in step (a) also applies to the activation solution implemented in step (a ').
    Similarly, all that has been previously described for step (b) and in particular the conditions of the mixing / kneading, the type of kneader, the temperature, the amount of alumino-silicate source and the mass ratio activation solution / MK applies, mutatis mutandis, to step (a '). Note however that the stirring during step (a ') may have a duration greater than 2 min, in particular between 4 min and 1 h and, in particular between 5 min and 30 min. Step (b ') of the process consists in introducing into the mixture (activation solution + alumino-silicate source) at least one superabsorbent polymer. It is obvious that this step must be implemented relatively quickly after the preparation of the aforementioned mixture and this, prior to any hardening of this mixture which could prevent the production of a homogeneous mixture following step (b ') .
    The superabsorbent polymer (s) is (are) added to the mixture (activation solution + alumino-silicate source) in one or more times. Once the superabsorbent polymer (s) added to the mixture (activation solution + alumino-silicate source), the preparation obtained is mixed using a kneader, a stirrer, a magnetic bar, an ultrasonic bath or a homogenizer. The mixing / kneading during step (b ') of the process according to the invention is carried out at a relatively high speed as defined above, in order to obtain a homogeneous mixture following step (b'). Step (b ') of the process according to the invention is carried out at a temperature of between 10 ° C. and 40 ° C., advantageously between 15 ° C. and 30 ° C. and, more particularly, at room temperature (ie 23 ° C. ± 5 ° C) for a period of less than 30 min, in particular less than 15 min, in particular between 15 s and 10 min and, more particularly, between 30 s and 5 min.
    In addition, as envisaged in the context of the first form of implementation, sand, granulate and / or fines such as previously defined can be used to prepare the composite material object of the invention. The sand, granulate and / or fines may be added during step (a '); following step (a ') and prior to step (b'); during step (b ') and / or following step (b') and prior to step (c ').
    Finally, all that has been described for step (c) also applies to step (c ').
    The present invention also relates to the use of a composite material as previously defined or capable of being prepared by a preparation method as previously defined as material for 3D printing.
    In addition, as previously explained and exemplified in the experimental part below, the properties conferred on a geopolymer, following the addition of one or more superabsorbent polymer (s), make it possible to envisage other uses for the composite material according to the invention and in particular in the field of building. Thus, the present invention relates to the use of a composite material as previously defined or capable of being prepared by a preparation method as defined above: (i) as a filling compound, (ii) as a joint, taking into account improved adhesion properties by adding one or more superabsorbent polymer (s) and / or (iii) as shotcrete.
    The present invention also relates to a method for preparing a macroporous and mesoporous geopolymer comprising the steps of: 1) preparing a composite material comprising at least one superabsorbent polymer in a geopolymer matrix according to the preparation method as defined above and then 2) removing said at least one superabsorbent polymer by a treatment selected from the group consisting of heat treatment, oxidative treatment, photo-degradation treatment and extraction via a supercritical fluid or ultrasound. Step (2) of the process according to the present invention consists in eliminating the superabsorbent polymer (s) and thus releasing the porosity of the composite material obtained following step (1). Different variants are envisaged as to this elimination.
    The first of these variants consists of a heat treatment. By "heat treatment" is meant, in the context of the present invention, the fact of subjecting the composite material of step (1) to a high temperature ie a temperature greater than 200 ° C., in particular between 300 ° C. and 1000 ° C and in particular between 400 ° C and 800 ° C.
    This heat treatment is advantageously carried out under oxygen, under air, under an inert gas such as argon or under a neutral gas such as nitrogen and advantageously under oxygen or under air. This heat treatment step consists of calcination or sublimation of the organic compounds that are the superabsorbent polymers used.
    This step has a duration of between 15 minutes and 12 hours, and especially between 1 am and 6 pm. It is possible for those skilled in the art to vary the conditions of the heat treatment and this, depending on the composite material obtained at the end of step (1) to obtain a porous geopolymer free of any organic compound.
    The 2nd of the variants envisaged to eliminate the superabsorbent polymer (s) used (s) is to oxidize these elements mainly CO2 and H2O. Such oxidative treatment is in particular either a plasma treatment or an ozone treatment.
    The plasma treatment consists in exposing the composite material obtained following step (1) to a plasma. As a reminder, plasma is a gas in the ionized state, classically considered as a fourth state of matter. The energy required for the ionization of a gas is provided by means of an electromagnetic wave (radio frequency or microwave). Plasma is composed of neutral molecules, ions, electrons, radical species (chemically very active) and excited species that will react with the surface of materials.
    We distinguish the so-called "cold" plasmas and the so-called "hot" plasmas which are distinguished from each other with respect to the ionization rate of the species contained in the plasma. For so-called "cold" plasmas, the ionization rate of the reactive species is less than 10 ~ 4 whereas for so-called "hot" plasmas, it is greater than 10 -4. The terms "hot" and "cold" come from the fact that the so-called "hot" plasma is much more energetic than the so-called "cold" plasma.
    The plasma is advantageously generated by a mixture of at least two gases, the first and second gases being respectively selected from the group consisting of inert gases and the group consisting of air and oxygen. The duration of the plasma treatment is between 1 and 30 min, and in particular between 5 and 15 min.
    An ozone treatment consists in exposing the composite material obtained following step (1) to ozone. This exposure may involve either contacting this composite material with a flow of ozone, or the disposition of the latter in an atmosphere containing ozone. The necessary ozone can be obtained from a gas rich in oxygen such as air, oxygen, air enriched in oxygen or an oxygen-enriched gas, via an ozone generator such as as a UVO-Cleaner Model 42-200 low pressure mercury vapor lamp (28 mW / cm 2, 254 nm). The duration of the ozone treatment can be variable. By way of nonlimiting examples, this duration is advantageously between 30 sec and 3 h, in particular between 1 min and 1 h, in particular between 5 min and 30 min and, more particularly, of the order of 10 min ( 10 min ± 3 min).
    The third of the variants envisaged for removing the superabsorbent polymer (s) used is a photo-degradation treatment. The latter consists of a degradation of the organic compounds contained in the composite material obtained following step (1) by means of exposure to light radiation and in particular to UV light.
    Advantageously, the UV light used has a wavelength of between 10 nm and 400 nm, in particular between 100 nm and 380 nm and, in particular, between 180 nm and 360 nm. Any UV source can be used to generate such UV light. By way of example, mention may be made of a UV lamp, a low-pressure mercury lamp, a medium-pressure mercury lamp, a high-pressure mercury lamp, a very high-pressure mercury lamp, an arc lamp electric, a halide lamp, a xenon lamp, a laser, an ArF excimer laser, a KrF excimer laser, an excimer lamp or synchrotron radiation.
    The UV treatment in the context of the present invention can be carried out at a temperature between 5 ° C and 120 ° C, in particular between 10 ° C and 80 ° C and, in particular, between 15 ° C and 40 ° C. More particularly, the UV treatment according to the invention is carried out at room temperature. The UV treatment in the context of the present invention lasts from 1 min to 5 h, in particular from 5 min to 1 h and, in particular, from 10 min to 45 min. The irradiation may be single or repeated several times, in particular from 2 to 20 times and in particular from 3 to 10 times.
    This UV treatment is advantageously carried out under gas and in particular in the presence of a gas rich in oxygen and / or ozone such as air, oxygen, ozone, oxygen enriched air and or in ozone or a gas enriched with oxygen and / or ozone.
    The last of these variants consists of an extraction of the organic compounds that are superabsorbent polymers implemented by a supercritical fluid or ultrasound.
    In what precedes and what follows, the expression "supercritical fluid" is used in its usual acceptance, namely that a "supercritical fluid" is a fluid heated to a temperature higher than its critical temperature (maximum temperature in liquid phase , whatever the pressure or temperature of the critical point) and subjected to a pressure greater than its critical pressure (pressure of the critical point), the physical properties of such a supercritical fluid (density, viscosity, diffusivity) being intermediate between those of liquids and gases. Step (2) of the process according to the invention makes use of the remarkable properties of solubility of organic compounds that supercritical fluids exhibit.
    Any supercritical fluid known to those skilled in the art and generally used in the extraction or solubilization processes of organic materials is used in the context of the present invention. Advantageously, the supercritical fluid used in the context of step (2) of the process according to the present invention is chosen from the group consisting of supercritical carbon dioxide (CO2), supercritical nitric oxide (N2O) and Freon. -22 supercritical, supercritical Freon-23, supercritical methanol, supercritical hexane and supercritical water. More particularly, the supercritical fluid used in the context of step (2) of the process according to the present invention is supercritical CO2, its critical temperature (31 ° C.) and its critical pressure (74 bar) being relatively easy to reach.
    The ultrasonic treatment can be carried out on the composite material obtained following step (1) placed with a suitable solvent in an ultrasound tank or with an ultrasound probe for a period of time of between 5 minutes and 24 hours, and in particular between 10 min and 12 h. By way of example, it is possible to use an ultrasound tank or an ultrasound probe releasing a power of between 200 W and 750 W and operating at a frequency of between 10 and 45 kHz.
    This extraction step carried out with both a supercritical fluid and ultrasound has a duration of between 15 minutes and 12 hours, and especially between 1 hour and 6 hours. It is possible for those skilled in the art to vary the treatment via a supercritical fluid and this, depending on the composite material obtained at the end of step (1) to obtain a porous geopolymer free of any organic compound.
    Once step (2) of the process according to the invention is carried out, a mesoporous and macroporous geopolymer i.e. a geopolymer having both macropores and mesopores is obtained. "Macropores" means pores or voids having an average diameter greater than 50 nm and in particular greater than 70 nm. By "mesopores" is meant pores or voids having a mean diameter of between 2 and 50 nm and especially between 2 and 20 nm. In this geopolymer, the macropores are essentially derived from the nanonodules and / or micronodules of superabsorbent polymers, while the mesopores result mainly from the geopolymerization process. Thus, the geopolymer obtained following the process according to the present invention has an open porosity, a penetrating open porosity, a connected porosity and a closed porosity.
    It is interesting to note that by modulating the amount of superabsorbent polymers used during step (1), ie during the preparation of the composite material, it is possible to influence the size of the superabsorbent polymer nodules and, by the same token, the final porosity in the geopolymer obtained following step (2). The final porosity in the geopolymer can therefore be pre-determined from step (1) of the process according to the present invention. Other features and advantages of the present invention will become apparent to those skilled in the art on reading the examples below given for illustrative and non-limiting, with reference to the accompanying figures.
    BRIEF DESCRIPTION OF THE DRAWINGS
    Figure IA to 1E are photographs taken under optical microscope of sodium polyacrylate (Aquakeep) in different environments: in the dry state (Figure IA), 0.2% by mass of Aquakeep in water (Figure IB ), 0.2% by weight of Aquakeep in an activating solution (Figure 1C), 0.5% by mass of Aquakeep in an activating solution (Figure 1D) and 1% by mass of Aquakeep in an activation solution (Figure 1E).
    Figure 2 shows the influence of Aquakeep concentration on the rheology of the activation solution.
    Figures 3A and 3B respectively show the influence of the Aquakeep concentration on the elasticity and the setting time. In Figure 3A, "G'ref" corresponds to the measurement made on a reference geopolymer without Aquakeep and "G'0.2%", "G'0.5%" and "G'1%" respectively correspond to measurements on geopolymers comprising 0.2%, 0.5% and 1% by weight of Aquakeep. In Figure 3B, "tan d ref" corresponds to the measurement made on a reference geopolymer without Aquakeep and "tan d 0.2%", "tan d 0.5%" and "tan d 1%" respectively correspond to measurements on geopolymers comprising 0.2%, 0.5% and 1% by weight of Aquakeep.
    Figures 4A and 4B respectively show the influence of the geopolymerization time (30 min "t30", 1h30 "tlh30", lh50 "tlh50" and 2h30 "t2h30") on the stress as a function of the shear rate and on the viscosity in function shear rate, the legend 0.5% SA corresponding to an activating solution alone containing 0.5% sodium polyacrylate.
    DETAILED DESCRIPTION OF PARTICULAR EMBODIMENTS I. Materials Used and Choice of Formulation
    In all of the following examples, the alumino-silicate source used is metakaolin. The metakaolin used is Pieri Premix MK (Grace Construction Products), whose composition determined by X-ray fluorescence is reported in Table 1. The specific surface area of this material, measured by the Brunauer-Emmet-Teller method, is equal to 19, 9 m2 / g and the average particle diameter (dso), determined by laser particle size, is equal to 5.9 μm.
    Table 1: Chemical composition of metakaolin used.
    In all of the following examples, the compensating cations and digestion agents selected are alkali hydroxides, introduced in the form of NaOH granules (Prolabo, Rectapur, 98%).
    A sodium silicate such as Betol 39T (Woellner) is also used in all of the following examples.
    Finally, the superabsorbent polymer used in all of the following examples is a sodium polyacrylate (PaaNa) sold under the trademark Aquakeep 10SH-NF (SUMIMOTO SEIKA). Figure 1 presents a series of Aquakeep optical microscope photographs in different environments. In the dry state, the latter is in the form of agglomerates of spherical balls whose average diameter is 25 μιτι (supplier's data) (Figure IA). When adding 0.2% Aquakeep in water, it swells by water absorption (Figure 1B). Figures IC, 1D and 1E show the influence of the Aquakeep content in a geopolymer activation solution (basic alkali silicate solution). The higher the concentration of Aquakeep, the smaller the size of the nodules, certainly because of a lower solution absorption but also a depolymerization of the crosslinked network.
    The geopolymer formulation according to the present invention used in the examples is given in Table 2 below:
    Table 2: Geopolymer formulation used.
    II. Preparation and characterization of the geopolymer according to the present invention. 11.1. Preparation of the activation solution containing Aquakeep.
    The alkali silicate solution is prepared at room temperature and then Aquakeep is added to this activation solution with magnetic stirring. This solution gels by swelling of the crosslinked polymers due to the absorption of a certain amount of saline solution, the degree of gelation increasing with the Aquakeep concentration.
    Activation solutions containing Aquakeep were characterized rheologically (Figure 2) and it was found that for a concentration of 0.2% Aquakeep, the solution behaves like a Newtonian fluid whereas for a
    Aquakeep concentration of 0.5% or 1%, a gelled solution appears (G '> G ") with a flow threshold.
    For an Aquakeep concentration of 0.5%, the threshold is approximately equal to 4 Pa and, for a 1% Aquakeep concentration, the threshold is equal to approximately 45 Pa. These flow curves can perfectly be described by a Herschel-Bulkley type law. 11.2. Addition of metakaolin and characterization of the geopolymer obtained.
    When the initial solution (activation solution + Aquakeep) is ready, the metakaolin is added at ambient temperature, with relatively constant stirring for a period of about 10 minutes and the geopolymerization reactions take place. The geopolymer is formed around the SAP grains and the material obtained is set to harden.
    Elastic modulus and setting time
    Figure 3A shows the evolution of the elastic modulus (G ') over time and according to the Aquakeep content. When the concentration increases, the elasticity increases because of the interactions between the PaaNa nodules and the setting time decreases (maximum on Tan delta in FIG. 3B) since sodium is added to the solution and thus the Si / Na ratio decreases. The elasticity increases by more than two decades with only an addition of 1% by mass of Aquakeep.
    Flowing rheological behavior
    The rheological behavior in flow was also determined in order to obtain the evolution of the flow threshold and the viscosity with the shear rate.
    Figure 4A is used to determine the flow threshold (plateau that is emerging at low shear rate). It thus passes from 4 Pa for the activation solution to about 15-20 Pa after 2:30 of geopolymerization. It should be noted that the rheological behavior differs a little from that of the activation solution.
    It would appear that the characteristic relaxation times of the geopolymer paste with Aquakeep are longer and that, therefore, the stress plateau appears at a lower shear rate. This characteristic is well reflected in the evolution of viscosity where a Newtonian plateau is emerging at a high shear rate (Figure 4B). Another interesting characteristic is the shear thinning character (decrease of the viscosity with the shear rate) of the mixture, which is beneficial for the injection processes.
    Membership Properties
    Regarding the increase in adhesion properties, observations at the laboratory scale allow to account for this increase.
    Indeed, the fact of adding sodium polyacrylate (PaaNa) allows a better affinity with the plastic pots in which the mixtures are made.
    REFERENCES
    [1] J.L. Provis, J.S.J Van Deventer, Woodhead, Cambridge, UK; 2009 [2] P. Steins, A. Poulesquen, F. Frizon, O. Diat, J. Jestin, J. Causse, D. Lambertin, S. Rossignol, Journal of Applied Crystallography, 47, (2014), 316-324 [3] Q. Li, Z. Sun, D. Tao, Y. Xu, Li P., H. Cui, J. Zhai, Journal of chance materials, 262 (2013), 325-331 [4] A. Fernandez -Jimenez, A. Palomo, DE Macphee, EA Lachowski, J. Am. Ceram. Soc., 88 (5), 2005, 1122-1126 [5] R. Castellani, A. Poulesquen, F. Goettmann, P. MArchal, L. Choplin, Col and Surf A, 454, (2014), 89-95 [ 6] A. Assmann, Dissertation of Stuttgart University, 2013: http://elib.uni-stuttgart.de/opus/volltexte/2013/8441/pdf/Dissertation Alexander Assmann.pdf [7] http: //www.rilem .org / docs / 2013142837_225-sap-unedited- version.pdf
    权利要求:
    Claims (10)
    [1" id="c-fr-0001]
    A composite material comprising at least one superabsorbent polymer in a geopolymer matrix.
    [2" id="c-fr-0002]
    2- composite material according to claim 1, characterized in that said superabsorbent polymer is selected from the group consisting of: - the polymers resulting from the polymerization with partial crosslinking of water-soluble ethylenically unsaturated monomers, such as acrylic polymers, methacrylic or vinyl, in particular crosslinked and neutralized poly (meth) acrylates; and the salts, in particular the alkaline salts such as the sodium or potassium salts of these polymers; starches grafted with polyacrylates; acrylamide / acrylic acid copolymers, typically in the form of salts, especially of alkaline salts and in particular of sodium or potassium salts; acrylamide / acrylic acid grafted starches, typically in the form of salts, especially of alkaline salts and in particular of sodium or potassium salts; the salts, in particular the alkaline salts and in particular the sodium or potassium salts, of carboxymethylcellulose; the salts, in particular the alkaline salts and in particular the sodium or potassium salts, of crosslinked polyaspartic acids; the salts, in particular the alkaline salts and in particular the sodium or potassium salts, crosslinked polyglutamic acids and their mixtures.
    [3" id="c-fr-0003]
    3- composite material according to claim 1 or 2, characterized in that said superabsorbent polymer is a poly (meth) acrylate sodium or potassium.
    [4" id="c-fr-0004]
    4- Formulation for the preparation of a composite material according to any one of claims 1 to 3, comprising: - an aluminosilicate source; an activation solution and at least one superabsorbent polymer.
    [5" id="c-fr-0005]
    5- A process for preparing a composite material according to any one of claims 1 to 3 comprising mixing together the various elements of the formulation according to claim 4.
    [6" id="c-fr-0006]
    6. Process according to claim 5, comprising the steps of: a) preparing an activating solution comprising at least one superabsorbent polymer, b) adding to the solution obtained in step (a) at least one alumino source -silicatée, c) subjecting the mixture obtained in step (b) to conditions allowing the hardening of the geopolymer.
    [7" id="c-fr-0007]
    7. A process according to claim 5, comprising the steps of: a ') adding to an activation solution at least one aluminosilicate source, b') adding to the mixture obtained in step (a ') said at least one a superabsorbent polymer, c ') subjecting the mixture obtained in step (b') to conditions permitting the hardening of the geopolymer.
    [8" id="c-fr-0008]
    8- Use of a composite material according to any one of claims 1 to 3 or capable of being prepared by a process as defined in any one of claims 5 to 7 as a material for 3D printing.
    [9" id="c-fr-0009]
    9- Use of a composite material according to any one of claims 1 to 3 or capable of being prepared by a process as defined in any one of claims 5 to 7 as a filler, seal and / or concrete projected.
    [10" id="c-fr-0010]
    10. A process for preparing a macroporous and mesoporous geopolymer comprising the steps of: 1) preparing a composite material comprising at least one superabsorbent polymer in a geopolymer matrix according to a process as defined in any one of claims 5; to 7 and then 2) removing said at least one superabsorbent polymer by a treatment selected from the group consisting of heat treatment, oxidative treatment, photo-degradation treatment and extraction via a supercritical fluid or ultrasound.
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    同族专利:
    公开号 | 公开日
    EP3353133B1|2019-07-10|
    DK3353133T3|2019-10-14|
    FR3041630B1|2020-10-16|
    US20180290925A1|2018-10-11|
    SI3353133T1|2019-11-29|
    JP2019500228A|2019-01-10|
    EP3353133A1|2018-08-01|
    WO2017050946A1|2017-03-30|
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    WO2015123732A1|2014-02-21|2015-08-27|Laing O'rourke Australia Pty Limited|Method for fabricating a composite construction element|CN111018416A|2019-12-04|2020-04-17|兰州大学|Method for modifying performance of coal ash-based geopolymer by ultrasonic waves|DE10202039A1|2002-01-18|2003-07-24|Basf Ag|Mixtures of hydrogel-forming polymers and building materials|
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    法律状态:
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    优先权:
    申请号 | 申请日 | 专利标题
    FR1559078A|FR3041630B1|2015-09-25|2015-09-25|SUPER-ABSORBENT POLYMER GEOPOLYMER, ITS PREPARATION PROCESS AND ITS USES|FR1559078A| FR3041630B1|2015-09-25|2015-09-25|SUPER-ABSORBENT POLYMER GEOPOLYMER, ITS PREPARATION PROCESS AND ITS USES|
    PCT/EP2016/072630| WO2017050946A1|2015-09-25|2016-09-23|Use of a geopolymer with superabsorbent polymer|
    JP2018515511A| JP2019500228A|2015-09-25|2016-09-23|Use of geopolymers with superabsorbent polymers|
    SI201630434T| SI3353133T1|2015-09-25|2016-09-23|Use of a geopolymer with superabsorbent polymer|
    EP16778248.1A| EP3353133B1|2015-09-25|2016-09-23|Use of a geopolymer with superabsorbent polymer|
    DK16778248.1T| DK3353133T3|2015-09-25|2016-09-23|Use of a superabsorbent polymer geopolymer|
    US15/762,437| US20180290925A1|2015-09-25|2016-09-23|Use of a geopolymer with superabsorbent polymer|
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