FR2946641A1 - Binder composition, useful for forming construction materials, comprises natural lime binder, metakaolin binder, and binder of an adjuvant comprising shrinkage reducer, water repellent hardener - Google Patents

Abstract

Binder composition (I) comprises: a natural lime binder (50-80 mass%), metakaolin binder (20-50 mass%), and binder (0.25-2 mass%) of at least one adjuvant comprising a shrinkage reducer, water repellent hardener, with a water/ binder ratio of 0.3-0.7.

Description

BINDER COMPOSITION FOR SHAPING CONSTRUCTION MATERIALS

The present invention relates to the field of eco-construction. More specifically, it relates to a composition having binding properties for the manufacture of construction materials with low environmental impact.

Field of the invention The evolution of construction, in a general context of sustainable development, tends to be done both in respect of natural resources (by favoring renewable resources), energy savings (at the same time in manufacturing and especially in use), and health and comfort (both the people responsible for implementation and the end user). Finally, the fate of the material at the end of its life must be done without generating new non-reusable waste. In this context, it is essential to dispose of building materials that are both resistant and non-polluting.

PRIOR ART In the field of construction, the most common binder is cement. The term "cement" refers to a powdery material forming with water or with a saline solution a binder plastic paste capable of agglomerating, by hardening, various substances. It also means, in a broader sense, any material interposed between two hard bodies to bind them. In general, the hardening appears quickly and the maximum strength of the cement is obtained in a few days. After drying, this paste retains its strength and stability even in water. Its most common use is in the form of powder used with water to aggregate fine sand and gravel (aggregates) to give concrete, the material of choice in the building sector.

However, the production of cement requires a large amount of energy and generates significant CO2 emissions. This poses environmental problems, in particular related to the contribution to the greenhouse effect and to global warming (CA Hendricks et al., Interlaken, Greenhouse Gas Control Technologies Proceedings of the 4th International Conference , Austria Aug. 30-Sept.2, IEA GHG R & D Program, UK 1998).

The amount of CO2 emitted during cement production can be divided into two parts depending on its source. The first comes from the burning of fossil energy necessary for the calcination of the raw material, it represents about 390 kilos per ton of cement. The second is induced by the decarbonation of the carbonaceous matter contained in the raw, it represents about 425 kilos per ton of cement. On average, 815 kilograms of CO2 are emitted for each tonne of cement produced (Gartner E. Industrially Interesting Approaches to Low Carbon Cernent, Cernent and Concrete Research, Vol 34, 2004, pp. 1489-98).

In the context of the development of materials with low environmental impact, previous studies have considered the use of hydraulic lime binder (containing 10% by volume of pozzolans) and air lime. The mechanical strength of this type of binder varies between 4 MPa at 14 days and 5 MPa at 15 months (Cérézo V., Thermal and acoustic mechanical properties of a material based on plant particles: experimental approach and theoretical modeling, thesis of National School of Public Works, 2005). In addition, these works have highlighted a long drying time and penalize for the implementation of the material.

Brief description of the invention

The present invention aims at overcoming the drawbacks of the prior art and proposes a binder composition for shaping construction materials that respect the environment, particularly in that it allows the incorporation of agroresources, corn-taking a hydraulic lime base, metakaolin and at least one water-repellent reducing reducer.

By shaping construction materials is meant pouring into molds or receptacles of various geometric shapes of a composition comprising a binder according to the invention in order to obtain a material suitable for use in the construction of residential structures or other building elements.

Agroresources means any plant material that can be incorporated as such or after various chemical or physical treatment processes (including thermal) to a binding phase to confer various specific properties related to the plant considered.

The binder according to the present invention represents an alternative to conventional cements by generating a lower impact on the environment. In fact, the calcination temperature of natural hydraulic lime is lower than that of cement (about 1000 ° C compared with 1450 ° C). As far as metakaolin is concerned, its production is based on the dehydroxylation of kaolinite, a chemical process that only generates water vapor emissions.

DETAILED DESCRIPTION More precisely, the present invention relates to a binder composition used for shaping construction materials incorporating agroresources, characterized in that it comprises 50 to 80% by weight of natural lime binder, 20 to 50% by weight. mass of metakaolin binder and 0.25 to 2% by weight of binder of at least one admixture comprising a water-repellent reducing hardener with a water / binder ratio of between 0.3 and 0.7.

The water / binder ratio determined according to the invention makes it possible to obtain an optimum viscosity allowing the binder to be mixed with any type of agroresources. The water taken into account in this report is the so-called effective water, ie the water available for the hydration of the binder. This report does not include water that is absorbed by the agroresource (s) associated with the binder. In this range of values, the binder obtained has a consistency that makes it possible to manipulate and shape it according to various techniques known to those skilled in the art such as pouring or vibrocompacting.

The natural lime is obtained by calcination of a rock composed mainly of calcium carbonate and, according to the deposit, elements which during the cooking process transform into silicates and calcium aluminates. It can therefore be a natural aerial or hydraulic lime. In order to obtain a binder with optimized mechanical properties, a natural hydraulic lime is preferably chosen, for example a NHL type lime (SOCLI). Preferably, the binder according to the present invention comprises 50 to 70% by weight of natural lime binder.

The metakaolin present in the binder according to the invention is an artificial material obtained from baking between 650 and 800 ° C of crushed kaolin. It is mainly composed of alumina and amorphous silica. It has a pozzolanic character and thus reacts with the calcium hydroxide of lime. It can be obtained, for example, by flash calcination of kaolin (ARGECO, Fumel). Preferably, the binder according to the present invention comprises 30 to 50% by weight of metakaolin binder.

In the case of a binder using a metakaolin obtained in the traditional way (first calcined for a few hours, then ground), the percentage used is closer to 30%. In the case of a metakaolin obtained by flash calcination (ground before calcination), the percentage is closer to 50%. In the latter case, the overall duration of the process for obtaining the binder is lower, which represents an economic interest.

The binder according to the invention has hygroscopic properties that are better than those of cement, it acts as an internal moisture regulator and can be described as a breathable material because it allows a transport of water vapor between the interior and the interior. without problem of condensation (Samri D. Physical analysis and hygrothermal characterization of building materials: experimental approach and numerical modeling, thesis of the National School of Public Works, 2008).

The proposed binder also has mechanical properties surpassing those of materials used for similar uses in construction. Its compressive strength is superior to that of plaster (Eve S. and others Microstructural and mechanical behavior of polyamide fiber-reinforced composite plaster, Journal of the European Ceramic Society, vol.22, 2002, pp. 2269-2275). 'to that of normalized natural hydraulic lime. In addition, the development of resistance is from an early age. A standard NHL 5 natural hydraulic lime guarantees a resistance of 5 MPa at 28 days, the proposed binder exceeds 10 MPa from 14 days and reaches 17 MPa at 28 days.

Finally, the mechanical performance of this binder is maintained in the case of immersion in water, which is not the case of plaster for example.

The proposed binder has a limited environmental impact compared to a conventional cementitious binder. It has hygroscopic properties and vapor permeability that can be used in the building in terms of indoor air quality.

Its compressive strength, in the short and long term, surpasses that of plaster or hydraulic lime and remains constant when immersed in water. This property would be used outdoors or in conditions of exposure to water (bathroom, kitchen).

In a preferred manner, the water-repellent reducing hardener of the binder composition according to the invention is a glycerol carbonate. This compound in fact leads to good curing qualities and also has the advantage of being of plant origin and produced according to an eco-certified process, which corresponds to an objective of respect for the environment of the invention. The percent purity of the glycerol carbonate may be variable. The incorporation of glycerol carbonate allows accelerated hardening of the dough as well as higher mechanical strength at younger ages. These results are particularly interesting in the case of production in prefabrication, allowing a faster demolding, even immediate.

In a particular embodiment of the invention, said at least one adjuvant additionally comprises at least one air entrainer. Preferably, the air entrainer is chosen from amphiphilic molecules of plant origin. Among these amphiphilic molecules, ethoxylated sorbitan monolaurate and / or acetylated monococoate glycerol are preferred.

Increased maneuverability is achieved by ethoxylated sorbitan monolaurate and acetylated monococoate glycerol, which facilitates the processing of the fresh material. In addition, these additives also have an air-entraining effect, responsible for the creation of a large closed porous network lasting in the cured state.

The addition of glycerol carbonate, ethoxylated sorbitan monolaurate and acetylated monococoate glycerol induces a limitation of shrinkage and consequently a reduced risk of surface microcracking.

A hardening accelerator may also be added to the binder composition according to the present invention. This compound is preferably of mineral origin such as calcium chloride for example. It aims to improve the setting time and the strength of the building material obtained by mixing the binder with the selected agroresources.

The binder composition thus defined according to the invention finds a particularly advantageous application for the manufacture of building materials in combination with plant materials in the form of fibers or aggregates.

The schoolchild according to the present invention is intended for use in the formulation of materials with low environmental impact in the field of building. It constitutes the binding matrix incorporating agroresources. Several types of finished products can be considered.

For example, elements of the type prefabricated facing plates or projected plaster can be made. In this case, the incorporation of plant fibers into the mixture will improve its flexural strength and reduce its brittleness (the flexural strength of the material containing 1% dry weight of flax fiber binder reaches 6 MPa against 2 , 5 MPa for the binder alone).

Prefabrication of self-supporting blocks or tiles is also possible. The addition of light aggregates such as hemp hemp or sunflower marrow then gives the product thermal insulation properties. These elements could be used in filling on a wooden frame or partition wall in buildings.

The water resistance of the binder makes it possible in all cases to envisage an application outdoors or in rooms in which it would be subjected to splashes of water (bathroom, kitchen).

The rapid stiffening of the binder and its relatively high early age resistances make it possible to envisage production in prefabrication with immediate demolding. This technique reduces production costs by optimizing mold rotation.

This binder, thanks to its reduced environmental impact and its hygroscopic properties, could be associated with renewable agroresources to formulate an eco-material meeting the new requirements of consumers in terms of environmental impact, comfort and quality of the environment. indoor air.

The properties and advantages of the composition which is the subject of the present invention will emerge more clearly in the light of the examples which follow. These are given for illustrative purposes only and should not be interpreted as limiting the scope of the composition according to the invention, which extends in particular to means equivalent to those described in the present application.

The following figures also serve to illustrate the present invention:

- Figure 1: Evolution of the compressive strength (Rc) over time of a corn-20 position according to the invention and a control composition. - Figure 2: Total removal of a composition according to the invention and a control composition. - Figure 3: Mechanical strengths of a composition according to the invention and a control composition. 4: Mechanical properties of a composition according to the invention reinforced by flax plant fibers and a control composition based on fiber-free plaster.

EXAMPLES

Example 1: CO2 emission balance of the manufacture of a binder according to the invention

A binding mixture composed of 49.5% of NHL 5 natural hydraulic lime from Saint Astier, 49.5% of metakaolin and 1% of glycerol carbonate (CG) is produced with a ratio Eeff / L = 0.5. In total, this binder induces the emission of about 482 kilograms of CO2 per ton of binder produced is a reduction of 44% compared to conventional cement.

Example 2 Characterization of the Properties of a Binder According to the Invention A mixture identical to Example 1 is produced. Its compressive strength (Rc) is compared to a control binder comprising 50% NHLS Saint Astier and 50% meta-kaolin. As illustrated in FIG. 1, the binder according to the invention has an improved Rc of 50% at 9 days and 15% after 49 days compared with the control. This same mixture allows a total shrinkage reduction of about 30% over the control mixture, as shown in Figure 2. In addition, for a mixture of 49% metakaolin, 49% NHLS natural hydraulic lime from Saint Astier, 1% CG and 1% Ethoxylated Sorbitan Monolaurate (SME), the shrinkage-limiting effect is maintained (Figure 2).

FIG. 3 shows the 28-day compressive strengths (Rc28j) and the 28-day flexural strengths (Rf28j), control mixtures and according to the invention containing 1% of CG as previously defined. These results highlight the improvement of the mechanical properties by adding GC regardless of the storage conditions (100% relative humidity, 65% relative humidity and immersion in water). The water resistance of the binder is to be emphasized.

Example 3 Use of a Binder According to the Invention Associated with Vegetable Flax Fibers

A composite material was made by incorporating 1% by weight of dry binder of flax fibers into a matrix according to the invention composed of 49% NHLS Saint Astier, 49% metakaolin, 1% CG, and 1% of EMS. The Eeff / L ratio was set at 0.5. The results presented in FIG. 4 show an improvement of the flexural strength of the composite by more than 186% with respect to the raw matrix. The compression performance of the raw schoolchild according to the invention surpasses that of the plaster, and the fiber composite has mechanical performance much higher than that of the fiber plaster.

Claims (11)

CLAIMS1- Binder composition used for shaping construction materials incorporating agroresources, characterized in that it comprises 50 to 80% by weight of natural lime binder, 20 to 50% by weight of metakaolin binder and 0, 25 to 2% by weight of binder of at least one adjuvant comprising a water-repellent reducing reducer with a water / binder ratio of between 0.3 and 0.7. 2- binder composition according to claim 1, characterized in that said at least one adjuvant further comprises at least one air entrainer. 3. Binder composition according to claim 1 or 2, characterized in that said at least one adjuvant further comprises at least one curing accelerator. 4- binder composition according to any one of the preceding claims, characterized in that the lime is a natural hydraulic lime. 20 5. Binder composition according to any one of the preceding claims, characterized in that the water-repellent reducing reducer hardener is a glycerol carbonate. 6. Binder composition according to any one of the preceding claims, characterized in that said at least one air entrainer is selected from amphiphilic molecules 25 of plant origin. 7- binder composition according to claim 6, characterized in that said at least one air entrainer is selected from sorbitan monolaurate ethoxylated and / or glycerol monococoate acetylated. 8. Binder composition according to any one of the preceding claims, characterized in that the curing accelerator is a compound of mineral origin. 30 9. Binder composition according to any one of the preceding claims, characterized in that it comprises 50 to 70% by weight of natural lime binder. 10- binding composition according to any one of the preceding claims, caractéri-5 sée in that it comprises 30 to 50% by weight of metakaolin binder. 11- Use of a binder composition according to any one of claims 1 to 10 for the manufacture of building materials in combination with vegeta-les in the form of fibers or aggregates. 10