FR2956397A1 - Adjuvant, useful for hydraulic binder for the manufacture of elements for the construction field, comprises e.g. alkyl sulfonate, alphaolefinsulfate and/or alkylbenzenesulfate; and calcium salt soluble in water - Google Patents

Abstract

Adjuvant (I) comprises: an alkyl sulfonate, an alkylethersulfonate, a hydroxyalkylethersulfonate, an alphaolefinsulfonate, an alkyl benzene sulfonate, an alkyl sulfate, an alkyl ethersulfate, a hydroxyalkylethersulfate, an alphaolefinsulfate and/or alkylbenzenesulfate; and a calcium salt soluble in water. Independent claims are included for: (1) hydraulic binder comprising the adjuvant; (2) hydraulic composition comprising the hydraulic binder; (3) lightweight concrete comprising the composition; (4) manufacturing a hydraulic composition comprises contacting the adjuvant, water and the hydraulic binder; (5) manufacturing a lightweight concrete comprising introducing gas into the hydraulic composition; and (6) element for construction field, made of the hydraulic binder, hydraulic composition or lightweight concrete.

Description

The subject of the present invention is structural elements made of insulating light concrete, in particular light blocks of concrete, in particular of foamed concrete. There are many types of building materials for large works in the form of masonry blocks. It is possible to cite inter alia terracotta (for example hollow or cellular brick of the MonomurTM type), cementitious materials (for example concrete blocks or blocks) or vegetable matter (for example hemp such as ChanvriblocTM) among these blocks. , lightweight concrete blocks are very advantageous for many applications because of their thermal insulation properties. Lightweight concrete is lighter than traditional concrete because of the pores or voids it contains. These pores or voids are due to the presence of air in the concrete, which forms bubbles. Indeed with 1 m3 of raw material, one manufactures about 5 m3 of finished product, ie a block composed of 20% of materials and 80% of air (valid for a block in density of 400 kg / m3). The difficulty in the realization of light concrete blocks is to combine lightness and strength of the block. The most common ways of producing lightweight cementitious materials for making these blocks are: a) generating a gaseous release by chemical reaction between an aluminum powder and a reagent rich in lime, sand and cement when setting the concrete; b) produce an aqueous foam (by introducing air into a mixture of water and foaming agent) and inject the foam into the dough, or c) aerate directly a dough in a kneader. However, these methods are not really satisfactory. The former does not allow sufficient density control because of the complexity of the process. The second involves the addition of foam water which naturally fluidifies the dough, but at the expense of the final mechanical properties. The third does not allow to obtain a good robustness, nor a control of the size of the bubbles. In the latter two cases, the lowest fluidity is obtained by the known means that are the use of fluidizing agents and / or water reducer, and occasionally by a granular optimization of the mixture of powders. However, the use of fluidizing agents (such as superplasticizers) leads to an improvement in fluidity, but this is associated with a strong segregation of the particles, as well as an accentuated tendency to the generation of lumps which penalizes the mechanical resistance.

In order to meet the requirements of industrialists, it became necessary to find another way to make light concrete blocks.

Also the problem to be solved by the invention is to simplify the manufacturing processes of these blocks and also the ability to produce fluid cementitious pastes, very fluid with a water / cement and water / solid weak, while retaining high thermal and mechanical properties of the final material. Very unexpectedly, the inventors have demonstrated that the joint use of an accelerator and a foaming agent provides, by synergistic effect, a very significant gain in fluidity to the cement paste before foaming, without penalizing any other property .

For this purpose, the present invention provides a hydraulic binder admixture comprising at least - alkylsulfonate, alkylethersulfonate, hydroxyalkylethersulfonate, alphaolefinesulfonate, alkylbenzenesulfonate, alkylsulfate, alkylethersulfate, hydroxyalkylethersulfate, alphaolefin sulfate, and / or alkylbenzenesulfate; and a calcium salt soluble in water. The invention also provides a hydraulic binder comprising the adjuvant above. The invention also proposes a hydraulic binder comprising in percentage by weight relative to the mass of cement - from 20 to 99.98% of Portland cement and / or aluminous cement and / or magnesium cement and / or sulfoaluminous cement; from 0 to 80% of mineral particles of sizes ranging from 0.1 μm to 300 μm; from 0.01 to 5% of an alkyl sulphonate, an alkyl ether sulphonate, a hydroxy alkyl ether sulphonate, an alpha olefin sulphonate, an alkyl benzene sulphonate, an alkyl sulphate, an alkyl ether sulphate, a hydroxy alkyl ether sulphate, an alphaolefin sulphate, and / or an alkylbenzene sulphate - from 0.01 to 5% of a water-soluble calcium salt. The invention also relates to a hydraulic composition comprising at least the hydraulic binder above. The invention also relates to a light concrete comprising the hydraulic composition above. The invention also relates to a method for manufacturing the hydraulic composition described above comprising a step of contacting at least the adjuvant described above, water and a hydraulic binder.

The invention also relates to an element for the field of construction made using the hydraulic binder or the hydraulic composition or lightweight concrete described above. Finally, the invention relates to the use of a hydraulic binder or a hydraulic composition or light concrete described above for the manufacture of elements for the field of construction. The invention provides at least one of the critical advantages described below. Advantageously, the invention particularly offers the possibility of producing lightweight blocks with an apparent density of between 100 and 800 kg / m 3.

The invention offers another advantage that the light blocks according to the invention have excellent thermal, acoustic and / or mechanical properties. Another advantage of the present invention is that the adjuvant according to the invention makes it possible to produce hydraulic compositions, such as cementitious pastes, having a very low water level compared to the same paste without adjuvants.

In addition, thanks to the hydraulic compositions according to the invention, the setting is not significantly affected, and the accelerator continues to play its role. And again, advantageously, the light blocks according to the invention make it possible to eliminate or considerably reduce the thermal bridges at the level of the slab noses, the sloping walls, the chaining, the lintels, etc. For example, it may be considered to remove indoor or outdoor insulation. Finally, the manufacture of light blocks according to the invention makes it possible to use a cold molding process, followed by drying, for example in the open air, which considerably reduces the energy required for their production and thus reducing the associated 002 emissions.

In addition, advantageously, the adjuvant according to the invention makes it possible to reduce the viscosity of the hydraulic composition. Finally, the invention has the advantage of being able to be implemented in at least one of the industries, such as the building industry, the chemical industry (adjuvants) and the cement industry, in the construction markets ( building, civil engineering, roads or prefabrication in factory or on site), or ready mix concrete plants. Other advantages and characteristics of the invention will become clear from reading the description and examples given by way of purely illustrative and nonlimiting that will follow.

By the term "hydraulic binder" is meant according to the present invention any compound having the property of hydrating in the presence of water and whose hydration makes it possible to obtain a solid having mechanical characteristics. The hydraulic binder according to the invention may in particular be a cement. Preferably, the hydraulic binder according to the invention is a Portland cement in accordance with the EN 197-1 standard and / or an aluminous cement. By the term "hydraulic composition" is meant according to the present invention a mixture of at least one hydraulic binder, with water, optionally aggregates, optionally adjuvants according to EN 934-2, and optionally additions. The expression "hydraulic composition" according to the invention indistinctly refers to a composition in the fresh or hardened state. The hydraulic composition according to the invention may be a cement slurry, a mortar or a concrete. Preferably, the hydraulic composition according to the invention is a cement slurry or a mortar. More preferably, the hydraulic composition according to the invention is a cement slurry. A hydraulic composition can be for example a concrete such as high performance concrete (BHP), ultra high performance concrete (BUHP), self-compacting concrete, self-leveling concrete, self-compacting concrete, fiber concrete, ready-mixed concrete , construction concrete, lightweight concrete, precast concrete, calendered concrete or colored concrete. The term "ready-to-use concrete" according to the invention a concrete having an open time of sufficient workability to allow the transport of concrete to the site where it will be poured. The term "concrete" according to the invention comprises mortars, in this case the concrete comprises a mixture of at least one hydraulic binder, sand, water and optionally adjuvants and optionally mineral additions. The term "concrete" according to the invention denotes indistinctly fresh concrete or hardened concrete. By the term "addition" is meant according to the present invention slags, silica fumes, fly ash, or limestone or siliceous fillers.

By the term "setting" is meant according to the present invention the transition to the solid state of the hydraulic binder by hydration reaction. The setting is usually followed by the hardening period. By the term "hardening" is meant according to the present invention the acquisition of the mechanical strengths of a hydraulic binder. Curing usually takes place after the end of the setting. By the expression "elements for the field of construction" is meant according to the present invention any element of a construction such as for example a floor, a screed, a foundation, a base, a wall, a partition, a counter partition, ceiling, beam, worktop, pillar, cinderblock, lightweight concrete block, post, panel, cornice, mold, cladding, plaster, insulation (acoustic and / or or thermal). Adjuvant Firstly, the subject of the invention is a hydraulic binder admixture comprising at least an alkylsulfonate, an alkylethersulfonate, a hydroxyalkylethersulfonate, an alphaolefinesulfonate, an alkylbenzenesulphonate, an alkylsulphate, an alkylethersulphate, a hydroxyalkylethersulphate, an alphaolefin sulphate, and / or an alkylbenzene sulphate; and a calcium salt soluble in water. Preferably, the adjuvant according to the invention comprises an alkyl sulphate or a linear or branched carbon chain alkyl ether sulphate of formula C n H 2 n +, - (OCH 2 CH 2) m -SO 3 M wherein n is between 8 and 14 and m is between 0 and 9. M being an alkaline or alkaline earth cation. Preferably, the adjuvant according to the invention comprises a linear or branched alkyl ether sulfate of formula CnH2n +, - (OCH2CH2) m -SOO3M in which n is between 9 and 11 and m is between 1 and 6.

According to a variant of the invention, the adjuvant according to the invention comprises a mixture of alkyl ether sulfate and alkyl sulphate. Preferably, the water-soluble calcium salt of the adjuvant according to the invention is chosen from calcium chloride, calcium nitrite and calcium nitrate. The calcium salt soluble in water may be in the form of powder or liquid, anhydrous or hydrated. Preferably, the adjuvant according to the invention further comprises a foam stabilizing agent, such as betaine, an amine oxide, or a fatty amide. Preferably, the adjuvant according to the invention further comprises a water-reducing agent, preferably a superplasticizer, such as for example a PCP-type superplasticizer without antifoam agent. The term "poly" or "polycarboxylate polyoxide" according to the present invention is understood to mean, inter alia, a copolymer of acrylic or methacrylic acids and of their poly (ethylene oxide) (POE) esters. On the other hand, the adjuvant according to the invention used according to the invention may have a variable degree of purity. According to a variant of the invention, the adjuvant does not comprise an antifoaming agent, or any agent having the property of destabilizing an air emulsion in a liquid. Hydraulic Binder The subject of the invention is also a hydraulic binder comprising the adjuvant according to the invention.

The hydraulic binder according to the invention may further comprise in percentage by weight relative to the mass of cement - from 20 to 99.98% of Portland cement and / or aluminous cement and / or magnesium cement and / or cement sulfoaluminous; from 0 to 80% of mineral particles of sizes ranging from 0.1 μm to 300 μm; from 0.01 to 5% of an alkyl sulphonate, an alkyl ether sulphonate, a hydroxy alkyl ether sulphonate, an alpha olefin sulphonate, an alkyl benzene sulphonate, an alkyl sulphate, an alkyl ether sulphate, a hydroxy alkyl ether sulphate, an alphaolefin sulphate, and / or an alkylbenzene sulphate - from 0.01 to 5% of a water-soluble calcium salt. Preferably, the hydraulic binder according to the invention may further comprise in percentage by weight relative to the mass of cement - from 30 to 60% of Portland cement and / or aluminous cement and / or magnesium cement and / or sulfoaluminous cement; from 40 to 70% of mineral particles of sizes ranging from 0.1 μm to 300 μm; from 0.1 to 1% of an alkylsulfonate, an alkylethersulfonate, a hydroxyalkylethersulfonate, an alphaolefinesulfonate, an alkylbenzenesulfonate, an alkylsulfate, an alkylethersulfate, a hydroxyalkylethersulfate, an alphaolefin sulphate, and / or an alkylbenzene sulphate - from 0.1 to 2% of a water-soluble calcium salt. Preferably, the hydraulic binder comprises mineral particles. The preferred mineral particles are calcium carbonate, glass beads, expanded glass particles, silica fumes, slags, fly ash, pozzolans or limestone or siliceous fillers. Preferably, the hydraulic binder comprises mineral particles of size ranging from 1 μm to 80 μm. According to a variant of the invention, the hydraulic binder may comprise polymer beads such as polystyrene beads, ExpancellTM beads, aluminosilicate microspheres or cenospheres, such as fillites, classified or unclassified fly ash, ceramics, light powders, or sand. The Portland cement that is particularly suitable according to the invention is that described according to the standard EN 197-1.

Cements of the calcium aluminate type, for example those based on calcium silicates, melted cements or aluminous cements, are also suitable according to the invention as well as cements conforming to standard NF EN 14647. Particularly suitable sulphoaluminium cement according to the invention is that described in the patent application WO 2006/018569. Preferably, the hydraulic binder further comprises calcium sulfate, hydrate, hemihydrate or anhydrous. Preferably, the hydraulic binder further comprises lime.

Composition The subject of the invention is also a hydraulic composition comprising at least one hydraulic binder according to the invention. Preferably, the hydraulic composition according to the invention is a cement slurry, a mortar or a concrete.

According to a variant of the invention, the hydraulic composition can comprise polymer beads such as polystyrene beads, ExpancellTM beads, aluminosilicate microspheres or cenospheres, such as fillites, classified or non-classified fly ash, ceramics, light powders, aluminum powders and sand.

According to another variant of the invention, the hydraulic composition may comprise lightweight aggregates, most often artificial and made from mineral materials, which are used in particular for the manufacture of so-called "light" concretes. The light aggregates are defined in particular by the NF EN 13055-1 standard of December 2002. These light aggregates are, for example, clays (expanded clays), schists (expanded schists) or silicates (vermiculite or perlite) or pumice stones. The subject of the invention is also a method for manufacturing a hydraulic composition according to the invention, characterized in that it comprises a step of contacting at least one adjuvant according to the invention with water and a hydraulic binder.

Preferably, this contacting step is carried out according to one of the following ways: the adjuvant according to the invention is added at the same time as and / or in water; the adjuvant according to the invention is added directly to at least one of the components of the hydraulic composition according to the invention before adding water; the adjuvant according to the invention is added during the mixing.

Preferably, the components of the hydraulic composition to which the adjuvant according to the invention can be added are aggregates, fibers, a hydraulic binder, slag, silica fumes, fly ash, calcareous or siliceous fillers, pozzolans, admixtures, mixing water, pre-wetting water, etc.

Advantageously, when the adjuvant according to the invention is added during the mixing, it can be added at the beginning, in the middle or at the end of said mixing. It may even be envisaged to add the adjuvant according to the invention last, just before stopping the mixer in which the components are mixed. Advantageously, the adjuvant according to the invention can be added continuously in the hydraulic composition, even after the end of the mixing operation. The invention also relates to a lightweight concrete comprising the hydraulic composition according to the invention. The lightweight concrete according to the invention may comprise from 30 to 90% air by volume, preferably from 60 to 80%. This air can be in the form of micro-air cells and give lightweight concrete a honeycomb structure giving it thermal insulation properties ("distributed insulation"). The air can be absorbed homogeneously in the mass of the material and can assume its role as an insulator. The light concrete according to the invention can make it possible to produce blocks, in particular blocks intended for large works but also for second works. These blocks can be in various forms such as for example in the form of bricks, honeycomb, size and variable thickness. These blocks have the advantage of having great maneuverability, and in particular to be cut with a hand saw. It is also possible to sand the surface of the block if an element protrudes, for example, using a sanding board. The lightweight concrete blocks according to the invention may be generally in the form of a rectangular parallelepiped of gray color, but other colors may be envisaged. A complete range of blocks, lintels, floor and roof slabs, partition tiles can be used to build a house made entirely of lightweight concrete according to the invention, by adapting the density of the block to its function. The installation of the material proves extremely fast and easy to work 3 m2 / hour for a solid wall thanks to an assembly realized with a mortar-adhesive (laying said "with thin joint" which limits the thermal bridges) . It is possible to assemble the blocks using traditional mortar according to a conventional laying method.

The invention offers another advantage that the lightweight concrete according to the invention have excellent thermal properties, and in particular a very low thermal conductivity. Thermal conductivity (also called lambda (2)) is a physical quantity that characterizes the behavior of materials during conductive heat transfer. Thermal conductivity is the amount of heat transferred per unit area and a unit of time under a temperature gradient. In the international system of units, the thermal conductivity is expressed in watts per meter Kelvin, (W • m-1.K-1). Conventional concretes have a thermal conductivity at 23 ° C and 50% relative humidity between 1.3 and 2.1. Traditional lightweight structural concretes have thermal conductivities generally greater than 0.8 W / m.K at 23 ° C and 50% relative humidity. The lightweight concrete according to the invention has a thermal conductivity of from 0.05 to 0.6 W / mK, preferably from 0.05 to 0.4 W / mK, more preferably from 0.05 to 0.25 W / mK. mK, even more preferably from 0.05 to 0.15 W / mK The invention offers another advantage that the lightweight concrete according to the invention have excellent acoustic properties, and in particular a very low phonic conductivity. The invention offers another advantage that the lightweight concrete according to the invention have excellent mechanical properties, and in particular a very good compressive strength. The lightweight concrete according to the invention has a compressive strength of from 1 to 10 MPa, preferably from 2 to 8 MPa, more preferably from 2 to 4 MPa, even more preferably 3 MPa. The invention offers another advantage that the lightweight concrete block according to the invention have a great lightness, and in particular a very low density. The lightweight concrete block according to the invention has a bulk density of from 100 to 800 kg / m3, preferably from 300 to 700 kg / m3, more preferably from 400 to 600 kg / m3, even more preferably from 450 to 550 kg / m3. kg / m3. According to the use of lightweight concrete according to the invention, it will be appropriate to adapt the density of the concrete to its application.

The invention also relates to a method for manufacturing a lightweight concrete according to the invention characterized in that it comprises a step of introducing gas into the hydraulic composition according to the invention. The introduced gas is preferably air.

The step of introducing gas into the hydraulic composition according to the invention can be done in different ways, and in particular either by direct introduction of gas, or by introducing a dispersion of a gaseous phase into a liquid.

According to a first variant of the process according to the invention, the introduction of gas can be done by direct introduction of air. In particular, the direct air injection method described in application WO 2005/080294 is particularly suitable. According to this first variant, the air is introduced under pressure into the hydraulic composition according to the invention, in particular the pressure is between 1 and 5 bar. According to a second variant of the process according to the invention, the introduction of gas can be done by introducing a dispersion of a gaseous phase into a liquid, in particular by introducing an air foam into water. The air-in-water dispersion can be introduced directly into the hydraulic composition according to the invention and then mixed in a static mixer, batchwise or continuously. As an example embodiment of this variant, there may be mentioned the case where the hydraulic composition according to the invention, comprising or not the adjuvant according to the invention, is manufactured in a concrete plant. The hydraulic composition is deposited in a mixer truck (for example a mixer truck) and then a foam is added either directly in the truck or directly on the site when the truck has arrived. Then the frothed slurry is poured into a mold. The invention also relates to an element for the field of construction, characterized in that it is carried out using a hydraulic binder according to the invention or a hydraulic composition according to the invention or a light concrete according to the invention.

The invention also relates to the use of a hydraulic binder according to the invention or a hydraulic composition according to the invention or a light concrete according to the invention for the manufacture of elements for the field of construction. According to the use of lightweight concrete according to the invention, it will be appropriate to adjust the density of lightweight concrete.

Brief Description of the Figures The following figures illustrate the invention without limiting its scope. Figure 1 shows the relationship between viscosity and shear rate for different pastes in which different specific adjuvants were added. Figure 2 shows a diagram of the first variant of the method of manufacturing a lightweight concrete according to the invention with direct introduction of air.

Referring initially to Figure 2, the method according to the invention for manufacturing a lightweight concrete comprises the preparation of a batch slurry (1) comprising cement, mineral particles, adjuvants, water, an accelerator, a foaming agent. The process comprises continuous foaming (2) with the introduction of air into the Mondomix dynamic mixer, and finally the casting / forming of light concrete (3). The following examples illustrate the invention without limiting its scope.

EXAMPLES

Materials: Millifoam C or Millifoam H: it is an anionic type foaming agent (alkyl ether sodium sulphate) supplied by Hunstman; Calcium Chloride: Pure CaCl2 from Verre Labo Mula; Portland cement is a CEM 152.5 R cement from the Lafarge cement plant in Port La Nouvelle (lot number LHY-3830 or LHY-3867); The sulfoaluminous cement is that described in the patent application WO 2006/018569. The mineral filler is calcium carbonate supplied by OMYA under the name Betocarb HP Entrains whose D50 is 7.8 μm, the D10 is 1.7 μm, the D90 is 93 μm and with a maximum particle size of 200 μm (lot number ADD-0239); The plasticizer is a blend comprising a polyoxide polycarboxylate (PCP) supplied by Chryso under the name Chrysolab EPB 530-017; The fly ash comes from South Africa (Superpozz) and North America (Willcounty) Pozzolans come from Greece (Yali). Water: tap water;

Realization of hydraulic compositions according to the invention:

The cement, the mineral filler and the calcium salt are weighed together on the scale. Then the mixing water and the thinner (Chrysolab) are weighed separately. In the same way the Millifoam is weighed separately. All the weighed powders are placed in the mixing tank (RayneriTM mixer MALX-104) and are agitated using the planetary rotary blade of the kneader (17 rpm for 1 to 2 minutes). The mixing water comprising the plasticizer is added to the powders in the mixer tank (33 rpm for 1 to 2 minutes depending on the volume). A grout of cement is then obtained which is left stirring for 2 additional minutes in the kneader. The mixer is stopped. The bowl of the kneader is scraped then Millifoam is poured on the surface of the grout. Mixing is restarted to incorporate the Millifoam into the slurry (speed ranging from 17 to 25 rpm for about 2 minutes). The cement grouts are obtained and are ready to be foamed. Table 1 below shows the chemical compositions of the various cement slurries produced according to the invention.

Table 1: Grout formulations 1 2 3 4 5 6 Millifoam H 1.45 2.2 1.42 1.49 1.42 1.41 Pure CaCl2 0.8 0.1 0.78 0.83 0.78 0 , 79 Cement CEM 152.5 R 40,13 0 26,63 41,61 26,64 39,29 Sulfoaluminous cement 0 69,7 0 0 0 0 CaCO3 39,74 0 27,3 0 40,85 0 Chrysolab 0, 16 0 0.13 0.16 0.13 0.16 Water 17.72 26.8 19.64 19.54 19.38 18.45 Delaying (citric acid) 0 1.3 0 0 0 0 Pozzolans 0 0 0 0 10.8 0 Fly ash Superpozz 0 0 24.1 36.37 0 0 Fly ash Willcounty 0 0 0 0 0 39.9% by mass in relation to the total mass of the formulation

Figure 1 expresses the relationship between viscosity and shear rate for different cement slurries. It can be observed that the presence of a plasticizer (Chrysolab) does not contribute alone to a significant reduction of the viscosity. It is also observed that the use of low dose calcium chloride does not provide significant advantages in terms of fluidity and even that the use of high doses leads to an increase in viscosity. It can also be observed that Millifoam alone contributes to reducing the viscosity. The combination of Millifoam with calcium salt has a combined effect where the viscosity is greatly reduced.

Realization of lightweight concrete according to the invention

The realization of light concrete according to the invention is continuous. The cement slurry, obtained previously, is poured into a buffer tank kept under stirring using a Rayneri Turbotest mixer (MEXP-101) comprising a pale deflocculator (the speed of the blade varies from 1000 rpm to 400 rpm). revolutions / minutes depending on the volume of grout). The grout is pumped using a Moineau type volumetric pump (SeepexTM MEXP-413 eccentric screw pump) at a flow rate of approximately 1 L / minute. The grout is introduced into a MondomixTM MALX-160 type hob, to which compressed air is added at a rate of 2.75 L / minute. The flow rate will be adapted to the desired foam density at the end of the whipper, generally from 1 to 4 L / minute. The rotational speed of the overrun is 400 rpm, however, the rotational speed will be adapted to the desired foam density at the end of the overrun and may range from 250 to 1500 rpm. At the end of the whipper, a helical static mixer is present (IsojetTM mixer). A foam is thus obtained, it is a lightweight concrete according to the invention.

Realization of lightweight concrete blocks according to the invention

Size block 10 × 10 × 10 cm (volume 1 L): The foams, obtained previously, are cast in polystyrene molds of size 10 × 10 × 10 cm at room temperature (20 ° to 23 ° C.). They are left waiting for 12 to 24 hours, the blocks being covered by a plastic film. Then they are unmolded. Blocks are thus obtained. Block Size 25 X 33 X 50 cm (volume 41.25 L): Foams, obtained previously, are cast in wooden molds of size 25 X 33 x 50 cm at room temperature (20-23 ° C). They are left waiting for 12 to 24 hours, the blocks being covered by a plastic film. Then they are unmolded. Blocks are thus obtained.

Mechanical resistance The mechanical resistance was tested at 7 days and 28 days after completion of the blocks. The blocks are kept in an oven at 45 ° C and 10% relative humidity for 24 hours before the test. Then they are crushed by a ZwickTM press (PRES-018) at a pressure of 1000 Newtons / second until the block breaks. Table 2 below shows the maximum breaking forces for the blocks made from formulation 1. Table 2: Maximum breaking force Maximum breaking strength of the block at 7 days block at 28 days Formulation 1 at a density 2 , 8 MPa (28 000 2.8 MPa (ie 28 000 Newtons / 0.5 Newtons / 0.01 m2) 0.01 m2) Formulation 1 at a density of 1.7 MPa (17 000 1.7 MPa) (ie 17,000 Newtons / 0.43 Newtons / 0.01 m2) 0.01 m2) thermal conductivity

The thermal conductivity of the blocks was measured using a CT meter (AMPG-218). A measuring cell is arranged, clamped, between two flat faces of a block. The cell has a heat source and a thermocouple separated by an insulating element. The heat is transmitted from the source to the thermocouple by the material surrounding the cell. The temperature rise at the thermocouple and the energy transmitted by the heat source as a function of time make it possible to calculate the thermal conductivity of the material surrounding the measuring cell. Table 3 below shows the thermal conductivities for the blocks made from formulation 1 at different densities.

Table 3: Thermal Conductivity of Block in W.m. K, Formulation 1 at a Density of 0.5 0.225 Formulation 1 at a Density of 0.44 0.207 Formulation 1 at a Density of 0.38 0.177 14

Claims (13)

CLAIMS 1-A hydraulic binder admixture comprising at least - alkylsulfonate, alkylethersulfonate, hydroxyalkylethersulfonate, alphaolefinesulfonate, alkylbenzenesulfonate, alkylsulfate, alkylethersulfate, hydroxyalkylethersulfate, alphaolefin sulfate, and / or alkylbenzenesulfate; and a calcium salt soluble in water. 2. Adjuvant according to claim 1, characterized in that it comprises a linear or branched carbon chain alkyl sulphate or alkyl ether sulphate of formula C n H 2n +, - (OCH 2 CH 2) m -SO 3 M wherein n is between 8 and 14 and m is between 0 and 9, M being an alkaline or alkaline earth cation. 3. Adjuvant according to claim 1 characterized in that it comprises a linear or branched alkyl ether sulfate of formula CnH2n +, - (OCH2CH2) m-OSO3M wherein n is between 9 and 11 and m is between 1 and 6. 4. Adjuvant according to claim 1 characterized in that it comprises a mixture of alkyl ether sulfate and alkyl sulphate. 5. Adjuvant according to claim 1 characterized in that the calcium salt soluble in water is selected from calcium chloride, calcium nitrite and calcium nitrate. 6- hydraulic binder characterized in that it comprises the adjuvant according to one of claims 1 to 5. 7- hydraulic binder characterized in that it comprises in percentage by weight relative to the mass of cement - from 20 to 99.98% of Portland cement and / or aluminous cement and / or magnesium cement and / or sulfoaluminous cement; from 0 to 80% of mineral particles of sizes ranging from 0.1 μm to 300 μm; from 0.01 to 5% of an alkyl sulphonate, an alkyl ether sulphonate, a hydroxy alkyl ether sulphonate, an alpha olefin sulphonate, an alkyl benzene sulphonate, an alkyl sulphate, an alkyl ether sulphate, a hydroxy alkyl ether sulphate, an alphaolefin sulphate, and / or an alkylbenzene sulphate - from 0.01 to 5% of a water-soluble calcium salt. 8- Hydraulic composition, characterized in that it comprises at least one hydraulic binder according to one of claims 6 or 7. 9- Lightweight concrete comprising the composition of claim 8. 10- A method of manufacturing a hydraulic composition according to claim 8 characterized in that it comprises a step of placing in contact between at least one adjuvant according to one of claims 1 to 5, water and a hydraulic binder . 11- A method of manufacturing a lightweight concrete according to claim 9 characterized in that it comprises a step of introducing gas into the hydraulic composition according to claim 8. 12- Element for the field of construction, characterized in that it is carried out using a hydraulic binder according to any one of claims 6 or 7 or a hydraulic composition according to claim 8 or a lightweight concrete according to claim 9. 13- Use of a hydraulic binder according to any one of claims 6 to 7 or a hydraulic composition according to claim 8 or a lightweight concrete according to claim 9 for the manufacture of elements for the field of construction .