The present invention relates to an aqueous specific polymer dispersion, to a polymer dispersion comprising the said dispersion as a mixture with at least one alkyd dispersion and to their uses in coating or treatment compositions.
EP 1 304 343 B1 describes an aqueous polymer dispersion comprising from 10 to 70% by weight of a first polymer with a Tg of between −30° C. and 100° C. and from 30 to 90% by weight of a second polymer with a Tg of between −10° C. and 18° C. According to this document, the dispersions described simultaneously have good film formation at low temperature and a degree of hardness. The monomer composition of the first polymer comprises a multiethylenic monomer and that of the second polymer comprises a “crosslinking” monomer chosen from those carrying acetoacetoxy groups and cyanoacetoxy groups. This document relates to the improvement in the resistance to soiling of paints by rendering the particle a little harder by virtue of inclusions of polymer with a high Tg in the soft polymer. However, improvement in the resistance to blocking of the paint remains fairly low, in particular in the cases exemplified, where the Tg of the hard part is low, remaining less than 13° C.
WO 2005/049184A2 describes an aqueous polymer dispersion obtained by a multistage process. The first stage corresponds to the synthesis of a polymer having a Tg of greater than or equal to 50° C., which polymer comprises, in its monomer composition, a monomer comprising a weak acid group, a monomer comprising a strong acid group and a monomer comprising a ketone group. The second stage corresponds to the synthesis of a polymer having a Tg of between −30° C. and 10° C., which polymer comprises, in its monomer composition, a monomer comprising a weak acid group, a monomer comprising a strong acid group and a monomer comprising a ketone group. According to this description, these dispersions have an MFT of less than 30° C., good film formation, good resistance to high temperature, a high gloss and a good resistance to water and to chemicals. The fact that these two polymer compositions comprise high levels of hydrophilic monomers, such as carboxylic acids, phosphates and diacetone acrylamide, and the fact that they are in addition polymerized at high pH, is a disadvantage with respect to controlling the structure of the particles and the operational performances. This is because this type of composition and this type of process do not make possible a clear distinction from the hydrophilicity of the hard part with respect to that of the soft part, thus resulting in a random structure of the polymer particles. The risk of this type of particle morphology is that of resulting in heterogeneous and uncontrolled film formation and thus in certain failings, such as poor reproducibility of the elongation properties of the paint film or a fairly high roughness of the varnish film.
There is thus a need, with respect to this state of the art, for novel dispersions which easily form films without a coalescence agent, resulting in the achievement of homogeneous films with an MFFT obtained which is well managed and representative of the specific structure of the hard core/soft shell polymer particle, dispersions which are also stable, both during the polymerization and during prolonged storage before use, no change over more than 3 months of storage at 50° C., with good reproducibility of the characteristics. Furthermore, these novel dispersions are self-crosslinkable and behave as single-component crosslinkable compositions, type 1K, during film formation and the departure of the water, giving transparent (homogeneous) films free from failings in terms of structure and of performance and thus making it possible to obtain coatings having a high gloss, good chemical resistance, good wet adhesion, good flexibility and also excellent resistance to blocking (good even at higher temperature), and a high hardness. More particularly still, there is a need for aqueous polymer dispersions having good compatibility with specific polymers and more particularly with alkyds. These specific dispersions, as a mixture with alkyd dispersions, thus make possible the additional improvement in the gloss, in the resistance to water, in the hardness and in the rate of drying with the achievement of a satisfactory resistance to blocking very rapidly after film formation.
More particularly, the objective of the invention is the achievement, by a specific process, of a dispersion having particles structured as a hard core/soft shell with such a structure being well managed and reproducible in terms of structure and performance, which means that the hard and soft phases are organized according to a perfectly reproducible core and shell geometry. This structure, because it is truly obtained, makes it possible to have structured particles which form perfect films, even with very little coalescence agent, by virtue of the soft shell which completely covers the hard core. The excellent film formation (reproducible and homogeneous) thus makes it possible to obtain specific properties of gloss, chemical resistance, adhesion and flexibility. Furthermore, the managed structure of the hard core reproducibly provides the properties of hardness and of resistance to blocking. This perfectly managed structure thus results in a compromise in properties at a level entirely exceptional and unmatched to date because the core and the shell of the particle are managed by the control of the specific compositions and of a specific process used. Given that the objective was to control the hard core/soft shell structure, the process which has been chosen is a direct process, with the core of the particle being obtained before the shell, in the order of addition of the corresponding compositions, thus making it possible to obtain the structure by virtue of the synthesis and the kinetics and not by virtue of a thermodynamic equilibrium (reverse diffusion of one phase into the other by chemical affinity). In the latter case, often chosen for reasons of simplicity, the final structure is based on a thermodynamic equilibrium and the kinetics for obtaining the equilibrium and the nature of the equilibrium are difficult to manage and to reproduce. In such a case, this results in latexes having properties which vary, in particular the film formation and thus all the other properties mentioned beforehand and which are directly related to the film formation. Consequently, a very simple way of confirming that the particle is well managed with regard to targeted and stable structure is to measure the minimum film-formation temperature. Thus, in the case of the present invention, due to the excellent management of the structure, the MFFT is predictable, reproducible and stable. The dispersion as defined according to the present invention thus makes it possible to first satisfy these general requirements and subsequently, some more specific forms of the invention, additionally satisfy more particular technical requirements more specifically targeted by these preferred forms of the invention.
Thus, the first subject matter of the present invention relates to an aqueous polymer dispersion, structured as regards the structure of the particles formed of polymer as a core/shell structure, with said core being hard and said shell being soft, with a specific composition and specific characteristics for each polymer corresponding to the core P1 and to the shell P2. A specific process for the preparation of said aqueous dispersion also comes within the subject matters of the present invention.
A second subject matter of the more specific aqueous dispersion of the present invention is an aqueous polymer dispersion which comprises at least one dispersion as defined in the first subject matter of the present invention and, in addition, at least one second nonstructured polymer dispersion, said polymer being selected from several reactive or unreactive polymers and more particularly from polyesters, more particularly unsaturated polyesters, and more preferably still alkyds, polyamides or polyurethanes.
Another subject matter of the invention relates to a coating or treatment composition comprising at least one dispersion of the invention as defined according to the first or the second subject matter defined above. It relates in particular to protective and/or decorative coating compositions from paints, varnishes, transparent coatings, inks or adhesives and treatment compositions for fibers.
Another subject matter of the invention relates to the use of dispersions defined according to the present invention in coatings, more particularly protective and/or decorative coatings, or the treatment of fibers.
The final subject matter of the invention relate respectively to a substrate coated starting from a coating composition according to the invention and a fiber treated with a treatment composition, the two compositions respectively comprising at least one dispersion as defined according to the invention.
Thus, the first subject matter of the present invention is an aqueous polymer dispersion comprising particles structured as a hard/soft core/shell, with the following specific characteristics:
Preferably, said phase P2 also comprises at least one transfer agent selected from hydrophilic mercaptans or mercaptans carrying an ionic group.
In fact, said acetoxy, diacetone, methylol or alkoxysilane groups of said monomers M3 provide said dispersion of the invention with a character of self-crosslinkable dispersion behaving as a 1K system (single-component self-crosslinkable system), in post-polymerization, during the stage of film formation-drying, the self-crosslinking being promoted by the departure of the water and of the neutralizing agent during said drying in the course of film formation.
More particularly, said polymer phase P1 is composed of a seed polymer phase P0 and of a complementary polymer phase P′1, meaning complementary to P0 to give P1, with the composition of said phase P0 being devoid of said monomers M1 and M2 and, with regard to the remainder (apart from M1 and M2), it being possible for the compositions of P0 and P′1 to be identical or different.
Preferably, said phase P2 comprises at least one second transfer agent selected from hydrophobic mercaptans, with the ratio by weight of hydrophilic agent to hydrophobic agent being greater than 1 and preferably greater than 1.5. The overall content by weight of said first and second transfer agents represents from 0.02 to 2% and preferably from 0.05 to 1.5%, with respect to the total weight of monomers of said dispersion (total weight of the phases P1+P2). With respect to P2, this % by weight varies from 0.02 to 5% and preferably from 0.05 to 4%.
More preferably, when the content by weight of P1 exceeds 35%, preferably 30%, said Tg1 in this case remains below 75° C.
Said Tg1 and Tg2 terms, as defined in the present invention, are determined by calculation according to Fox relationship and, in this calculation, the potential presence is taken into account of plasticizer or of any compound, including residual monomers, which can play such a role and can thus affect the Tg of the polymer.
The difference between said Tg1 and Tg2 values thus calculated preferably varies from 20 to 140° C. and preferably from 30 to 115° C.
The monomer M1 of the phase P1 can be chosen from monofunctional or polyfunctional allyl ester monomers derived from α,β-unsaturated carboxylic or dicarboxylic acids (such as allyl(meth)acrylate, monoallyl or diallyl maleate or monoallyl or diallyl tetrahydrophthalate) or polyfunctional allyl esters of saturated di- or polycarboxylic acids (such as diallyl phthalate or triallyl trimellitate) or other polyallyl monomers (such as triallyl cyanurate), polyfunctional (meth)acrylic esters with a functionality of at least 2, such as polyalkylene glycol di(meth)acrylates (such as ethylene glycol di(meth)acrylate, tripropylene glycol di(meth)acrylate or diethylene glycol di(meth)acrylate), alkylene diol or polyol di(meth)acrylates, preferably with alkylene ranging from C2 to C8 (such as 1,6-hexanediol di(meth)acrylate, 1,3-butylene glycol di(meth)acrylate, 1,4-butanediol di(meth)acrylate, neopentyl glycol di(meth)acrylate or trimethylolpropane tri(meth)acrylate), and polyvinylbenzenes (such as divinylbenzenes, divinyltoluenes, divinylnaphthalenes or trivinylbenzene). Those preferred are allyl(meth)acrylates, butanediol di(meth)acrylates or hexanediol di(meth)acrylate.
The monomer M2 of the phase P1 can be chosen from (meth)acrylic, fumaric, maleic, itaconic, vinylbenzoic, crotonic or isocrotonic acids and/or their anhydrides and preferably methacrylic acid (MAA) and/or acrylic acid (AA). AA and MAA are the most preferred.
More particularly, said monomers M1 and M2 of the phase P1 represent an overall content by weight ranging from 0.5 to 10% and preferably from 1 to 8% of the total weight of the phase P1, with said monomer M2 representing from 0.1 to 5% by weight and preferably from 0.2 to 4% by weight of said phase P1.
In the dispersion according to the invention, the phase P2 also, like P1, comprises at least one monomer M2 as defined above, with respective contents of M2 in the phases P1 and P2 such that the ratio of the content of M2 in P1 to that in P2 varies from 1/1 to 1/10 and preferably from 1/2 to 1/8.
Said monomer M3 can be present in said phase P2 at a content by weight ranging from 1 to 25% and preferably from 1 to 15%, expressed with respect to the total weight of P1+P2, more particularly with a %, expressed with respect to P2, ranging from 1 to 60% and preferably from 1.5 to 40%.
According to a more preferred form of the present invention, said monomer M3 carries a diacetone group and said dispersion additionally comprises in the dispersed form, adipic acid dihydrazide, which is added to the dispersion at the end of the polymerization of P1 and P2, before or after the addition of the neutralizing agent.
According to a more preferred form of the present invention, said monomer M3 carries an acetoacetoxy group, which is quantitatively converted into the enamine group masked form, this being done at the end of the polymerization of P1 and P2.
According to a more preferred form of the present invention, said monomer M3 carries an acetoacetoxy group, which is quantitatively converted into the enamine group masked form, this being done in situ during the polymerization corresponding to (the production of) the phase P2, said phase P2 being, in such a case, devoid of any monomer M2 as defined above.
According to a yet more specific form, said phase P1 can also comprise (in addition to P2) at least one monomer M3 carrying an acetoacetoxy group. More particularly still in this case, said acetoacetoxy group of the phase P1 can be quantitatively converted into the enamine masked form, this taking place during the polymerization corresponding to (the production of) the phase P2. In fact, the conversion to enamine in the phase P1 is obtained in this case after the polymerization corresponding to the production of the phase P1.
In the dispersion of the invention, said phase P2 can comprise, in addition to the monomers M2 and/or M3, at least one other (that is to say different) monomer M4 carrying, in addition to the polymerizable ethylenic unsaturation, at least one functional group selected from: hydroxyl, such as carried by hydroxyalkyl (meth)acrylates with alkyl from C2 to C4 (such as HEMA or HPMA), amine, such as carried by aminoalkyl(meth)acrylates or aminoalkyl(meth)acrylamides, for example DAMEMA (dimethylaminoethyl methacrylate) or TBAEMA (t-butylaminoethyl methacrylate), oxirane, such as carried by glycidyl(meth)acrylate (such as GLYMA), phosphates, phosphonates or phosphinates, such as carried by phosphates or phosphonates or phosphinates of hydroxylalkyl(meth)acrylates and ethoxylated and/or propoxylated hydroxyalkyl(meth)acrylates, amide, such as (meth)acrylamide, sulfate and sulfonate, such as carried by (meth)acrylates of hydroxyalkylsulfonates (such as the methacrylate of hydroxyethylsulfonate) or (meth)acrylamides of hydroxyalkylsulfonates (such as acrylamidopropanesulfonic acid) and their salts, imide, such as maleimide, aziridine, such as carried by the methacrylate of 1-(2-hydroxyethyl)aziridine, oxazoline or imidazole, such as carried by 2-(2-oxoimidazolidin-1-yl)ethyl methacrylate, provided that the choice of the monomers M4 is made so as to avoid a reaction or an ionic interaction during the synthesis which would render the latter impossible between the various groups of the monomers M4 or between the groups of the monomers M4 and the groups of the other monomers.
Said phase P2 can comprise, in addition to these monomers (M2 and/or M3 and/or M4), at least one other (that is to say different) monomer M5 selected from at least one oil (glycerol esters) of unsaturated C10 to C36 fatty acids (including dimers) and/or at least one methyl ester corresponding to these fatty acids, preferably at least one linseed oil and/or at least one methyl ester of linoleic acid and/or linolenic acid.
According to a preferred form of the invention, said phase P2 of the dispersion of the present invention comprises both the monomer M3 and the monomer M5 as defined above.
As regards the monomer structure (or monomer composition) of the phases P1 and P2, they can either be based on purely acrylic monomers and thus on a pure acrylic structure (“acrylic” here meaning both acrylic and/or methacrylic) or else based on a mixed structure which can comprise, in one of the two phases (P1 or P2) or in both phases, vinylaromatic monomers, more particularly styrene and/or its derivatives, such as vinyltoluenes or else vinylbenzene, or/and preferably styrene and/or vinyltoluenes. More particularly, P1 and/or P2 can comprise such vinylaromatic monomers. According to another alternative form, the phase P1 alone is purely acrylic and, according to another alternative form, the phase P2 alone is purely acrylic and, according to a third alternative form, the two phases P1 and P2 are purely acrylic and thus consequently said dispersion is also purely acrylic.
According to another alternative form of the dispersion of the present invention, the phase P2 comprises vinylaromatic monomers and the phase P1 is purely acrylic and, according to another alternative form, the phase P2 is purely acrylic and the phase P1 comprises vinylaromatic monomers as defined above. The most preferred alternative forms of the dispersion of the invention correspond to: a phase P2 comprising vinylaromatic monomers with a phase P2 being purely acrylic, the dispersion being, in this case, of styrene/acrylic type, and a dispersion which (P1 and P2) is purely acrylic.
Said phase P1 can comprise and preferably comprises a seed phase P0, devoid of monomers M1 and M2 as defined above, with said phase P0 representing from 2 to 25% by weight and preferably from 5 to 20% by weight of the weight of said phase P1. More particularly, the phase P1 is obtained before said phase P2, which phase P2 is obtained by polymerization of the monomers corresponding to this polymer phase, at a temperature below or equal to and preferably below Tg1 as defined above. More preferably still, the temperature (for the polymerization of P2) is at least 5 degrees below Tg1.
The dispersion of the invention as described above can be obtained by emulsion polymerization, comprising (that is to say in the presence of) a seed P0, and with the following specific additional characteristics:
The unspecified anionic surfactant can be chosen from sulfates or sulfonates or phosphates or phosphonates of C9 to C14 fatty alcohols which are optionally alkoxylated with, as alkoxy units, ethoxy and/or propoxy, ethoxy being the more preferred alkoxy unit, and with a preferred number of alkoxy units ranging from 2 to 30 and preferably from 2 to 10, said anionic surfactant preferably being selected from dodecylbenzenesulfonate, sodium lauryl sulfate, ethoxylated sodium lauryl sulfate, ethoxylated sodium isotridecyl sulfate, ethoxylated ammonium lauryl phosphate or sulfosuccinate.
The choice may be made, as nonionic surfactant, from alkoxylated fatty alcohols, preferably alkoxylated C12 to C16 fatty alcohols, with the preferred alkoxy units being ethoxy and/or propoxy units and more preferably ethoxy units, the number of said alkoxy units preferably being from 3 to 50 and more preferably from 5 to 40 ethoxy units.
More specifically, the process for the preparation of a dispersion as defined according to the invention comprises at least the three following stages:
The initiators of the seeding stage (i) represent a content by weight of from 0.1 to 4% of the total weight of P1+P2.
As regards the temperature ranges used in this process:
According to a preferred form of the process, stage ii) of emulsion polymerization of the monomer composition P′1 (and preferably P1) is continued up to a degree of conversion of at least 95%, before addition of the monomer composition P2.
The second subject matter of more specific aqueous dispersion according to the invention is an aqueous polymer dispersion which comprises, in addition to a (at least one) first aqueous polymer dispersion as defined above, at least one other second aqueous polymer dispersion (or dispersion of water-dispersible resins), preferably based on saturated and/or unsaturated polyester resins and more particularly on alkyd resins, more particularly still modified alkyd resins, such as acrylic-modified alkyd resins, or alkyd resins modified by styrene or by urethane or by oxidizing treatment, or based on acrylic copolymers, or based on acrylated acrylic oligomers, or based on polyurethanes, or based on hydrocarbon resins, such as aliphatic C5 or aromatic C9 or mixed C5/C9 hydrocarbon resins. More preferably, said dispersion according to the invention comprises, in addition to a (at least one) aqueous dispersion as defined according to the first subject matter of the invention defined above, at least one other (second) polymer dispersion which is based on at least one alkyd resin as defined above (modified or unmodified and, in the case where it is modified: acrylic-, styrene-, urethane- or amide-modified or modified by oxidizing treatment). According to the latter preferred case, said aqueous dispersion comprises an alkyd dispersion (or dispersion of alkyd resin) with a content by weight of said alkyd resin representing from 15 to 45% by weight of the total weight of the alkyd and of the other polymer of the dispersion as defined according to the first subject matter of the invention above (said other polymer of the dispersion corresponding to P1+P2). This content varies in a range extending from 15 to 85%, with respect to the total weight of the P1+P2 monomers.
According to a more preferred form, said aqueous dispersion, as defined above as second subject matter of specific dispersion of the invention, comprises, as polymer dispersion (defined as first subject matter of the invention), at least one aqueous dispersion comprising at least one monomer M5 chosen from at least one oil (glycerol ester) of at least one unsaturated C10 to C36 fatty acid and/or at least one methyl ester corresponding to these fatty acids and more preferably at least one linseed oil and/or one methyl ester of linoleic acid and/or linolenic acid. The modification by such a monomer M5 of the polymer dispersion defined as first subject matter of the invention contributes to substantially improving the chemical resistance, the resistance to blocking and the compatibility and adhesion of the film of said dispersion with an alkyd coating, applied either after or before said film to the same substrate to be protected and/or decorated.
Said dispersion, as defined as second subject matter of more specific dispersion of the invention, has the advantage of being able to be prepared by simple mixing of at least one other aqueous polymer dispersion or aqueous resin dispersion as already defined above and preferably by simple mixing of at least one aqueous alkyd dispersion with at least one aqueous dispersion as defined as first subject matter of the present invention.
Another subject matter of the invention relates to a coating composition or a treatment composition which comprises at least one aqueous dispersion as already defined above according to the second subject matter of the invention.
According to a first possibility, said coating composition is a protective and/or decorative coating composition and it is preferably selected from paints, varnishes, transparent coatings, inks or adhesives.
Preferably, the treatment composition is a composition for the treatment of fibers, which can be natural or synthetic and organic or inorganic and can be in the form of isolated fibers or in the form of a mat or of woven or nonwoven fabrics. Mention may be made, as examples of fibers, of fibers of glass, carbon, textile or aramid, such as Kevlar®.
Another subject matter of the invention relates to the use of an aqueous dispersion as defined according to the first subject matter or as defined according to the second subject matter of the present invention, which subject matters are defined above and below, in protective and/or decorative coatings or in the treatment of fibers.
The use of said dispersions according to the invention in the coatings more particularly relates to the protection and/or decoration of substrates, preferably selected from wood, board, metal, plastic, plaster, concrete, fiber-reinforced cement or glass.
Said use in the treatment of glass fibers and textile fibers can be carried out with said fibers in the form of woven or nonwoven fibers.
Another subject matter of the invention relates to a coating obtained by the use of at least one dispersion as defined according to the first or the second subject matter of dispersion of the present invention or by the use of a coating composition as defined above according to the present invention.
Finally, first a substrate coated with at least one layer of at least one coating composition as defined above according to the invention and subsequently a fiber treated with at least one treatment composition as defined above according to the present invention also come within the invention.
The examples below in the experimental part, without in any way limiting the scope of the invention, are presented in order to give a better illustration of the present invention, its performance and technical advantages.
The procedure described below describes the synthesis of the dispersion according to example 1. It remains the same for the other dispersions of the other examples described in this patent apart from the modifications indicated for compositions or other parameters. Specifically:
The amounts of monomers M1 and M2 in P1 and those of M2 and M3 in P2 remain unchanged with respect to the combined P1+P2 monomers (with regard to 100 p of P1+P2 monomers), in all the examples.
Subsequently, the Tg values of the core (Tg1) and of the shell (Tg2) are adjusted by varying the ratio by weight of methyl methacrylate and butyl acrylate present in each of the phases P1 and P2 according to Fox law and so as to obtain, with the other monomers present, the percentage by total weight of each of the phases P1 and P2, their sum coming to 100.
A 3 1 (internal capacity) glass reactor provided with a jacket and equipped with efficient stirring (vortex), with a three-flow reflux condenser and with control and regulation of the material temperature. The reactor comprises the number of inlets necessary for the separate introduction of the various components and also an inlet dedicated to rendering the assembly inert with nitrogen. Leaktightness is confirmed before each synthesis. The apparatus is equipped with a system which makes it possible to control the flow rates for the introduction of the components.
12 g of Disponil FES 32 are dissolved in 1016 g of demineralized water as vessel heel. The temperature of the vessel heel is brought to 85° C.
19.5 g of MMA and 19.5 g of BuA are mixed.
12 g of Aerosol A102 and 24 g of Disponil FES 32 are dispersed in 95 g of demineralized water with good stirring.
The following are added in turn and with good stirring:
The preemulsion thus formed is white and stable and it will be kept gently stirred.
It will be used for the synthesis of the core of the particle, P1, composed of P0 and P′1 (P1=P0+P′1).
12 g of Aerosol A102 and 6 g of Tergitol 15S9 are dispersed in 171.7 g of water with good stirring.
The following are added in turn and with stirring:
A white and stable preemulsion is obtained.
10% of this preemulsion, i.e. 91.6 g, will be withdrawn and used to carry out a seeding before running in P2.
The following are then added to the preemulsion, still with good stirring:
This white and stable preemulsion, P2, will be used for the synthesis of the shell of the particle.
4.2 g of sodium persulfate are dissolved in 80 g of water.
1:2 g of sodium metabisulfite are dissolved in 10.8 g of water.
1 g of TBHP (70%) is dissolved in 4.5 g of water.
0.5 g of SFS is dissolved in 11.5 g of water.
The vessel heel with the initial charge, being stable in temperature at 85° C., are then introduced for the P0 seeding, the mixture of 19.5 g of MMA and 19.5 g of BuA. Once the temperature has stabilized, 70% of the sodium persulfate solution are added. The exothermicity maximum marks the end of this stage, the particle size is approximately 30 nm and the conversion is greater than 70%.
The introduction of the preemulsion P′1 lasts 90 minutes, at a polymerization temperature of 85° C.
iii) Stage of Thermal Curing and Cooling
The temperature is maintained at 85° C. for 60 minutes. At the end of the thermal curing, the reaction medium is cooled to 65° C. The conversion is then approximately 100%.
The seed composed of 91.6 g of the P2 fraction is introduced into the reactor at 65° C. Mixing is carried out for at least 5 min.
Beginning of the separate introductions:
While the materials are being run in, which lasts 150 minutes, the temperature of the medium is maintained at 65° C. This stage is followed by a postcuring at 65° C. lasting 30 minutes.
The TBHP and SFS solutions are added at 65° C. over 30 minutes. This redox treatment is followed by a curing at 65° C. for 30 minutes before cooling to ambient temperature.
The latex is neutralized at 30-35° C. by addition of sodium hydroxide solution to pH 8 and a biocide is subsequently added. The latex is subsequently filtered through a 100 μm cloth. The solids content is 41.5%.
The final particle size is approximately 90 nm, the viscosity is less than 100 mPa·s and the measured MFFT is 5° C.
The list of the various aqueous dispersions prepared on the basis of this procedure is presented in table 2 below, with the parameters which vary from one test to another being indicated.
In example 7, the amount of Radia 7061 introduced during the synthesis of the shell (P2) is 2%, with respect to the P1+P2 total weight.
The Tg values of the phases are calculated according to the Fox law from the Tg values of the homopolymers indicated as below:
The solids content of the aqueous dispersions is measured according to the ISO standard 3251.
b) pH
The pH of the aqueous dispersions is measured according to the ISO standard 976.
The viscosity of the aqueous dispersions is measured according to the ISO standard 2555.
The size of the particles is measured by Photon Correlation Spectroscopy (PCS) using an N4+ device from Beckman Coulter. The sample is diluted (3 to 5 drops of emulsion in 50 ml of water) in a polystyrene cell using deionized water through a 0.22 μm cellulose acetate filter. The size of the particles is measured at a temperature of 25° C., under a measurement angle of 90° and at a wavelength of the laser of 633 nm.
The MFFT of the aqueous dispersions is measured according to the ISO standard 2115.
It should be noted that the MFFT expected for a particle perfectly structured as a hard/soft core P1/shell P2 is close (plus or minus as a function also of the % of P2) to the Tg2 (see table 9). When the MFFT is close to the mean Tg, this is a sign that the particle is not structured (mixture of the P1 and P2 phases). More particularly, it may be considered, to a first approximation, that, for a perfectly structured particle having a % P2 exceeding 60%, said MFFT (expected) tends to be coincident with the Tg2 to within the accuracy of measurement of the MFFT (+−2° C.) and of the Tg2 (according to Fox). For a % P2 up to 60%, the expected MFFT varies according to the information presented in table 9.
Tensile Strength:
The tests of tensile strength were carried out on an MTS 1MH tensile testing device, at a temperature of 23° C. and at 50% relative humidity (RH) and with a 50N cell.
The rate of the test is 5 mm/min.
The performances of the aqueous dispersions described in table 2 are evaluated on films applied from gloss paint formulations as described in tables 4 and 5.
Manufacture of the Mill Base:
The water and the various constituents are successively introduced with stirring into a receptacle, at high speed in a Disperlux model 2075 disperser, to a fineness <10 μm.
Manufacture of the Paint:
The binder or binders (or the fast-drying alkyd emulsion and/or the aqueous dispersion), the mill base prepared above, the water and the various constituents are successively introduced with stirring into a receptacle.
Pigment volume concentration: PVC=19%
Solids content by weight=52.3%
Solids content by volume=40%
Density: d=1.26
Pigment volume concentration: PVC=19%
Solids content by weight=54.1%
Solids content by volume=41%
Density: d=1.28
a) Viscosity
b) pH
c) Gloss
d) Hardness
e) Resistance to Blocking
The damage caused on the paint films is then quantified on a scale varying from 0 to 8 according to the instructions given in table 6 below:
f) Resistance to Water
Drops of water are subsequently deposited for a predetermined time (15 minutes and 30 minutes) at the surface of the paint films and the damage caused is evaluated, before drying and after drying for 24 hours, on a scale varying from 0 to 4 according to the instructions given in table 7 below:
g) Resistance to Staining
The resistance to household stains is tested on the paints applied at 200 μm wet to Leneta P121-10N PVC sheets after drying for a week. The stains are in contact with the test paint for 15 min, according to the model below. Grading is carried out according to the standard NF EN 12720 after cleaning off the stain using a dilute Teepol solution. This grading takes into account losses in gloss, variations in coloring or modifications to the structure of the paint film tested:
h) Flexibility Test
The surface defects (cracking/blistering) are graded at the end of each cycle on a scale varying from 0 to 10 as indicated in table 8 below:
In order to judge the management of the targeted structure of the particles during the preparation of the dispersions according to the invention, the following significant criteria were used:
The Tg2 values are calculated according to Fox law, as already explained above for the Tg values.
These characteristics are given for each dispersion in table 10 below:
Only the films coming under the invention are transparent (homogeneous and free from defects) and with an experimental MFFT within the expected MFFT range according to the data of table 9. The tests outside the invention result in hazy films and/or films exhibiting a higher MFFT than that expected and closer to the mean Tg according to Fox (of P1 and P2), which would correspond here, in such a case, to an at least partial loss of the structure of the particles obtained. These results are shown in table 11 below:
The monitoring over time of the characteristics, such as viscosity, pH, solids content and particle size, of the dispersion of example 1, placed in an oven at 50° C., has made it possible to demonstrate that all the characteristics of the dispersion obtained according to the invention are completely stable. Remarkably, the MFFT is stable after testing at 50° C. for 15 weeks (see
3) Results with Regard to Acrylic Paint Formulations (Table 12)
The thickness of the paint film and its method of application vary according to the test desired.
For each measurement, reference is made to the corresponding test method in sections A, 4 to 6.
The VOC values (in g/l) are calculated using the “PV6FORMULA, Version 2-3” formulation software as described above.
The viscosity measurements show that the paint formulations exhibit good stability on storage.
4) Results with Regard to Acrylic/Alkyd Paints, Based on Mixtures of the Alkyd Dispersions with the Polymer Dispersions According to Examples 1 and 7
The preparation of the acrylic/alkyd paints is described in section A 5, and more particularly 5.3, table 5.
The VOC values (in g/l) are calculated using the “PV6FORMULA, Version 2-3” formulation software, as described above.
The mechanical properties of the emulsion films and the test of flexibility of the paint film make it possible to evaluate the flexibility and the cohesion of the coating obtained.
Example 1 according to the invention exhibits a high elongation at break and a high breaking stress: these results show that the film obtained from example 1 is flexible and cohesive. These observations are confirmed by the very good results obtained by the flexibility test: the example according to the invention makes it possible to obtain a very stable coating as the freezing/thawing cycles progress.
The results presented in table 15 show a very good compromise in properties in terms of gloss, hardness, resistance to blocking, resistance to water and resistance to stains.
The resistance to blocking of the two tests is excellent after drying for 24 hours and contact at 23° C. for 24 hours. A difference is noted when the test is carried out under more critical conditions, after drying for 48 hours and contact at 50° C. for 1 hour. In the latter case, it is observed that the addition of the methyl ester of linseed oil in example 7 makes it possible to markedly improve the resistance to blocking.
The acrylic dispersions obtained according to the invention exhibit a very good compatibility with the alkyds. The results present in table 16 show that the mixture makes it possible to significantly improve the gloss of the film and the resistance to water, and results in a very good level of hardness after 7 days. Furthermore, the resistance to blocking of the two formulations remains identical and excellent.
Number | Date | Country | Kind |
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09/03667 | Jul 2009 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2010/004315 | 7/15/2010 | WO | 00 | 1/23/2012 |