FR2926219A1 - Solid cosmetic composition, useful for deodorant in a form of stick and for exfoliating stick, comprises soap dissolved in water soluble organic solvent, and external hydrophilic phase in which an internal aqueous phase is dispersed - Google Patents

Abstract

Solid cosmetic composition comprises: a soap dissolved in a water soluble organic solvent such as a primary alcohol; and an external hydrophilic phase in which an internal aqueous phase is dispersed, where the phases are separated from each other by an intermediate lipophilic phase comprising internal aqueous phase and external hydrophilic phase containing the soap dissolved in the organic solvent. An independent claim is included for a process for preparing the solid cosmetic composition, comprising preparing (A) a first phase obtained by mixing a quantity of an aqueous phase and a quantity of a lipophilic phase, preparing (B) a second phase obtained by mixing a quantity of a hydrophilic surfactant and the organic solvent (27-73 wt.%), preparing (C) a phase by mixing a determined quantity of soap and the remainder of the total quantity of organic solvent, mixing (D) of a quantity of first phase (under low agitation) with a quantity of second phase, and mixing (E) of the obtained mixture (under low agitation) and a quantity of third phase to obtain the composition.

Description

The present invention relates to solid cosmetic compositions containing a soap, such as sodium stearate, and being in the form of a bread or stick, also called a stick. More particularly, the invention relates to solid cosmetic compositions in the form of sticks, such as deodorants or skin scrubs containing soap. Such compositions are essentially composed of a soap, such as sodium stearate, an organic solvent, such as a primary alcohol, for example propylene glycol or butylene glycol, and water. The soap allows the gelation of the composition. These solid compositions have the major disadvantage of degrading over time. Indeed, droplets appear on the surface of the compositions thus betraying a phenomenon of exudation which significantly alters the aesthetic appearance of the composition. The applicants were able to define the exudation as the concentration on the surface of the composition of both soap molecules, water and organic solvent. The exudation mechanism can be explained as follows. Over time, the soap molecules lose their affinity for their environment in favor of a greater affinity for the air and thus migrate to the surface of the composition, bringing with them molecules of water and organic solvent. . Droplets, visible and fragile, are then formed on the surface of the composition in which the soap molecules are solubilized in water. Then the water tends to evaporate and the soap molecules are then at the interface between the air and the organic solvent. The droplets become less fragile to the touch. When a certain balance is reached between the amount of soap molecules on the surface and the amount of soap molecules in the composition, the organic solvent returns to the composition. All that remains is the impression of the drops on the surface of the composition. This phenomenon of exudation is observed for all the solid cosmetic compositions comprising a soap, such as sodium stearate, dissolved in an organic solvent. On the other hand, solid cosmetic compositions, such as deodorant breads, or sticks, generally contain one or more fragrances. After application, for example in the armpits, perfumes are in contact with the skin and penetrates inside of it. These perfumes are particularly irritating and can lead to redness and tingling phenomena. The solution 2 commonly provided is the addition of softening compounds for the skin. This solution is however not completely satisfactory. In addition, there is observed over time a change or loss of the smell of perfume. This modification is the consequence of the oxidation of the perfume molecules. An object of the present invention is to provide a solid cosmetic composition containing a soap, such as sodium stearate, dissolved in an organic solvent, such as a primary alcohol, in the form of a bread or a rod, or stick, which is perfectly stable and which does not exhibit any alteration of its aesthetic appearance over time resulting from exudation phenomena. Another object of the present invention is to provide such a solid cosmetic composition which does not cause irritation phenomena related to the presence of perfume in the composition. Another object of the present invention is to provide such a solid cosmetic composition which allows a very good stability of the perfumes contained in the composition. For this purpose, a solid cosmetic composition according to the invention, of the type comprising a soap dissolved in an organic solvent, such as a primary alcohol, is characterized in that it comprises an external hydrophilic phase in which a phase is dispersed. so-called internal aqueous, said phases being separated from each other by a so-called intermediate lipophilic phase which contains said internal aqueous phase, said external hydrophilic phase comprising said soap dissolved in said organic solvent. The internal aqueous phase of the solid composition according to the invention functions as a water reservoir, or alternatively as an osmotic pump system, for supplying water into the external hydrophilic phase in which the soap is located and the latter to have a good affinity for his environment. A spontaneous stream of water exists from the internal aqueous phase of the composition to the outer hydrophilic phase. This flow of water results from a difference in chemical potential existing between the external hydrophilic phase, concentrated in solute, for example sodium stearate, and the internal aqueous phase which is compartmentalized in an intermediate lipophilic phase and which does not contain no solutes. This flow of water is continuous until the value of the osmotic pressure of the external hydrophilic phase reached corresponds to the equilibrium of the chemical potentials between the hydrophilic phase

3 external and the internal aqueous phase. Thus, thanks to the structure of the composition, no exudation phenomenon is observed. To better understand the role of the structure of the composition in the prevention of exudation phenomena, it is necessary to examine the mechanism responsible for exudation, that is, the parameters responsible for the instability of the medium, or system. . The relation between the parameters of the system is given, in a general way, by the following Gibbs-Duhem relation: dG = -SdT + VdP + E; dn; , where S is the entropy of the system, G is the free energy, P is the system pressure, T is the system temperature, V is the system volume, i is the chemical potential of the i species, and n is the number of moles of species i. dG = 0, at equilibrium. In the case of a classical solid composition, the Gibbs-Duhem equation is written: AG = -SAT.

In this case, the variation of free energy AG depends on the entropy S of the system and the temperature variation AT. Thus, these two parameters are responsible for the exudation phenomena. Since exudation is a spontaneous phenomenon, the variation of free energy, AG, is negative. Entropy S is always positive. In this case, the temperature variation must be positive. Thus, it is an increase in temperature that is responsible for the exudation phenomena. In the case of a composition according to the invention, the following relationship is obtained: AG = -SAT + V j- [+ (E;) An; = is, in which is the chemical potential of the species i, n; is the number of moles of the species i, H is the pressure difference between the external hydrophilic phase and the internal aqueous phase of the composition, T is the temperature of the system and V is the volume of the system. The part of the equation (VH + (E;) An;) is provided by the structure of the composition, that is to say in that an internal aqueous phase is dispersed in an intermediate lipophilic phase, - even dispersed in an external hydrophilic phase. As explained above, the chemical potential gradient existing between the external hydrophilic phase and the internal aqueous phase causes a diffusion of water from the internal aqueous phase into the external hydrophilic phase until the equilibrium of the chemical potentials between the two phases is reached. There is therefore no observed exudation phenomena.

According to one embodiment of the invention, the composition comprises between 0.07 and 1.50%, by weight, of internal aqueous phase, between 0.26 and 13.50%, by weight, of intermediate lipophilic phase, between 1.80 and 8.0%, by weight, of a soap, of the organic solvent in a quantity sufficient for 100%, by weight, relative to the total weight of the composition. Preferably, said composition comprises between 65 and 89% by weight of organic solvent. According to one embodiment of the invention, the solid cosmetic composition comprises a multiple emulsion of the H / L / H type in which said internal aqueous phase is in the form of one or more droplets dispersed in said intermediate lipophilic phase itself. even dispersed in said external hydrophilic phase. The term "H / L / H type emulsion" is understood to mean a three-component second-order emulsion comprising an external hydrophilic or continuous phase in which a lipophilic phase containing itself an internal hydrophilic phase is dispersed. According to one characteristic of the invention, the mean diameter of said droplets of internal aqueous phase is between 5 and 20 m, preferably between 5 and 10 m. According to another characteristic of the invention, the number of droplets of internal aqueous phase is between 1.7.105 and 3.7.106 droplets per cm3 of composition. Advantageously, said composition comprises between 0 and 10%, by weight, of at least one hydrophobic surfactant and between 0.5 and 10%, by weight, of at least one hydrophilic surfactant, relative to the total weight of the composition. Since the internal phase of the emulsion is aqueous, the surfactant chosen to stabilize the aqueous phase droplets must be hydrophobic. Conversely, the surfactant chosen to stabilize the lipophilic phase must be hydrophilic. In addition, a composition according to the invention being intended to be in contact with the skin, the selected surfactants should not cause irritation phenomena. Nonionic or polymeric surfactants are thus preferred. Finally, the internal aqueous phase being in the form of droplets, the amount of hydrophobic surfactant must be large enough to ensure the stability of the water droplets and prevent their coalescence. Advantageously, said one or more hydrophobic surfactants are chosen from silicone surfactants, such as dimethicone copolyol, and / or nonionic surfactants, such as polyoxyethylenated fatty alcohol ethers, ethoxylated and propoxylated polymers, or a mixture of such surfactants. nonionic, and in that the hydrophilic surfactant is a mixture of a nonionic surfactant and an ethoxylated and propoxylated polymer. According to another embodiment of the invention, said composition comprises a dispersion of liposomes in said external hydrophilic phase, said internal aqueous phase being contained inside said liposomes. According to this particular embodiment, the membrane of the liposome vesicles is constituted by the intermediate lipophilic phase and the internal aqueous phase of the composition is contained in the liposomes. Thus, the liposome dispersion functions in the same way as the H / L / H type multiple emulsion, that is to say as an aqueous reservoir supplying water in the external hydrophilic phase of the composition to increase the affinity of the soap in its environment as explained above. A solid composition according to the invention may comprise both a multiple emulsion of H / L / H type and dispersion of liposomes. According to this embodiment of the invention, said composition comprises between 0.13 and 5.00%, by weight, relative to the total weight of the composition, of an aqueous solution of lecithin at 15%. The aqueous solution of lecithin allows the formation of liposomes. Advantageously, said organic solvent is propylene glycol or ethylene glycol and said soap is a fatty acid salt such as sodium stearate. According to one embodiment, said composition further comprises at least one dye soluble in the external hydrophilic phase. According to one embodiment of the invention, said composition comprises, in addition, at least one perfume soluble in the intermediate lipophilic phase. The perfumes thus contained in the lipophilic phase are protected against oxidation phenomena. In addition, when the composition is applied to the skin, the perfumes thus contained in the lipophilic phase do not penetrate inside the skin as soon as they are applied to the skin but remain on the surface. According to another embodiment of the invention, said composition further comprises at least one perfume soluble in the external hydrophilic phase. According to one embodiment of the invention, said composition further comprises at least one dye soluble in the external hydrophilic phase.

According to one embodiment of the invention, the composition further comprises between 0.01 and 3.00% by weight of a crosslinked polymer, relative to the total weight of the composition. The crosslinked polymer by its structure contributes to the good distribution of the internal aqueous phase dispersed in the external hydrophilic phase and allows the suspension of various components of the composition to be suspended. For example, the crosslinked polymer may be guar gum, hydroxypropyl guar gum, xanthan gum, a cellulosic polymer, a polysaccharide, a crosslinked acrylic acid polymer. Another object of the present invention is to provide a solid composition comprising a soap dissolved in an organic solvent which comprises a stable suspension of solid particles and which can be cast in a mold, such as a solid rod support, in a range. temperatures sufficiently wide to allow flexibility to the preparer during its manufacturing process. For this purpose, a solid cosmetic composition according to the invention comprises between 0.01 and 3.00% by weight of a crosslinked polymer, relative to the total weight of the composition and comprises, in addition, a suspension of non solid particles. selected from diatomaceous earth, oyster shell powder, Actinidia sinensis seeds, Oriza sativa seeds, grape seeds, polymeric beads or a mixture of 2 to 15 %, by weight, relative to the total weight of the composition and whose average size is between 100 and 10,000 m. Preferably, the average size of said non-water-soluble solid particles is between 300 and 600 m. These non-water-soluble solid particles are chosen for their exfoliating and / or aesthetic properties. The invention also relates to a deodorant in the form of a stick, also called a stick, comprising a solid cosmetic composition as defined above, and an exfoliating stick comprising a solid cosmetic composition as defined above. The invention also relates to a method for preparing a solid composition of the type comprising a soap dissolved in a water-miscible organic solvent, such as a primary alcohol, characterized in that it comprises: a step (A) ) for preparing a first phase (P1) obtained by mixing a determined amount of an aqueous phase and a determined amount of a lipophilic phase,

A step (B) for preparing a second phase (P2) obtained by mixing a determined quantity of at least one hydrophilic surfactant and from 27 to 73%, by weight, of the total amount of said organic solvent and a step (C) for preparing a phase (P3) by mixing a determined amount of a soap and the remainder of the total amount of said organic solvent. Then, a step (D) mixing, with gentle stirring, a determined amount of first phase (P1) with a determined amount of second phase (P2) and, - a mixing step (E), with slight stirring , the mixture obtained in the preceding step and a determined amount of third phase (P3) so as to obtain said composition. The use of three phases, and the order in which the phases are mixed, are essential features of the process according to the invention. According to one embodiment of the invention, said step of preparing a first phase (P1) comprises adding a determined amount of at least one hydrophobic surfactant, with vigorous stirring. According to one embodiment of the invention, said determined quantity of aqueous phase is between 0.07 and 1.50%, said determined quantity of lipophilic phase is between 0.26 and 13.50, said quantity of hydrophobic surfactants. is between 0 and 10%, said amount of hydrophilic surfactants is between 0.5 and 10%, said total amount of organic solvent is between 65.10 and 89.30% by weight and said amount of soap is between 1.80 and 8.00%, by weight, relative to the total weight of the composition. According to one embodiment of the invention, said process additionally comprises adding between 0.13 and 5.00%, by weight relative to the total weight of the composition, of an aqueous lecithin solution. at 15% by weight. The addition of this lecithin solution allows the formation of liposomes. The process for preparing a composition according to the invention comprises the addition of between 0.01 and 3.00% by weight of at least one crosslinked polymer, relative to the total weight of the composition.

According to a particular embodiment of the invention, the process further comprises the addition of between 2 and 15%, by weight, of non-water-soluble solid particles chosen from diatomaceous earth, shell powder and the like. oysters, the seeds of

Actinidia sinensis, Oriza sativa grain, grape seed, polymeric bead or mixture thereof, based on the total weight of the composition. According to one characteristic of the invention, the method according to the invention further comprises a step of casting said composition in a mold at a temperature of between 50 and 90 ° C. The presence of a crosslinked polymer in the composition according to the invention allows the casting of the composition in a temperature range sufficiently wide to allow industrialization of the preparation process. A composition according to the invention may also comprise other elements usually used in cosmetology.

The invention will be better understood on reading the following embodiments of depilatory compositions, which are intended to be illustrative and nonlimiting. Table 1, below, presents the main ingredients used in the manufacture of solid compositions according to a preferred embodiment of the invention. The values presented are expressed in% by weight.

Table 1: Phases% to be introduced Pi Water phase 0.07-1.5 Hydrophobic surfactants 0-10 Lipophilic phase 0.26-13.50 P2 Organic solvent 42-82.80 Hydrophilic surfactants 0.50-10 Colorant 0-0 , 22 Water 0-20,40 P3 Soap 1,80-8,00 Organic solvent QSP 10020 1) Solid compositions in the form of an emulsion of aqueous phase type - in lipophilic phase - in hydrophilic phase (H / L / H):

1.1) Process for producing a solid composition in the form of an H / L / H emulsion: Step A: The P1 phase is prepared by mixing the biosmosed water with the lipophilic phase, under vigorous stirring between 20 ° C and 35 ° C, in a container placed on a magnetic stirrer. A cloudy mixture is obtained. The hydrophobic surfactant is then added to the mixture gradually with gentle stirring until the mixture becomes clear. The P1 phase obtained is an H / L type emulsion (hydrophilic phase in lipophilic phase), that is to say that the aqueous phase is dispersed in the lipophilic phase. Step B: The P2 phase is prepared by dissolving the hydrophilic surfactant in the organic solvent. The mixing is carried out at a temperature between 50 and 80 ° C. Step C: The P3 phase is prepared by dissolving the soap in the organic solvent by homogenization at a temperature between 85 and 90 ° C. Step D: The phase P 1 is then mixed with the phase P2. The mixture is made under slight stirring. The mixture of the phases P1 + P2 makes it possible to obtain an emulsion of the H / L / H type (hydrophilic phase in a lipophilic phase in a hydrophilic phase), that is to say that the aqueous phase is dispersed in the phase lipophilic, itself dispersed in the organic solvent. Step E: The H / L / H emulsion obtained is mixed, with slight stirring, with the phase (P3). In such a composition, the determined amount of first phase (P1) is between 1 and 15%, by weight, said determined amount of second phase (P2) is between 55 and 90% by weight, and said determined amount of third phase (P3) is between 9 and 30%, by weight, relative to the total weight of the composition. The resulting composition is then cast in a plastic mold, or stick carrier, at a temperature between 70 and 75 ° C.

1.2) Example 1: solid deodorant composition in the form of a stick (stick 1) Table 2: Distinct phases of the% to be introduced production method (by weight) P1 Biosmosed water 0.23 Synperonic PE L64 0.58 Perfume 1.50 P2 Propylene glycol 59.67 Synperonic PE F127 0.80 Brij 35 0.20 Sol. Violet DC 2 at 0.1 0.15 Sol. FDC Red 4 at 0.1 0.04 Biosmosed water 13 P3 Sodium stearate 5.5 Propylene glycol Q.S.P. Synperonic PE L64 and Synperonic PE F127 are the trade names of the hydrophobic and hydrophilic ethoxylated and propoxylated polymeric surfactants, respectively, marketed by Quimasso France; Brij 35 is the trade name of a hydrophilic ethoxylated nonionic surfactant marketed by the company Uniquema; floor. Violet DC 2 at 0.1 and the ground. FDC Red 4 to 0.1 are the trade names of two dyes, respectively of violet and red color. The manufacturing process is as described in 1.1. The perfume in the P1 phase is fat soluble. The organic solvent is propylene glycol. The soap is sodium stearate. 1.3) Example 2: deodorant composition in the form of a stick (stick 2) Table 3: 10 distinct phases of the process% to be introduced by manufacture (weight) Pl Sodium chloride 0.02% 0.23 Synperonic PE L64 0.58 Fat-soluble perfume 1.50 5 P2 Propylene glycol 67.67 Synperonic PE F127 0.80 Brij 35 0.20 Sol. Violet DC 2 at 0.1 0.15 Sol. FDC Red 4 at 0.1 0.04 Biosmosed water 5 P3 Sodium stearate 5.5 Propylene glycol Q.S.P. The composition was manufactured according to the preparation method described in 1.1. 1.4) Example 3: deodorant composition in the form of a stick (stick 3) Table 4: Distinct phases of the process% at introduction of manufacture (weight) Pl Biosmosed water 0.23 Synperonic PE L64 0.58 Liposoluble perfume 1.50 P2 Propylene glycol 67.67 Synperonic PE F127 0.80 Brij 35 0.20 Sol. Violet DC 2 at 0.1 0.15 Sol. FDC Red 4 at 0.1 0.04 Biosmosed water 30 P3 Sodium stearate 5.5 Propylene glycol Q.S.P. The composition was manufactured according to the preparation method described previously in 1.1.

1.5) EXAMPLE 4: Exfoliating solid composition in the form of a stick comprising a crosslinked polymer (Stick 41

Table 5 Distinct Phases of% by Manufacturing Process introduce (by weight) Pl Biosmosed water 0.23 Synperonic PE L64 0.58 Perfume 1.50 P2 Propylene glycol 59.67 Synperonic PE F127 0.80 Brij 35 0.20 Sol. Violet DC 2 at 0.1 0.15 Sol. FDC Red 4 at 0.1 0.04 Biosmosed water 13.00 P3 Sodium stearate 5.50 Guar gum 1.20 hydroxypropyl (40% aqueous solution) Propylene glycol Q.S.P. The composition was manufactured according to the preparation method described in 1.1 except for the preparation of the P3 phase. In the preparation of this phase, the hydroxypropyl guar gum is in the form of a premix with biosmosed water before being added to the propylene glycol in which the sodium stearate is dissolved. Diatomaceous Earth particles were simply added to the P3 phase.

1.6) Example 5: Deodorant composition in the form of a stick comprising an H / L / H emulsion and a dispersion of liposomes (stick 5) Table 6 Distinct phases of the% of the manufacturing process introduce (by weight) P 1 biosmosed water , 23 Synperonic PE L64 0.58 Fragrance 1.50 P2 Propylene glycol 63.68 Synperonic PE F127 0.80 Brij 35 0.20 Sol. Violet DC 2 at 0.1 0.15 Sol. FDC Red 4 at 0.1 0.04 Biosmosed water 9 P3 Sodium stearate 5.50 15% aqueous solution of lecithin Propylene glycol Q.S.P. The composition was manufactured according to the preparation method described in 1.1 except for the preparation of the P3 phase. In the preparation of this phase, a 15% aqueous solution of lecithin is mixed with the propylene glycol in which the sodium stearate is dissolved. The composition obtained is in the form of an H / L / H type emulsion and additionally comprises a dispersion of liposomes obtained by adding the 15% lecithin solution. The internal aqueous phase of the composition is then both contained in the droplets of the emulsion and in the liposomes. 1.7) Example 6: Deodorant composition in the form of a stick in the form of a dispersion of liposomes (stick 6)

Table 7 1315 Distinct Phases of% by Manufacturing Process introduce (by weight) Pl Biosmosed Water 0.23 Perfume 2.07 P2 Propylene Glycol 63.66 Brij 35 0.99 Sol. Violet DC 2 at 0.1 0.15 Sol. FDC Red 4 to 0, 1 0.04 Biosmosed water 9 P3 Sodium stearate 5.50 15% solution of lecithin 4 Propylene glycol Q.S.P. The composition was manufactured according to the preparation method described in 1.1 except for the preparation of the P3 phase. In the preparation of this phase, a 15% aqueous solution of lecithin is mixed with the propylene glycol in which the sodium stearate is dissolved. The composition obtained is in the form of a liposome dispersion obtained by adding the 15% lecithin solution. The internal aqueous phase of the composition is then contained in the internal phase of the liposomes.

1.8) Example 7: Controls: Deodorant compositions in the form of sticks not containing an H / L / H emulsion or a liposome dispersion:

Table 8: Control 1 (% by weight) Control 2 (wt%) Water 10 5 Propylene glycol 83.60 88.60 Sodium stearate 5.5 5.5 Phenoxyethanol 0.9 0.9 Total 100 100 Water and propylene glycol are mixed using strong agitation at a temperature between 75 and 80 ° C. The sodium stearate is then added maintaining the same stirring until a homogeneous mixture is obtained.

Phenoxyethanol, a bactericidal agent, is then added to the mixture. The product obtained is poured into a stick support at a temperature between 70 and 75 ° C. 1.9) Visual appearance of the sticks of Examples 1 to 6 and controls 1 and 2: The sticks are closed by plugs screwed onto the supports and are placed in a room whose temperature is maintained at 20 ° C overnight. The next morning, the caps are unscrewed and the sticks are left at room temperature for 24 hours. The appearance of each of the sticks is then observed and reported in Table 9. Table 9 ++++: Droplets cover the entire surface of the composition, abundantly. +++: droplets cover the entire surface of the composition + +: a few droplets are visible on the surface of the composition - - -: no droplet visible on the surface of the composition

Controls 1 and 2, which do not comprise a double H / L / H type emulsion, both exhibit exudation phenomena. Droplets are visible on the surface of the sticks. The phenomenon is accentuated for control 2 in which the amount of water is less than the amount of water of control 1 (5% and 10%, respectively) and the amount of propylene glycol is greater than that of control 1 (88%). , 6% and 83.6%, respectively). On the other hand, the control 2 has a greater transparency than the control 1. Thus, if the water is necessary in the composition, its quantity must be limited because of the opacity that it entails.

The sticks 1 and 4, comprising a double H / L / H type emulsion, with droplets of internal aqueous phase, exhibit no exudation phenomenon. Stick 5, comprising a double H / L / H type emulsion with internal aqueous phase droplets and a liposome dispersion, exhibits no exudation phenomenon. Likewise, the stick 6 comprising a dispersion of liposomes exhibits no phenomenon of exudation.

The sticks 2 and 3, each comprising a double emulsion of H / L / H type, exhibit exudation phenomena. The phenomenon is very accentuated for the stick Control 1 Control 2 Sticks 1,4,5,6 Stick 2 Stick 3 Exsudation +++ ++++ --- +++ ++

16 2, with respect to the stick 3. The stick 2 comprises sodium chloride in the internal phase droplets while the stick 3 comprises water in the droplets. Thus, the addition of an electrolyte in the internal droplets accentuates the phenomenon of exudation. Indeed, the addition of the electrolyte in the internal phase of the emulsion decreases the concentration gradient between the internal hydrophilic phase and the external hydrophilic phase ([NaCl] i = 8.6 × 10 -4 mol.L-1 [sodium stearate] e = 1.87.10-1 mol.L-1) relative to the concentration gradient existing in the absence of electrolyte. This proves that in sticks 1 and 3, there is indeed a migration of water from the internal phase, that is to say the water droplets, into the outer hydrophilic phase, the migration being decreased in the stick 2. Comparison of sticks 1 and 3, which differ only in the amount of water in the outer hydrophilic phase, proves that water is needed in this phase. The sodium stearate is then diluted and its affinity for its medium is improved. The solution proposed by the invention for eliminating visible exudation phenomena on the surface of sticks thus consists in maintaining the presence of water in the external hydrophilic phase. Thanks to the water present in the outer hydrophilic phase, the soap molecules have a good affinity for their medium. The water droplets allow a regulation of the amount of water present in the external hydrophilic phase, through the migration of their water into this phase. Similarly, the water contained in the liposomes can migrate into the outer hydrophilic phase and eliminate the exudation phenomenon. 1.10 Solidity of the Invention According to the Invention: Water Droplets Needed for the Stability of a Composition The observation under the microscope of the internal emulsion of the solid composition of the stick 1 shows that the average diameter of the water droplets is 10 m. The density of the stick is 1,040. Volume (V) of water in each droplet (g): V = 4/3 II R3 = 4.19.10E'2L, with R, radius of a droplet = 10.10-6m Area (Sg) of a droplet. Sg = 4 II R2 = 1.26 × 10 -5 cm 2 amount of water per cm 3 of composition:

There is 0.23 g of water per 100 g of composition. The density of the composition being equal to 1.040, then 100 g of composition corresponds to a volume of 96.15 cm3. The quantity of water for 96.15 cm3 of composition is 0.23 g. 2.39 × 10 -3 g of water / cm 3 of composition, ie 2.39 × 10 -6 L of water per cm 3 of composition, are thus obtained.

Number of water droplets per cm3 of composition: 2.39 × 10 -6 / 4.19 × 10 -12 = 570406 droplets of water per cm 3 of composition. Total area (St) per cm3 of composition: St = 1.26 × 10 -5 * 570406 = 7.19 cm 2 per cm 3 of composition Total surface area (st, reference) for the same amount of water per cm 3 of composition containing only one single drop of water: V = 2.39 × 10 -6 LR = 0.83 mm Byte = 0.09 cm 2 The migration of the water being favored by the total surface of the droplets, a solid composition comprising only a single droplet will not provide sufficient surface area for water migration. Table 1 indicates that the amount of aqueous phase in the composition is between 0.07 and 1.5%, by weight, relative to the total weight of the composition. Thus, a composition according to the invention comprises between 1.7 × 10 5 and 3.7 × 10 6 aqueous phase droplets / cm 3 of composition for a total surface area of droplets of aqueous phase of between 2.142 and 30 cm 2 / cm 3 of composition.

2) Composition exfoliating solid in the form of sticks 2.1) Example 8: Exfoliating composition comprising a crosslinked polymer (Stick 7)

A solid composition in the form of a stick, or stick, as defined in Table 10, comprising non-water-soluble solid particles known for their exfoliant properties, such as diatomaceous earth particles, was manufactured according to the method. next. The propylene glycol is mixed with 60 to 80% of the total amount of water using strong stirring at a temperature between 75 and 80 ° C. Sodium stearate is then added while maintaining the same agitation until a

18 homogeneous mixture is obtained. Diatomaceous earth particles and phenoxyethanol, a bactericidal agent, are then added to the mixture. Finally, the hydroxypropyl guar gum is mixed with the rest of the water and added to the mixture. The product obtained is poured into a plastic mold, used as a support for the stick, at a temperature of between 50 and 80 ° C.

Table 10: Stick 7 (wt%) Water Q.S.P. 100 Propylene glycol 70 Sodium stearate 5.5 Guar gum 1,2 hydroxypropyl 40% aqueous solution Diatomaceous earth 2,5 Phenoxyethanol 0.9 2.2) Example 9: Exfoliating composition in the form of an emulsion H / LH and comprising a crosslinked polymer (Stick 8)

Table 11: Distinct Phases of% by manufacturing process introduce (by weight) Pl Biosmosed water 0.23 Synperonic PE L64 0.58 Fragrance 1.50 P2 Propylene glycol 63.68 Synperonic PE F127 0.80 Brij 35 0.20 Soil . Violet DC 2 at 0.1 0.15 Sol. FDC Red 4 at 0.1 0.04 Biosmosed water 9 P3 Sodium stearate 5.50 1,2-hydroxypropyl guar gum (40% aqueous solution) Diatomaceous earth 2.50 Propylene glycol QSP 100 The composition was manufactured according to the preparation process described in 1.5. Diatomaceous Earth particles were simply added to the P3 phase.

2.3) Observations of the compositions of Examples 8 and 9

The solid compositions (sticks 7 and 8), once poured into their respective supports, are quite stable. The distribution of diatomaceous earth particles is homogeneous. The particles are held in suspension by hydroxypropyl guar gum, the crosslinked polymer. This one has indeed created a kind of mesh in the composition allowing the maintenance of the particles of Diatomaceous Earth.

Claims (24)

1) solid cosmetic composition of the type comprising a soap dissolved in a water-miscible organic solvent, such as a primary alcohol, characterized in that it comprises an external hydrophilic phase in which an internal aqueous phase is dispersed, said phases being separated from each other by an intermediate lipophilic phase which contains said inner aqueous phase, said outer hydrophilic phase comprising said soap dissolved in said organic solvent. 2) solid cosmetic composition according to claim 1, characterized in that it comprises between 0.07 and 1.50% by weight of internal aqueous phase, between 0.26 and 13.50% by weight of intermediate lipophilic phase, between 1.80 and 8.00% by weight of a soap, of the organic solvent in an amount per 100%, by weight, relative to the total weight of the composition. 3) solid cosmetic composition according to one of claims 1 to 2, characterized in that it comprises a multiple emulsion of the type H / L / H wherein said internal aqueous phase is in the form of one or more dispersed droplets in said intermediate lipophilic phase itself dispersed in said outer hydrophilic phase. 4) solid cosmetic composition according to claim 3, characterized in that the average diameter of said droplets of internal aqueous phase is between 5 and 20 m, preferably between 5 and 10 m. 5) solid cosmetic composition according to one of claims 2 to 4, characterized in that the number of droplets of internal aqueous phase is between 1.7.105 and 3.7.106 droplets per cm3 of composition. 6) solid cosmetic composition according to one of claims 1 to 5, characterized in that it comprises between 0 and 10% by weight of at least one hydrophobic surfactant and between 0.5 and 10% by weight of at least a hydrophilic surfactant, relative to the total weight of the composition. 21 7) solid cosmetic composition according to claim 6, characterized in that said hydrophobic surfactant or surfactants are chosen from silicone surfactants, such as dimethicone copolyol, and / or nonionic surfactants, such as polyoxyethylenated ethers of fatty alcohols, ethoxylated and propoxylated polymers, or a mixture of such nonionic surfactants, and in that the hydrophilic surfactant is a mixture of a nonionic surfactant and an ethoxylated and propoxylated polymer. 8) solid cosmetic composition according to one of claims 1 to 7, characterized in that it comprises a dispersion of liposomes in said outer hydrophilic phase, said inner aqueous phase being contained in said liposomes. 9) solid cosmetic composition according to claim 8, characterized in that it comprises between 0.13 and 5%, by weight, relative to the total weight of the composition, an aqueous solution of lecithin 15%. 10) solid cosmetic composition according to one of claims 1 to 9, characterized in that said organic solvent is propylene glycol or ethylene glycol and in that said soap is a fatty acid salt such as sodium stearate . 11) solid cosmetic composition according to one of claims 1 to 10, characterized in that said composition further comprises at least one perfume soluble in the intermediate lipophilic phase. 25 12) solid cosmetic composition according to one of claims 1 to 1, characterized in that said composition further comprises at least one fragrance soluble in the outer hydrophilic phase. 13) solid cosmetic composition according to one of claims 1 to 12, characterized in that it further comprises at least one dye soluble in the external hydrophilic phase. 14) solid cosmetic composition according to one of claims 1 to 13, characterized in that it comprises, in addition, between 0.01 and 3% by weight of a crosslinked polymer, relative to the total weight of the composition. 15) The solid cosmetic composition according to claim 14, characterized in that said crosslinked polymer is guar gum, hydroxypropyl guar gum, xanthan gum, a cellulosic polymer, a polysaccharide or a crosslinked polymer of acrylic acid. 16) solid cosmetic composition according to one of claims 14 to 15, characterized in that it further comprises a suspension of non-water-soluble solid particles, such as diatomaceous earth, oyster shell powder, Actinidia sinensis seeds, Oriza sativa seeds, grape seeds, or mixtures thereof, the quantity of which is between 2 and 15%, by weight, relative to the total weight of the composition and the average size of which is between 100 and 10 000 m. 17) deodorant being in the form of a stick or a stick, characterized in that it comprises a solid cosmetic composition as defined in any one of claims 1 to 16. 18) Exfoliating stick characterized in that it comprises a solid cosmetic composition as defined in any one of claims 1 to 16. 19) Process for preparing a solid cosmetic composition, of the type comprising a soap dissolved in a water-miscible organic solvent, such as a primary alcohol, characterized in that it comprises: a step (A) for preparing a first phase (P1) obtained by mixing a determined amount of an aqueous phase and a determined amount of a lipophilic phase, a step (B) for preparing a second phase ( P2) obtained by mixing a determined amount of at least one hydrophilic surfactant and from 27 to 73%, by weight, of the total amount of said organic solvent and a step (C) of preparing a phase (P3 ) by mixing a determined quantity of a soap and the remainder of the total amount of said organic solvent. Then, a step (D) of mixing, with gentle stirring, a determined quantity of the first phase (P1 ) with a determined amount of second phase (P2) and, - a mixing step (E), under low agitation, the mixture obtained in the preceding step and a determined amount of third phase (P3) so as to obtain said composition. 20) Process for the preparation of a solid composition according to claim 19, characterized in that said step of preparing a first phase (P1) comprises the addition of a determined quantity of at least one hydrophobic surfactant, under strong conditions. agitation. 21) A method for preparing a solid composition according to one of claims 19 to 20, characterized in that said determined amount of aqueous phase is between 0.07 and 1.50%, said determined amount of lipophilic phase is understood between 0.26 and 13.50, said amount of hydrophobic surfactants is between 0 and 10%, said amount of hydrophilic surfactants is between 0.5 and 10%, said total amount of organic solvent is between 65.10 and 89.30% by weight and said amount of soap is between 1.80 and 8.00%, by weight, relative to the total weight of the composition. 22) A process for preparing a solid composition according to one of claims 19 to 21, characterized in that it comprises, in addition, the addition of between 0.13 and 5.00% by weight of a 15% aqueous solution of lecithin, relative to the total weight of the composition. 23) Process for the preparation of a solid composition according to one of claims 19 to 22, characterized in that it comprises, in addition, the addition of between 0.0] and 3.00% by weight of at least one crosslinked polymer, relative to the total weight of the composition, as well as the addition of between 2 and 15%, by weight, of non-water-soluble solid particles chosen from diatomaceous earth, oyster shell powder, the seeds of Actinidia sinensis, the grains of Oriza sativa, the grape seeds, or their mixture, in relation to the total weight of the composition. 24) A process for preparing a solid composition according to claim 23, characterized in that it comprises, in addition, the casting of said composition in a mold at a temperature between 50 and 90 ° C.