JP2012085871A - Cosmetic applicator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cosmetic applicator for liquid foundation which has fine cells to reduce absorption of the liquid foundation, and has moist feeling on the surface, and has a high density and an appropriate hardness.SOLUTION: The cosmetic applicator used for liquid foundation is made of latex rubber to which an aromatic ester is added.

Description

  The present invention relates to a cosmetic applicator, and particularly to a cosmetic applicator suitable for a liquid foundation, a so-called cosmetic puff.

  Conventionally, it has been known to add oils such as plant-based, animal-based and petroleum-based oils in order to soften and give a moist feeling to latex foams relating to cosmetic applicators.

  There exists patent document 1 as a prior art which discloses such a technique. The sponge described in Patent Document 1 is foam-molded using NBR latex rubber or the like as a material, and has a moist feeling by including fats and oils in this material. Here, fats and oils are natural or artificially obtained fatty acid esters, lanolin, fats and oils extracted from animal hair, squalane and squalene (squalanes, fats and oils extracted from the deep sea shark liver, and artificial products Known), bisabolol, wax and the like, and one kind or a mixture of two or more kinds can be used. Moreover, it is disclosed that the usage-amount of these fats and oils is 0.5-20 weight part with respect to 100 weight part of raw material resin, Preferably it is 1.0-10 weight part.

Japanese Patent Laid-Open No. 2002-20520

  In the prior art of Patent Document 1, if the amount of oils and fats used is less than the above amount used, a moist feeling cannot be achieved. Occurs and a uniform sponge cannot be obtained.

  In general, when a large amount of oils and fats (oil) is added to obtain a moist feeling and give flexibility at a predetermined density, the foam cell becomes rough, and the foundation scraping and application performance to the skin may be inferior. Are known. In particular, the cells of cosmetic puffs used in foundations such as liquid foundations, cream foundations, and emulsion foundations are required to be fine. However, since the foundation is generally an oil in water (O / W), a large amount of fats and oils are used. A cosmetic puff to which a kind is added becomes oleophilic per se, and when the cell diameter is increased, the foundation is easily sucked and the coating performance is deteriorated.

  In other words, in order to give a soft and moist feeling, simply increasing the amount of plasticizer such as fats and oils to produce an applicator such as a cosmetic sponge or puff having an appropriate density and hardness. Was difficult.

  Therefore, the present invention has been made in view of the above problems, and as a result of intensive studies, the present inventors have added an aromatic ester so that the cosmetic applicator has an appropriate density. It has the knowledge that it has softness and moist feeling. The purpose of the present invention is based on this knowledge, as a cosmetic applicator for a liquid foundation, the cell is made finer, the liquid foundation is less sucked, and has a moist feel on the surface. An object of the present invention is to provide a cosmetic applicator having a high hardness.

In order to solve the above problems, a cosmetic applicator for use in a liquid foundation is provided, which is made of a latex rubber to which an aromatic ester is added.
According to this, as a makeup application tool for liquid foundation, it is possible to make the cell finer, reduce the suction of the liquid foundation, have a moist feel on the surface, and have high density and appropriate hardness Become.
In general, a liquid foundation refers to a low-viscosity liquid foundation. In this specification, a liquid foundation includes cream type, emulsion type, mousse type, and broadly gel type foundations, powder type, Other than stick-type and cake-type foundations, it refers to all foundations provided in cream form from emulsions as well as low-viscosity liquids.

  The aromatic ester includes at least one of trimellitic acid, pyromellitic acid, and benzoic acid, and the added amount is 25 to 65 parts by weight with respect to 100 parts by weight of the latex rubber. May be a feature.

Further, the density may be 160 to 270 kg / m ³ and the F hardness may be 55 to 85.

  As described above, according to the present invention, as a cosmetic foundation application device for a liquid foundation, the cell is made finer, the liquid foundation is less sucked, and the surface has a moist feel. It becomes possible to have.

A photomicrograph of the cell structure of a cosmetic puff. <A> A cell structure evaluated as “an optimal cell structure for a liquid foundation”. <B> Cell structure evaluated as “cell structure suitable for liquid foundation”. <C> Cell structure evaluated as “cell structure that cannot be used for liquid foundation but can be used for powder foundation”. The micrograph of the cell structure of Example 1 and 5. The micrograph of the cell structure of the comparative examples 1 and 5.

Hereinafter, the present invention will be described in more detail.
The latex rubber as the main component used in the present invention is preferably excellent in oil resistance and the like, and therefore NBR latex is used. NBR latex is a synthetic rubber latex containing acrylonitrile and butadiene as main components. In the examples according to the present invention, Nipol 531B manufactured by Nippon Zeon Co., Ltd. was used, but the present invention is not limited to this.

In the examples and comparative examples according to the present invention, a foaming agent was added to generate stable foam in the latex, and FR-14 manufactured by Kao Corporation was used. However, the present invention is not limited to this.
In the examples and comparative examples according to the present invention, a foam stabilizer was added to bring about a fine and uniform cell structure, and a trimen base manufactured by Chemtura was used, but the present invention is not limited to this.
In the examples and comparative examples according to the present invention, a coagulant was added to promote the coagulation of the latex rubber, and SSF (sodium fluorosilicate) manufactured by Shimonoseki Mitsui Chemicals, Inc. was used. Not.
Further, in the examples and comparative examples according to the present invention, a vulcanizing agent was added to ensure the elasticity of the latex rubber, and powdered sulfur manufactured by Hosoi Chemical Industry Co., Ltd. was used. However, the present invention is not limited to this.
In the examples and comparative examples according to the present invention, a vulcanization accelerator is added to accelerate vulcanization, and two types of zinc oxide manufactured by Sakai Chemical Industry and Noxeller MZ manufactured by Ouchi Shinsei Chemical are used. However, it is not limited to this.

What was blended as shown in Table 1 above is the basic raw material of the cosmetic applicator according to the present invention, the embodiment according to the present invention is the type of plasticizer and It is obtained by changing the amount of addition.

  In the present invention, the type of plasticizer added to the latex rubber is an aromatic ester. Aromatic esters may be those that are not listed as substances subject to the positive list system of the Food Sanitation Law or substances that are not subject to regulation such as European Chemical Substance Regulation (REACH). Specifically, trialkyl (especially ethylhexyl, octyl) trimellitate, dialkylene (especially propylene) glycol dibenzoate, etc., preferably trimellitic acid-based, pyromellitic acid-based, benzoic acid-based esters, or these Is a mixture containing at least two.

  Specifically, the trimellitic acid ester is trisethylhexyl trimellitate (TOTM). More specifically, for example, DIC Monosizer W-705, Kao Corporation Trimerix T-08, J There is a product manufactured by Plus, and the pyromellitic acid ester is tetraethylhexyl pyromellitate. More specifically, for example, there is PL-80 manufactured by ADEKA, and benzoic acid ester is dipropylene glycol. More specifically, there are, for example, monosizer PB-3A manufactured by DIC, J120 manufactured by J-Plus, and Benzoflex 9-88 manufactured by Genovique Specialties.

  As the linear plasticizer, citric acid-based acetyltryptyl citrate (ATBC) and the like can also be used for cosmetic applicators, but the linear plasticizer provides a softening effect, but the cell becomes rough, so a liquid foundation. As the cosmetic applicator suitable for the above, an aromatic system in which the cell is fine and the touch is good is preferable.

  The added amount of the aromatic ester added as a plasticizer is 25 to 65 parts, preferably 30 to 60 parts, more preferably 40 to 60 parts with respect to 100 parts by weight of the rubber solid content in the latex rubber. The number of copies. When two or more types of aromatic esters are added, the number of parts added refers to the total number of parts added.

The density of the cosmetic applicator is 160 to 270 kg / m ³ , the F hardness is 55 to 85, preferably the density is 164 to 269 kg / m ³ , and the F hardness is 57 to 81, more preferably The density is 202 to 269 kg / m ³ and the F hardness is 61 to 81.
The kind of ester to be added, the number of added parts, the density, and the F hardness are based on Examples and Comparative Examples described below.

  In Table 2, the kind of ester added in Examples 1-10 and Comparative Examples 1-7 and the number of added parts are shown. In these examples and comparative examples, a cosmetic puff as a cosmetic applicator was manufactured by the manufacturing method described later. The amount of gas mixed into the latex rubber was 200 to 400 ml / latex 100 ml. Adjust as appropriate.

<Example>
In Example 1, the aromatic ester is a benzoic acid type, and the density was 164 kg / m ³ , F.sub.3 when the added amount was 30 parts by weight with respect to 100 parts by weight of the rubber solid content in the latex rubber. The hardness was 57. As a result of visual evaluation of the cell structure, a cell structure suitable for liquid foundation could be produced.

In Example 2, the aromatic ester is a benzoic acid type, and the added amount is 30 parts by weight with respect to 100 parts by weight of the rubber solid content in the latex rubber. As a result, the density was 184 kg / m ³ and the F hardness was 67. As a result of visual evaluation of the cell structure, a cell structure suitable for the liquid foundation could be manufactured.

In Example 3, the aromatic ester is trimellitic acid type, and when the amount of addition is 30 parts by weight with respect to 100 parts by weight of the rubber solid content in the latex rubber, the density is 198 kg / m ³ , The F hardness was 67. As a result of visual evaluation of the cell structure, a cell structure suitable for liquid foundation could be produced.

In Example 4, the aromatic ester is a pyromellitic acid type, and when the amount of addition is 30 parts by weight with respect to 100 parts by weight of the rubber solid content in the latex rubber, the density is 224 kg / m ³ , The F hardness was 65. As a result of visual evaluation of the cell structure, a cell structure suitable for liquid foundation could be produced.

In Example 5, the aromatic ester is a benzoic acid type, and when the amount of addition is 40 parts by weight with respect to 100 parts by weight of the rubber solid content in the latex rubber, the density is 202 kg / m ³ , F The hardness was 67. As a result of visual evaluation of the cell structure, a cell structure optimum for the liquid foundation could be produced.

In Example 6, the aromatic ester is a benzoic acid type, and the added amount is 40 parts by weight with respect to 100 parts by weight of the rubber solid content in the latex rubber. As a result, the density was 214 kg / m ³ and the F hardness was 72. As a result of visual evaluation of the cell structure, it was possible to produce an optimal cell structure for the liquid foundation.

In Example 7, the aromatic ester is trimellitic acid type, and when the amount of the added part is 50 parts by weight with respect to 100 parts by weight of the rubber solid content in the latex rubber, the density is 213 kg / m ³ , The F hardness was 61. As a result of visual evaluation of the cell structure, an optimum cell structure for the liquid foundation could be produced.

In Example 8, the aromatic ester is a benzoic acid type, and the density was 227 kg / m ³ , F. The hardness was 73. As a result of visual evaluation of the cell structure, a cell structure optimal for a liquid foundation could be produced.

In Example 9, the aromatic ester is a benzoic acid type, and the added amount is 50 parts by weight with respect to 100 parts by weight of the rubber solid content in the latex rubber. As a result, the density was 269 kg / m ³ and the F hardness was 81. As a result of visual evaluation of the cell structure, a cell structure optimum for the liquid foundation could be produced.

In Example 10, the aromatic ester is a trimellitic acid type, and when the amount of addition is 60 parts by weight with respect to 100 parts by weight of the rubber solid content in the latex rubber, the density is 262 kg / m ³ , The F hardness was 71. As a result of visual evaluation of the cell structure, an optimal cell structure for the liquid foundation could be produced.

<Comparative example>
In Comparative Example 1, when manufactured without adding a plasticizer, the density was 150 kg / m ³ and the F hardness was 62. As a result of visual evaluation of the cell structure, a cell structure that could not be used for the liquid foundation was obtained.

In Comparative Example 2, the aromatic ester is a benzoic acid type, and when the amount of addition is 20 parts by weight with respect to 100 parts by weight of the rubber solid content in the latex rubber, the density is 149 kg / m ³ , F The hardness was 53, and as a result of visual evaluation of the cell structure, a cell structure that could not be used for the liquid foundation was obtained.

  In Comparative Example 3, the aromatic ester is trimellitic acid type, and when the amount of addition is 70 parts by weight with respect to 100 parts by weight of the rubber solid content in the latex rubber, the cell structure collapses, It can no longer be used as a cosmetic puff.

  In Comparative Example 4, the aromatic ester is a benzoic acid type, and when the amount of addition is 70 parts by weight with respect to 100 parts by weight of the rubber solid content in the latex rubber, the cell structure collapses and the makeup Can no longer be used as a puff.

In Comparative Example 5, the plasticizer is adipic acid that is not an aromatic ester (specifically, diisononyl adipate (DINA)), and the added amount is 30 parts by weight with respect to 100 parts by weight of the rubber solid content in the latex rubber. As a result, the density was 271 kg / m ³ and the F hardness was 76. As a result of visual evaluation of the cell structure, a cell structure that could not be used for the liquid foundation was obtained.

In Comparative Example 6, citric acid that is not an aromatic ester (specifically, acetyltributyl citrate (ATBC)) is used as the plasticizer, and the added number of parts is 100 parts by weight of the rubber solid content in the latex rubber. When manufactured at 30 parts by weight, the density was 247 kg / m ³ and the F hardness was 68. As a result of visual evaluation of the cell structure, the cell structure was unusable for a cosmetic puff. The addition of an acid, not an ester compound, changed the viscosity of the reaction mixture, the timing of the crosslinking reaction, etc., and could not be solidified while retaining fine bubbles.

In Comparative Example 7, the plasticizer is azelaic acid that is not an aromatic ester (specifically, diethylhexyl azelate (DOZ)), and the added number of parts is 100 parts by weight of rubber solid content in the latex rubber. When manufactured at 50 parts by weight, the density was 253 kg / m ³ and the F hardness was 60. As a result of visual evaluation of the cell structure, the cell structure was unusable for a cosmetic puff. The addition of an acid, not an ester compound, changed the viscosity of the reaction mixture, the timing of the crosslinking reaction, etc., and could not be solidified while retaining fine bubbles.

Cell structure visual evaluation: The cell structure was visually evaluated by the following four stages using a microscope.
4: Optimal cell structure for liquid foundation 3: Cell structure suitable for liquid foundation 2: Cell structure that cannot be used for liquid foundation (cell structure that can be used for powder foundation, etc.)
1: The cell collapses or the cell becomes very rough and cannot be used as a cosmetic puff.

<Visual evaluation method>
As shown in FIG. 1, <A> indicates a cell structure optimal for a liquid foundation, <B> indicates a cell structure suitable for a liquid foundation, and <C> cannot be used for a liquid foundation. A cell structure that can be used for a powder foundation or the like is shown.

  In the cell structure optimal for the liquid foundation of <A>, the finest and most uniform cell is constituted compared to the others. In the cell structure suitable for the liquid foundation of <B>, the cell structure is relatively uniform as compared with the optimum cell structure for the liquid foundation, but the cell is rough. In the cell structure that cannot be used for the liquid foundation of <C>, the cell is rougher and not uniform than others.

  In this way, the fine and uniform cell structure has a high density and moderate hardness with less liquid liquid suction and a moist feel on the surface, compared to a rough and uneven cell structure. It can be used as a cosmetic puff.

  As shown in FIG. 2, the cell structure of Example 1 has a liquid foundation of <B> according to visual evaluation by comparing with the cell structures of <A>, <B>, and <C> in FIG. It can be said that the cell structure is determined to be a suitable cell structure. Similarly, the cell structures of Examples 2 to 3 were determined to have the cell structure of <B>. Similarly, it can be said that the cell structure of Example 5 is a cell structure that is determined to be the optimal cell structure for the liquid foundation of <A>. The cell structures of Examples 6 to 10 were similarly determined to have the cell structure of <A>.

<Critical significance>
As a result of visual evaluation, the addition amount of the plasticizer in Examples 1 to 10 evaluated as the cell structure suitable for the liquid foundation or the cell structure suitable for the liquid foundation was 30 to 60 parts by weight, and the density was 164 to 269 kg / m is ^3, F hardness is 57-81. Moreover, the addition amount of the plasticizer in Examples 5-10 evaluated as the optimal cell structure for the liquid foundation is 40-60 parts by weight, the density is 202-269 kg / m ³ , and the F hardness is 61- 81.

In addition, when each value of the comparative example is considered, the addition amount of the aromatic ester as a plasticizer is 25 to 65 parts by weight, the density is 160 to 270 kg / m ³ , and the F hardness is 55 to 85. It can be said that it can be used as a makeup puff for a liquid foundation. The value of 25 parts by weight of the addition amount is an intermediate value of the number of parts by weight of benzoic acid in Example 1 and Comparative Example 2. Moreover, the value of 65 parts by weight of the addition amount is an intermediate value of the number of parts by weight of trimellitic acid in Example 10 and Comparative Example 3.

Moreover, the value of density 160 kg / m ³ is a value between the density in Example 1 and Comparative Example 2. Further, the density of 270 kg / m ³ is almost the same as the density in Example 9. The density of Comparative Examples 6 and 7 are ^{247kg / m 3, 253kg / m} 3, is a value between 160~270kg / m ^3, the plasticizer is not aromatic esters.
When a plasticizer other than an aromatic ester is added, the hardness becomes low and the texture becomes soft, but the cell does not become fine, which is not preferable as a cosmetic puff for a liquid foundation.

  Moreover, the value 55 of F hardness is an intermediate value of F hardness in Example 1 and Comparative Example 2. Moreover, the value of F hardness of 85 is almost the same value as the F hardness in Example 9. In addition, although F hardness of Comparative Examples 1, 5, 6, and 7 is a value between 55-85, respectively, Comparative Example 1 is a value when a plasticizer is not added, Comparative Examples 5, 6, And the plasticizer in 7 is not an aromatic ester.

  That is, when the amount of the plasticizer added is less than 25 parts by weight, the cell does not become fine, and the difference from the conventional cosmetic puff in the cell structure is reduced, which is not preferable as a cosmetic puff for liquid foundation. On the other hand, if the addition amount of the plasticizer exceeds 65 parts by weight, the rubber is too soft to maintain the cell skeleton, and the cell structure is crushed during vulcanization.

Further, when the density is less than 160 kg / m ³ , the cell structure becomes very rough, which is not preferable as a makeup puff for a liquid foundation, and when the density exceeds 270 kg / m ³ , the cell structure becomes hard. It is not preferable as a puff for use. Further, when the F hardness is less than 55, it is not preferable because it is too soft as a makeup puff for a liquid foundation, and when the F hardness exceeds 85, it is too hard when touched and the touch is not preferable.

<Application performance evaluation method and evaluation>
A method for evaluating the application performance of the liquid foundation will be described.
After measuring the weight of the cosmetic puff (30 mm × 45 mm × 7.5 mm) before use, 0.01 g of liquid foundation is dropped into the cosmetic puff.

  Thereafter, as with applying the foundation, the index finger is pressed against the back of the makeup puff, and one end of the makeup puff is sandwiched between the thumb and forefinger and the other end is sandwiched between the index and middle fingers. In this state, the foundation is applied to the graph paper with the makeup puff held by the finger. Specifically, the length of each application is set to about 15 cm, and it is moved from the left to the right on the graph paper in a certain direction, so that a certain area is applied. Repeat until the color stops.

After confirming that the color of the foundation is no longer applied to the graph paper, the weight of the cosmetic puff is measured again, and the coating rate is obtained by the equation (1).

Formula (1) ... Application rate =
(Weight of foundation placed on puff-weight of foundation remaining on puff after application) / Weight of foundation placed on puff

  Further, the cosmetic puff is cut from the cross section, and the depth at which the foundation soaks and discolors is measured. Moreover, the area | region where the foundation stain | pollution | contamination by the cosmetic puff produced | generated after application | coating is cut from graph paper, and an application area is measured.

The application rate indicates the ratio of the liquid foundation remaining on the skin, and the larger the value, the more efficiently it can be applied to the skin. The penetration depth indicates the amount of liquid foundation remaining in the cosmetic puff, and the smaller the value, the less the penetration and the less liquid foundation remaining. The larger the coating area, the larger the liquid foundation coating area, which is preferable for use.

  As shown in Table 3, according to this evaluation method, in the example (Example 8) according to the present invention, the penetration depth is smaller than that of the conventional cosmetic puff (Comparative Example 1), and the coating is applied. The rate is high and the coating area is wide. That is, the cosmetic puff according to the present invention has little penetration into the cosmetic puff, has a large amount of liquid foundation that can be placed on the skin, can be spread widely on the skin, and the liquid foundation is efficiently applied to the skin. It can be seen that it can be applied.

<Manufacturing method>
In order to manufacture the material for the cosmetic applicator according to the present invention, a known Dunlop method is used. In the Dunlop method, the latex rubber, vulcanizing agent / vulcanization accelerator aqueous dispersion and additive mixture stored in a storage tank are pumped up, mixed with air and coagulant with a mixing head such as Oaks mixer, and stirred. Then, uniform fine bubbles are contained and foamed. Next, the foamed latex rubber is taken out from the mixing head, poured into a mold, solidified, vulcanized, demolded, washed with water, and dried to obtain a latex foam. A cosmetic applicator is produced by cutting the latex foam into an appropriate size and thickness.

  Conventionally, a material for a cosmetic applicator having a target density has been obtained by controlling the flow rate of gas injected into an oak mixer or the like. For example, a latex foam having an appropriate density and hardness can be obtained by adjusting the volume of the gas to be gas-liquid mixed when the amount of plasticizer added is 40 parts by weight. Conventionally, in order to vary the hardness, the density is varied by adjusting the volume of the gas mixed with the latex rubber, thereby varying the hardness.

  However, in the present invention, the density and hardness can be varied by varying the amount of plasticizer added. In the latex foam adjusted to the same hardness, the density increases as the amount of plasticizer increases (see Examples 2 and 5). On the other hand, in the latex foam adjusted to the same density, the hardness becomes lower and softer as the amount of plasticizer increases.

In addition, the density of the cosmetic applicator in the present specification refers to the density determined according to JISK7222 “Foamed plastics and rubber—How to determine the apparent density”.
Moreover, F hardness of the cosmetic applicator in this specification means the hardness calculated | required by Asuka rubber hardness meter F type (made by Kobunshi Keiki Co., Ltd.).

  It should be noted that the present invention is not limited to the illustrated embodiments, and can be implemented without departing from the contents described in the claims.

In order to solve the above problem, a cosmetic applicator for use in a liquid foundation is provided, which is made of a foam obtained by adding an aromatic ester to NBR latex and foaming and curing it .
According to this, as a makeup application tool for liquid foundation, it is possible to make the cell finer, reduce the suction of the liquid foundation, have a moist feel on the surface, and have high density and appropriate hardness Become.
In general, a liquid foundation refers to a low-viscosity liquid foundation. In this specification, a liquid foundation includes cream type, emulsion type, mousse type, and broadly gel type foundations, powder type, Other than stick-type and cake-type foundations, it refers to all foundations provided in cream form from emulsions as well as low-viscosity liquids.

In addition, the aromatic ester may be a compound that does not fall under the target substance of the positive list of the Food Sanitation Law or the target substance of the European chemical substance regulation . Further, the aromatic ester includes at least one of trimellitic acid, pyromellitic acid, and benzoic acid, and the number of added parts is 25 to 65 with respect to 100 parts by weight of the rubber solid content in the NBR latex. It may be characterized by being a weight part.

In order to solve the above problems, the addition of aromatic ester NBR latex, Ri Do foamed cured foam, the aromatic ester, trimellitic acid, pyromellitic acid, at least benzoic acid A cosmetic applicator for use in a liquid foundation is provided that includes one and contains 25 to 65 parts by weight with respect to 100 parts by weight of the rubber solid content in the NBR latex .
According to this, as a makeup application tool for liquid foundation, it is possible to make the cell finer, reduce the suction of the liquid foundation, have a moist feel on the surface, and have high density and appropriate hardness Become.
In general, a liquid foundation refers to a low-viscosity liquid foundation. In this specification, a liquid foundation includes cream type, emulsion type, mousse type, and broadly gel type foundations, powder type, Other than stick-type and cake-type foundations, it refers to all foundations provided in cream form from emulsions as well as low-viscosity liquids.

In addition, the aromatic ester may be a compound that does not fall under the target substance of the positive list of the Food Sanitation Law or the target substance of the European chemical substance regulation .

Claims (3)

  A cosmetic applicator used for a liquid foundation, comprising latex rubber to which an aromatic ester is added.   The aromatic ester contains at least one of trimellitic acid type, pyromellitic acid type, and benzoic acid type, and the added part number is 25 to 65 parts by weight with respect to 100 parts by weight of rubber solid content in the latex rubber. The cosmetic applicator according to claim 1. The cosmetic applicator according to claim 1 or 2, wherein the density is 160 to 270 kg / m ³ and the F hardness is 55 to 85.