BRUSH FOR COSMETIC IMPLEMENTS AND MANUFACTURING METHOD OF THE SAME

Abstract

A brush for cosmetic implements includes a brush part attached to a support member; the brush part includes a plurality of synthetic resin fibers whose tip end has a conically tapered surface, and a plurality of fiber bundles composed of a plurality of synthetic resin fibers is formed at least three places in a radial circumferential surface of the support member, and further formed in an axial direction of the support member. Provided is a brush for a cosmetic implements in which a brush bristle having a tapered end is provided around the support member in the radial direction, and a manufacturing method thereof.

Description

BACKGROUND OF THE INVENTION

Field of the Invention

The present invention relates to brushes for cosmetic implements and a manufacturing method of the same. More specifically the invention relates to brushes for cosmetic implements such as a mascara brush, having bristles that extends in radial directions of the support member, perpendicular to the axis thereof and a manufacturing method of the same.

Description of Related Art

As a brush for cosmetic implements having bristles that extends in radial directions of the support member, perpendicular to the axis thereof, a mascara brush, for example, to apply mascara onto eyelashes is known. In this mascara brush, for example, a large number of the brush bristles are fixed between two twisted wires such that the bristles extend from the wires (the axis) in radial directions, perpendicular to the axis. In addition, some brushes have bristles (fibers), free ends of which are formed to be tapered, and are capable of easily entering between the eyelashes when mascara is applied.

Various proposals have been made on this tapered bristles (fibers). For example, Patent Literature 1 proposes bristles whose cross section of the free end is formed in a wedge shape. In addition, Patent Literature 2 proposes that the tip part of the bristles are fused and extended in a thermal processing, and formed in a right-triangular tapered shape seen from a side face. Further, Patent Literature 3 proposes that the tip part of the bristles are formed in a right-triangular shape seen from a side face by polishing process with whetstones or files.

Since the free end (the tip part) of the bristles, according to Patent Literature 1 to 3, are formed in a wedged shape or a right-angle triangular shape, as previously described, when the bristles having a wedged shaped or right-angle triangular shaped cross section 50 are arrayed to face in one direction, there arises a problem of difference of repulsive forces; one of the them is generated against a force applied from A direction along the axis of the support member and the other is generated against a force applied from B direction opposite to A direction. That is, it is problematic that a feeling of use is different because softness and flexibility differ in the direction of use.

To solve this problem, Patent Literature 4 teaches a brush for cosmetic implements is proposed having bristles (fibers) whose tip part is formed in a conical shape.

A brush for cosmetic implements in Patent Literature 4 is composed of a brush part and a support member to which the brush part is inserted to fix; in the brush part bristles made of synthetic resin having the tip ends formed in a tapered shape (a conical shape) are erectedly disposed in a row in the longitudinal direction and each adjacent bristles is separated from each other.

This brush for cosmetic implements having bristles (fibers) whose tip ends are formed in a conical shape enables to improve a feeling of use because the repulsive force generated against a force from A direction along the axis of the support member and the repulsive force generated against a force from B direction opposite to A direction are made substantially equal.

REFERENCES OF PRIOR ART

Patent Literature

1. Japanese Unexamined Patent Application Publication No. 2004-49906

2. Japanese Unexamined Patent Application Publication No. 2008-30730

3. Japanese Unexamined Patent Application Publication No. 2009-60998

4. Japanese Patent No. 4846323

SUMMARY OF THE INVENTION

As stated above, a brush for cosmetic implements disclosed in Patent Literature 4, however, is provided with a brush part where bristles made of synthetic resin are erectedly disposed in a row in the longitudinal direction.

The brush, however, fails to include plural rows of bristles on the circumferential surface of the axial direction (on the periphery of the cross section) of the support member. Accordingly, it is inconvenient to users to have to apply mascara to the eyelashes while paying attention to the position of the brush part.

To eliminate such an inconvenience, it is possible to insert the plural brush parts around all the circumference of the support member, but this raises an additional problem to increase the radius of the support member. Another method is to implant tapered bristles at plural positions on the circumferential surface of the axial direction by fusing or adhesion, but this further causes to make the length of the bristles (tip part) uneven. Further another method is tapering the tip part of the bristles after being planted at plural positions on the circumferential surface of the axial direction. As described above, forming the tip ends of the bristles (fibers) to have a conical shape is difficult by tapering with whetstones or files, and tapering with thermal processing may adversely cause the bristles to fuse to each other.

At the time of development of a brush for cosmetic implements in which a brush part is formed at a plurality of positions around the support member in the radial direction, a method to taper the tip part of the bristles after being planted on the circumference of the support member has been intensively studied. As a result, it is found that a particular manufacturing method enables to form tip-tapered bristles at a plurality of positions around the support member in the radial direction.

It is an object of the invention to provide a brush for cosmetic implements having tip-tapered bristles at a plurality of positions around the support member in the radial direction and a manufacturing method of the brush.

A brush for cosmetic implements according to the present invention is a brush for cosmetic implements having a brush part provided on a support member, and includes a plurality of synthetic resin fibers whose tip part has a conically tapered surface; a fiber bundle composed of a plurality of synthetic resin fibers on a circumferential surface as to extend at least in three radial directions of the support member; and the fiber bundles provided on a surface of an axial direction of the support member.

Since the fiber bundles are provided on a circumferential surface as to extend at least in three radial directions of the support member and in addition on a surface of an axial direction of the support member, mascara can be applied to eyelashes, and an improved feeling of use is achieved, without paying attention to the position of the brush part when in use. The circumferential surface in the radial direction of the support member means not only the circumferential surface at one cross section of the support member but also a cross section drawn by one rotation of a metallic wire rod (the support member) like a twisted brush, which will be described later, and the peripheral surface of this cross section is also included in the circumferential surface in the radial direction.

It is desirable that the support member is made of two or more metal wires, and that the synthetic resin fiber bundles are held between wires and fixed by twisting. In particular, by setting the number of the metal wires to be three or more, the number of combination of fibers increases and brushes having various arrangement of fibers can be manufactured.

The fiber bundles are preferably composed of straight fibers mixed with non-straight fibers, where the axis of the straight fibers is linear and the axis of the non-straight fibers is curved, such as crimped fiber.

By mingling straight fibers with non-straight fibers, occurring of lumping of mascara or clamping of eyelashes or damage of skin can be prevented. Further the mingling of fibers can improve retainability of mascara liquid on the brush and reduce the number of redipping.

A brush according to the present invention is a brush for cosmetic implements having a brush part attached to a support member, wherein the brush part includes a plurality of synthetic resin fibers whose tip part has a conically tapered surface, the plurality of synthetic resin fibers is disposed on a circumferential surface of the support member to extend in at least two radial directions, and the synthetic resin fibers are disposed on a circumferential surface of the axial direction, and wherein the support member is made of two or more metal wires twisted and the synthetic resin fibers are provided on the support member, interposed and fixed by the twisted wires.

Thus, when the support member is made of twisted wires, a plurality of synthetic resin fibers is easily fixed to the support member. In particular, using twisted two metal wires enables to achieve a small outer diameter support member and to manufacture easily and at low cost, and to provide a small and inexpensive brush for cosmetic implements.

Further the brush part of the brush for cosmetic implements is preferably provided whole circumferential surface of the support member, and the whole shape is preferably formed in a columnar or small conical shape.

Still further the plurality of synthetic resin fibers is preferably composed of straight fibers mixed with non-straight fibers, similar to the case of the fiber bundles. By mixing straight fibers with non-straight fibers, occurring of lumping of mascara or clamping of eyelashes or damage of skin can be prevented. Further the mixing of fibers can improve retainability of mascara liquid on the brush and reduce the number of redipping.

In order to achieve the above object, the present invention provides a manufacturing method of the brush for cosmetic implements, including the steps of: bundling the synthetic resin fibers to provide a brush part on the support member; immersing the brush part in a solution bath in which a soluble liquid is contained; moving the brush part up and down from an upper side of a polishing/rubbing blade; causing the brush part to come into contact with a polishing/rubbing blade for a predetermined time; dissolving and swelling a surface of the synthetic resin fiber; and scrubbing off the surface of the synthetic resin fiber by the polishing/rubbing blade, to form the tapered surface.

The manufacturing method includes the steps of bundling the synthetic resin fibers to provide a brush part on the support member; immersing the brush part in a solution bath in which a soluble liquid is contained; moving the brush part up and down from an upper side of a polishing/rubbing blade; causing the brush part to come into contact with a polishing/rubbing blade for a predetermined time; dissolving and swelling a surface of the synthetic resin fiber; and scrubbing off the surface of the synthetic resin fiber by the polishing/rubbing blade, to form the tapered surface, and therefore the tapered surface is easily formed to the bristles provided on the circumferential surface of the support member. The present invention can provide the brush for cosmetic implements provided with bristles having tapered tip ends on a circumferential surface of the support member and the manufacturing method of the brush.

BRIEF DESCRIPTION OF THE DRAWING

FIG. 1 is a cross-sectional view showing a cosmetic implement which uses a brush for cosmetic implements according to the present invention;

FIGS. 2A and 2B are a sectional view and a side view showing an application part of a brush for cosmetic implements according to the present invention;

FIG. 3 is a front view of the application part of a brush for cosmetic implements according to the present invention;

FIG. 4 is a perspective view of the application part of a brush for cosmetic implements according to the present invention.

FIG. 5A is a view showing a fiber (brush bristle) having a tapered surface formed, and FIG. 5B is a view showing fibers (brush bristles) without having a tapered surface formed;

FIGS. 6A to 6E are across sectional views showing an example of modified fiber shape of a synthetic resin fiber (brush bristle);

FIG. 7 is a perspective view showing the synthetic resin fiber (bristle) having a projecting and recessed portion formed on a tapered surface;

FIG. 8 is a side view showing a brush part in which the whole shape is formed in a cylindrical shape;

FIGS. 9A and 9B are views showing a brush part in which the whole shape is formed in a conical shape;

FIG. 10 is a schematic diagram showing the steps of the manufacturing method according to the present invention;

FIG. 11 is an enlarged view of a main part of an arrangement of polishing/rubbing blades and the brush part shown in FIG. 10;

FIG. 12 is a side view showing the polishing/scrubbing blade shown in FIG. 11; and

FIG. 13 is a schematic view showing a conventional brush for cosmetic implements.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Hereinafter, an explanation will be made of an embodiment of the present invention with reference to the drawings FIGS. 1 through 5. Cosmetic implements to which the brush according to the present invention is utilized are such as eye-liners, mascaras, nail polish, lipsticks, hair dyes. In the present embodiments, a mascara having fluidity will be described as an example. A cosmetic implement A includes a container 10 containing a coating liquid K, a cap 20 threadedly engaging with the container 10, and applicator 30 provided with a brush part 3 immersed in the coating liquid K in the container 10.

The container 10 is formed in a bottomed cylinder shape having a neck portion 11 and contains a prescribed amount of the coating liquid K of mascara with fluidity. The coating liquid includes, as disclosed in Japanese Patent No. 5791424, a viscosity modifier 0.1 to 2 wt %, a film-forming agent 0.5 to 30 wt %, a pigment having an average diameter 1 mm or larger 0.5 to 30 wt %, dispersant 0.1 to 2 wt % and a surfactant 0.1 to 2 wt %, and the liquid to be used has a viscosity ranging from 2 to 10 Pa·s with a shear velocity of 3.83 s⁻¹, both measured at 25° C. with an EHD type viscometer.

At the upper part of the container 10, the neck portion 11 having a narrow cylinder-shaped opening 12 upward is integrally formed with the container. On the outer circumferential surface a screwed part 13 for fastening is formed in circumferential direction and the screwed part 13 is threadedly engaged with a screwed part 21 on the inner surface of the cap 20.

A squeezing body 25 is fitted to an opening 12 of the neck portion 11 of the container 10. The squeezing body 25 is made of a material with properties of flexibility and viscoelasticity, substantially formed in a cylindrical shape, and the diameter (width of the opening) of the squeezing body is gradually reduced from near the upper end (one end) towards the lower end (the other end). A ring-shaped flange 26 protrudes radially outward from the uppermost end of the squeezing body 25 and is fixed to the opening periphery of the neck portion of the container 10.

The applicator 30 includes a support shaft 31 and an application part 1, the application part 1 for holding the liquid is provided on a distal end of the support shaft 31. Specifically, a rod-like support 2 of the application part 1 is fittingly fixed in a mounting hole 31a bored at the distal end of the support shaft 31.

The application part 1 will be described with reference to FIGS. 2 through 5. As described above, the application part 1 includes a rod-like support member 2 and the brush part 3; the support member of the application part 1 is fittingly fixed in a mounting hole 31a bored at the distal end of the support shaft 31, and a plurality of fiber bundles 3A, made of a plurality of synthetic resin fibers 3a extending in the radial direction of the support member 2, are disposed on a circumferential surface of the radial direction and the axial direction of the support member 2.

In this embodiment, brush part 3 is provided point-asymmetrically at three positions on a radial circumferential surface of the support member 2.

The brush part 3 is prepared by planting fiber bundles 3A formed of synthetic resin fibers in implanting holes 2a of the support member 2; the implanting holes 2a are formed at plural positions on the circumferential and axial direction of the support member 2 and the fiber bundle 3A is planted in each implanting holes 2a to thereby form the brush part 3 having plural fiber bundles 3A disposed on a radial and axial direction of the support member 2. The outer diameter of the brush part 3 is preferably 6 mm to 8 mm, for example.

The support member 2 is formed of resins, such as polypropylene, polyacetal and polyoxymethylene, to have a diameter of 0.5 to 4.0 mm and a length of 10 to 30 mm. The fiber bundles 3A are planted by melting or adhesion to the support member 2.

Length of the synthetic resin fibers 3a planted to the support member 2A are 1.0 to 5.0 mm from the surface of the support member 2. Material used for the synthetic resin fibers for the brush part 3 are polyamide-based resin, such as 6,6 nylon, 6 nylon, 12 nylon, 6,10 nylon, and 6,12 nylon; polyolefin-based resin, such as polyethylene, and polypropylene; polyester-based resin, such as polyethylene terephthalate, polybutylene terephthalate, and poly trimethylene terephthalate.

Fibers having a diameter of 0.03 to 0.18 mm, more preferably 0.05 to 0.15 mm are used for synthetic resin fibers 3a because of appropriate elasticity and prevention of bending or breaking, where the diameter denotes the size of columnar part of the fibers the surface 3a1 of which are not tapered. The synthetic resin fibers 3a may have any one of cross sections of an ellipse, a star, a cocoon, a cross or a polygon.

The number of the assembled synthetic resin fibers 3a in a bundle, that is, a fiber bundles 3A, may be properly determined, and the number of fibers may preferably be 5 to 30 for a bundle which is to be implanted in a single planting hole 2a (See FIG. 2A). The number of fiber bundles 3A to be implanted can be set as needed; typically 5 to 20 places can be preferably adopted.

In the present embodiment, as shown in FIG. 3, fiber bundles 3A made of plural synthetic resin fibers 3a are implanted at three positions in the radial circumferential surface of the support member 2, and also implanted in the axial direction of the support member 2. That is, the fiber bundles 3A are provided on the circumferential surface of the support member so as to extend in three directions of the radial direction of the support member and further provided in the circumferential surface of the axial direction of the support member.

In the present embodiment, as shown in FIGS. 2 and 4, the fiber bundles 3A are implanted at nine positions in a row in the axial direction of the support member 2. The fiber bundles 3A are implanted accordingly at 27 positions in total in the radial circumferential surface and axial directions. The number of the fiber bundles 3A, implanted in the radial circumferential surface and axial directions, may be increased or decreased as needed, and not limited the number of 27.

As shown in FIG. 5A which is an enlarged schematic drawing, the synthetic resin fibers 3a forming the brush 3 include tapered fibers 3b each having diameter formed to be gradually smaller toward the tip and tapered fibers 3b, being specific synthetic resin fibers, on the tip part of which a tapered surface 3b1 is formed tapering toward the tip. The length X of the tapered surface 3b1 of the tapered fibers 3b is formed in a range of 0.5 to 4.0 mm from the tip of the synthetic resin fibers.

Here, the synthetic resin fibers are prepared such that a taper ratio, a percent ratio of defined by X/(X+Y), falls within a range between 10 to 80%, where X denotes the length of the tapered surface from the tip end of the synthetic resin fibers, and X+Y denotes the length of a mascara brush from the surface of a mascara brush head to the tip end of a synthetic resin fiber; that is, X+Y is the sum of the length Y of the non-tapered surface on which the tapered surface is not formed from the surface 2A1 (synthetic resin fiber planted surface) of the mascara brush support member 2 and the length X of the tapered surface. And the ratio X/X+Y is defined by (length X of the tapered surface)/(length X+Y from the tip of the synthetic resin fiber of the mascara brush to the mascara brush head surface).

The number of tapered fibers 3b is configured to occupy more than 80% of the total number of the synthetic resin fibers forming the brush. The brush may contain tapered fibers that are out of the range described above up to 30% of the total number of the synthetic resin fibers or may contain untapered fibers 3c up to 30%, as shown FIG. 5B. These fibers that are contained less than 30% in the brush are preferably of the same material and the same diameter as the tapered fibers 3b from the manufacturing view point.

As described above, the length X of the tapered surface 3b1 of the tapered fiber 3b is formed as to fall within a range from 0.5 mm to 4 mm from the tip end of the synthetic resin fiber such that each fiber is easy to enter between eyelashes. If the length of the length X of the tapered surface 3b1 is less than 0.5 mm, each fiber is difficult to enter between the eyelashes because of the short length of the tapered surface. If the length X of the tapered surface 3b1 exceeds 4 mm, bending strength of the fiber gets weakened and becomes smaller than that of the eyelashes, and as a result, this undesirably causes the synthetic resin fibers to fail to enter between the eyelashes. In addition, it undesirably becomes unable to curl both the eyelashes because the upper eyelashes are pushed up or the lower eyelashes are pushed down.

When the taper ratio of the tapered fibers is less than 10%, it is undesirable because the tapered fibers 3b may have larger bending strength, sweep away eyelashes and are hard to enter between each of the eyelashes. In contrast, when the taper ratio exceeds 80%, the fibers 3b may be turned down, or hard to enter deeply into the eyelashes, or may push up or lower the eyelashes, and resultantly curling up of the eyelashes with the brush becomes difficult; thus it is undesirable for use.

The brush part 3 is formed such that the number of the tapered fibers occupies at least 80% or more of the total fibers. When the number of the tapered fibers is less than 70% of the total number of the fibers, the tapered fibers 3b may undesirably fail to give a sufficient effect of tapering.

Thus configured brush part 3 containing a larger number of tapered fibers 3b allows the bending strength to be getting stronger from the tip part 3A1, which is the tip part in the radial direction of the support member 2, to downward to the support member as shown in FIG. 3, and accordingly to improve a feeling of use. That is to say, the tip part of the tapered fibers 3b are configured to easily enter between the eyelashes, when mascara applied. The bending strength can be made larger downwardly through the tapered surface 3b1 and a straight body 3b2, and the fibers can easily enter between the eyelashes one by one, overcoming the bending strength of the eyelashes. Consequently, the mascara liquid can be applied finely to each of the eyelashes and curling of the eyelashes firmly performed with pushing the upper eyelashes up or lower eyelashes down. Tapering of the fibers at the tip ends additionally allows to provide a soft touch to the root of the eyelashes and the skin and to prevent from excessively applying of the liquid.

The synthetic resin fibers 3a (the tapered fibers 3b) may be formed to have a curved surface 3d, as shown in FIG. 6A, which is concave being recessed along the axial direction or to have a flat face 3e on the tip end. As shown in FIG. 6B, a tapered surface 3b1 may be formed from the top to the lowest part of the fibers without the straight part 3b2 and may have a round top surface 3f. Further, as shown in FIG. 6C, an acute part 3g may be formed at the top end of the tapered fibers 3b.

As shown in FIG. 6D, in addition, a plurality of tapered faces 3j1, 3j2, and 3j3 may be formed on the synthetic resin fibers (the tapered fibers 3b). Dimensions of the tapered faces 3j1, 3j2, and 3j3 are determined as to meet the relationship of cross section ratios which are in a range of 0.8 to 0.9 at the top part 3k2 of the tapered face 3j1 and in a range of 0.2 to 0.4 at the top part 3k3 of the tapered face 3j2, while the cross section at the support member surface 3k1 of the synthetic resin fibers 3a (3b) shown in FIG. 6D to be 1.0, to form a tapered shape as a whole. The tapered face 3j1 may be formed to be a straight body 3b2 and the fiber may have two tapered faces 3j2 and 3j3.

Further, the synthetic resin fibers 3a may have a non-straight shape in which the axis of the fiber is bent, that is a crimped shape. The degree of bending 31t of the crimped fiber 31 is preferably three to four times as much as the diameter of the fiber. When tapering is performed to crimped fibers 31, the tapered face is preferably formed after the crimping processing is carried out to make the axis of the fibers curved.

Since features of eyelashes, such as density, length, thickness, may differ person to person, choosing the optimal fiber shape or tip-tapering shape adapting to each feature allows to improve a feeling of use of mascara.

FIG. 7 shows the surface of tapered synthetic resin fibers, the surface which has projected portions 3h and recessed portions 3i and an average depth t1 of the recessed portions (height from the top of the projected portions 3h to the bottom of the recessed portions) is formed to be in a range of 0.01 μm to 10 μm. When the average depth t1 is less than 0.01 μm, the tapered surface of the synthetic resin fibers is too smooth to maintain the liquid in the recessed portions 3i, and good coatability cannot be obtained. In contrast, when the average depth t1 of the recessed portions exceed 10 μm, the coatability is unpreferably lowered because the rigidity of the fibers decreases and liquid transfer is inhibited by excessive collection of the liquid at the recessed portions. Thus, the average depth t1 of the recessed portions 3i in a range of 0.01 to 10 μm preferably allows good retainability of the liquid and high rigidity of the fibers.

In addition, an average distance t2 between the projected portions 3h is set to be 10 to 70 μm. The average distance t2 less than 10 μm unfavorably causes the number of projected portions and the recessed portions to become large, the fiber surface to become rough, liquid separation from the recessed portions to be inadequate, and a skin touch to be uncomfortable. In contrast, the average distance t2 more than 70 μm undesirably causes to decrease the number of projected portions and the recessed portions and to reduce retainability of the liquid. As a result, the average distance t2 in a range of 1 to 70 μm achieves good retainability of the liquid and an excellent skin touch.

The projected portions 3h and recessed portions 3i on the fiber surface can be formed into rugged fiber surface by molding with a mixture of fine particles such as titanium dioxide. Thus prepared fibers are not preferable because the rigidity of fibers may decrease due to presence of foreign material, and particles may be detached as the brushes are being used. After blasting process with bombarding fine particles into an untapered fiber surface in order to form projected portions 3h and recessed portions 3i is performed, tapered surfaces are formed; this may likely cause the projected portions 3h and recessed portions 3i to be lost or the fibers to be broken at the recessed portions 3i. In contrast, when blasting process is performed after forming tapered surfaces, the tapered surfaces subject to heavy damage and become unsuitable for use to mascara brushes. Accordingly, a preferable manufacturing method will be described later to form the projected portions 3h and recessed portions 3i.

Synthetic resin fibers having a tapered surface are preferably made of polyamide-based resin, which is desirable in the manufacturing method described later. The fiber surface of the polyamide-based resin is easy to make the fiber in a semi-swollen state in a dissolving liquid, and it is possible to selectively peel off only the necessary portion with a polishing-rubbing member, and the projected portions 3h and recessed portions 3i having an arbitrary shape are easily formed. In addition, since polyamide-based resin has a high affinity for water, a mascara brush may be formed using all synthetic resin fibers including synthetic resin fibers having a tapered surface with a polyamide-based resin.

In the above embodiment, explained is that fiber bundles 3A formed of a plurality of synthetic resin fibers 3a are planted on a brush part 3 both in a radial circumferential surface and at plural positions in an axial direction of the support member by melting or adhesion.

The brush part 3 according to the present invention is not limited to the above case. For example, as shown in FIG. 8, the fiber bundles 3A composed of a plurality of synthetic resin fibers 3a may be disposed with a predetermined separation between metal wires 4A and 4B, and then the fiber bundles 3A (tapered fibers 3b) may be fixed by twisting the wires 4A and 4B. In addition, the number of metal wire rods may be two or more, such as 4A and 4B, and it may be formed with three or more wire materials. Also in the case of such a so-called twisted brush, plural fiber bundles 3a composed of a plurality of synthetic resin fibers 3a (tapered fibers 3b), extending in the radial direction of the wires 4A and 4B, may be disposed in the longitudinal direction (axial direction) of the wires 4A and 4B.

In the brush part 3 as shown in FIG. 8, a diameter D1 of the brush part 3 attached at the distal end of the support member 2 and a diameter D2 of the brush part 3 attached at the proximal end of the support member are formed to be nearly the same, and forms a columnar shape as a whole. As shown in FIG. 9, the diameter D 2 of the brush part 3 attached to the rear end side of the support member 2 is larger than the diameter D 1 of the brush part 3 attached to the front end side of the support member 2, which may form a conical shape as a whole. Furthermore, as a modified example, the support member 2 is not linear with respect to the axis but may be curved in an arc shape in accordance with the arrangement of the eyelashes.

An embodiment of a manufacturing method according to the present invention will be described with respect to FIGS. 10 through 12. Firstly a brush part 3 is formed by attaching bundles of a predetermined number of synthetic resin fibers 3a having a predetermined length onto the support member. The attachment of the fiber bundles is performed by adhesion or melting. Alternatively, synthetic resin fibers 3b may be placed between metal wires 4A and 4B, and then the wires 4A and 4B may be twisted to hold the fibers.

Followingly, the tapering processing of synthetic resin fibers 3a is performed by polishing and rubbing while the synthetic resin fibers are swollen using a soluble or swellable processing liquid. The processing liquid to be used differs for each type of synthetic resin fiber; for example, in a case of a polyester-based resin fiber, a sodium hydroxide aqueous solution is generally used, and in a case of a polyamide-based resin fiber, a mixed liquid of meta-cresol and a calcium chloride methanol solution is used.

When the brush part 3 is formed with crimped fibers, the tapered face is preferably formed after the crimping processing to synthetic resin fibers 3a is carried out to make the axis of the fibers curved.

The tapering processing of the synthetic resin fibers using this kind of processing liquid will be explained by taking a case of using nylon fibers, which is a polyamide-based resin, as an example.

In this processing method, as shown in FIG. 10 with reference numerals 50A, 50B, and 50C, a processing apparatus is used in which a plurality of solution baths are arrayed in series. When this processing method is employed, as respective processing liquid used for polishing/rubbing and cleaning of nylon fibers, meta-cresol or a saturated calcium chloride methanol solution is used as a soluble liquid of the first solution bath 50A, a mixed liquid of calcium chloride 15% (by weight) and methanol 85% (by weight) is used as a soluble liquid of the second solution bath 50B, and methanol (100%) is used as a cleaning liquid in the cleaning liquid bath 50C.

A polishing/rubbing member 52 for polishing and rubbing the nylon fibers to perform the tapering processing is provided in each of the first solution bath 50A and the second solution bath 50B. The polishing/rubbing member 52 includes polishing/rubbing blades 53 in a thin disk-shape, a rotational shaft 54 on which a plurality of the polishing/rubbing blades 53 are disposed in parallel at a predetermined interval, and a spacer 55 disposed between every polishing/rubbing blades 53. At least a part of the polishing/rubbing member 52 (the polishing/rubbing blades 53) is disposed to be submerged in the soluble liquid bath. The polishing/rubbing member 52 is also disposed in the cleaning bath 50C, but since the cleaning liquid is a non-swellable to nylon fibers, polishing/rubbing are hardly performed in this section.

In a case of processing the brush part 3 with this apparatus, firstly the brush part 3 is rotated, as indicated with an arrow R in FIG. 10; while the brush part 3 being moved up and down, as indicated with an arrow Y in FIG. 10, from an upper side of the polishing/rubbing body 52, and/or being moved forward and backward, as indicated with an arrow X in FIG. 10, and being moved from the paper deep side to the paper near side of FIG. 10 (left-right direction in FIG. 12), the brush part 3 is brought into contact with the polishing/rubbing blade 53 for a predetermined time.

In this situation, when the soluble liquid in the solution bath 50A adheres to the brush part 3, the surface of the nylon fibers get dissolved and swelled, and is scrubbed off by the polishing/rubbing blade 53.

That is, as illustrated in FIG. 12, since a combing blade 53a having a saw-tooth shape is formed on the polishing/rubbing blade 53, the polishing/rubbing blade 53 comes into contact with the fibers 3a of the brush part 3 to comb the fibers to repeat the dissolution and rubbing. At this time, by controlling a velocity of the up and down movement of the brush part 3 and the moving velocity thereof from the paper deep side to the paper near side in FIG. 10 (in the left-right direction in FIG. 12), the nylon fibers forming the brush part 3 are processed in a tapered shape. The tip part of the brush part 3 is formed in a tapered shape to become thinner toward the tip part.

The polishing/rubbing blade 53 may be fixed, but the polishing/rubbing blade 53 may be formed to rotate by the up and down movement of the brush part 3 and the movement of the brush part 3 from the paper deep side to the paper near side in FIG. 10 (in the left-right direction in FIG. 12). In addition, by the up and down movement of the brush part 3 and the lateral movement of the brush part 3 from the paper deep side to the paper near side in FIG. 10 (in the left-right direction in FIG. 12), the nylon fiber is processed in the tapered shape, but the nylon fiber may be processed in the tapered shape by moving the brush part 3 up and down, forward to backward, and rotating without the above lateral movement of the brush part 3.

Then, the brush part 3 is transferred to the second solution bath 50B, and moved up and down and rotated, and the brush part 3 is brought into contact with the polishing/rubbing blade 53 for a predetermined time.

The amount of polishing/rubbing of the brush part 3 in the second solution bath 50B is larger than that in the first solution bath, whereby the basic action is the same as that in the first bath 50A. That is, by controlling the speed of up and down movement and rotation of the brush part 3, nylon fibers 3a forming the brush part 3 is processed to become fibers 3b having a tapered surface 3b1 shown in FIG. 5A.

Finally, the brush part 3 is transferred to the cleaning bath 50C, and the fibers 3b are cleaned by making the brush part 3 come into contact with a polishing/rubbing member 52 for a predetermined time, which completes the processing of the brush part 3.

In the previously explained method, by controlling the movement (movement distance) of the brush part 3 in the upper-lower direction and the movement of the brush part 3 from the paper deep side to the paper near side in FIG. 10 (in the left-right direction in FIG. 12), a plurality of small projecting portions 3h are formed on a surface of the tapered surface 3b1 in an axial direction of the fiber. At this time, a recessed portion 3i is formed between the adjacent projecting portions 3h. That is, the projecting portion and recessed portion alternately and sequentially appear in the axial direction of the fiber having the small projecting portions 3h and recessed portions 3i.

The manufacturing method specified above allows to obtain a brush for cosmetic implements, having a brush part in which a plurality of synthetic resin fibers is conically tapered at the tip portion, and in which bundles of the fibers composed of a plurality of synthetic resin fibers are formed at least three positions on the radial circumference of a support member and further in an axial direction. The brush for cosmetic implements can be applicable to a mascara brush around eyes, and other brushes for such as eyeliners, nail polishes, lip sticks, and hair dyes.

A brush is studied which can prevent occurring of lumping of mascara or clamping of eyelashes or damage of skin. An experiments of use were performed on brushes whose fiber bundles include straight fibers, non-straight fibers (crimped fibers), and both fibers mixed.

Here, the straight fiber is a fiber whose axis is linear and the non-straight fiber (crimped fibers) is a fiber whose axis is curved. The experiments will be explained in detail, but the scope of the present invention is no limited thereby.

A brush part is prepared by implanting fiber bundles formed of 5 to 10 6-nylon fibers to implanting holes on a support member and fixed by adhesion. The implanting holes are formed on circumferential surfaces in a radial and an axial direction at 30 to 45 positions. The brush has 30 to 45 fiber bundles on circumferential surfaces in a radial and an axial direction at each implanting holes. The fiber bundles have a length of 3 mm from the surface of the support member, and the outer diameter of the brush is 8 mm.

The nylon fibers includes straight fibers with a tapering ratio of 10 to 30% and crimped fibers which are prepared by crimping processing to straight fibers with a tapering ratio of 15 to 35%, and a mixing ratio is set as shown in Table 1. The used fibers have a diameter of 2.5 mil (0.0635 mm approximately), 3.5 mil (0.0762 mm approximately) and 4 mil (0.1016 mm approximately), respectively. Samples are labeled with A to L, which are different in mixing ratio of used fibers having different shapes and diameters.

TABLE 1
Mixing ratio (%)	A	B	C	D	E	F	G	H	I	J	K	L
Fiber shape	Straight 2.5 mil	100	—	—	—	—	—	50	—	—	50	—	—
&	(About 0.0635 mm)
Fiber diameter	Straight 3 mil	—	100	—	—	—	—	—	50	—	—	50	—
	(About 0.0762 mm)
	Straight 4 mil	—	—	100	—	—	—	—	—	50	—	—	50
	(About 0.1016 mm)
	Crimped 2.5 mil	—	—	—	100	—	—	—	—	—	—	—	—
	(About 0.0635 mm)
	Crimped 3 mil	—	—	—	—	100	—	50	50	50	—	—	—
	(About 0.0762 mm)
	Crimped 4 mil	—	—	—	—	—	100	—	—	—	50	50	50
	(About 0.1016 mm)
Evaluation	Mascara lumps	B	A	B	B	A	B	A	A	A	A	A	A
	Clumped eyelashes	B	A	B	B	A	B	A	A	A	A	A	A
	Skin damage	A	A	B	A	A	B	A	A	A	A	A	A

The ingredients of the mascara under evaluation are: synthetic smectite 0.6 wt % as a viscosity modifier (Lucentite SWN (Trade Name), supplied by Co-op Chemical Co., Ltd.); xanthan gum 0.4 wt % as also a viscosity modifier (Ekogamu GM (Trade Name), supplied by DSP Gokyo Food & Chemical Co., Ltd.); ammonium acrylates copolymer 25 wt % as a film-forming agent (YodosolGH800F (Trade name), supplied by Akzo Nobel N.V.), cabon black having an average diameter of 0.2 mm 3 wt % as a pigment (LC902 (Trade Name), supplied by LCW); silica particle as a pigment 3 wt % (Silica Micro bead P-500 (Trade Name), supplied by JGC Catalysts and Chemicals Ltd.); polyoxyethylenebehenylether 1 wt % as a surfactant (BB-30 (Trade Name), supplied by Nikko Chemicals Co., Ltd.); nylon fibers 5 wt % (NFBR-10D-2T (Trade Name), supplied by DAITO KASEI KOGYO CO., LTD.); sterilizer with an optimal quantity (a mixture of ethylparaben, ethylparaben, phenoxyethanol); 1,3 butanediol 10 wt % and purified water for the remaining part.

The viscosity of the mascara ranges from 2 to 10 Pa·s with a shear velocity of 3.83 s⁻¹, both measured at 25° C. with an EHD type viscometer.

Brushes under test are evaluated with three items: occurrence of lumps of mascara, occurrence of clumps, and damage to the skin, when the mascara is applied to eyelashes. Lumps and clumps respectively means clots of dried mascara on the eyelashes and partial sticking of eyelashes together.

The occurrence of lumps is rated A when the number of lumps is two or less, and rated B when the number is 3 to 5. The occurrence of clumps is rated A when the number of places of clumps is 2 or less, and rated B when the number is 3 to 5. The skin damage is rated A if the skin does not hurt when combed with a brush, and rated B if hurts. The results of the evaluation are shown in Table 1. It is found that mixed cases give better results: less mascara lumps, less clumped eyelashes and less skin damage, compared to the brushes that are composed of only straight fibers or only non-straight fibers.

Claims

1. A brush for cosmetic implements, having a brush part that is attached to a support member,

wherein the brush part includes a plurality of synthetic resin fibers whose tip end has a conically-tapered surface, and

wherein a plurality of fiber bundles composed of a plurality of synthetic resin fibers is formed on a circumferential surface of the support member as to extend in three radial directions, and the fiber bundles are further formed on a circumferential surface in an axial direction of the support member.

2. The brush for cosmetic implements according to claim 1, wherein the support member is formed of twisted two or more metal wires, and wherein the synthetic resin fiber bundles are held between the wires and fixed to the support member by twisting the metal wires.

3. The brush for cosmetic implements according to claim 1, wherein the fiber bundle is mixedly formed with straight fibers and non-straight fibers.

4. A brush for cosmetic implements, having a brush part that is attached to a support member,

wherein the brush part includes a plurality of synthetic resin fibers whose tip end has a conically-tapered surface, and

wherein a plurality of fiber bundles composed of a plurality of synthetic resin fibers is formed on a circumferential surface of the support member as to extend in at least two radial directions and formed on a circumferential surface in an axial direction, and wherein the support member is formed of twisted two or more metal wires and the synthetic resin fiber bundles are held between the wires and fixed to the support member by twisting the metal wires.

5. The brush for cosmetic implements according to claim 4, wherein the plurality of synthetic resin fibers mixedly includes straight fibers and non-straight fibers.

6. The brush for cosmetic implements according to claim 1, wherein the brush part is formed on the whole area of the circumferential surface of the support member.

7. The brush for cosmetic implements according to claim 1, wherein a whole shape of the brush part is formed to be a columnar or a conical shape with a diameter decreasing toward a top portion.

8. A manufacturing method of the brush for cosmetic implements described in claim 1, the method comprising steps of:

a step in which synthetic resin fibers are bundled and a brush part is formed on the support member, and

a step in which the brush part is immersed in a solution bath containing a soluble liquid; the brush part is brought into contact with a polishing/rubbing blade for a predetermined time to dissolve and swell the surface of the synthetic resin fibers; and the tapered surface is formed by scrubbing off with the polishing/rubbing blade.

9. The brush for cosmetic implements according to claim 2, wherein the fiber bundle is mixedly formed with straight fibers and non-straight fibers.

10. The brush for cosmetic implements according to claim 2, wherein the brush part is formed on the whole area of the circumferential surface of the support member.

11. The brush for cosmetic implements according to claim 3, wherein the brush part is formed on the whole area of the circumferential surface of the support member.

12. The brush for cosmetic implements according to claim 4, wherein the brush part is formed on the whole area of the circumferential surface of the support member.

13. The brush for cosmetic implements according to claim 5, wherein the brush part is formed on the whole area of the circumferential surface of the support member.

14. The brush for cosmetic implements according to claim 2, wherein a whole shape of the brush part is formed to be a columnar or a conical shape with a diameter decreasing toward a top portion.

15. The brush for cosmetic implements according to claim 3, wherein a whole shape of the brush part is formed to be a columnar or a conical shape with a diameter decreasing toward a top portion.

16. The brush for cosmetic implements according to claim 4, wherein a whole shape of the brush part is formed to be a columnar or a conical shape with a diameter decreasing toward a top portion.

17. The brush for cosmetic implements according to claim 5, wherein a whole shape of the brush part is formed to be a columnar or a conical shape with a diameter decreasing toward a top portion.

18. The brush for cosmetic implements according to claim 6, wherein a whole shape of the brush part is formed to be a columnar or a conical shape with a diameter decreasing toward a top portion.

19. The brush for cosmetic implements according to claim 7, wherein a whole shape of the brush part is formed to be a columnar or a conical shape with a diameter decreasing toward a top portion.

20. A manufacturing method of the brush for cosmetic implements described in claim 2, the method comprising steps of:

a step in which synthetic resin fibers are bundled and a brush part is formed on the support member, and

a step in which the brush part is immersed in a solution bath containing a soluble liquid; the brush part is brought into contact with a polishing/rubbing blade for a predetermined time to dissolve and swell the surface of the synthetic resin fibers; and the tapered surface is formed by scrubbing off with the polishing/rubbing blade.