The present invention relates to a powder case, and more specifically, to a powder case where a powder chamber is integrated with a brush to directly transfer and apply powders on the brush by a powder supplying unit that is configured to penetrate through the powder chamber by an elevation operation, thereby applying a predetermined amount of powders on the brush and minimizing a waste of powders.
Reviewing a general configuration of a rouge powder case that is being currently sold in the city, a powder chamber is separated from a brush. This has been used by covering powders received in the powder case on the brush or spraying powders received in the powder case on the brush.
However, the related art has a problem in that a large amount of powders disappears in the air in the course of moving powders received in the powder case to the brush.
As such, there are problems in that the powders disappearing in the air fall at the circumference to contaminate the circumference or are inhaled in the interior of the body to damage health.
In addition to the related art, a product that the powder case is integrated with the brush has been known.
In the product, holes (or space) are formed in a bottom portion of the brush to apply powders through the holes by shaking the case or spouting air through the holes. However, the applied amount is different depending on the shaking strength, such that there is a problem in that it is inconvenient to use.
Further, in the related art, a case of stopping the holes for applying powders frequently occurs. In this case, a consumer strongly shakes the case to apply a larger amount of powders. Thereby, if the stopped holes are opened, there is a problem in that a large amount of powders gushed out at a time.
In addition, since a mechanism of the powder case according to the related art depends on gravity, the holes should face down to use this. In other words, when wearing powders below a jaw, the brush faces up, such that there is a problem in that it is difficult to apply powders.
The method for spouting powders using air has a problem in that it is very inconvenient to use since a large amount of powders disappear in the air and an applied amount of powders is very irregular.
Moreover, the related art has a problem in that it is difficult to receive the brush in the case (or cap) since a diameter of the unfolded brush is larger than that of the powder case due to the folded characteristic of the brush.
The present invention proposes to the above problems of the related art. It is an object of the present invention to provide a powder case that is easy to use by configuring a powder chamber and a brush in a body.
It is another object of the present invention to provide a powder case capable of easily opening and closing a cap by wearing powders using a brush and then receiving the brush in a case body.
It is still another object of the present invention to provide a powder case of directly moving and applying powders on a brush by a powder supplying unit that is configured to penetrate through a powder chamber by an elevation operation.
It is yet another object of the present to provide a powder case capable of applying a predetermined amount of powders on a brush to minimize a waste of powders and stably applying powders even in the state where the brush faces up.
In order to achieve the above objects, there is provided a powder case including: a case body; a powder chamber that is elevatably installed in the case body and includes a brush provided on an upper surface thereof; powder supplying units that supply powders inside the chamber to the brush side of the upper side when penetrating through the center of the powder chamber; and an elevation operating unit that elevates the powder chamber.
When the powder chamber rises, powders are loaded on the upper part of the powder supplying unit and when the powder chamber falls, powders loaded on the upper part of the powder supplying unit are supplied to the center of the brush.
The plurality of powder supplying units can be installed to simultaneously penetrate through the powder chamber.
In addition, the elevation operating unit is formed with a vertical guide groove that cuts the case body in a vertical direction and is installed with a lever to penetrate through the vertical guide groove in a direction from the outside to the inside, so that the powder chamber can be elevatably operated by the lever.
The elevation operating unit is formed with the vertical guide groove that cuts the case body in a vertical direction and is formed with guide projections on an outer surface of the powder chamber to be protruded to the outside of the vertical guide groove, so that an outer tub having a spiral guide groove formed in an inner diameter thereof and rotatably coupled with the outer diameter of the case body elevates the powder chamber therein when rotating, the spiral guide groove being coupled with the guide projection and guiding it.
Further, the plurality of guide projections are formed on the outer diameter of the powder chamber and the plurality of vertical guide grooves and the plurality of spiral guide grooves, which are coupled with the guide grooves, are formed in a circumferential direction.
The powder chamber may be formed with a sealing unit to seal a through hole on the upper surface to which the brush is coupled.
At this time, the powder chamber is configured of a plurality of chambers separately and each of the powder chambers may be separately provided with the brush, the lever, and the powder supplying unit.
Moreover, the elevation operation unit is coupled with a rotating handle that is rotatably installed at the lower part of the case body and is installed with a screw rotational shaft to penetrate from the center of the rotating handle to the upper part of the case body, so that the screw rotational shaft can rotate to be interlocked with the rotating handle to elevate the powder chamber.
In order to achieve the above objects, there is provided a powder case including: a case body; a powder chamber that is integrally formed in the upper part of the case body and includes a brush provided on an upper surface thereof; powder supplying units that supply powders inside the chamber to the brush side of the upper side while penetrating through the center of the powder chamber and elevating it; and an elevation operating unit that elevates the powder supplying unit.
When the powder supplying unit falls in a state where the powder chamber is fixed, powders are loaded on the upper part of the powder supplying unit and when the powder supplying unit rises, powders loaded on the upper part of the powder supplying unit are supplied to the center of the brush.
The plurality of powder supplying units can be installed to simultaneously penetrate through the powder chamber.
In addition, the elevation operating unit is formed with a vertical guide groove that cuts the case body in a vertical direction and is installed with a lever to penetrate through the vertical guide groove in a direction from the outside to the inside, so that the powder supplying unit is elevatably operated by the lever.
The elevation operating unit is formed with the vertical guide groove that cuts the case body in a vertical direction and is formed with guide projections extended to the powder supplying unit to be protruded to the outside of the vertical guide groove, so that an outer tub having a spiral guide groove formed in an inner diameter thereof and rotatably coupled with the outer diameter of the case body elevates the powder supplying unit therein when rotating, the spiral guide groove being coupled with the guide projection and guiding it.
Further, the plurality of guide projections may be formed on the circumference of the powder supplying unit and the plurality of vertical guide grooves and the plurality of spiral guide grooves, which are coupled with the guide grooves, may be formed in a circumferential direction.
The powder container may be formed with a sealing unit to seal a through hole on the upper surface to which the brush is coupled.
The present invention according to the above configuration configures the powder container and the brush in a body, making it possible to conveniently wear powders and reduce the amount wasted to transfer powders to the brush.
In addition, the present invention wears powders using the brush and then receives the brush in the case body, making it possible to easily open and close the cap.
The present invention directly transfers and applies powders to the brush by the powder supplying unit that is configured to penetrate through the powders chamber by the elevation operation, such that a predetermined amount of powders are applied on the brush, thereby making it possible to minimize the waste of powders, stably apply powders even in the state where the brush faces up, and increase the use convenience.
Hereinafter, exemplary embodiments the present invention will be described in detail with reference to the accompanying drawings.
As shown in the drawings, the powder case according to the first embodiment of the present invention is configured to include a case body 110, a powder chamber 130, a powder supplying unit 140, and an elevation operating unit 150.
The case body 110 is manufactured in a cylindrical shape whose lower side is sealed and upper side is opened and the bottom center thereof is formed with the powder supplying unit 140 in a pillar shape. At this time, the upper side of the case body 110 is detachably coupled with a separate cap 110′.
The powder chamber 130 is elevatably installed inside the case body 110 and the inner space sealed in the upper and lower surfaces thereof includes powders and the upper surface thereof is attached with the brush 120.
At this time, the upper and lower surfaces of the powder chamber 130 are formed with through holes 131 and 133 through which each of the powder supplying units 140 in a pillar shape penetrates.
When the powder supplying unit 140 penetrates through the center of the powder chamber 130, that is, the through holes 131 and 133, powders are loaded inside the chamber and supplied to the brush 120 side of the upper side thereof. Preferably, a circular pillar can be used. In addition to this, however, a pillar shape having a cross section in various shapes, such as a triangle, a quadrangle, etc., can be used.
At this time, an upper end of a pillar of the powder supplying unit 140 can be formed with a concave groove to easily load powders or can be attached with a separate brush 141 to cover and transfer powders.
As described above, the present invention loads powders on the upper part of the powder supplying unit 140 when the powder chamber 130 rises and supplies powders loaded on the upper part of the powder supplying unit 140 to the center of the brush 120 when the powder chamber 130 falls. Preferably, the powder supplying unit 140 is configured so that it penetrates through the powder chamber 130 and enters the middle part of the brush 120.
The elevation operating unit 150 for elevating the powder chamber 130 is provided. The elevation operating unit 150 is formed with a vertical guide groove 151 that cuts the case body 110 in a vertical direction and is installed with a lever 152 to penetrate through the vertical guide groove 151 in a direction from the outside to the inside. The elevation operating unit operates the lever 152 along the vertical guide groove 151 and interlocks it with the powder chamber 130 to elevate the powder chamber.
The present invention divides the plurality of powder supplying units 140 and disposes them in the case body 110 and can form a plurality of through holes so that the powder supplying units 140 simultaneously penetrates through the powder chamber 130.
The powder chamber 130 can be formed with a sealing unit (not shown) for sealing the through hole 131 on the upper surface with which the brush 120 is coupled. The sealing unit can be installed using rubber, membrane, etc., which are not shown in the drawings. This is operated to be opened and closed according to the advance and retreat of the powder supplying unit 140 and when the powder supplying unit 140 is out of the through hole, in particular, the through hole 131 of the upper surface, can prevent powders inside the powder chamber 130 from being leaked to the outside.
In the present invention, the plurality of powder chambers 130 are independently formed in the case body 110 and each of the powder chambers 130 may include the separate brush 120, elevation operating unit 150, and powder supplying unit 140.
As shown in the drawings, the powder case according to the second embodiment of the present invention is configured to include the case body 110, the powder chamber 130, the powder supplying unit 140, and the elevation operating unit 150.
The case body 110 is manufactured in a cylindrical shape whose lower side is sealed and upper side is opened and the bottom center thereof is formed with the powder supplying unit 140 in a pillar shape. At this time, the upper side of the case body 110 is detachably coupled with the cap 110′.
The powder chamber 130 is elevatably installed inside the case body 110 and the inner space sealed in the upper and lower surfaces thereof includes powders and the upper surface thereof is attached with the brush 120.
At this time, the upper and lower surfaces of the powder chamber 130 are formed with through holes 131 and 133 through which each of the powder supplying units 140 in a pillar shape penetrates.
When the powder supplying unit 140 penetrates through the center of the powder chamber 130, that is, the through holes 131 and 133, powders are loaded inside the chamber and supplied to the brush 120 side of the upper side thereof. Preferably, a circular pillar can be used. In addition to this, however, a pillar shape having a cross section in various shapes, such as a triangle, a quadrangle, etc., can be used.
At this time, an upper end of a pillar of the powder supplying unit 140 an be formed with a concave groove to easily load powders or can be attached with a separate brush 141 to cover and transfer powders.
As described above, the present invention loads powders on the upper part of the powder supplying unit 140 when the powder chamber 130 rises and supplies powders loaded on the upper part of the powder supplying unit 140 to the center of the brush 120 when the powder chamber 130 falls. Preferably, the powder supplying unit 140 is configured so that it penetrates through the powder chamber 130 and enters the middle part of the brush 120.
The elevation operating unit 150 for elevating the powder chamber 130 is provided. The elevation operating unit 150 is formed with a vertical guide groove 151 that cuts the case body 110 in a vertical direction and is formed with guide projections 153 on an outer surface of the powder chamber 130 to be protruded to the outside of the vertical guide groove 151, so that an outer tub 155 having a spiral guide groove 154 formed in an inner diameter thereof and rotatably coupled with the outer diameter of the case body elevates the powder chamber 130 therein when rotating, the spiral guide groove being coupled with the guide projection 153 and guiding it.
Herein, the plurality of guide projections 153 can be formed at the outer diameter of the powder chamber 130 and the plurality of vertical guide grooves 151 and spiral guide grooves 154, which are coupled with the guide projections 153, can be formed in a circumferential direction.
The present invention divides the plurality of powder supplying units 140 and disposes them in the case body 110 and can form a plurality of through holes so that the powder supplying units 140 simultaneously penetrates through the powder chamber 130.
The powder chamber 130 can be formed with a sealing unit (not shown) for sealing the through hole 131 on the upper surface with which the brush 120 is coupled. The sealing unit can be installed using rubber, membrane, etc., which are not shown in the drawings. This is operated to be opened and closed according to the advance and retreat of the powder supplying unit 140 and when the powder supplying unit 140 is out of the through hole, in particular, the through hole 131 of the upper surface, can prevent powders inside the powder chamber 130 from being leaked to the outside.
In the present invention, the plurality of powder chambers 130 are independently formed in the case body 110 and each of the powder chambers 130 may include the separate brush 120, elevation operating unit 150, and powder supplying unit 140.
The case body 110 is manufactured in a cylindrical shape whose upper and lower sides are opened, wherein the lower side is coupled with a rotating handle 156. At this time, the rotating handle 156 is rotatably coupled with the case body 110 side and the bottom center is formed with the powder supplying unit 140 that is configured of a screw rotational shaft 157.
The powder chamber 130 is elevatably installed inside the case body 110 and the inner space sealed in the upper and lower surfaces thereof includes powders and the upper surface thereof is attached with the brush 120.
At this time, the upper and lower surfaces of the powder chamber 130 are formed with through holes 131 and 133 through which each of the powder supplying units 140 configured of the screw rotational shaft 157 penetrates.
At this time, a thread, which is screw-connected with the screw rotational shaft 157, can be formed in at least any one of the through holes 131 and 133 of the upper and lower surfaces. When the power supplying unit 140 penetrates through the center of the powder chamber 130, that is, the through holes 131 and 133, it loads powders inside the chamber and supplies them to the brush 120 of the upper side and interlocks with the operation of the rotating handle 156 of the lower part to elevate the powder chamber 130 screw-connected on the screw rotational shaft 157.
At this time, an upper end of a pillar of the powder supplying unit 140 can be formed with a concave groove to easily load powders or can be attached with a separate brush 141 to cover and transfer powders.
As described above, the present invention loads powders on the upper part of the powder supplying unit 140 when the powder chamber 130 rises and supplies powders loaded on the upper part of the powder supplying unit 140 to the center of the brush 120 when the powder chamber 130 falls. Preferably, the powder supplying unit 140 is configured so that it penetrates through the powder chamber 130 and enters the middle part of the brush 120.
The elevation operating unit 150 for elevating the powder chamber 130 is provided. The elevation operating unit 150 is rotatably coupled with the rotating handle 156 at the lower part of the case body 110 and is formed with the screw rotational shaft 157 to be penetrated from the center of the rotating handle 156 to the upper part of the case body 110, and the screw rotating shaft 157 rotates interlocking with the rotating handle 146 to elevate the power chamber 130.
The powder chamber 130 can be formed with a sealing unit (not shown) for sealing the through hole 131 on the upper surface with which the brush 120 is coupled. The sealing unit can be installed using rubber, membrane, etc., which are not shown in the drawings. This is operated to be opened and closed according to the advance and retreat of the powder supplying unit 140 and when the powder supplying unit 140 is out of the through hole, in particular, the through hole 131 of the upper surface, can prevent powders inside the powder chamber 130 from being leaked to the outside.
As shown in the drawings, the powder case according to the fourth embodiment of the present invention is configured to include a case body 110, a powder chamber 130, a powder supplying unit 140, and an elevation operating unit 150.
The inside of the case body 110 in a cylindrical shape is provided with the powder chamber 130 At this time, the powder chamber 130 is integrally on the upper part of the case body 110.
The powder chamber 130 is elevatably installed inside the case body 110 and the inner space sealed in the upper and lower surfaces thereof includes powders and the upper surface thereof is attached with the brush 120.
At this time, the upper and lower surfaces of the powder chamber 130 are formed with through holes 131 and 133 through which each of the powder supplying units 140 in a pillar shape penetrates.
The lower part of the case body 110 is installed with the powder supplying unit 140. When the powder supplying unit 140 penetrates through the center of the powder chamber 130, that is, the through holes 131 and 133, powders are loaded inside the chamber and supplied to the brush 120 side of the upper side thereof. Preferably, a circular pillar can be used. In addition to this, however, a pillar shape having a cross section in various shapes, such as a triangle, a quadrangle, etc., can be used.
At this time, an upper end of a pillar of the powder supplying unit 140 can be formed with a concave groove to easily load powders or can be attached with a separate brush 141 to cover and transfer powders.
At this time, the upper end of the pillar of the powder supplying unit 140 is formed with a concave groove to easily load powders or the lower end thereof is formed with a circular support that contacts the inner diameter of the case body 110.
As described above, the present invention loads powders on the upper end of the powder supplying unit 140 when the powder chamber 130 falls in a state where the powder chamber 130 is fixed and supplies powders loaded on the upper end of the powder supplying unit 140 to the center of the brush 120 when the powder chamber 130 rises. Preferably, the powder supplying unit 140 is configured so that it penetrates through the powder chamber 130 and enters the middle part of the brush 120.
The elevation operating unit 150 for elevating the powder chamber 130 is provided. The elevation operating unit 150 is formed with a vertical guide groove 151 that cuts the case body 110 in a vertical direction and is installed with a lever 152 to penetrate through the vertical guide groove 151 in a direction from the outside to the inside, so that the powder supplying unit 140 is elevated by the lever 152.
The present invention divides and disposes the plurality of powder supplying units 140 and can form a plurality of through holes so that the powder supplying units 140 simultaneously penetrates through the powder chamber 130.
The powder chamber 130 can be formed with a sealing unit (not shown) for sealing the through hole 131 on the upper surface with which the brush 120 is coupled. The sealing unit can be installed using rubber, membrane; etc., which are not shown in the drawings. This is operated to be opened and closed according to the advance and retreat of the powder supplying unit 140 and when the powder supplying unit 140 is out of the through hole, in particular, the through hole 131 of the upper surface, can prevent powders inside the powder chamber 130 from being leaked to the outside.
As shown in the drawings, the powder case according to the fifth embodiment of the present invention is configured to include a case body 110, a powder chamber 130, a powder supplying unit 140, and an elevation operating unit 150. The inside of the case body 110 in a cylindrical shape is provided with the powder chamber 130 At this time, the powder chamber 130 is integrally formed on the upper part of the case body 110.
The powder chamber 130 is elevatably installed inside the case body 110 and the inner space sealed in the upper and lower surfaces thereof includes powders and the upper surface thereof is attached with the brush 120.
At this time, the upper and lower surfaces of the powder chamber 130 are formed with through holes 131 and 133 through which each of the powder supplying units 140 in a pillar shape penetrates.
The lower part of the case body 110 is installed with the powder supplying unit 140. When the powder supplying unit 140 penetrates through the center of the powder chamber 130, that is, the through holes 131 and 133, powders are loaded inside the chamber and supplied to the brush 120 side of the upper side thereof. Preferably, a circular pillar can be used. In addition to this, however, a pillar shape having a cross section in various shapes, such as a triangle, a quadrangle, etc., can be used.
At this time, an upper end of a pillar of the powder supplying unit 140 can be formed with a concave groove to easily load powders or can be attached with the separate brush 141 to cover and transfer powders and or the lower end thereof is formed with a circular support that contacts the inner diameter of the case body 110.
As described above, the present invention loads powders on the upper end of the powder supplying unit 140 when the powder chamber 130 falls in a state where the powder chamber 130 is fixed and supplies powders loaded on the upper end of the powder supplying unit 140 to the center of the brush 120 when the powder chamber 130 rises. Preferably, the powder supplying unit 140 is configured so that it penetrates through the powder chamber 130 and enters the middle part of the brush 120.
The elevation operating unit 150 for elevating the powder chamber 130 is provided. The elevation operating unit 150 is formed with a vertical guide groove 151 that cuts the case body 110 in a vertical direction and is formed with guide projections 153 extended to the powder supplying unit 140 to be protruded to the outside of the vertical guide groove 151, so that an outer tub 155 having a spiral guide groove 154 formed in an inner diameter thereof and rotatably coupled with the outer diameter of the case body elevates the powder supplying unit 140 therein when rotating, the spiral guide groove being coupled with the guide projection 153 and guiding it.
At this time, the plurality of guide projections 153 can be formed at the circumference of the powder supplying unit 140 and the plurality of vertical guide grooves 151 and spiral guide grooves 154, which are coupled with the guide projections 153, can be formed in a circumferential direction.
The present invention divides and disposes the plurality of powder supplying devices 140 and can form a plurality of through holes so that the powder supplying devices 140 simultaneously penetrates through the powder chamber 130.
The powder chamber 130 can be formed with a sealing unit (not shown) for sealing the through hole 131 on the upper surface with which the brush 120 is coupled. The sealing unit can be installed using rubber, membrane, etc., which are not shown in the drawings. This is operated to be opened and closed according to the advance and retreat of the powder supplying unit 140 and when the powder supplying unit 140 is out of the through hole, in particular, the through hole 131 of the upper surface, can prevent powders inside the powder chamber 130 from being leaked to the outside.
The present invention according to the above configuration forms the powder chamber 130 and the brush 120 in a body, making it possible to conveniently wear powders and reduce the amount consumed to transfer powders to the brush 120 and wears powders using the brush 120 and then, receives the brush in the case body, making it possible to easily open and close the cap 110′.
In addition, powders are directly transferred and applied to the brush 120 by the powder supplying unit 140 that is configured to penetrate through the powder chamber 130 by the elevation operation to uniformly apply powders on the brush 120, making it possible to minimize the waste of powders, stably apply powders even in the state where the bush faces up, and increase the use convenience.