The present invention relates to hair care products and more particularly, relates to a hair clip that is particularly suited for curly hair and configured for increasing hair volume and root lift.
There are a wide number of hair accessory products commercially available and tailored to perform different functions. For example, one class of hair accessories is hair clips. As is known, hair clips generally comprise clasps for holding hair in place. They are often made from metal and/or plastics and sometimes feature decorative fabric.
Within the hair clip class, there are many different types of hair clips and these clips are used in different settings. For example, some hair clips are designed to be worn all day, while there are other hair clips that are only intended to be used during a hair treatment and more particularly, are used at home or a hair salon after the hair is washed and treated with hair products, such as shampoo, conditioner and the like.
As is also known, curly hair is often considered to be more challenging and harder to manage. There are therefore many products that are commercially marketed that are directed to treating and controlling curly hair, including products meant to increase hair volume, etc. Some of these products are in the form of hair clips that are designed to lift a curl grouping (of hair) in an effort to increase hair volume. Traditionally, these clips were in the form of a pair of flat jaws that are biased to allow the jaws to move between an open position in which the jaws are separated for receiving hair and a closed position in which the jaws are seated against one another. While these clips have some degree of effectiveness, there is a need for an improved hair clip that is configured to lift a hair grouping.
A hair clip, particularly for curly hair, includes a first curved jaw having a proximal end portion and a curved distal end portion; and a second curved jaw coupled to the first jaw. The second curved jaw has a proximal end portion and a curved distal end portion. An axle is coupled to the proximal end portions of the first and second curved jaws, thereby permitting the first and second curved jaws to pivot relative to one another between an open position and a closed position. The clip also has a biasing element disposed between the proximal end portions of the first and second curved jaws. The biasing element applies a biasing force to both the first and second curved jaws such that in a rest position, the first and second curved jaws are in the closed position. The curved nature of the two jaws serves to lift a curl grouping away from the scalp, thereby maintaining the curl grouping and increase hair volume, etc.
As described herein and illustrated in the figures, the first and second jaws 110, 200 are biased with a biasing element 300. The illustrated biasing element 300 is in the form of a torsion spring having a coiled portion 302 and a first leg 304 and a second leg 306. The first and second legs 304, 306 are spaced apart from one another with an angle being defined therebetween. As discussed below, the first leg 304 is in contact with and applies a biasing force to the first jaw 110 and the second leg 306 is in contact with and applies a biasing force to the second jaw 200. The torsion spring 300 ensures that in the rest position, the first and second jaws 110, 200 are closed relative to one another (i.e., the hair clip 100 is in the closed position) and in order to open the first and second jaws 110, 200 relative to one another, the user must overcome the biasing force of the torsion spring 300 resulting in pivoting of the first and second jaws 110, 200, whereby the torsion spring 300 is compressed.
The first jaw 110 is preferably an integral piece that can be made from different materials (e.g., metal or plastics) and by different techniques (e.g., casting or molding). The first jaw 110 has a first (proximal) end 111 and an opposing second (distal) end 113. At the first end 111, the first jaw 110 includes a first body portion 120 and a second body portion 130, in the form of an extension (elongated finger), extends outwardly from the first body portion 120. As shown, the second body portion 130 can be tapered toward the second end 113 and in particular, the second body portion 130 can be an inwardly tapered structure resulting in the second body portion 130 being narrower at the second end 113 than the opposite first end 111.
Also, as shown in the side elevation view of
The first body portion 120 includes first and second spaced walls 140, 142 with an open space 141 defined therebetween. The first and second spaced walls 140, 142 extend outwardly from a base surface 145 that extends therebetween and is part of the first body portion 120. The first and second spaced walls 140, 142 can be formed perpendicular to the base surface 145 and parallel to one another. The first and second spaced walls 140, 142 can have any number of different shapes and in the illustrated embodiment, the first and second spaced walls 140, 142 are generally triangular in shape. Along an underside of the base surface 145, a first leg 304 of the tension spring 300 is seated and in particular, the underside can contain a recessed channel for receiving and containing the first leg 304.
The second jaw 200 is preferably an integral piece that can be made from different materials (e.g., metal or plastics) and by different techniques (e.g., casting or molding). The second jaw 200 has a first (proximal) end 211 and an opposing second (distal) end 213. At the first end 211, the second jaw 200 includes a first body portion 220 and a second body portion, in the form of a pair of extensions (fingers) 235, extends outwardly from the first body portion 220.
Unlike the single finger structure of the first jaw 110, the second jaw 200 has the pair of fingers 235 that are spaced apart from one another. As shown in the figures, the spacing between the pair of fingers 235 is such that the extension (finger) 130 of the first jaw 110 can be received therein between the pair of fingers 235. Unlike the tapered extension 130, each of the extensions 235 has a substantially uniform width along its length.
Also, as shown
The extensions 235 come together at a junction 240 which then leads to the first portion 210.
The second jaw 200 also includes a pair of upstanding protrusions or tabs 250 that act as stops as described below. The pair of tabs 250 are located at or proximate the junction 240 and are upwardly curved in a direction away from the extensions 235. The pair of tabs 250 are spaced apart from one another with the space defined therebetween being sized and shaped to receive the extension 130 of the first jaw 100. The portion of the extension (finger) 130 that extends through the space between the tabs 250 is a proximal end portion that is closer to the first portion 120 than the distal end 113 of the extension 130.
The degree of curvature (the slope) of the tabs 250 is greater than the degree of curvature (slope) of the extensions 235 and can be selected such that the height of the tabs 250 is greater than the height of the extensions 235. In other words, the distal end of the tabs 250 is above (slightly) the distal ends of the extensions 235. The tabs 250 also limit the movement of the first jaw 100 in that in the closed position (rest position), the first jaw 100 contacts the tabs 250.
The first body portion 120 includes first and second spaced walls 140, 142 with an open space 141 defined therebetween. The first and second spaced walls 140, 142 extend outwardly from a base surface 145 that extends therebetween and is part of the first body portion 120. The first and second spaced walls 140, 142 can be formed perpendicular to the base surface 145 and parallel to one another. The first and second spaced walls 140, 142 can have any number of different shapes and in the illustrated embodiment, the first and second spaced walls 140, 142 are generally triangular in shape. Along an underside of the base surface 145, the first leg 304 of the tension spring 300 is seated and in particular, the underside can contain a recessed channel for receiving and containing the first leg 304.
Similarly, the first body portion 220 includes first and second spaced walls 222, 224 with an open space defined therebetween. The first and second spaced walls 222, 224 extend outwardly from a base surface 225 that extends therebetween and is part of the first body portion 120. The first and second spaced walls 222, 224 can be formed perpendicular to the base surface 225 and parallel to one another. The first and second spaced walls 222, 224 can have any number of different shapes and in the illustrated embodiment, the first and second spaced walls 222, 224 are generally triangular in shape. Along an underside of the base surface 225, a second leg 306 of the tension spring 300 is seated and in particular, the underside can contain a recessed channel for receiving and containing the second leg 306.
The first and second legs 304, 306 of the tension spring 300 applies biasing force to the first portions 120, 220 of the first and second jaws 110, 200 respectively. This biasing force repels the first portions 120, 220 from one another.
When the first jaw 110 is mated with the second jaw 200, the first and second spaced walls 222, 224, are disposed between the first and second spaced walls 140, 142 of the first body portion 120 of the first jaw 110. The first and spaced walls 222, 224 can pivot relative to the first jaw 110 and the first and second spaced walls 140, 142.
An axle 400 passes through holes formed in the first and second spaced walls 222, 224 and enters axially aligned holes formed in the first and second spaced walls 140, 142. The axle 400 passes through the center opening of the tension spring 300. The axle 400 further couples the first and second jaws 110, 200 to one another and also allow for the controlled pivoting of the two jaws 110, 200 relative to one another.
The curvature of the extension 130 and the curvature of the two extensions 235 are selected such that in the closed position, the distal ends of the extension 130 are aligned and lie at least substantially within the same perpendicular plane in one embodiment.
As shown in
From the side view shown in
First, the hair 10 is cleansed and hydrated using conventional products, such as shampoo and conditioner, etc. The hair 10 is then typically at least partially dried as by using a towel (towel drying).
Once the hair clip 100 is in the desired location and the hair grouping 10 which is intended to be lifted from the scalp 20, the force being applied to the jaws 110, 200 is removed (i.e., the user releases the proximal ends of the jaws 110, 200) and this results in the jaws 110, 200 moving back toward the closed position due the biasing force of the tension spring 300 (
The hair clip 100 thus maintains the hair in an upright position as the hair grouping 10 dries and thus, the hair clip 100 is thus configured to increase volume and optimize hair definition and create root lift.
According to one exemplary embodiment, the hair clip 100 is positioned at the root of the curl and the hair clip 100 holds the hair grouping 10 up while it dries. Once removed, the result is increase volume at the roots of the curls.