Graphene polymer composites for hair styling tools and appliances

Abstract

A hairstyling assembly comprising the main components of a handle and a barrel and bristles having a graphene material composite for retaining energy and is electrically conducting static electricity from a head of hair through the bristles and barrel and handle to ground.

Claims

1. A hairstyling apparatus, comprising: a handle configured to be gripped by a hand of a user; a barrel mounted to said handle; and a plurality of bristles extending from said barrel, said bristles configured to engage hair of the user; wherein said handle, said barrel, and said bristles comprise graphene; wherein said graphene provides an electrically-conductive pathway between said plurality of bristles, said barrel, and said handle such that static electricity generated by engagement of said bristles with the hair is dissipated to the hand via said hairstyling apparatus; wherein said handle comprises a coating including said graphene; and wherein said coating has a thermal conductivity is in the range of six to eight Watts per meter-Kelvin.

2. The hairstyling apparatus of claim 1, wherein said handle further comprises a polymer substrate covered by said coating.

3. The hairstyling apparatus of claim 1, wherein said barrel is formed of a composite, said composite comprising a polymer and said graphene.

4. The hairstyling apparatus of claim 3, wherein said polymer comprises polyoxymethylene.

5. The hairstyling apparatus of claim 3, wherein said composite has a thermal conductivity of four to eight Watts per meter-Kelvin.

6. The hairstyling apparatus of claim 1, wherein said bristles are formed of a composite, said composite comprising a nylon and said graphene.

7. The hairstyling apparatus of claim 6, wherein said nylon comprises Nylon 46 and/or Nylon 66.

8. A hairstyling apparatus, comprising: a handle comprising first graphene particles; a barrel mounted to said handle and comprising second graphene particles; a plurality of bristles extending from said barrel, said bristles comprising third graphene particles; and an electrically-conductive pathway extending between said handle and said bristles, said electrically-conductive pathway comprising said first graphene particles, said second graphene particles, and said third graphene particles; wherein said barrel is formed of a composite, said composite comprising a polymer and said second graphene particles; and wherein said composite has a thermal conductivity is in the range of four to eight Watts per meter-Kelvin.

9. The hairstyling apparatus of claim 8, wherein said handle further comprises a substrate and a coating covering at least a portion of said substrate; and wherein said coating comprises said first graphene particles.

10. The hairstyling apparatus of claim 9, wherein said substrate comprises a polymer.

11. The hairstyling apparatus of claim 8, wherein said second graphene particles comprise graphene powder and graphene nanoplatelets.

12. The hairstyling apparatus of claim 8, wherein said third graphene particles comprise graphene powder and graphene nanoplatelets.

13. The hairstyling apparatus of claim 8, wherein said bristles further comprise a nylon material.

14. The hairstyling apparatus of claim 8, wherein, with said handle held by a hand of a user and said bristles engaged with hair of the user, said electrically-conductive pathway dissipates static electricity from the hair to the hand.

15. A hairstyling apparatus, comprising: a handle configured to be gripped by a hand of a user; a barrel mounted to said handle; and a plurality of bristles extending from said barrel, said bristles configured to engage hair of the user; wherein said handle, said barrel, and said bristles comprise graphene; wherein said graphene provides an electrically-conductive pathway between said plurality of bristles, said barrel, and said handle such that static electricity generated by engagement of said bristles with the hair is dissipated to the hand via said hairstyling apparatus; wherein said barrel is formed of a composite, said composite comprising a polymer and said graphene; and wherein said composite has a thermal conductivity is in the range of four to eight Watts per meter-Kelvin.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Other advantages of the present invention will be readily appreciated, as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings wherein:

(2) FIG. 1 is a perspective view of the hairstyling assembly.

(3) FIG. 2 is a section view of the hairstyling assembly.

(4) FIG. 3 is a section view of the barrel of the hairstyling assembly.

(5) FIG. 4 is a side view of the bristle tree assembly.

DESCRIPTION OF THE ENABLING EMBODIMENT

(6) Referring to the Figures, wherein like numerals indicate corresponding parts throughout the several views, a hairstyling assembly 20 of the type for styling hair is generally shown in FIG. 1. This styling device is known as a hairbrush. Other types of hairstyling assembly 20 may include, but are not limited to all types of brushes, hair dryers, diffuser attachments, flat irons, hair curlers, hair clips, hair pins, barrettes, headbands, haircutting combs, detangling combs and brushes, hot rollers, and velcro rollers.

(7) The device, generally indicated in FIGS. 1 and 2, includes a handle 22 for holding while styling hair, having a cylindrical shape and extending along a center axis A. The handle 22 has a distal end 24 that extends through a grip section 26 and into a cup-shaped end 28 being radially larger than the grip section 26. The handle 22 presenting a hanger hole 30 extending transversely through the distal end 24 for storage or usage functions, e.g., storage by a hook or looping a cord through the hole 30 for fastening around a person's wrist. The handle 22 has a bore 32 extending along the center axis A from the cup-shaped end 28.

(8) A barrel 34 of the styling device is retained in the cup-shaped end 28 of the handle 22 and axially aligned with the center axis A and extending to an open end 36. FIG. 3 shows the barrel 34 having a wall 38 that is defined by an interior 40 and an exterior 42 and surrounding the center axis A. The wall 38 of the barrel 34 having a plurality of apertures 44 forming a honeycomb pattern mutually in an offset relationship to one another. Alternatively, the apertures 44 can be arranged in other such patterns, for instance, where the ovals are lined in a block grid pattern or diagonal grid pattern, or instead elongated parallel apertures 44, that extend the length of the barrel 34. The preferred shape of the apertures 44 is an oval for optimal airflow, venting, and heat distribution, but can also be other shapes, such as for example, triangles, squares, hexagons, and other geometric type shapes.

(9) A bristle tree assembly 46, shown in FIG. 4, including a rod 48 with a mounting section 50 and a bristle section 52. The mounting section 50 of the rod 48 retained in the bore 32 of the handle 22. A plurality of bristles 54 are anchored to the bristle section 52 of the rod 48 and extend radially from the bristle section 52 of the rod 48. The bristles 56 extend outwardly past the interior 40 of the barrel 34 and through the apertures 44 to the exterior 42 of the barrel 34. The diameter of the apertures 44 are dimensioned such that the total cross-section of the plurality of bristles 54 extending through a single aperture 44 only fills a fraction of the aperture 44 cross-section. A top cap 58 being cup-shaped and covering the open end 36 of the barrel 34 to close off the open end 36 of the barrel 34. The top cap 58 can also be provided with a bore 32 for receiving the bristle section 52 of the rod 48 so that the rod 48 is coaxially supported with respect to the handle 22.

(10) The handle 22 a molded polymer, and is characterized by a coating 60 disposed on the handle 22. The coating 60 comprises, Propane and being a % volume of 25˜30 VM&P Naphtha and being a % volume of 25˜30 Heptane and being a % volume of 13˜15 N-Butane and being a % volume of 5˜10 Xylene and being a % volume of 5˜10 Methyl Ethyl Ketone and being a % volume of 1˜5 Methyl n-Amyl Ketone and being a % volume of 1˜4 Ethylbenzene and being a % volume of 1˜2 N006-010-P graphene powder and being a % volume of 7 Alkyl Sulphonate and being a % volume of 2˜3 Benzenepropanamide,N,N′-1,6-hexanediylbis [3,5-bis(1,1-dimethylethyl)-4-hydroxy and being a % volume of 0.05˜0.2.

(11) The graphene polymer based thermal coating 60 can be applied to the substrate surface of any polymer. The coating 60 transforms the surface of the polymer into having a thermal conductivity of about 6-8 Watts per meter Kelvin (W/mK), a surface resistivity of 1×10.sup.4˜10.sup.6, and increased mechanical and tribological strength. The paint base can also have different finishes such as a rubber finish, leather finish, suede finish, metallic finish, faux finish, plaster finish, texture sand finish, sandstone finish, flat finish, and satin finish. Other suitable paint bases including polyurethane paint, elastomer paints, and other rubberized and plastic paint coatings may be used.

(12) The barrel 34 comprises: Polyoxymethylene POM and being a % volume of 77˜87 N006-010-P graphene powder and being a % volume of 9˜19 N002-PDR nano graphene platelets and being a % volume of 0.5˜1 Alkyl Sulphonate and being a % volume of 2˜3 Benzenepropanamide,N,N′-1,6-hexanediylbis [3,5-bis(1,1-dimethylethyl)-4-hydroxy and being a % volume of 0.05˜0.5.

(13) The POM graphite polymer composite transforms the polymer into having a thermal conductivity of about 4-8 Watts per meter Kelvin (W/mK), and a surface resistivity of 1×10.sup.4, as well as, increased qualities of higher tensile and mechanical strength and improved antibacterial properties. POM is the preferred polymer base for the graphene polymer composite, but can be substituted by nylon, polypropylene, ABS, and other like polymer based materials. Alkyl sulphonate is the preferred antistatic agent. Ionic antistats of cationic compounds, quaternary ammonium, phosphium, or sulfonium salts, and nonionic compounds, including sodium salts of sulfonates, phosphates, and carboxylic acids, can replace the alkyl sulphonate. Nonionic antistats including glycerol esters of fatty acids, and ethoxylated teriary amines, can also replace alkyl sulphonate. N002-PDR nano graphene platelets is preferred, but can be replaced with graphene oxide. Other additives can also be added into the current invention including, antioxidants, thermal stabilizers, antimicrobial agents, flame retardants, colorants, lubricants, clip agents, and radiation stabilizers.

(14) The rod 48 comprises of any type of conductive material, such as, aluminum, iron, steel which is preferably rust-proof, or a composite plastic with conductive qualities.

(15) The bristles 56 comprise: a material chosen from the material group of Nylon wherein the material is Nylon 46 or Nylon 66 and being a % volume of 86˜96 N006-010-P graphene powder and being a % volume of 1.5˜10 N002-PDR nano graphene platelets and being a % volume of 0.5˜1.0 Alkyl Sulphonate and being a % volume of 2˜3 Benzenepropanamide,N,N-1,6-hexanediylbis [3,5-bis(1,1-dimethylethyl)-4-hydroxy and being a % volume of 0.05˜0.5.

(16) The graphene nylon polymer composite transforms the polymer into having increased thermal conductivity by transferring the heat energy form the initial point of contact down and throughout the entire bristle 56 of the styling device and therefore preventing structural failure in a localized area of the bristle 56. Static dissipation is reduced to a surface resistivity of 1×10.sup.6˜10.sup.9, as well as, increased qualities of higher tensile and mechanical strength and improved antibacterial properties.

(17) The percentage of graphene nano platelets dispersion varies upon the level of static dissipation desired contrasted with the level of mechanical stiffness desired for the bristle 56. Graphene Oxide (GO) can also be introduced into the formula as a partial substitute for graphene nanoplatelets to increase the flexibility of the bristles 56.

(18) Alkyl sulphonate is the preferred antistatic agent for the bristle 56 formula. Ionic antistats of cationic compounds including quaternary ammonium, phosphonium, or sulfonium salts, and nonionic compounds, including sodium salts of sulfonates, phosphates, and carboxylic acids, can replace the alkyl sulphonate. Nonionic antistats including glycerol esters of fatty acids, and ethoxylated teriary amines, can also replace alkyl sulphonate.

(19) Tourmaline powder can be used as an additive by emitting anions to help eliminate moisture form the hair. Other additives can also be added into the current invention including, antioxidants, thermal stabilizers, antimicrobial agents, flame retardants, colorants, lubricants, slip agents, and radiation stabilizers. The top cap 58 is molded in one piece from plastic/polymer material and coated with the coating 60.

(20) The graphene and antistatic agent is for retaining energy and for electrically conducting static electricity from a person's hair the bristles 56 and barrel 34 and the handle 22 to ground.

(21) The general characteristics, particle size distribution and physical sizes of the N002-PDR Nano Graphene Platelets are as follows in Tables 1-3 (Data retrieved from Angstron Materials Technical Data Sheet, revision date Apr. 1, 2014).

(22) TABLE-US-00001 TABLE 1 General Characteristics of the N002-PDR Nano Graphene Platelets PARAMETER SPECIFICATIONS Visual Fluffy, Light Powder Color Match Standard, Black Moisture  ≤0.5% Solids ≥97.90% True Density ≤2.20 g/cm.sup.3 Specific Surface Area 400 m.sup.2/g-800 m.sup.2/g Carbon by wt % ≥95.00% Hydrogen by wt %  ≤2.00% Nitrogen by wt %  ≤0.50% Oxygen by wt %  ≤2.50% Ash by wt %  ≤2.50%

(23) TABLE-US-00002 TABLE 2 Particle Size Distribution of the N002-PDR Nano Graphene Platelets PARAMETER SPECIFICATIONS MT10  3.30 um-3.90 um MT50  8.00 um-10.00 um MT90 17.00 um-20.00 um

(24) TABLE-US-00003 TABLE 3 Physical Sizes of the N002-PDR Nano Graphene Platelets PARAMETER SPECIFICATIONS Average Lateral Dimension ≤10.00 um (x & y) Average Through-Plane ~1.0-1.2 nm (as estimated Dimension (z) by BET and particle size distribution data)

(25) The general characteristics, particle size distribution and physical sizes of the N006-010-P Nano Graphene Platelets are as follows in Tables 4-6 (Data retrieved from Angstron Materials Technical Data Sheet, revision date Aug. 14, 2012).

(26) TABLE-US-00004 TABLE 4 General Characteristics of the N006-010-P Nano Graphene Platelets are Fine Greyish-Black Carbon in Powder Form PARAMETER SPECIFICATIONS Visual Homogeneous; No Aggregation Color Match Standard Greyish-Black Moisture  ≤1.20% Solids ≤98.80% True Density ≤2.20 g/cm.sup.3 Specific Surface Area 21 m.sup.2/g Carbon by wt % ≤97.00% Hydrogen by wt %  ≤0.70% Nitrogen by wt %  ≤0.50% Oxygen by wt %  ≤1.50% Ash by wt %  ≤1.50%

(27) TABLE-US-00005 TABLE 5 General Characteristics of the N006-010-P Nano Graphene Platelets are Fine Greyish- Black Carbon in Powder Form PARAMETER SPECIFICATIONS MT10  4.00 um-8.00 um MT50 10.00 um-14.00 um MT90 23.00 um-27.00 um

(28) TABLE-US-00006 TABLE 6 General Characteristics of the N006-010-P Nano Graphene Platelets are Fine Greyish-Black Carbon in Powder Form PARAMETER SPECIFICATIONS Average Lateral Dimension ≤14.00 um (x & y) Average Through-Plane ~10.0-20.0 nm (as estimated by a Dimension (z) Dye Absorbing Method and particle size distribution data)

(29) Please note that the composites described in the present invention include, but are not limited to, compounded polymers such as PP, POM, LDPE, HDPE, LLDPE, ABS, PA6, PA46, PLA, Nylons, UHMWPE, and TPEs.

(30) Obviously, many modifications and variations of the present invention are possible in light of the above teachings and may be practiced otherwise than as specifically described while within the scope of the appended claims.