Patent Document

This application claims priority to Provisional Application Serial No. 60/179,578 filed on Feb. 1, 2000. 
    
    
     FIELD OF THE INVENTION 
     This invention relates to a method and apparatus for improved manufacture of elastic hair fasteners. More particularly, this invention relates to a method and apparatus wherein opposed ends of an extension of textile feedstock are adhesively secured to one another without metal joints so as to improve both the performance and appearance of elastic hair fasteners assembled therefrom. 
     BACKGROUND OF RELATED TECHNOLOGY 
     It is well known for individuals to use expandable, elastic hair fasteners for securement and decoration of one or more sections of hair. People desire such fasteners to accomplish multiple functions, such as elevating hair to satisfy safety or hygiene concerns or restraining hair in order to achieve a desired cosmetic appearance. Since such fasteners are inexpensive and reusable for an extended duration of time, users often purchase the fasteners in multiples so as to produce hairstyles of both simple and complex variations with minimal cost and effort. 
     The basic operation of the fastener requires the user to use a conventional fastener to hold the hair in place, tying the fastener around a portion of hair at least once. Thus, elastic hair fasteners of this type can perform many desired functions by incorporation of a seemingly simple design. A conventional elastic hair fastener is shown in FIG.  1 . Fastener  1  is generally a loop or lasso-shaped member formed from a predetermined length of textile feedstock such as braidstock  3 . Braidstock  3  incorporates a core  5 , made of rubber or similar elastomeric material, circumferentiallly sheathed by a continuous weave  7  of braided fibers or filaments (further shown in FIG.  1 B). The relation of the core and filaments in the braidstock is such that the filaments are arranged so that the core is wrapped thereby and the covered core thus obtained and not easily separated from the sheath. The fibers are generally selected from the group of thermoplastic materials including polypropylene and nylon, such materials having smooth finishes upon weaving and demonstrating superior strength characteristics and flexibility with minimal cost. 
     Braidstock  3  is cut into an extension having a predetermined length defined by a pair of opposed free ends (not shown). Braidstock  3  is formed into a loop by joining these opposed ends to form a butt joint  11  thereby. As further shown in FIG. 1A, joint  11  is traditionally secured by a metal clamp  13  formed from a sheet of metal having opposed edges  15 . Clamp  13  is circumferentially wrapped around an exterior surface of braidstock  3  so that edges  15  are adjacent one another so as to form a gap  17  therebetween. Clamp  13  provides additional securement of butt joint  11  therein so as to prevent disengagement of the hair fastener during use. 
     Although the metal clamp is well-suited for high-speed production, its incorporation into the hair fastener imposes a high cost on an otherwise inexpensive assembly. The metal clip further compromises the aesthetics of the hair fastener, because the tarnish of the metal stands out from the hair so as to draw attention to the elastic therewithin. In addition, such metal clamps are arranged circumferentially about the braid, leaving a gap between the ends thereof. This gap not only further deteriorates the appearance of the fastener, but also, more importantly, contributes to the discomfort of the wearer by pulling on the hair during adornment, removal and/or adjustment of the fastener therein. Hair that gets caught in the gap or between the metal clip and the braid gets damaged upon pulling of the fastener from the hair and creates enormous physical distress for the wearer. 
     In an attempt to obviate the problems inherent in conventional elastic hair fasteners as described hereinabove, a current method for assembling hair loops was developed wherein free ends of an extension of feedstock are manually adhered to one another. Other steps in the assembly process are likewise performed manually, such as holding the ends together manually until secure and manipulating the bond area manually until an acceptable aesthetic joint is realized. It is evident that such a method unnecessarily consumes resources of time, money and personnel, thereby eliminating the benefits realized by the fastener&#39;s cost effective design. 
     Since the manufacture of elastic hair fasteners is conducive to automation, and considering the savings of time and money associated therewith, it is desirable to provide a method of making elastic hair fasteners which eliminates the deleterious effects of metal clamps used as securement devices. It is further desirable to incorporate such a method into a manufacturing apparatus which retains the cost effectiveness of the hair fastener design while providing multiple hair fasteners having improved functional and aesthetic characteristics. 
     SUMMARY OF THE INVENTION 
     The present invention provides an improved method and apparatus for manufacturing elastic hair fasteners that eliminate the need for a metal clamp in the fastener assembly. The apparatus of the present invention that employs the inventive process is an incremental, automatic system that utilizes intricate mechanisms that are pneumatically actuated and controlled electrically. The apparatus feeds textile feedstock from a bulk supply along a feed track to a predefined staging position. Once the feedstock has reached this position, it is cut into an extension having a predetermined length and a pair of opposed free ends. The extension is rolled into a half circle, and one free end is positioned in a precise location. In this location, adhesive is applied to the free end, and the other half of the extension is thereafter rolled into a half circle, completing the loop. At this point, the two loop ends are positioned adjacent one another so as to be adhesively joined. Once joined precisely, a cold forming clamp is applied to the joined ends for a period of time necessary to fixture the assembly. After fixturing, the cold form clamp is released and a hot form clamp is applied for a period of time to shape the joint of the two ends into an aesthetically pleasing joint free of burrs and irregularities. Once formed, the assembly is complete and the loop is released into a bin for storage. 
     One advantage of the present invention is the elimination of metal clamps from elastic hair fastener assemblies. Elimination of the metal clamp from the manufacturing process reduces the costs associated with compiling the hair fastener assembly. Such cost reduction is desirable because the hair fastener itself is an inexpensive item, making it appealing to consumers for purchase in multiple quantities. 
     Another advantage of the present invention is to improve the function of the fastener by eliminating the metal clamp thereon. The production of a substantially smooth fastener without the sharp edges provided by metal clamps is desirable to avoid damage to hair caused by entanglement of the hair in such sharp edges. Distress to the wearer is avoided, thereby easing the effort required to don or remove the fastener. 
     Another advantage of the present invention is to improve the aesthetic quality of the fastener. Metal clamps used to secure feedstock ends often have a shiny, glossy or tarnished finish that stands out from the uniform color of the fastener and the color and texture of the hair within which it is used. The metal thereby detracts from the desired visual effect of the coiffure, instead drawing unwanted attention to the fastener when the wearer wishes to create an illusion that no assistance in the creation of the hair design was necessary. 
     Still another advantage of the present invention is the automated manufacture of elastic hair fasteners from a quantity of textile feedstock. Reductions in production time and expense are achieved by effecting sufficient securement of textile feedstock joints simply by application of an adhesive thereto. 
     A hair fastener assembly apparatus of the present invention was developed to adhesively join two opposed free ends of a length of textile feedstock. A machine takes and feeds straight feedstock, cuts the feedstock to a predetermined desired length extension, applies an adhesive to at least one free end thereof and fixes the free ends together to form a joint and resultant loop thereby. Each of a cold forming process and a hot forming process is executed on the joint so as to strengthen the joint and improve its aesthetic appearance. A cold forming step is required to fixture the loop ends, and a hot forming step is required thereafter to make the joint aesthetically pleasing. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 shows a conventional braided elastic hair fastener having a metal clamp assembled therewith. 
     FIG. 1A shows an exploded view of a metal clamp of a conventional braided elastic hair fastener of FIG.  1 . 
     FIG. 1B shows a cross-section taken along line A—A of the conventional braided elastic hair fastener of FIG.  1 . 
     FIG. 2 shows a schematic view of a hair fastener assembly apparatus used to perform an adhesive assembly method of the present invention after feeding of textile feedstock thereinto. 
     FIG. 3 shows a schematic view of the apparatus of FIG. 2 applying adhesive to a free end of feedstock while cutting the feedstock to an extension having a predetermined desired length. 
     FIG. 4 shows a schematic view of the apparatus of FIG. 2 during roll over of a first free end of feedstock and manipulation of a newly cut second free end at an opposed extremity thereof. 
     FIG. 5 shows a schematic view of the apparatus of FIG. 2 wherein an opposed free end of the feedstock is rolled and brought adjacent the first free end so that the ends are adheringly connected to one another so as to form a hair fastener loop thereby. 
     FIG. 6 shows a perspective view of a preferred embodiment of a hair fastener assembly apparatus of the present invention. 
     FIG. 7 shows an alternate perspective view of the hair fastener assembly apparatus of FIG.  6 . 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     In the present invention, at least one, but preferably a plurality, of elastic hair fasteners is manufactured according to a method in which adhesive replaces metal clamps in the securement of two opposed free ends of textile feedstock. In the present method, textile feedstock, which generally includes an elastomeric core having a circumferential sheath of polymeric fibers already disposed therearound, is fed into an assembly machine and cut into a plurality of extensions having a predetermined desired length. Each extension includes a pair of free ends at opposed extremities of the extension. A roll over tool is used to roll one of the ends so as to form a half-circle or half-loop from the extension. A pneumatically actuated dispenser deposits an amount of fast-curing adhesive on the rolled free end. A second roll over tool is actuated so as to roll the second end into alignment with the first end and complete the loop. The ends are brought into contact with one another so as to become adhesively secured to one another. A cold forming tool integrated into the machine is then used to perform a cold forming operation, thereby strengthening the joint formed between the two free ends. A hot forming tool performs a hot forming operation on the joint to produce an aesthetically pleasing joint, and the completed assembly is thereafter delivered to a storage bin. 
     Before processing the feedstock, several important factors must be considered regarding the feedstock design itself which have a large effect on the magnitude and consistency of the pull strengths achieved when using an adhesive assembly process. One important factor is the selection of fabric forming method that will be used to produce a textile sheath. Commonly used fabric forming methods include interlacing (i.e. weaving and braiding), interlooping (i.e. weft and warp knitting), bonding and tufting. As contemplated herein, the feedstock utilized in the present inventive process and apparatus utilizes a braid wherein two yarn systems are interlaced such that the paths of the yarns are diagonal to the fabric delivery direction, forming either a flat or tubular structure. Thus, other factors to consider include the number of filaments in the braid weave (normally 8, 16 or 32), the filament type and diameter, the filament denier, texture and shape (i.e., round, rectangular, etc.), the number of weaves, the density of the braid and the braid pattern. 
     Filament quality characteristics which are most important to achieve superior braids for use in a braided elastic hair fastener include short- and long-term weight uniformity, imperfections, weight variation, tensile properties, strength, lubricity and flexibility. Warp yarns closest to the edges of a fabric undergo more stress due to widthwise contraction of the fabric toward the center, causing linear angular displacement of these outermost yams. The straightness of individual warp yarns and their freedom to act independently as they pass through a weaving machine are important to good weaving performance. Yarns that are crossed and tangled cannot proceed without excessive stress and yams that are restricted will not weave at top performance. Attention to details in the yarn preparation processes and in the weaving process should yield good results, however, additional variables such as mean pull force, variation in the pull force, aesthetics in the assembly and ease of tacking down the braid fibers at the butt joint can also be evaluated to determine the optimum adhesive and braid material combination. 
     The core of feedstock material is preferably a conventional core rubber such as ethylene propylene diene monomer (EPDM). EPDM is a rubber that is capable of withstanding extensive temperature and moisture variations without cracking or deterioration. EPDM exhibits a high tensile strength, extreme elongation capabilities and can be exposed to numerous chemicals without any detrimental effect. The ethylene content of EPDM allows for highly predictable cure rates and physical properties achieved thereby, greatly reducing variability. EPDM cord stock will not exert a high amount of stress on the hair fastener joint in use. 
     Fasteners of the type contemplated herein are likely to be subjected to repeated application of heat from hair dryers, curlers and curling irons, hot blowers, diffusers and similar hair styling equipment. Similarly, the fasteners and the adhesively secured butt joints thereof will be exposed to various chemicals in the form of shampoos, conditioners, styling products (sprays, gels, mousses and the like), chlorine, perspiration, makeup and other environmental contaminants, to which the butt joints must remain resistant. The fastener will further be used for both short and long sections of hair of varying thickness, requiring superior strength and resiliency characteristics. 
     Feedstock for use with the present invention, therefore, desirably incorporates fibers made from synthetic thermoplastic filaments such as polypropylene and nylon. Polypropylene exhibits a combination of superior physical, chemical, mechanical and thermal properties that are important not only to the fabrication process but also to the long-term use of the resultant hair fastener. Polypropylene is a desirable material for fibers due to its light weight, superior working temperature and high tensile strength. Polypropylene is impact resistant and maintains a high compressive strength so as to retain stiffness and flex. It is a non-toxic material that is easily fabricated and therefore amenable to weaving in a variety of weave patterns. Polypropylene demonstrates excellent chemical resistance, which is desirable in hair fasteners due to the plethora of hair products, activities and environmental contaminants that the fastener will encounter while adorning the wearer&#39;s head. Moreover, polypropylene is resistant to staining and exhibits a low moisture absorption rate, assisting in the rapid transport of moisture away from the material and thus away from the fastener. It is also a tough and semi-rigid material that exhibits good heat resistance, excellent flexibility and a “living hinge” capability (meaning that in thin sections where the molecules are oriented, the material can be flexed almost indefinitely without failure). One of polypropylene&#39;s most important properties is its low price, which is due to a relatively simple synthesis from the low cost petrochemical propylene. 
     Another desired material for the fibers of the present invention is nylon. Nylon, like polypropylene, is a synthetic thermoplastic that can be woven in filament form. Nylon is stronger yet weighs less than any other commonly used fiber. It is elastic, resilient and responsive to heat settings, however, nylon fibers are also smooth, non-absorbent and dry quickly. Thus, dirt does not cling to the smooth fiber nor is the fiber weakened by chemicals and perspiration. Nylon melts at high temperatures and exhibits excellent toughness and fatigue properties as well as moisture, abrasion and chemical resistance. Nylon possesses good memory, and this ability to return to its original position after being deformed is a highly desirable characteristic for reusable fasteners. Nylon filaments in the feedstock offer higher pull strengths, even in assemblies where there is much less braid material available at the joint, making it easier to tack down the nylon frays at the butt joint to create an aesthetically pleasing interface. Any weave or filament design can be used in the present invention for either of nylon or polypropylene. 
     Although polypropylene and nylon are recognized herein as desirable fibers useful with the present invention, it is evident that any fiber suitable for the successful operation of the present invention apparatus and method may be used. Numerous other thermoplastic filaments can be utilized, including polyethylene and the like. The processability of a polymer, even in filament form, is highly dependent on its Theological properties, which have close relationship with its molecular weight, molecular weight distribution, temperature and shear rate. As a result, cure times may vary without affecting the overall operability of the apparatus or effectiveness of the disclosed method. 
     Selection of an appropriate adhesive is also important in the execution of the present inventive method. Selection of the proper adhesive is dependent upon numerous factors, such as the materials to be bonded, the end use of the adhered materials and the physical properties required thereby. In the automated environment contemplated herein, the adhesive solution must allow for very rapid processing (desirably 1 second cycle tine), resist repeated stretching and must adhere to the filament weave around the outer diameter of the elastic core. 
     In the hair elastic assembly process of the present invention, it is desirable to utilize surface insensitive ethyl cyanoacrylate adhesives, although any adhesive capable of bonding the selected material may also be employed. An example of such a desired adhesive is Loctite Prism 401, a product of Loctite Corporation of Rocky Hill, Conn. (wherein Loctite is a registered trademark of Loctite Corporation.). Such adhesives are general purpose, low viscosity, fast curing adhesives that are specifically formulated for difficult to bond substrates such as polypropylene and nylon weaves. Cyanoacrylate adhesives are therefore well suited for high-speed production due to their rapid curing times. In addition, cyanoacrylates are generally clear colorless liquids, thereby improving the appearance of the bondline after cure. The bond that is typically achieved with such materials exceeds the industry strength specifications, eliminates the potential for damage to hair and lowers the raw material costs. Examples of useful cyanoacrylate adhesives are described in U.S. Pat. Nos. 5,066,743, 5,288,794 and 5,314,562, all of which are incorporated herein by reference. Other types of adhesives, such as anaerobics, silicones, epoxies, acrylics, hot melts and the like, may also be useful. It is understood that this illustration of useful adhesives is merely illustrative, and other adhesive compounds amenable to use in the present invention may also be employed. 
     Now referring to the figures, in which like elements are identically numbered, FIGS. 2-5 show a schematic representation of an adhesive assembly machine used herein incorporating the present inventive process. 
     An adhesive assembly process of the present invention is initiated by loading a quantity of feedstock  20  in the direction of arrow A into an adhesive assembly apparatus  22 , described further hereinbelow. Adhesive assembly apparatus  22  includes plate-supported feed tracks  24 , which feed tracks guide feedstock  20  from an initial loading position to a subsequent staging position as shown in FIG.  2 . In the staging position, feedstock  20  overlays feed tracks  24  such that a free end  26  thereof lies adjacent a normally protruding stop  28 . 
     After feedstock  20  reaches the predetermined staging position, a first reciprocating member  30  imparts upward motion in the direction of arrow B to free end  26  such that a face  26   a  thereof lies within a plane normal to the plane in which face  26  was originally positioned (see FIG.  3 ). Simultaneously, a platen  38  having rounded edges  38   a  moves in a direction of arrow C so as to create a curved portion in feedstock  20  and thereby begin formation of the fastener loop. Platen  38  is in parallel alignment with feed tracks  24  so as to sandwich feedstock  20  therebetween. Downward movement of platen  38  brings platen  38  in communication with feedstock  20  so as to maintain tension therein. Platen  38  keeps feedstock  20  in a straight configuration while reciprocating member  30  forces free end  26  upward. 
     Also at this time, a first roll over tool  50  is actuated so as to have horizontal reciprocating motion. Roll over tool  50  includes curvature  50 a that corresponds to a rounded edge  38   a  of platen  38 . Roll over tool  50  slides toward platen  38  in the direction of arrow D so as to envelop free end  26  therebetween. Free end  26  of feedstock  20  is bent so as to form a curve conforming to the shape of curvature  50   a,  further forming the loop configuration of the hair fastener assembly. 
     At this point, a pneumatically actuated adhesive dispenser  34  having an air cylinder  35  coupled therewith moves vertically downward in the direction of arrow E. Dispenser  34  includes a chamber  34   a  for retention of a flowable adhesive therein and an adhesive applicator  36  that regulates the flow of the adhesive therethrough and thereby releases the adhesive in a predetermined desired quantity onto a substrate. As reciprocating member  30  brings free end  26  in alignment with adjacent applicator  36 , applicator  36  dispenses a predetermined desired quantity of adhesive on face  26   a  so as to wet the fibers present thereat. Such quantity is pre-selected according to the type of feedstock used. 
     As adhesive is applied to face  26   a,  a vertically reciprocating cutter element  40  supporting a cutting blade  42  thereupon moves vertically upward in the direction of arrow F through an aperture  44  in feed tracks  24  (see FIG.  3 ). Aperture  44  is located at a predetermined position so that blade  42  cuts feedstock  20  to form a feedstock extension  20 ′ having a second free end  26 ′ which defines a predetermined length of the extension. Feedstock  20  is desirably cut so that each of the pair of extension segments on either side of the butt joint is approximately the same length. Attention is given to cleanly cutting the feedstock to facilitate the assembly of the resultant hair fastener and to ensure that the length yields an abutting relationship of the free ends. 
     Referring now to FIG. 4, a second reciprocating member  46  is thereafter actuated in a vertical reciprocating motion in the direction of arrow G so as to impart upward movement to free end  26 ′ such that a face  26   a ′ thereon faces dispenser  34 . At this time, blade  42  is retracted from aperture  44 , and reciprocating member  30  is likewise retracted in the direction of arrow B′. 
     A second roll over tool  52  having reciprocating vertical motion is also provided in FIG. 5 that slides in a direction of arrow H. Roll over tool  52  also includes a curvature  52   a  defined on an interior surface thereof which corresponds to a rounded edge  38   a  of platen  38 . Roll over tool  52  slides toward platen  38  from an opposing side thereof so as to sandwich free end  26 ′ therebetween and complete the formation of a loop thereby. Each of reciprocating members  30  and  46  and each of cutting tool  40  and roll over tools  50  and  52  can be pneumatically actuated or otherwise directed by programmable logic controller, PC based controller or other means of executing machine logic. 
     It is evident that once roll over tool completes its migration with respect to feedstock  20 , free end  26  is in communication with free end  26 ′ and the flowable adhesive so as to be adheringly connected thereto, forming a butt joint  60  thereat. During this step, it is desirable to bond the fibers at joint  60  together and attain proper alignment thereat to achieve acceptable performance characteristics as defined hereinabove. 
     In a post assembly operation, joint  60  undergoes a cold forming operation (i.e. cold clamping) such as that performed by a pair of clamping jaws. The cold form of the joint forces the adhesive to be evenly distributed and ensures proper alignment thereat. The advantages of cold forming include improvement of joint strength without the application of heat, which is important to achieving aesthetically pleasing parts with acceptable strengths. The anticipated cold forming time ranges from 3-6 seconds when using cyanoacrylate adhesives. 
     After completion of the cold forming process, a hot forming process is executed on joint  60  so as to soften the material thereat, such as that performed with a pair of clamping jaws having heat applied thereto. The hot form accelerates the cure of the adhesive, spreads out adhesive and cleans up the joint aesthetics. The hot form cycle typically ranges from about 250° F. to about 400° F. and occurs for a duration of about 1 to 3 seconds. Each of the hot and cold forming processes is desirably carried out on assembly apparatus  22  so that the entire process is executed on a single piece of machinery. The newly created elastic hair fastener assemblies are thereafter unloaded from the apparatus and distributed a storage unit for further disposition. 
     Now referring to FIGS. 6 and 7, a preferred embodiment of assembly apparatus  22  of the present invention is illustrated. Assembly apparatus can include a series of several independent heads that share a common machine base and control system. Each head will perform all functions to assemble a single loop, yielding the maximum “up time” of the machine. Any head on the machine can be shut down without affecting the assembly of loops by the other heads. Although each head on the machine is preferably designed to accept a large diameter braid, additional machines can be designed to accommodate other diameters using the principles described herein. 
     An elongate piece of feedstock (not shown) is loaded in assembly apparatus  22  via a feed track having sections  24   a  (first section),  24   b  (second section) and  24   c  (third section) supported upon a base plate  25 . The feedstock is fed along the feed track until a free end thereof reaches an initial loading position at which a rake  27  is mounted upon a mounting block  29 . Rake  27  slidingly advances inward at an angle (desirably at approximately 45°) along a slide  31  supported by a slide support  33 . Rake  27  provides a plurality of teeth thereon which engage the feedstock and impart translating motion thereto so as to pull the feedstock along the feed track and thereby advance the feedstock to a staging position as shown and described hereinabove with respect to FIG.  2 . 
     At the staging position, the feedstock is cut by a cutting blade  42  that is reciprocally actuated by an air cylinder  43 . Cutting blade severs the feedstock to form a textile extension having a predetermined length. A free end of the feedstock is thereafter turned upward away from the feed track by a reciprocating thruster  35  having a pair of push-up members  30  and  46  in a goal post-type configuration. Members  30  and  46  are supported upright by a spring block  39  positioned adjacent a spacer bar  41 . One end of the feedstock may be upwardly lifted prior to the other end, or both ends may be lifted simultaneously depending upon the desired application of adhesive. 
     Opposing ends of the feedstock are thereafter rolled over by a pair of opposed roll-over tools  50  and  52 , each of which is supported on a mounting bar and actuated by a thruster  53  so as to effect linear displacement. Roll-over tools  50  and  52  are thereby actuated so as to capture the feedstock in a curvature thereof and thereby form a loop  70  as shown in FIG.  7 . 
     An actuating adhesive dispenser  34  retaining a quantity of adhesive therein is thereafter slidingly reciprocated toward loop  70  so as to dispense a predetermined amount of adhesive to either or both of the ends of the feedstock. The free ends of the feedstock are thereafter brought together so as to be adheringly secured to one another, thereby forming a butt joint  60  (shown in FIG. 5) on loop  70 . 
     Referring back to FIG. 6, after forming butt joint  60  and ensuring proper overlap of fibers thereat, a cold forming operation is performed in which a cold clamp block  63  is utilized. Cold clamp block  63  typically utilizes a pair of clamps, jaws or similar apparatus to compress the butt joint and strengthen the joint thereby. Similarly, the joint is thereafter subjected to a hot forming process as described hereinabove during which a gripper  65  including a set of clamps or jaws  67  grasps joint  60  therebetween and applies heat thereto supplied by a heater  69 . 
     An illustrative sequence of the present inventive process and the requisite time for its completion using a hair assembly apparatus of the present invention is provided below. It is emphasized that the times provided herein are merely an example of the efficiency with which the present process can be completed, and that these times can be affected by the selection of materials and adhesive as described thoroughly hereinabove. It is therefore understand that any or all steps may be modified in sequence or duration to adapt to different types of feedstock. 
     
       
         
               
             
               
               
               
             
               
               
               
               
             
           
               
                   
               
               
                 Example of Requisite Time to Perform Steps in Process for Manufacturing 
               
               
                 Elastic Hair Fasteners Using a Hair Fastener Assembly Apparatus 
               
             
          
           
               
                   
                 Sequence: 
                 Time 
               
               
                   
                   
               
             
          
           
               
                   
                 Feed and cut to length 
                 0.5 
                   
               
               
                   
                 Form loop 
                 1.0 
               
               
                   
                 Dispense adhesive 
                 1.0 
               
               
                   
                 Join ends 
                 0.5 
               
               
                   
                 Cold form 
                 5.0 
               
               
                   
                 Hot form 
                 1.0 
               
               
                   
                 Unload 
                 0.5 
               
               
                   
                 Total 
                 9.5 
                 seconds 
               
               
                   
                   
               
             
          
         
       
     
     The apparatus of the present invention, in performing the inventive process, is capable of taking braided stock from a box, feeding it, cutting it to length, bonding it and unloading a finished looped hair fastener into an outfeed chute for storage. Adhesive may be supplied to one or both ends of the braidstock extension, but is desirably only supplied to one side so as to avoid problems associated with excess adhesive. 
     The present invention provides a more aesthetically pleasing hair elastic that substantially eliminates the possibility for damaging or pulling hair. The hair loop assembly machine of the present invention also eliminates the need for any manual operation, which results in more consistently assembled and higher quality parts. This approach allows for the process to be automated, thereby achieving low cost production while enhancing the performance and appearance of the completed product. 
     Various changes to the foregoing described and shown methods and corresponding structures would now be evident to those skilled in the art. Accordingly, the particularly is closed scope of the invention is set forth in the following claims.

Technology Category: b