Simultaneous-access surfaces for reel-flange fasteners

Information

  • Patent Grant
  • 6598825
  • Patent Number
    6,598,825
  • Date Filed
    Monday, January 29, 2001
    23 years ago
  • Date Issued
    Tuesday, July 29, 2003
    21 years ago
Abstract
A flange design for spools and reels may be provided from molded materials such as plastics. Improved strength, stiffness, fracture resistance, energy absorption, and toughness may be provided by appropriate design of corrugations extending substantially radially from a hub or core portion toward a rim portion. Spools and reels may be produced from Styrene plastics, olefinics such as polyethylene and polyprophelene, and may have tubes formed from the same or different materials. Flanges may be designed to crush near a rim or to be stiff near a rim. Likewise, portions of a flange may be designed to buckle, fracture, or otherwise fail sufficiently to absorb energy, while protecting a spool from excessive fracture or distortion. Likewise, portions of the flange may be designed to fail while others nearby do not, in order to protect against catastrophic failure (e.g. extensive separation). Thus, whether a tube is integrally formed with a flange or attached to a flange by fasteners or bonding, the impact load typically tested by drop testing a loaded flange (wire-wrapped flange) may be survived by designing wall thickness, corrugation dimensions, and angles to selectively balance distortion, fracture, toughness, or stiffness of various portions of a spool or reel.
Description




BACKGROUND




1. The Field of the Invention




This invention relates to spools and reels for receiving stranded materials, and, more particularly, to novel systems and methods for producing plastic flanges for reels and spools as take-up of electrical wire during manufacture.




2. The Background Art




Spools and reels have suffered from a lack of intelligent application of technology for many years. Spools date back hundreds if not thousands of years. Wooden spools and reels have been used in the textile industry as well as various electrical industries for many years with almost no innovation in their structures. Some use of plastic materials began a few decades ago. Nevertheless, manufacturing techniques continue to fall short of implementing all of the principles of engineering that are available.




Manufacturing techniques tend to focus on the simplicity of manufacture, and the simplicity of design, rather than the optimization of strength, weight, stiffness, non-catastrophic failure modes, and the like. Some of these latter considerations have been found to be significant in the manufacture and use of plastic spools and reels. Accordingly, developments by Applicant have provided improved methods for providing spools and reels having substantially reduced weight with improved stiffness and cost. Moreover, failure modes are available to provide “graceful degradation” of performance rather than catastrophic failure of spools and reels in situations such as the dropping of loaded reels or spools.




Spools and reels are used in many industries. However, in the wire and cable industry, the comparative weight of stranded material on a reel or spoon is greater than others of similar size in other industries. Fracture of flanges near an outer diameter thereof is common if dropped. Likewise, due to the conventional shapes of central tubes (hubs, cores, etc.), the junctions with flanges are not inherently resistant to fracture from impact loads caused by dropping. Dropping from a working bench is common for reels and spools. Manufacturing processes for manufacturing reels and spools, as well as manufacturing processes for wire and other stranded materials, typically compels smooth circumferential edges at the outermost diameter of a flange. Accordingly, a spool not retained on an arbor during use (using the wire, rather than manufacturing and taking up the wire) may roll easily across any flat surface. Thus, while a spool or reel is considered tare weight in shipping wire and cable, and a disposable item whose cost is to be minimized a spool or reel must function reliably and durably during its entire useful life.




Otherwise, a substantial length of stranded material may be damaged beyond use. The material held on a spool or reel having a value of a few dollars may itself have a value of one thousand times the cost of a spool. A value two orders of magnitude greater than that of the spool is routine for wire of common usage.




STATE OF THE ART




Stranded materials, upon manufacture, are typically taken up directly onto a reel or spool. The take-up spool or reel receives the strand directly from the last step in the manufacturing process. Thereafter, the filled spool is effective for storage and handling purposes. Upon sale or distribution, the spool is often placed on an arbor, either alone or with other spools, for convenient dispensing of the linear or stranded material. Linear or stranded materials include electrical wire whether in single or multiple strands and cable (comprising multiple wires), rope, wire rope, hose, tubing, chain and plastic and rubber profile material (generally any polymeric or elastomeric extruded flexible material).




In general, a host of elongate materials as diverse as pharmaceutical unit dose packages, fiberoptic line and log chains are stored on spools. Likewise, ribbon, thread and other stranded materials are wrapped on spools.




The requirement for a spool in the manufacture and handling of wire is substantially different from spools in the textile industry. For example, the weight of wire is several times the weight of thread or rope. The bulk of wire, which translates to the inverse of density, is substantially lower for wire than for hose, tubing or even chain.




Meanwhile, most spools are typically launched on a one way trip. The collection and recycling of spools is hardly worth the effort, considering that their materials are not easily recyclable.




In the art, a typical spool has a tube portion extending between two flange portions positioned at either end of the tube portion. A spool may have a rounded rim or rolled edge at the outermost diameter. This rim serves structural as well as aesthetic and safety purposes. Spools may be manufactured in a variety of tube lengths. Each flange is fitted by some fixturing to one end of the tube and there retained. Details of spools are contained in the U.S. Pat. No. 5,464,171 directed to a mating spool assembly for relieving stress concentrations, incorporated herein by reference.




The impact load of a spool of wire dropping from a bench or other work surface to a floor in a manufacturing environment is sufficient to fracture the spool in any of several places. Fracture may damage wire, preclude removal, or release the wire in a tangled, useless mass.




Spools may break at the corner where the tube portion meets the flange portion or may fracture at an engagement portion along the tube portion. Spools may break near the corner between the flange and the tube portion where a joint bonds or otherwise connects the tube portion to the flange portion.




Spools and reels experience significant breakage during drop tests when manufactured in styrene or styrene-based plastics such as ABS. Polyolefins are very tough materials. Tough means that a material can tolerate a relatively large amount of straining or stretching before rupture. By contrast, a material which is not tough will usually fracture rather than stretch extensively. As a result, when a reel of wire is dropped, the energy of impact breaks the spool.




Polyolefins, by contrast, may actually be drawn past yielding into their plastic elongation region on a stress-strain chart. Polyolefins thus elongate a substantial distance. The result is that olefinic plastics will absorb a tremendous amount of energy locally without rupture. Thus, the wire on a spool which has been dropped does not become a tangled mat of loops.




Given their toughness, olefinic parts will bend, strain, distort, but usually not break. Nevertheless, olefinic plastics are not typical in the art of wire spools. Polyolefin parts are not bonded into multi-piece spools. However, lack of a solvent is one problem, lack of a durable adhesive is another. Therefore, any spool would have to be manufactured as unit of a specific size. The inventory management problem created by unique spools of various sizes is untenable, although the cost of some olefinic resins is lower than that of styrene-based resins.




Moreover, the cycle time of molds directly related to material properties is usually much faster for styrene-based resins. The designs available use wall thicknesses which result in warpage as well. All these factors, as well as others, combine to leave olefinic resins, and bonded parts made therefrom, largely unused in the spool industry.




In drop tests, a spool may be dropped axially, radially or canted off-axis. In a radial drop, spools that break typically fail near the middle of the length of the tube. In axial drops, flanges may separate from tubes in failed spools. In an off-axis drop, flanges typically fracture, and may separate from tubes, releasing wire.




Large spools are typically called reels in the wire industry. Heavy-duty reels of 12 inches in diameter and greater (6 feet and 8 feet are common) are often made of wood or metal. Plastic spools of 12-inch diameter and greater are rare and tend to be very complex. The rationale is simple. Inexpensive plastics are not sufficiently strong or tough to tolerate even ordinary use with such a large mass of wire or cable wrapped around the spool.




Moreover, large flanges for reels are very difficult to manufacture. Likewise, the additional manufacturing cost of large spools is problematic. High speed molding requires quick removal after a short cycle time. Flanges are typically manufactured to have very thick walls. Increased thicknesses directly lengthen cycle times. Thus, designs do not scale up. Therefore, the flanges have very slow cooling times and molding machines have low productivity in producing them.




Styrene plastic is degraded by recycling. That is, once styrene has been injection molded, the mechanical properties of the resulting plastic are degraded. Thus, if a spool is recycled, ground up into chunks or beads and re-extruded as part of another batch, the degradation in quality can be substantial. Olefinic plastics improve over styrene-based plastics in that olefinic plastics can be completely recyclable. The mechanical properties of an olefinic plastic are virtually identical for reground stock as for virgin stock.




In reels, a 12-inch diameter unit is instructive. Such a spool is usually manufactured of wood. Nevertheless, a plastic spool in 12-inch diameter may also be manufactured with a pair of plastic flanges holding a layered cardboard (paperboard) tube detained therebetween. The flanges are typically bolted together axially to hold the tube within or without a circumferential detent as with wooden reels.




The reels have an additional difficulty when they are dropped during use. The flanges do not stay secured. The flange and tube are often precarious wooden assemblies held together by three or more axial bolts compressing the flanges together. The tube is prone to slip with respect to the flanges, breaking, tilting or otherwise losing its integrity under excessive loads. Such loads result from the impact of dropping onto a floor from a bench height or less. For the largest reels, rolling over or into obstacles or from decks during handling is more likely to be the cause of damage.




Very large cables, having an outside diameter up to several inches is taken up during manufacturing on a very large reel, from two feet to eight feet in diameter. The current state of the art dictates wooden reels comprised of flanges capturing a barrel-like tube of longitudinal slats therebetween. The two flanges are held together by a plurality of long bolts extending therethrough.




Wooden reels are not typically recyclable. A splinter or blemish in a reel can damage insulation on new cable or wire wrapped therearound at the manufacturing plant. Damaged insulation destroys much of the value of a reel of cable or wire. That is, the wire must be spliced, or may have damage extending over several wrapped layers of wire. Splices segmenting the original length of wire wrapped on the reel add costs in labor, reliability, service and the like.




Wood cannot be recycled and reconstructed cost effectively. In addition, the plurality of bolts and nails must be removed with other related metal hardware. The reels do not effectively burn without the labor investment of this dismantling operation.




Also, a wooden reel that is slightly out of adjustment, damaged, or broken, is problematic. A broken reel leaves a large area splintered to damage wire insulation. A reel which is loose will tilt and twist as the slats shift with respect to the flanges.




Steel reels tend to be more frequently recyclable. However, each must be returned in its original form to be reused. Thus, the bulk of transfer is as large as the bulk of original shipment, although the weight is less. Also, steel is heavy, subject to damage by the environment such as by stains, rust, peeling of paint, denting, accumulation of coatings or creation of small burrs on surfaces and corners. For example, when a reel is rolled over a hard surface, sharp objects, grit or rocks tend to raise small burrs on the outer edge of the flange. Similarly, contact with any sharp or hard object can raise burrs on the inside surfaces of the flanges.




As with wooden reels, only to a greater extent, a burr on a steel reel tends to act like a knife, slicing through insulation and ruining wire. Perhaps the most difficult aspect of burrs is that they are hardly detectable at sizes which are nevertheless highly damaging to insulation. Of course the weight and cost of steel reels is another factor in the difficulty of employing them for delivery of cable.




What is needed is a design for large (12 inches greater diameters) and small diameter (typically 6½-inch outside diameter) plastic spool flanges, which can tolerate the energy of being dropped when fully wrapped with wire. In addition, even in the standard styrene-based plastic spools, a better design is desired. What is needed in large reels of from a foot to eight feet approximately in outside flange diameter is a reel which is dimensionally stable, maintains structural integrity in service and during accidental dropping, which will not fracture or separate at a flange if it is dropped, and which is economically recyclable.




In a large reel, on the order of two to eight feet in diameter, what is needed is a lightweight, high-strength reel. The reel should not tend to damage wire when scratched, gouged, or otherwise having a burr raised on any key surface. Similarly, a large reel should be resilient enough that it does not maintain a permanent set, such as a steel reel will, when damaged. A plastic reel should be formed in a design that resists fracture and of a material which is tough. The material should be flexible enough that a burr will not damage insulation. A large reel should be recyclable. Recycling is most efficient if a reel can be reground near the site of use. Empty reels are more voluminous than they are heavy.




Moreover a design is needed that provides improved toughness by virtue of design, regardless of the toughness of the material. Catastrophic failure of reels and spools limits their applicability within the wire and cable industry. The risk of losing the use of the stranded material held thereon is not to be risked for the cost of using plastic spools and reels.




BRIEF SUMMARY AND OBJECTS OF THE INVENTION




In view of the foregoing, it is a primary object of the present invention to provide spools and reels and a method of designing them that will optimize strength, stiffness, fracture, distortion, toughness, and so forth at various locations within the flanges for survival of drop tests.




It is an object of the invention to provide various flange designs that can absorb shock or impact loads without completely fracturing.




It is an object of the invention to provide a design of, and method for designing, flanges of spools and reels having controlled fracture and controlled distortion in order to optimize survival of flanges and the integrity of the flange-to-tube transitions in configurations of spools having minimum weight and highest produceability in molding outputs.




It is an object of the invention to provide selective distortion, stiffness, and fracture of a flange in order to protect the integrity of a core or hub region of the flange.




It is an object of the invention to provide an eccentric application of impact loads transmitted from a rim toward a core region of a flange connecting to a tube portion, whether the tube is initially formed integrally or separately from the flange.




It is an object of the invention to provide multiple regions within the web of a flange, with the regions adapted to provide differing material properties, including different sections, moments of inertia, stiffness, strength, toughness, fracture-resistance, fracture-susceptibility, and the like.




It is an object of the invention to provide increased stiffness in the web while employing thinner walls, yet such that impact loads will not separate a rim and web from a core region of a flange, but maintain mechanical integrity of the flange especially in the tube transition region.




The invention solves this multiplicity of problems with flanges for plastic spools and reels formed in a multi-piece structure preferably by molding from olefinic, ABS, styrenic, and other plastics. Some of the designs may be made tough, even when manufactured of styrene-based plastics. The designs are particularly well adapted to manufacture using molded polyethylene and polypropylene or similar olefinic plastics regardless of tube (core) retention methods.




The structures and methods of the invention apply to spools and reels of all sizes. However, a structure that can be injection molded in a 6½-inch flange diameter may have to be roto-molded (tumble-molded) to produce an eight foot diameter spool or reel. Consistent with the foregoing objects, and in accordance with the invention as embodied and broadly described herein, an apparatus and method are disclosed, in suitable detail to enable one of ordinary skill in the art to make and use the invention.




In one presently preferred embodiment of an apparatus in accordance with the invention, a central tube or core section may be disposed between two flanges. Construction of the core and flange joints may be done in accordance with various approaches known in the art, as well as those articulated in U.S. Pat. No. 5,464,171, incorporated herein by reference.




Nevertheless, a tube may be completely hollow, ribbed or corrugated, itself. Alternatively, tubes may be arranged to fit within cavities formed in flanges, or to fit outside a sleeve protruding inwardly from a flange, or both at once. In certain embodiments, a flange and tube may be molded in a single piece with a mating tube and associated flange being molded in another piece. The two pieces may then be bonded together by a suitable means to provide a complete spool or reel.




Hybrid spools and reels may be formed using different materials for flanges than for tubes (cores). In other embodiments, a single material may be used for both flanges and tubes assembled from two or more parts. In one presently preferred embodiment, a cardboard tube may be adapted to fit over sleeves protruding from integrally formed flanges extending therefrom.




In one embodiment, flanges may be corrugated to provide a multiplicity of beneficial features. Thickness of walls, more complete closure of cavities (on all sides but one, for example), selective fracture resistance and fracture susceptibility, stiffness, strength, rigidity, a moment of inertia, a section, and so forth may be affected.




Corrugations may be arranged in a spoke-like configuration extending radially from a core or a hub portion of a flange. Alternatively, corrugations may extend radially at uniform or non-uniform circumferential angles. Corrugations may extend circumferentially between orthogonal surfaces thereto or surfaces non-orthogonal thereto in order to optimize weight, strength, stiffness, toughness, and other significant functionality.




Corrugations may terminate in selective angles with respect to tangents to the hub (core) portion, and at different selected angles with respect to tangents to a rim or outer circumference of a flange. Moreover, an angle of sweep measured between a tangent of a corrugation edge proximate a core and such an angle measured proximate a rim may differ by any suitable number of degrees. Accordingly, corrugations may be formed to direct loads radially between a hub and rim portion of a flange.




Alternatively, corrugations may be arranged to preclude direct transfer of loads normal to any tangents to a hub, rim, or both. Loads may include compression, tension, shear, bending, and so forth. Corrugation surfaces may be designed to provide a selected strength, stiffness, and toughness at any location within a flange. Corrugations may provide axial loading to retain stranded material, even after substantial damage to a flange. Moreover, the balance between strength, stiffness, and toughness may be designed specifically to be different at different locations within a flange. Accordingly, flanges may be designed specifically to address loading caused by different types of falls, a major source of damage in use.




Eccentric and tangential interception of corrugations by a hub of a flange may be designed to promote absorption of energy of an impact, by distortion, selective fracture, or by rigid survival. However, in certain embodiments, portions of a flange may be designed to fail to a selected extent in a selected region in order to protect other portions of the flange that would result in more costly damage if allowed to fracture.




Thus, for example, outer portions of a flange may be permitted to crush, bend, break, and so forth in order absorb certain loads. The rim having greater circumference, more material may be naturally provided for absorbing such damage. Meanwhile, a hub may be configured to minimize damage, since a hub may be substantially smaller than a rim (outer diameter or outermost portion) of a flange. In one presently preferred embodiment, bending loads may selectively fracture corrugation walls on one axial side, while transferring loads away to other areas. This re-distribution may reduce fractured circumference at the core, maintaining integrity while permitting fracturing of adequate length to absorb shock loads.




Even near a hub, geometries of flanges may promote selective fracture. For example, selected portions of corrugations may be designed to have thicknesses, angles, and loads calculated to cause a fracture of a limited length and direction. Other nearby locations may be configured with geometries, materials, thicknesses, and so forth to virtually preclude fracture in a similar circumstance. Both features, one susceptible to ready fracture at a known location, and one resistant to expected fracture at a nearby location may provide selective fracture for absorption of energy without catastrophic failure. Catastrophic failure may be regarded as a failure that is likely to destroy the contents of a spool or reel, render it otherwise useless due to increased effort to retrieve, or create an impossibility or difficulty of supporting and retrieving stranded materials, and the like.




In other embodiments, circumferential corrugations may be used. Moreover, angled or curved corrugations may be used in combination with one another, or circumferential corrugations, or with surfaces of various configurations in order to optimize fracture toughness, strength, stiffness, etc. In one embodiment, a flange may be subdivided radially to provide portions having greater or lesser resistance to fracture or energy absorption. Corrugations may have axial depth. Axial depth may be constant or variable in a radial, axial or circumferential direction. Nevertheless, molding considerations may provide or benefit from certain uniformities.




Inner surfaces of flanges, those surfaces in contact with the stranded materials stored thereon, may be smooth or corrugated. Accordingly, distances across corrugations may be uniform or non-uniform in a radial, circumferential, or axial direction. Moreover, a directorix may be defined for each corrugation, and even each surface extending in a more-or-less radial direction. Thus, adjacent surfaces or directrices defining surfaces extending radially but connected circumferentially by orthogonal or other surfaces, may have different angles, and may be angled, curved, both, or alternating.




As a practical matter, inner surfaces or interior surfaces of a spool may desirably be designed to extend circumferentially a greater portion of circumference of a flange at any given radius. Thus, the inner, clear span of a stranded material between axial support surfaces will be a relatively lesser fraction of the overall circumference at any radius. Nevertheless, multiple corrugations having sufficiently high frequency to provide short clear spans may obviate any necessity for non-uniformity in a circumferential expanse of any corrugation on an inner or outer surface of a flange. Likewise, surface liners, such as a paperboard, or re-ground plastics, and other inexpensive materials may be installed during manufacture, or after manufacture, to separate wire or other stranded materials from touching an interior flange surface or from tending to escape axially into corrugations corresponding to exterior flange surfaces.




Various alternative embodiments of corrugated spools and reels may be fabricated to have corrugations in various shapes, orientations, and locations. For example, corrugated core regions associated with the portion of a flange within an outer diameter of a connecting tube may be corrugated in various configurations, just as the outer portion of the flange may be corrugated in various configurations.




The core and outer portion of a flange need not be corrugated in the same manner, the same pattern, the same direction, or with any other similar orientation. Moreover, the core and the outer portion of a reel may be made as separate pieces, and secured together with the same fastener that secures the intervening or connecting tube in place. Alternatively, a different fastener may hold the core and outer portion together, while a tube fastener holds the flange to the tube.




In selected embodiments, a core may not require corrugations, but may have apertures to accommodate the two prongs of tools or a tool such as a stapler. A true stapler has an active prong comprising the head, which delivers the staple, and an inactive or anvil prong, for receiving the staple and bending the ends thereof.




The apertures allow access to a tube by a two-prong or double prong tool (e.g. stapler), and to the portions of a reel flange designed to hold the tube. Access may be provided by an aperture and a recess (part of a corrugation) or by a pair of corrugations located radially inside and radially outside of the tube.




In selected embodiments, cross-sections may be defined to run radially, and thus vary in circumferential dimension along a radius. Cross-sections may be rectangular, trapezoidal, sinusoidal, or of any variety, provided in any other corrugated system. Alternatively, corrugations may be disposed to run with cross-sections normal to a circumferential direction. That is, a corrugation may extend with its own longitudinal direction lying along a circumferential path about a flange, that is, wherein a cavity of a corrugation cross-section appears in the radially and axially extending plane with respect to the flange.











BRIEF DESCRIPTION OF THE DRAWINGS




The foregoing and other objects and features of the present invention will become more fully apparent from the following description and appended claims, taken in conjunction with the accompanying drawings. Understanding that these drawings depict only typical embodiments of the invention and are, therefore, not to be considered limiting of its scope, the invention will be described with additional specificity and detail through use of the accompanying drawings in which:





FIG. 1

is a perspective, exploded view of one embodiment of a spool made in accordance with the invention;





FIG. 2

is a schematic end elevation view of a geometry for defining features of reels and spools made in accordance with the invention;





FIG. 3

is a schematic diagram of an end elevation view of a spool in accordance with the invention having circumferential corrugations;





FIG. 4

is a schematic diagram of an end elevation view of a spool and reel geometry illustrating core, sweep and rim angles for a directorix defining a corrugation path for several embodiments of an apparatus in accordance with the invention;





FIG. 5

is a perspective view of one embodiment of a disassembled reel made in accordance with the invention;





FIG. 6

is a schematic, side, radial, sectioned view of the reel of

FIG. 5

illustrating both inner and outer corrugation sections;





FIG. 7

is a cutaway perspective view of one embodiment of a flange in accordance with the invention, having a surface protection layer and curved corrugations;





FIGS. 8-12

are schematic axial views of flanges made in accordance with the invention and having differing configurations for directorix angles for core, sweep, and rim angles as well as curvature;





FIG. 12

is a schematic axial view of a flange in accordance with the invention having corrugations of different core angels;





FIG. 13

is a schematic axial view of a flange in accordance with the invention having two radially distinct regions for providing varying relationships between stiffness and fracture resistance as well as eccentric loading of the flange by tangential corrugations;





FIG. 14

is a side elevation, sectioned view of reel in accordance with the invention having a radially tapered corrugation and illustrating inner and outer faces thereof;





FIG. 15

is a schematic sectional view of a radial aspect of a flange in accordance with the invention, illustrating selected embodiments of corrugations;





FIG. 16

is a schematic sectional view of one half of a radial surface of a flange in accordance with the invention, including spiral and circumferential corrugations, tapered corrugations, and corrugations of constant axial dimension;





FIG. 17

is a perspective, exploded view of one alternative embodiment of a corrugated reel in accordance with the invention;





FIG. 18

is a side elevation view of a flange and tube assembly for the apparatus of

FIG. 17

;





FIG. 19

is a partial, cut-away, side, elevation, cross-sectional view of one embodiment of the apparatus of

FIG. 17

, configured to promote the use of a folded staple fastening mechanism;





FIG. 20

is a partial, cut-away, side, elevation, cross-sectional view of one embodiment of the apparatus of

FIG. 17

, configured to promote the use of a bolt;





FIG. 21

is a perspective, exploded view of one alternative embodiment of a corrugated reel in accordance with the invention;





FIG. 22

is a side elevation view of a flange and tube assembly for the apparatus of

FIG. 21

;





FIG. 23

is a perspective, exploded view of one alternative embodiment of a corrugated reel in accordance with the invention;





FIG. 24

is a side elevation view of a flange and tube assembly for the apparatus of

FIG. 23

;





FIG. 25

is a partially cut-away, side, elevation, cross-sectional view of one alternative embodiment for a flange in the apparatus of

FIG. 23

, illustrating a method for fastening using two tools or a two-prong tool such as a stapler;





FIGS. 26-28

are end, cross-sectional views of cut-away portions of alternative embodiments of a flange suitable for use in the apparatus of

FIGS. 17

,


21


, and


23


, relying on molded tab portions associated with a flange, in order to secure a tubular member thereto in various orientations;





FIG. 29

is a cut-away perspective view of a portion of one embodiment of a flange in accordance with the invention, including multi-dimensional corrugations;





FIG. 30

is a partially cut-away, cross-sectioned, perspective view of an alternative embodiment of undulating ribs in one embodiment of a flange, also illustrating an alternative or optional closure on a flange base;





FIGS. 31-38

illustrate alternative embodiments of twin sheet constructions relying on a base and closure to form a flange in at least two pieces, in which the corrugations may run in any combination of radial or circumferential directions; and





FIG. 39

is a comparison of alternative embodiments of flanges incorporating various twin sheet construction concepts.











DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS




It will be readily understood that the components of the present invention, as generally described and illustrated in the Figures herein, could be arranged and designed in a wide variety of different configurations. Thus, the following more detailed description of the embodiments of the apparatus and methods of the present invention is not intended to limit the scope thereof. Rather, the scope of the invention is as broad as claimed herein. The illustrations merely represent certain, presently preferred embodiments of the invention. Embodiments of the invention will be best understood by reference to the drawings, wherein like parts are designated by like numerals throughout.




Those of ordinary skill in the art will, of course, appreciate that various modifications to the details of the apparatus and methods illustrated in the Figures may easily be made without departing from the essential characteristics of the invention. Thus, the following description of the Figures is by way of example, and not limitation, and simply illustrates certain presently preferred embodiments consistent with the invention as claimed.




Referring to

FIG. 1

, an apparatus


10


may be referred to as a spool


10


or reel


10


. The apparatus


10


may include flanges


12


,


14


, each being provided with a rim


16


and web


18


. The web


18


may extend continuously or discontinuously in a radial, circumferential, axial, or all such, or any combination of such directions. The web


18


extends, whether continuously or periodically (e.g. perforated, spoked, etc.), between a region proximate a tube


20


and the rim


16


near an outermost circumference of a flange


12


. In speaking of flanges


12


,


14


, in general, a single flange


12


may be referred to, and may be interpreted as including features that may be included in all flanges


12


,


14


, but need not be necessarily inputted thereto in all embodiments.




The web


18


extends between the rim


16


and a core


22


or hub


22


near the tube


20


and intended to engage the tube


20


in certain presently preferred embodiments. In other embodiments, the tube


20


may be formed in parts integrated with respected flanges


12


,


14


, and bonded or otherwise fastened to form the tube


20


as an integrated portion of a single-piece spool.




As a practical matter, a cap


23


may be positioned as part of the core


22


or applied thereto in order to seal, space, or otherwise serve the flange


12


. For example, the cap


23


may be a portion of the external portion of the core


22


. Meanwhile, an interior portion


24


of a core


22


may be tubular in nature, and may include multiple tubes or sleeves for capturing or otherwise engaging the tube


20


extending between the flanges


12


,


14


.




The cap


23


may be provided in order to provide an aperture


26


for receiving a driver or dog from a machine on which the apparatus


10


may rotate. Other apertures


27


,


28


may be used for other functions such as starting and tying, respectively, the stranded material (e.g. wire) wrapped about the tube


20


between the flanges


12


,


14


.




Each flange


12


,


14


may be provided with corrugations


30


. Corrugations


30


may be configured to have cavities


31


on opposite, alternating sides of each respective flange


12


,


14


. The alternating nature of the cavity


31


and the surfaces


29


is somewhat arbitrary. That is, when viewing a flange


12


,


14


from one side, (e.g. axially speaking) the raised portion may be thought of as a surface


29


and the depressed portion may be thought of as a cavity


31


, not withstanding each cavity


31


is defined by a surface


29


.




An arbor aperture


32


may be sized to rotate freely and support the apparatus


10


on an arbor during delivery from, or wrapping of the contained, stranded material thereon. The arbor aperture


32


may have a surface


33


operating as an arbor bearing


33


for supporting the weight of the apparatus


10


while accommodating friction, wear, and other structural requirements.




A cavity


34


may be provided as part of the inside portion


24


of a core. Inside refers to the location seen from the same side of a flange


12


,


14


as the stranded material would occupy. The cavity


34


may receive the tube


20


. Alternatively, a cavity


34


may be corrugated, ribbed, or otherwise filled. In one embodiment, the cavity


34


may be irrelevant. In such an embodiment, a rim


20


may be designed to extend over an outermost diameter of the core


22


, and more particularly an inside portion


24


of a core


22


. As noted, the cavity


34


may simply be an extension of a tube


20


made in two parts, each part integrally formed with its respective flange


12


,


14


.




Referring to

FIG. 2

, and to

FIGS. 1-16

generally, an apparatus


10


may include flanges


12


,


14


in which the web


18


extends in a variety of shapes between a rim


16


and a core


22


. In general, the direction of a specific corrugation


30


may extend in any of the directions available. Corrugations


30


may be shaped to appear like spokes


38


, although the specific functionality may be substantially different.




For example, viewing the flange portion


10


of an apparatus


10


in

FIG. 2

, the core portion


22


may be surrounded by the web


18


extending in a radial direction


44


, having a thickness in an axial direction


46


at any location, and extending circumferentially


48


or in a circumferential direction


48


. The directions radially


44


, axially


46


, and circumferentially


48


may be defined with respect to a center


50


or axis


50


of the apparatus


10


. The arbor aperture


32


may be defined by an arbor radius


52


formed within the cap


23


having a capped radius


54


.




Each of the corrugations


30


may extend axially, radially, and circumferentially, as needed to connect the core


22


and the rim


16


. The outermost flanged diameter


58


may be thought of as the effective outer diameter of the apparatus


10


and the flange


12


. In one presently preferred embodiment, the thickness


57


of the rim


16


may be substantially, even orders of magnitude, less than the outermost diameter


58


. Thus, the flange radius


59


about the center


50


is substantially the same on either side of the rim


16


, in such a circumstance.




In certain embodiments, the rim


57


may not exist other than to be the edge of the flange


12


. However, in keeping with structural mechanics factors, a rim


16


may extend axially away from a surface


29


of a web


18


. In certain embodiments, the surface


29


may be flush with the rim


16


, axially. In other embodiments, the rim


16


may extend axially away from the surface


29


beyond that amount needed to define the cavity


31


with respect thereto.




In certain selected embodiments, a flange


12


may be formed to have a core region


62


of the web


18


extending a portion of the flange radius


59


away from the core


22


(hub


22


, cap


23


, etc.). The remainder of the radius


59


may be covered by a rim region


64


of the flange


12


as illustrated by a generic flange portion


40


. The rim region


64


of a web


18


is distinct from the rim


16


. A rim


16


may typically extend orthogonally away from a surface


65


defining the web


18


.




Thus, a core region


62


is that portion of a flange


12


and specifically of the web


18


of a flange


12


extending between a core


22


and some detectable or significant transition portion


60


or transition


60


of the web


18


. Between the rim


16


and the transition


60


extends the rim portion of the web


18


of the flange


12


. The transition


60


may be positioned anywhere desired for improving the structural integrity of a flange


12


. Meanwhile, in general, a spool


10


or a reel


10


may be manufactured with or without any of the apertures


26


,


27


,


28


,


32


as determined to be suitable for the apparatus


10


.




The significance of the transition


60


, which may be a mathematical circle or other geometry as well as a region having some radial dimension that is not insignificant, is for providing differing balances of strength, weight, stiffness, toughness, fracture-resistance, and fracture-susceptibility of the flange


12


. Moreover, the direction of corrugations may change between the core region


62


and the rim region


64


.




For example, a flange


12


may have corrugations


30


extending in a completely or substantially radial direction. A flange


12


may have corrugations


30


forming the web


18


and extending exclusively in a circumferential direction. Alternatively, the flange


12


may have corrugations


30


having a circumferentially curving aspect extending between the core


22


and the rim


16


continuously or discontinuously. In one embodiment, both curved and straight corrugations may exist in a single flange. In certain embodiments, certain types of corrugations


30


may be disposed in the core region


62


of the flange


12


as compared with corrugations


30


in the rim portion


64


of the flange


12


.




Moreover, the rim portion


64


may be designed to promote or resist crushing, fracture, resilience, etc. The core region


64


may be designed to resist or promote deflection, distortion, crushing, fracture, or the like. However, in one presently preferred embodiment, the core


22


must not be completely separable from the core region


62


of the flange


12


. Thus, the material characteristics of the rim region


64


and the core region


62


of the flange


12


may be designed to absorb shock, fracture, distortion, energy, and so forth without improper failures. Catastrophic failure (being rendered unusable, complete separation, rendering useless, etc.) of an apparatus


10


is to be avoided.




Nevertheless, spools


10


and reels


10


are dropped periodically. Such drops should be accommodated by a selected design for a flange


12


. Accordingly, the generic flange portion


40


illustrates the transition


60


in a dashed circle indicating that it may or may not exist and it may be moved radially inward or outward. Similarly, the rim


16


is delimited by the outermost diameter


58


and a dashed circle interior thereto indicating that the construction, thickness, and even existence of a rim


16


are design parameters that may be traded off against other considerations.




Thus, in general, a spool


10


or reel


10


may have a flange portion


40


of a flange


12


designed to optimize the performance of the apparatus


10


by a combination of structural stiffness, toughness, strength, weakness, distortion, energy absorption, selective fracture, and so forth.




Referring to

FIG. 3

, an apparatus


10


may have corrugations


66


,


67


,


68


,


69


extending in a circumferential direction


48


. A web


18


of a flange


12


may have numerous corrugations


30


. The corrugations may be disposed to have alternating surfaces


29


and cavities


31


. The extent in a radial direction


44


of any cavity


31


or surface


29


may be selected by a designer. Nevertheless, one may note that circumferential corrugations


66


-


69


may reduce the probability of transmitting a shock load directly from the rim


16


to the core


22


.




Substantial fracture of the core


22


causing separation from the core


22


from the web


18


over more than about a third of the circumference of a core, will typically be regarded as a catastrophic failure. A fracture extent of half or more often releases the wire thereon. Accordingly, some mechanism for absorbing shock loads applied to a rim


16


by a drop of a spool


10


or a reel


10


resulting in an impact of a rim


16


, may profitably be accommodated by eliminating or reducing the probability of catastrophic failure between the core


22


and the web


18


from shear, bending, or the like.




The rim


16


has a substantially larger aspect (size, radius, etc.) than does the core


22


. Accordingly, less material is typically available to support a force transmitted between the web


18


and the core


22


than is available to absorb a radial or bending shock at the rim


16


. Moreover, the bending moment of an axial component of a load at a rim


16


is substantially greater at the core


22


than at the rim


16


.




Several factors may be accommodated in a design. However, stress levels may be far higher at any interface between the core


22


and the web


18


, for a flange


12


having a constant thickness everywhere, as is good design practice for certain methods of plastics manufacture.




Referring to

FIG. 4

, and still referring generally to

FIGS. 1-16

, corrugations


30


or a particular surface


19


,


29


,


31


extending substantially, radially, or to some extent radially to a substantial amount of its traverse or extent, may be defined or described by a directorix


70


. Thus, a directorix


70




a


,


70




b


,


70




c


,


70




d


,


70




e


,


70




f


,


70




g


,


70




h


, may be regarded as a defining curvature for a selected wall


19


or connector


19


portion of a corrugation


30


. One may think of a connector


19


or a wall


19


as that portion of a corrugation


30


extending from a surface


29


to the bottom of a cavity


31


. Thus, a corrugation may extend principally in a radial direction


44


, a circumferential direction


48


, or both, while a connector


19


or a wall


19


will extend principally in an axial direction


46


, and radial direction


44


to connect adjacent corrugations


30


.




Each directorix


70


may have several features. Controls


72


,


74


,


75


,


76


illustrate certain controlling features for defining the shape of a directorix


70


and its traverse between a core


22


and a rim


16


. The traverse of a directorix


70


may be defined in terms of a core angle


80


, a sweep angle


74


, and a rim angle


76


. The core angle


72


may be defined with respect to a directorix


70


and a tangent


78


to the core


22


. A rim angle


84


may be defined with respect to a tangent


78


and a directorix


70


. A sweep angle


82


may be defined in terms of a difference between a tangent


85




a


to a directorix


70


at a core contact point


81


and a tangent


85




b


to the same directorix


70


at a rim contact point


83


.




Alternatively, a sweep angle


82


may be defined as a difference between a circumferential position of a core contact point


81


and a rim contact point


83


associated with a single directorix


70


of a corrugation


30


traversing between a core


22


and a rim


16


along a web


18


. The latter definition may provide insights into how much of a web


18


has been traversed by a directorix


70


(e.g. by a wall


19


of a corrugation


18


defined by a directorix


70


) in a circumferential direction. Adjacent walls


19


connected by a particular corrugation


30


may have different shapes, and thus more than one directorix


70


to define them.




In

FIG. 4

, the former definition of a sweep angle is used as illustrated in control


75


. The latter definition of sweep angle


82


is used in the control


74


. Each of the flanges in the controls A, B, C, D, E, F, G, H, I, J uses the former definition for sweep angle


82


.




In general, a directorix


70


may be straight or curved. A directorix


70


may or may not include an inflection point


89


as illustrated in the directorix


70




e


of control E in FIG.


4


. In certain embodiments, normals


79




a


with respect to a tangent


78


to the core


22


, and normals


79




b


with respect to the rim tangent


86


may be used to define sweeps


82


and other geometric features of any directorix


70


of a flange


12


.




In general, a directorix


70


, and thus the corresponding wall


90


contacting a core


22


or rim


16


at a core angle


80


or rim angle


84


, respectively, will affect the stress and stress concentration at the core contact point


81


or rim contact point


83


, respectively. One may note that a directorix


70


approaching a core


22


fully tangent thereto may promote stress concentrations at an interior region


77




a


, while reducing them at an exterior region


77




b


with respect to the core


22


and directorix


70


(see control B, control C, and controls


72


,


76


).




The point of designing and controlling a core angle


80


, sweep angle


82


, and rim angle


84


is to control structural design elements that may thereby control the localization of distortion, stress, fracture, toughness, and so forth in a flange


12


, and particularly at those locations where the web


18


of a flange


12


contacts a core


22


or a rim


16


.




One may think of a stress concentration, such as that which may arise in a region


77




a


, as an invitation to structural failure locally. One may think of a smooth transition such as may occur in a region


77




b


as promoting structural integrity by removing the directionality of forces that may tend to rupture the integrity of a flange between a directorix


70


(actually the wall


19


defined by the directorix


70


) and the core


22


.




Accordingly, a directorix


70


may be designed to promote failure in an interior region


77




a


or a corrugation wall breaking away from a core


20


. Meanwhile, the same directorix


70


may promote structural integrity with the core


22


at an exterior region


77




b


or on a axially oppositely disposed corrugated wall. Thus, during impact, a directorix


70


, meaning a wall


19


defined thereby, may selectively fracture and separate at distinct locations with respect to a core


22


, while others remain integral.




In

FIGS. 1-16

several, substantially orthogonal surfaces result from the use of corrugations


30


in flanges


12


. Accordingly, orthogonal surfaces may flex with respect to one another if not stiffened by a third mutually orthogonal surface. A separation of two surfaces may affect orthogonal surfaces until flexure becomes available to a last connecting surface. A combination of a portion of a core


22


maintaining its structural integrity with respect to a wall


19


(e.g. directorix


70


) may maintain a structural contact between each surface


29


, associated connecting wall


19


, core


22


, the cap


23


, and any combination thereof. At the same time, the same corrugation


30


may selectively fracture with respect to the core


22


at a somewhat different location. Typically a wall-thickness away or more from the integral portion, to absorb the energy of impact. Nevertheless, the integral portion and transferring loads away then maintains sufficient structural integrity of the web


18


and of the entire flange


12


to prevent loss of the contained, stranded material held by the apparatus


10


.




One may note that a directorix


70


, such as a directorix


70




a


that is normal to the core tangent


78


and the rim tangent


86


will typically transfer impact loads directly to the cores


22


from the rim


16


in a radial direction


44


. By contrast, a directorix


70


, such as a directorix


70




b


may still deliver impact loads from a rim


16


to a core


22


, radially eccentrically, or in bending with additional torsion outside of an axial-radial plane. Likewise, a directorix


70


, such as a directorix


70




c


,


70




d


,


70




e


,


70




f


,


70




g


may not have a straight line path in a radial direction between a rim


16


and a core


22


.




Web


18


may transfer loads through the wall


29


,


31


(exterior or interior surfaces


29


,


31


of corrugations


30


). Stiffening is not readily available from the connector


19


(wall


19


, directorix


70


) to transmit radial loads. Nevertheless, the connector


19


may be available to provide stiffness against excessive column buckling, shell buckling or distortion, and the like in a radial direction. Bending may be resisted more by radially direct walls


19


. Accordingly, the core angle


80


, sweep angle


82


, rim angle


84


, number of corrugations


30


, thicknesses thereof, and the like, may be designed to promote a selected amount of local distortion, fracture, integrity, toughness, and stiffness, and so forth within the web


18


and flange


12


generally.




Perforations within the web


18


may be used selectively to promote increased or reduced stress. For example, perforations may be provided at an interior region


77




a


to promote fracture while continuous material may provide the web


18


in a wall


29


of a corrugation


30


in the region


77




b


exterior to a core, contact point


81


. In one presently preferred embodiment, a bending load may fracture a corrugation


30


, but each corrugation is circumferentially discontinuous at any axial position. Thus, a corrugation may part radially and axially from a core


22


along a circumferential crack at or near the core


22


.




A corrugation


30


axially opposite an adjacent fractured one, will not then experience a bending load effective to separate it from the core at the circumferential location. Core angles


80


and circumferential discontinuity of corrugations tend to. control the direction of cracks, precluding extensive propagation circumferentially. Thus, a continuous crack will not propagate around the core


22


circumferentially


48


. The core


22


remains attached to the web


18


. Moreover, the corrugations provide structural strength and stiffness in three dimensions, preventing failure of the flange


12


in service.




Referring to

FIG. 5

, an elevated surface


90


and a flush surface


92


or recessed surface


92


may be thought of as the surfaces themselves, or the entire walls in such locations. One may note that the flush wall


92


or the recessed wall


92


, when viewed axially from outside a flange


12


provides a contact surface


92


for supporting stranded material to be wound on a tube


20


. Accordingly, one may design the corrugations


30


such that any pair of adjacent connector walls


19


within a single corrugation


30


are spaced to promote greater circumferential distance


48


(see

FIGS. 2-3

) than that for an elevated or exterior wall


90


.




Thus, the clear span


93


of wire crossing a corrugation


30


associated with an exterior wall


90


may be minimized. Alternatively, a cover


120


, such as a paper board, or inexpensive material not integral with a flange


12


(see FIG.


7


), may be provided to reduce bulging or pulling of stranded materials axially


46


into a cavity


31


, interior to a particular corrugation


30


.




A length


94


of a tube


20


may selected in accordance with a thickness


96


required to support the stranded material on a tube


20


. Accordingly, the ends


98


of the tube


20


may be fitted to a slot


100


designed to support the tube


20


of the associated length


94


, when fully loaded with product (stranded material), in a drop test or in an accident during operation. The core wall


102


may be designed to bond or fasten to the tube


20


in a manner calculated to maintain sufficient integrity between the tube


20


and the flange


12


,


14


during a drop, thereafter.




In order to provide minimum weight, minimum wall thicknesses, and the like for each flange


12


,


14


, a core sleeve


104


may be designed to support the ends


98


of the tube


20


. For example, less material is available to take the force of impact at the core


22


. Accordingly, additional support about the slot


100


may be provided by a core sleeve


104


extending inside a tube


20


, as well as the core wall


102


extending over the outside surface of the end


98


.




A bearing surface


106


may be formed to extend axially away from the cap


23


of a core


22


. Thus, less material may be used and wall thicknesses may be maintained at a constant value while providing additional bearing surface


106


to reduce friction and maintain integrity of the cap


23


. In large reels, typically greater than one foot in diameter


58


, and often several feet in diameter, the bearing surface


106


or bearing wall


106


(e.g. bearing


33


) may be a critical design feature for suitable life of an apparatus


10


.




As a practical matter, struts


108


may be provided inside a core


22


. In one embodiment, corrugations


30


may extend to the arbor aperture


32


. For example, the sleeve


104


may exist and extend axially away from the web


18


to receive the tube


20


. Alternatively, struts


108


may be sized to permit the core


22


to receive the tube


20


therein. Nevertheless, in one presently preferred embodiment, large reels


10


may have a slot


100


formed between a core wall


102


and a core sleeve


104


. In this latter embodiment, the struts


108


may be of any dimension desired consistent with those of the sleeve


104


.




Referring to

FIGS. 6-7

, and continuing to refer to the remaining

FIGS. 1-16

, a flange


12


of a spool or reel


10


may be provided with an inside face


110


(e.g. see also surface, faces, walls, etc. including walls


90


,


92


, and


29


,


31


). In the embodiment of

FIG. 6

, the inside face of a wall


111


of a corrugation


30


may be opposed to an outside face


112


thereof. Thus, an inside face


110


may be any face that is exposed to the interior of a spool


10


or a flange


10


while an exterior face


110


may be any surface exposed to an environment external to the portion of the spool


10


or reel


10


supporting or containing the stranded material. Thus, a cavity


31




a


may have an exterior surface


112


corresponding to the cavity surface


31


of FIG.


1


.




Meanwhile, the same corrugation


30




a


may have an interior surface


110


corresponding to an elevated surface


90


or outer wall


29


, depending on one's perspective. Thus, one may speak of a wall


111


of a corrugation


30


sharing or connecting to an adjacent wall


111


of an adjacent corrugation


30


by a connector


19


or connecting wall


19


. Thus, for example, a wall


111




a


of a corrugation


30




a


forming a cavity


31




a


may share a connecting wall


19




ab


with a wall


111




b


of a corrugation


30




b


. Similarly, the wall


111




a


may share a connecting wall


19




ac


with a wall


111




c


of a corrugation


30




c.






One may note that the region


77




a


of

FIG. 7

may form a sharp angle and a stress concentration between the connecting wall


19




ac


and the core wall


102


of the core


22


. Meanwhile, the region


77




b


is completely smooth or may be so designed for the connecting wall


19




ab


of the same corrugation


30




a


. Accordingly, for a radial load in tension, fracture may be anticipated in an area


77




a


before fracture in an area


77




b


. However, in bending, the web


18


may fracture along a line between


77




a


and


77




b


at maximum stress, but not usually at the same radial location on an adjacent corrugation


30




b


,


30




c


of opposite sense (inside/outside), which is acting as a fulcrum for the fracturing process. Connecting walls


19


may fracture partially or completely in an axial direction toward a fulcrum (e.g. regions between


77




a


and


77




b


for corrugations


30




b


,


30




c


).




One may also note however, that the cavity


31




a


also has various relationships with both the corrugation


30




a


and the corrugation


30




b


. Accordingly, the connecting wall


19




ab


within the cavity


31




a


may also have equivalent locations having the same geometry as the areas


77




a


and


77




b


for the corrugation


30




a.






However, such interior


77




a


and exterior


77




b


connecting regions will have an opposite sense on opposite sides of the respective walls


19




ac


and


19




ab


, and with respect to the adjacent and corresponding corrugations


30




c


,


30




b


, respectively. Thus, upon impact, a fracture may occur, partially separating a wall


111




a


from a core


22


, beginning at an area


77




a


and extending along the core


22


or the wall


102


of the core


22


toward the area


77




b


. However, adjacency of corrugations


30


may prevent extensive propagation circumferentially of any crack.




However, the wall


19




ab


may tend to fracture away from the core


22


within the cavity


31




a


. The corrugation


30


opposite a fractured one is acting as a fulcrum for fracture, yet maintaining its own integrity with the core


22


and particularly the core wall


102


in the area


77




b


. Thus, one may see that the dimensions of the corrugations


30


allow great design flexibility.




An inside face


110


of a wall


111


may be disposed opposite an outside face


112


thereof. The inside face


110


and the inside face and outside face


112


may exist for every wall


111


, regardless of the disposition of the wall


111


, on the inside


113


of the flange thickness


114


, or on the outside


115


of the flange


12


. The inside


113


direction may be thought of as -the region of the spool


10


or reel


10


that holds the stranded material (e.g. wire).




Thus, the cavity depth


95


and the wall thickness


118


may typically add up to the flange thickness


114


. Nevertheless, the flange thickness


114


need not be constant in a radial direction


44


. Similarly, a wall thickness


118


need not be uniform in a radial direction


44


or a circumferential direction


48


but may be adapted to absorb or sustain loads. Nevertheless, constant wall thickness at all locations tends to promote uniformity of stress and reliable manufacture at consistent molding times for plastics.




Extending in a radial direction


44


, a corrugation


30


may be tapered in order to reduce weight, balance forces, permit selected distortion, or provide more uniform impact loading, For example, near the rim


16


, more material exists in a circumferential direction


48


to absorb loading, breakage, distortion, and the like as a result of shock loads (forces, impact) when compared with a location near or at the core wall


102


.




Moreover, the bending moment on a flange


12


is greatest near the core


22


in response to a load applied near the rim


16


. Thus, a tapered flange


12


having a narrower flange thickness


114


near the rim


12


may provide a closer balance or more uniform distribution of forces in the flange


12


. On the other hand, selective fracture may be designed into various corrugations, as a result of a uniform flange thickness


114


, thus focusing energy at the core


22


as it interfaces with the web


18


(e.g. walls


111


and connector walls


119


.)




Referring to

FIG. 7

, one may note that a point


132


along a connector wall


19




ac


is one type of core contact point


81


or core contact line


81


for a directorix


19




ac


or connector wall


19




ac


. Similarly, for the corrugation


30




a


, the core contact line


81


or core contact point


81


is identified by the point or line


130


of tangency of the connector wall


19




ab


with the core wall


102


. Thus, adjacent connector walls


19




ac


,


19




ab


operate similarly. Nevertheless, with respect to any particular corrugation


30




c


,


30




a


, respectively, the connector walls


19




ac


,


19




ab


respectively, will behave differently with respect to their own individual interior


77




a


and exterior


77




b


angles at their respective contact points


132


,


130


or contact lines


132


,


130


.




Each connecting wall


19


may have one or more radii of curvature


124


about one or more centers


126


or center points


126


. That is, the radius


124


may not be constant. Moreover, the center point


126


may not be constant. Nevertheless, in one embodiment a uniform radius


124


about a single center


126


may be selected for each connector wall


19


. The design patterns


72


-


76


and A-G of

FIG. 4

illustrate selected samples of connector walls


19


, as a directorix


70


, in each case. Thus, the corrugations


30


of the flange


12


of

FIG. 7

may be formed as a variation of the control D or pattern D of FIG.


4


.




Nevertheless, the flange of

FIG. 7

may be designed to have any combination, or all combinations, or some other combinations of core angle


80


, sweep angle


82


, and rim angle


84


, as well as inflection points


89


and one or more radii


124


of curvature about one or more centers


126


of curvature. Moreover, the relative proportion of the inner face


110


of the web


18


, as compared with the outer face


112


of various corrugations


30


may be adjusted to provide more or less stiffness or distortion.




For example, if the width


133


of a corrugation


30


(e.g.


30




a


) is comparatively larger than the same dimension


133


of an adjacent corrugation


30


(e.g.


30




b


,


30




c


), at any given distance


131


or radius


131


from a central axis


50


of a flange


12


, distortion may be effected. Moreover, the clear span


93


between adjacent internal corrugations


30


(e.g. on the inside face of the flange


12


) may be reduced. The walls


111




a


having a larger dimension


133


may be more susceptible to distortion in an axial direction or a radial direction upon impact.




Accordingly, non-uniform stiffness within adjacent walls


111


, corresponding to adjacent corrugations


30


, may provide absorption of energy without failure of the fundamental structure of the flange. Nevertheless, the corrugations


30


may prevent catastrophic failure with an appropriate amount of relative stiffness where needed. Corrugations


30


having a comparatively narrower width


133


may be designed to bend or spring by virtue of having an aspect ratio closer to a value of one.




An aspect ratio may be thought of as the ratio of depth


95


of a cavity


31


with respect to a span


133


or width


133


of a single corrugation


30


at a particular radius


131


. Thus, for example, interior walls


111


in contact with stranded material may have comparatively larger widths


133


than exterior walls


111


not in contact with the stranded material. Moreover, provision of a sharp angle near the transition from a connector wall


19


to a corrugation wall


111


may promote selective fracture, allowing a corrugation


30


to spring separately from its adjacent corrugation. Thus, selective local failure or separation may actually protect the overall integrity of the flange


12


under impact or shock loading.




Stress concentration inhibition may be provided by fillets in selective corners. Increased stress concentration factors may be provided by sharpening the angle between connected, especially orthogonal, surfaces. Fillets need not be constant along the entire length of a directorix


70


(connector wall


95


).




In one embodiment, a corrugation


30


may be formed to have a comparatively sharper angle between a wall


111


and one of the adjacent connecting walls


19


with a comparatively more rounded transition between the same wall


111


and its opposite connecting wall


19


. Thus, one connecting wall


19


will remain with one corrugation


30


, while the adjacent connecting wall


19


will remain integral with the wall


111


of the next corrugation


30


.




For example, a corrugation


30




a


may remain integral with the connecting wall


19




ac


, by virtue of proper location of fillets, while separating from the connector wall


19




ab


due to an absence or sharpness of fillets. Similarly, the corrugation


30




b


or


30




c


may provide selective breakage and selective integrity in order to absorb more shock with distortion and breakage.




Breakage absorbs tremendous amounts of energy. Selective breakage may absorb energy of impact in areas where the contained wire or other stranded material on a tube


20


of a reel


10


or spool


10


will not be damaged or rendered unusable or inaccessible.




If the connector walls


19


of the corrugations


30


of

FIG. 7

are straightened in accordance with other designs illustrated in

FIG. 4

or similar thereto, impact loads may be delivered directly from the rim


16


to the core


22


. Accordingly, breakage may occur between the corrugations


30


and the core


22


. Whereas the apparatus of

FIG. 7

may provide eccentric loading on the core


22


, reducing, absorbing, or eliminating much of the radially directed energy from the corrugations


30


to the core


22


, a straight connector wall connected normal to a core tangent


78


, may fracture from the core


22


at the core wall


102


or in the web


18


. However, as with bending loads, once fracture occurs, a corrugation can both redistribute loads through the web


18


and resist further failure due to its shape. A comparatively longer core wall


102


(as compared with corrugation


30


thickness


114


axially) may act as a cantilevered “barrel stave,” flexing radially but not failing axially at all locations.




Again, in selected embodiments, one connector wall


19


corresponding to an individual corrugation


30


may have a core angle


80


close to perpendicular. Impact may cause shearing of the core


22


or web


18


and breakage. Meanwhile, an adjacent connector wall


19


may be curved or positioned eccentrically, tangent, or the like, with respect to the core


22


or a core tangent


78


.




The wall


19


may permit torsional distortion in one or more directions


44


,


46


,


48


. Accordingly, fracture may be reduced or eliminated for such a connector wall


19


. Thus, both fracture and toughness may be provided for absorbing impact without destroying the entire structural integrity of a corrugation


30


. In certain embodiments, adjacent corrugations


30


, meaning in this context adjacent and on the same side (e.g. inside or outside) of the flange


12


, may be disposed closer together and alternating in their impact resistance and toughness characteristics).




Referring to

FIG. 8

, specifically, and to

FIGS. 7-14

, generally, a core


22


may be formed flush with an outer face


112


of a corrugation wall


111


. A cap


23


may form a fixed end axially beyond, or flush with, the exterior surfaces


112


or outer faces


112


of the various corrugations


30


.




A corrugation


134


and an adjacent corrugation


136


may share a connector wall


135


, a specific instance of a wall


19


. Thus, the cavity


31


of the corrugation


136


is closed on only four sides and has a single open side. By contrast, the flanges


12


of

FIGS. 1 and 5

have five sides.




Accordingly, the corrugations


30


,


134


,


136


may be considered highly triangulated. Triangular shapes tend to be particularly rigid. Nevertheless, in view of the formation of contact areas


138


or connection areas


138


, the corrugation


134


may transition within a single surface


112


to the cap


23


of the core


22


. A corrugation


134


may tend to continue fracture and reduce or eliminate integrity between the portions of the web


18


, or between the web


18


and core


22


. However, all fracturing beginning in the corner


77




a


and proceeding circumferentially


48


a limited distance due to the circumferential discontinuity of material.




Fracture beginning in the corner


77




a


or stress-concentrating region


77




a


does not become equivalent for the corrugations


134


and


136


. A corrugation


134


shares the cap


23


of the core


22


, or shares a surface with the cap


23


. By contrast, the region


77




a


does not have a surface on the inside


113


of the flange


12


. A fracture may be propagated through the face


112


from the region


77




a


, toward the corrugation


136


, across the corrugation


134


. Loading may fracture corrugations


30


from cores


22


. In bending, a more likely event is the fracture of a connector wall


135


under the force from one corrugation


134


(


136


) acting as a fulcrum and the other


136


(


134


) separating completely or partially from the core


22


. The structural strength and stiffness of the web


18


may then redistribute loading even when partially separated from the core


22


by failure under bearing loads. The web


18


remains attached to the corrugation


134


and functional.




The contact region


141


under a fulcrum region of a corrugation


134


appears structurally to be continuation of the connector wall


135


. Bending may be axially inward or outward and corrugations


30


do not generally fracture the same on axially opposite sides of a flange


12


, nor in exactly the same defections. Thus overall integrity of the webs


18


, and of spools


10


or reels


10


(core


22


to web


18


) is excellent.




Fracture beginning through the region


138


and beginning at the corner


77




a


across the corrugation


134


, once started, may tend to propagate orthogonally though the core wall


102


(not seen, see FIGS.


5


-


7


), depending on core wall thickness


102


. Alternatively, cracks may propagate orthogonally along connecting walls


19


,


135


.




No flush surface is available between the core


22


and the corrugation


137


to carry a fracture circumferentially, and continuously in a single direction. However, in bending, tearing or fracturing of connecting surface


135


from the core


22


can occur. Likewise, all fracture need not occur at a core


22


, but may occur radially away therefrom.




An extended length of a core


22


protruding axially in an inward direction


113


(see

FIGS. 6

) from the corner


77




a


through the corrugation


137


may propagate only so far as distortion will allow and necessitate as loads are re-distributed.




Depending on the load directions, a portion of a core wall


102


may connect to the corrugation


137


, and may not completely sever the connecting wall


19


away from the corrugation


134


. Selected fracture can occur from incipient points


77




a


in corrugations


137


, but not from the same drop or the same bending load, typically.




The contact regions between a cap


23


and a corrugation


134


may tend to fracture about a core wall


102


. Similarly, in a next corrugation


136


, the region


141


may tend to be integral. A region


139


may tend to fracture, separating the outer face


112


of a corrugation


30


from the rim wall


102


. Thus, the region


141


may maintain its integrity with the web


18


and rim


22


, but typically in a drop or impact of an axially opposite sense, just as the corrugation


134


may. Thus, the corrugation


134


may tend to maintain integrity by reliance on the corrugations


136


,


137


and the shared connector walls


19


,


135


.




Each of the corrugations


30


(e.g.


30




a


,


30




b


,


134


,


136


,


137


) may have a fracture region


138


or a contact region


138


with the cap


23


, which region


138


may fracture. A core contact region


140


may remain intact but orthogonal thereto as an extension of a connecting wall


19


. Substantial loading may be remotely supported by the corrugations


30


. The regions


138


may be thought of as the fracture regions wherein a corrugation


30


(e.g.


30




a


,


30




b


,


134


,


136


,


137


) separates from the core


22


or itself. A region


139


,


140


may be viewed as an area where a connector wall


19


maintains integrity with the core wall


102


orthogonal to a rupturing corrugation face


112


. In opposite bending, roles of corrugations may reverse.




Rupture may propagate circumferentially across a corrugation


30


, radially through a core wall


102


, segmenting the core


22


circumferentially, if the wall


102


is comparatively thin. In the latter event, cantilevered portions may extend axially parallel to one another. Maintaining a certain portion of the core


22


near the flange web


18


free from rigid adherence to a tube


20


may promote greater durability. For example, a cardboard tube


20


tends to have great toughness, not failing in very high loadings, and most drop tests. Meanwhile, a core


22


may be able to flex substantially between axial breaks propagated from sharp corners


77




a


across outer surfaces


112


. Thickness design can control fracture.




Due to the nature of stress concentrations, fractures may begin in corners


77




a


and propagate radially through core walls


102


, but may be substantially less likely to propagate to or beyond a connector wall


135


. Whether fulcrumed in bending of flanges


12


, or stripped into slatted staves by a radially and axially directed fracture sympathetic to the fractured region


138


circumferentially from a corner


77




a


, adjacent corrugations


134


,


137


can survive and support one another.




Substantial loads can be re-distributed and transferred through corrugations


30


after a fracture almost anywhere between a rim


16


and a core


22


. Nevertheless, the comparatively rigid triangulation of a corrugation


30


may tend to break near the core in bending. Radial components of forces may tend to rotate the core


22


, or resolve forces into an eccentric, tangential load applied to, the core


22


and attached tube


20


.




Other dimensions of a flange


12


, and particularly of individual corrugations


30


, may be designed to crush, fracture, distort, or hold. An interior corrugation


142


may be provided with a start hole


27


for wire. The start hole


27


may be positioned to relieve stress, or to propagate or to initiate fracture in a selected region. Thus, various start holes


27


(for starting wire wrap) or small stress-relief apertures


27


may be disposed periodically about a flange


12


.




A rim wall


144


may extend axially


46


to any desired flange thickness


114


. A connector wall


146


on an “inner” side of a corrugation


30


a may maintain its integrity with the core wall


102


. The connector wall


148


may maintain its connection to the core


22


or core wall


102


, but is likely to propagate a fracture toward a corrugation


137


and cavity


31


. Meanwhile, the outer connector wall


148


will likely not maintain its connection with a connector wall


146


, except through the broken, and thus flexible, core


22


, having sympathetic fractures orthogonal to the surfaces


112


.




Providing a broader width


133


a in an interior corrugation


136


,


148


as compared to a width


133




b


of an exterior corrugation


134


,


149


respectively, may promote distortion in a radial direction


44


with substantial deflection in an axial direction


46


(see e.g.

FIGS. 2-3

for directions). The radius of curvature


124


of

FIG. 7

may be replaced by a comparatively rigid triangular structure directing forces eccentrically toward a core tangent


78


in FIG.


8


. Bending a flange


12


axially may actually create a torsional component about a radius when corrugations do not run strictly radially


44


.




A single point


152


may exist for each corrugation


30


of

FIG. 8

(e.g.


134


,


136


,


148


,


149


,


30




a


,


30




b


,


142


being specific examples). The single point


152


of

FIG. 8

corresponds to a line


132


extending axially as a contact line


132


or contact point


81


forming a vertex


81


between tangents


78


to the core wall


102


and the connector walls


19


for a particular corrugation


30


. Fileting may relieve all points


152


,


81


, etc.




Referring to

FIG. 9

, and continuing to refer to

FIGS. 8-14

, generally, various corrugations


30


(e.g. interior corrugation


136


and exterior corrugation


134


) may be defined in terms of interior connecting walls


146


and exterior connecting walls


148


. Each connecting wall


146


,


148


may be defined in terms of one or more radii of curvature


124




a


,


124




b


, measured from one or more centers of curvature


126




a


,


126




b


, respectively. In the embodiment of

FIG. 9

, a rim wall


144


may be continuous, despite the alternating inside and outside corrugations


136


,


134


, respectively.




The wall


102


of the core


22


, illustrated in hidden lines, is tangent to the corrugations


30


(e.g.


134


,


136


) at particular contact points


152


. The connecting region


138


between the exterior or outer corrugation


134


and the core


22


may operate to be fractured selectively in order to propagate fracture from a point


152


, maintaining selective attachment of connecting walls


146


to the core wall


102


.




A principal of selective proportioning of the thickness


133




a


of an inner or interior corrugation


130


in contact with the stranded material of the spool


10


or the reel


10


may provide a comparatively narrower thickness


133




b


for an exterior corrugation


134


. This may be particularly effective in an embodiment such as that illustrated for FIG.


9


.




Radial forces applied to the rim


16


may be largely resolved into circumferential forces applied to the core wall


102


, with selective fracturing at points


152


, and along connecting walls


148


(optionally), or elsewhere as desired. Bending may resolve into more torsion about a radius instead of a direct axial tension load in the web


18


or at the core


22


. Selecting an aspect ratio for each exterior corrugation


134


in order to approximately equalize axial and circumferential dimensions thereof, may again provide springs, selective fracturing, and selective deflection or distortion, of interior corrugations


136


in contact with the stranded material.




In general, a completely fracture-proof spool


10


or reel


10


is not necessarily the best. All materials must distort under load. A material or design that is too stiff to accept any distortion must typically fail under less load than a similar design having more flexibility. If sufficient strength can be added to absolutely preclude rupture at operational or accidental impact loads, then selective distortion and fracture may not be required. However, a spool


10


or a reel


10


having a value two orders of magnitude less than the value of stranded material contained thereon, does not bode well for an absolutely fracture proof design.




Referring to

FIG. 10

, one embodiment of an apparatus


10


may rely on a straight directorix


70


uniform in core angle


80


, sweep angle


82


and rim angle


84


for all corrugations


30


(e.g.


134


,


136


) defined thereby. Nevertheless, an interior point


156


or inner point


156


and an exterior point


154


may replace the single point


152


of FIG.


9


. Moreover, the core


22


is interior with respect to the core angle


80


of every directorix


70


, connecting wall


70


,


146


,


148


.




Note that no directorix


70


or corresponding connecting wall


19


(e.g.


146


,


148


) actually exists tangent to either the core


22


or the rim


16


. Nevertheless, sufficient eccentricity exists to operate similarly to the configurations of

FIGS. 8-9

. However, the straight connecting walls


19


(e.g. of which the specific examples


146


,


148


pertain to corrugation


136


) tend to stiffen the flange to direct loads in a straight line toward the core from the rim. Again, changing comparative widths


133




a


,


133




b


to form larger interior corrugations


136


may be used to promote features here described in association with

FIGS. 6-9

.




The applicability of perforations, selective filleting, selective stress concentration factors, and the like may be applied at the interior points


156


or exterior points


154


in order to provide preferential fracture in the region


141


and preferential integrity in the region


140


. Moreover, once some amount of fracture has occurred stress may be relieved. Moreover, inasmuch as three orthogonal surfaces appear at each of the corners


152


,


154


,


156


, a selective fracture to separate one surface from the other two, may permit flexure between the two remaining orthogonal surfaces. So long as rigidity is maintained, loads must either be supported or materials must be distorted (deflected) or fractured. Once a single surface has been fractured away from the remaining two, at a particular corner


152


,


154


,


156


, the flexure of the remaining two orthogonal surfaces may absorb deflection. The energy will have been absorbed by the fracture and being placed on more remote regions by virtue of that flexure.




One benefit of this design in bending of flanges


12


, is that fracturing may be directed. For example, adjacent corrugations


134


,


136


will not normally fracture circumferentially at a single radius, even across a single corrugation


134


,


136


. Corrugations will support one another in failure. More fracture, in more directions, can be absorbed with minimum loss of functional integrity of a flange


12


and spool


10


.




Referring to

FIG. 11

, a spool


10


or reel


10


may have a flange


12


in which a substantial sweep angle


82


(see

FIG. 4

) exists. A directorix


70


may define a connecting wall


146


between an exterior corrugation


134


and an interior corrugation


136


recessed to form a cavity


31


in the end of a flange


12


. The point


152


may be designed to operate to fracture. A sufficient sweep angle with an aspect ratio between the thickness


133




b


and the thickness


133




a


much less than one can provide the selective spring, distortion, fracture, and other benefits here to for described, to an even greater degree. Bending survival may be substantially enhanced. Distortion may be traded off against stiffness in radial loading, axial bending, or both, by selection of cor angle


80


, sweep angle


82


, and rim angle


84


. Discontinuous fracture may absorb energy, while corrugations transfer loads and retain structural integrity of a flange.




Thus, more distortion may be provided, even avoiding fracture or excess fracture. Meanwhile, the nature of the transition between the core


22


and any individual corrugation


30


(e.g.


134


,


136


) may promote regions


141


maintaining mechanical integrity with the core


22


. The adaptability of orthogonal surfaces being reduced from three at a point


152


or corner


152


by fracture to leave only two, may promote uncoupling of absorption of energy through fracture, and distortion of connections through flexure, in order to absorb energy but to avoid catastrophic failure (e.g. separation) and to maintain mechanical integrity.




Referring to

FIG. 12

, a directorix


70




a


may define a connecting wall


135


between an outer corrugation


134


and an inner corrugation


136


. A load applied radially may still be resolved eccentrically at the core


22


. Nevertheless, a sharp interior corner


156


may be normal to a core tangent


78


, while an exterior corner


154


on the same exterior corrugation


134


may be parallel to a core tangent


78


. A bending load may be resolved into plate distortion and loads in both axial and circumferential directions. Fracture directions may be thus controlled.




A point


152


may be formed by connecting walls


135


. Nevertheless, selection of the respective dimensions of the exterior corrugations


134


and interior corrugations


136


may leave a space for corners


154


,


156


in an individual interior corrugation


136


to be separated, analogously to the structure of FIG.


10


. Numbers, dimensions, and aspect ratios of corrugations


134


,


136


may be selected in accordance with design choices to balance strength, rigidity, flexibility, distortion, toughness, selective fracture, and so forth as described previously.




Continuous fracture of the web


18


from the core


22


can be avoided by the directionality of loadings in bending or direct radial impact. Moreover, distortion and stiffness may be balanced against each other in olefinic plastics, while fracture lengths and directions may be balanced against weight and strength in more brittle materials maintaining system integrity.




Referring to

FIG. 13

, a spool


10


or reel


10


may include a flange


12


having panels


160


disposed interiorly (toward the wire or strand) or exteriorly, alternating therebetween, or in some designed pattern. In the embodiment of

FIG. 13

, the connecting walls


162


are all illustrated as viewable from the exterior as ribs


162


. Nevertheless, the ribs


162


are only so displayed for the sake of clarity. As a practical matter, all of the combinations for recessing or raising individual panels


160


cannot be shown in a single figure. Accordingly, any of the panels


160


may be raised or recessed axially as desired. Thus, the ribs


162


may represent schematically the connecting walls


162


(e.g.


19


) between adjacent panels


160


. In the embodiment of

FIG. 13

, a core region


62


extends from a core


22


outward to a transition


60


.




Between the transition


60


or transition region


60


and the rim


16


, defined by a rim wall


13


extending circumferentially


48


and axially


46


, stiffness, toughness, fracture resistance, fracture susceptibility, and the like may be traded off differently than in the core region


62


. Accordingly, the rim region


64


may be designed to have very stiff, thin, fracture-susceptible walls. Thus, in a standard drop test (e.g. from workbench height) a portion of a flange


12


may be bent, crushed, or broken by axial, off-axis, or radial loads near the rim


16


in order to preserve the integrity of connections between the core


22


and the flange


12


in the core region


62


.




Alternatively, the rim region


64


of the web


18


may be adapted to provided selected distortion and deflection to absorb the energy of impact, up to some pre-designed failure point at which fracture may be precipitated. Nevertheless, in the core region


62


, flexibility, eccentricity, spring response, distortion, and the like as described with respect to other designs herein, may be appropriate.




The transition regions


60


may be defined by a medial rim


164


. A medial rim


164


may be smooth, or somewhat abrupt, and may be analogous to the outer rim


16


of the flange


12


. Accordingly, specific energy absorption mechanisms may be implemented near the medial rim


164


to mollify the transmission of radial loads toward the core


22


through the core region


62


of the flange


12


.




The counter-running, connecting walls


162


, tend to stiffen the flange substantially. Uniformly curved, connecting walls


162


, all oriented in a single orientation and distributed circumferentially


48


, may provide more flexibility, and less stiffness, both radially and in bending. The direction or sense of curvature of the connecting walls


162


in the rim region


164


and the connecting walls


135


in the core region


62


may be the same or opposite. Thus, either an inflected or a monotonic curvature or sense of curvature may be provided.




Referring to

FIG. 14

a spool


10


or a reel


10


may be provided with tapered corrugations


30


. The components of the apparatus of

FIG. 14

correspond to those of

FIG. 6

, but show schematically a variable cavity depth


116


and flange thickness


114


. The flange thickness


114


and cavity depth


116


vary with radial


44


position along the flange


12


. Both outer corrugations


134


and inner corrugations


136


are illustrated in cross section. The larger size of the rim


16


may provide distributed or re-distribution of loads upon localized failure of the web


18


between the rim


16


and the core


22


, as described above. Wider connecting walls


19


,


135


may absorb more energy of distortion during and preceding fracture, thus protecting a wall


111


opposite one failing in bending.




Referring to

FIG. 15

a cross-section of a flange


12


, in accordance with

FIG. 2

may illustrate various aspects of corrugations


30


. For example, a wall


111


of a corrugation


30


may have a uniform or non-uniform pitch


170


. Even with a uniform pitch


170


, the circumferential span


172


within a cavity


31


of a corrugation


30


may be different for interior and exterior corrugations


30


. For example, various patterns


174


(note, herein, that a trailing alphabetical character is simply a specific instance of the leading reference numeral that generically refers to all items of the same type or class) may have various aspect ratios of cavity depth


116


to width


172


.




An aspect ratio may change dramatically as a cavity width


172


narrows near the core


22


and widens near the rim


16


. By contrast, a cavity depth


116


may be more-or-less constant. However, a non-constant or non-uniform cavity depth


116


may be employed as illustrated in FIG.


14


. Accordingly, the aspect ratio of a corrugation


30


may change dramatically from a rim having a comparatively large circumferential dimension


172


and the smallest axial dimension


116


. Near the core


22


, the circumferential dimension


172


will be minimized, while the axial cavity depth dimension


116


will be maximized.




The pattern


174




a


presumes a rectangular or perpendicular relationship between connecting walls


19


and the corresponding corrugation walls


175




a


,


175




b


. The description of a wall


111


as an inner wall


175




a


and an outer wall


175




b


is merely for convenience.




A trapezoidal pattern


174




b


may provide a circumferential span


172


in a cavity


31




a


interior (near the wire) that may or may not be of the same dimension when disposed exterior to the flange (away from the wire). Similarly, a cavity depth


116


may vary circumferentially according to an angle


176


at which a wall


111


extends to form a ramp


177


along a ramp span


178


. The comparative proportion or aspect ratio of both the clear span


172


(clear circumferential span or open circumferential span


172


) and the cavity depth


116


may be designed for a specific application.




Moreover, the aspect ratio of open spans


172


corresponding to exterior walls


175




b


and interior walls


175




a


of corrugations


30


may be selected to provide the various benefits defined herein. Thus, that aspect ratio need not be unity. Moreover, the aspect ratio of cavity depth


116


to clear span


172


, or even to the total pitch


170


may be designed to promote structural integrity and energy absorption. Maximum cavity depth


116


may vary from one corrugation


30


to another


30


. In one embodiment, the aspect ratio of cavity depth


116


to clear span


172


for a corrugation


30


corresponding to an exterior wall


175




b


may be of an order of magnitude of one or less. Meanwhile, the angle


176


may typically be adapted between 0 and 90 degrees accordingly. Likewise, the angle


176


will affect the span


178


associated with the ramp portion


177


.




The pattern


174




c


may take on may of the attributes of the pattern


174




b


. Nevertheless, the pattern


174




c


may be seen as a degenerate form of the pattern


174




b


. The cavities


31


have collapsed (degenerate case) from trapezoids to triangles. Thus, one may compare the inside peak


179




a


corresponding to an interior wall


175




a


to the exterior or outside peak


179




b


corresponding to an interior wall


175




b


of a corrugation


30


. Accordingly, a flange thickness


114


may still be defined for all of the patterns


174


. Nevertheless, less surface area is presented to the stranded material in the design of the pattern


174




c


. Accordingly, stiff, stranded material, may be best adapted to the use of the flanges


12


of the pattern


174




c.






The pattern


174




d


may be thought of as a non-uniform aspect ratio of the interior cavities


31




a


to exterior cavities


31




b


corresponding to exterior corrugation walls


175




b


and interior corrugation walls


175




a


, respectively. Thus, the span


172




a


divided by the span


172




b


may provide a circumferential aspect ratio for non-uniform corrugations


30


. Likewise, uniform corrugations


30


may have a circumferential aspect ratio of one. That is, at any given radius


131


from a center


50


, the circumferential aspect ratio is one for a uniformly distributed arrangement of corrugations


30


extending substantially radially. Again, the aspect ratio of cavity depth


116


to span


172




a


, as well as the aspect ratio of cavity depth


116


to the exterior or outer span


172




b


may be designed as described hereinabove.




The pattern


174




e


may be sinusoidal or otherwise curved and inflected as desired. Many of burdens and benefits of the pattern


174




e


correspond to the pattern


174




c


. As a practical matter, the pattern


174




d


, if modified slightly to permit a draft angle (for molding) less radical than the ramp


177


of the pattern


174




b


, may provide an excellent combination of flexure, toughness, stiffness, energy absorption, spring response or resilience and so forth for a flange design.




Referring to

FIG. 16

, various configurations of flanges


12


are illustrated. In general, each flange extends from a center line


50


a distance


59


or a radius


59


to the outer extremity of a rim


16


. The pattern


180




a


reflects a cross-section cut, radially through half a flange


12


. The pattern


180


a may reflect the design of

FIG. 3

,

FIG. 7

,

FIG. 9

, or

FIG. 11

, in selected embodiments. That is, the walls


111


may extend to provide interior cavities and exterior cavities


31




b


. Thus, the corrugations


30


may extend circumferentially, exclusively, or circumferentially and radially as illustrated in

FIGS. 1-14

. A liner


182


may be provided as illustrated in the liner


120


of FIG.


7


.




The periodicity of the cavities


31




a


,


31




b


in a radial direction


44


may be governed by the frequency or circumferential pitch


170


of a directorix


70


defining corrugations


30


, regularly or irregularly, about the circumference


48


of a flange


12


. Accordingly a liner


182


of paper, or of some other material may be provided to promote or support stranded materials against bulging into the interior cavities


31




a.






The pattern


180




b


illustrates a tapered corrugation


30


. The corrugations


30


may be tapered regardless of which pattern


174


(see

FIG. 15

) is used. Similarly, the pattern


180




c


of

FIG. 16

corresponds to a uniform corrugation thickness


114


.




Referring to

FIGS. 17-18

, the tube


20


may secure two flanges


12


,


14


in which selected portions may be corrugated. For example, in the embodiment of

FIGS. 17-18

, the core


190


is itself corrugated. The core


190


may be corrugated synchronously with respect to corrugations


30


located outside (radially) of the core


190


. Thus, a recess


192


or cavity


192


corresponding to the core


190


may be juxtaposed radially across a region engaging the tube


20


from a recess


31


corresponding to the corrugation


30


of the outer region


200


. The core


190


may thus be synchronous, having the recesses


192


of the corrugation


191


aligned with, almost as if a continuation of, the recess


31


of a corresponding corrugation


30


in circumferential phase therewith.




In the embodiment illustrated, a wall


198


connects the web


194


corresponding to the recess


192


, to the web


196


corresponding to the outer surface


193


. In general, however, a corrugation


191


may have any effective cross-section. Thus, an undulating sinusoidal combination of recesses (defined by the inside web


194


or recessed web


194


, with respect to a viewer) and an outside web


196


need not be so angularly defined.




A sinusoidal shape has a position or displacement along a surface that is continuous. Moreover, a first derivative of that displacement is continuous. However, the first derivative of a rectangular corrugation is discontinuous. Thus, one may speak of the inside web


194


as the portion below or axially away from a viewer, and the outside web


196


as the portion of the sinusoidal shape that is closer to a viewer.




In a sinusoidal embodiment, one may think of the webs


194


,


196


as being those portions that are closest to a tangent perpendicular to an axis


46


of flange


12


. The wall


198


may be considered as the location where a tangent would be approximately or most nearly parallel to an axis


46


of the flange


12


.




Referring to

FIGS. 19-20

, a core


190


and an outer region


200


of a flange


12


may be synchronous, and thus provide an alignment region


210


. In an alignment region


210


, access is available on both sides of a tube


20


(e.g. wall thereof) in order to position a fastener


212


therethrough. In the embodiment of

FIG. 19

, the fastener


212


is a staple, and the embodiment of

FIG. 20

illustrates a bolt. A screw, a rivet, or other fastener as described herein may be suitably engaged to secure the tube


20


to the flange


12


. Moreover, the fastener


212


may be installed by a double-pronged device in which the fastener


212


can be accessed on either or both sides of the wall of the tube


20


. In this manner, a rivet or staple


212


is a possible fastener.




In general, access is only needed from either the cavity


192


of the corrugation of the core


190


, or from the cavity


31


of the corrugation


30


of the outer region


200


. Such an access would result in a tacking approach. For example, a screw, a staple that is not folded, or the like might be used in such a situation. However, in order to fasten a bolt


214


or fold a staple


212


, access from both cavities


31


,


192


may be provided by fabricating the flange


12


with synchronous corrugations


30


-


191


in order to provide the region of alignment


210


.




Referring to

FIG. 20

, the concept of synchronizing or leaving unsynchronized (asynchronous) the core


190


and the outer region


200


may be implemented in fabrication of the flange


12


, as a single piece, (e.g. homogeneously molded), or by fabricating the flange


12


from distinct pieces


190


,


200


. For example, if the core


190


is distinct, divided from the outer portion


200


by a parting line


216


, then the fastener


212


effectively assembles or fastens the core


190


to the outer portion


200


. Accordingly, the core


190


may be rotated to be synchronous or asynchronous with respect to the corrugation recesses


31


,


192


.




Referring to

FIGS. 21-22

, one embodiment of a flange


12


in accordance with the invention may effectively appear to have no core


190


when viewed from certain directions. For example, from “outside” the reel


10


, the outer surfaces


90




b


, corresponding to corrugations


30


having cavities


31


or recesses


31


of the flanges


12


,


14


appear to extend from an arbor hole


32


out to the rim


16


or edge


16


. The rim


16


may actually be a strengthened portion of a flange


12


, or simply the outermost portion of an outer diameter of a single sheet of material. Thus, the corrugations


30


may extend from the arbor hole


32


radially outward to the edge


16


or a rim


16


. Any of the cross-sections discussed herein may be used.




The sleeve


104


may be configured to extend axially from the flange


12


to be received within the tube


20


, or to receive the tube


20


therewithin. Thus, the tube


20


may abut the flange face


90




a


or surface


90




a


or may penetrate the face


90




a


to extend toward or beyond the outer face


90




b


. Thus, the sleeve


104


need not extend axially inward between the flanges


12


,


14


, beyond an inner face


90




a.






Referring to

FIGS. 23-24

, in one alternative embodiment of an apparatus in accordance with the invention, the core


22


need not be corrugated. That is, the core


22


need not be a corrugated core


190


. Rather, the core


22


may be perforated to provided apertures


226


positioned circumferentially to be radially opposite the recesses


31


of the corrugations


30


. In this embodiment, two tools such as drivers or wrenches, or a double-prong tool, such as a stapler, riveter, or the like, will be able to access space both inside and outside a tube


20


, in order to fasten the tube


20


securely with respect to the flange


12


.




In certain embodiments, a manufacturer may rely on one or more sleeves


104


. Sleeves provide relief for hoop stress. Hoop stresses arise due to loads inside or outside of a continuous sleeve


104


. However, due to the improved fastening methods and the increased number and types of fastening methods available in producing an apparatus in accordance with the invention, sleeves


104


are not required. Instead, discontinuous tabs


228


can be affirmatively fastened to the tube


20


.




The tabs


228


may extend from one flange


12


toward another flange


14


, or may extend from a flange


12


away from a flange


14


. Fasteners capable of carrying a tensile load along their principal axes can now be used. The tabs


228


may be bound to the tube


20


with radially oriented tensile forces in a fastener


212


. Thus, in addition to holding a shearing load acting in an axial direction


46


, the fastener may now also support a tensile load within an axis (acting radially with respect to the flange


12


) of the fastener


212


itself.




Noteworthy features of the discontinuous tab


228


design include the lack of hoop stress support, which was provided by the sleeve


104


. All hoop stresses imposed, whether compressive or tensile, in the tube


20


are supported only by the tube


20


. With appropriate tolerances, the tabs


228


may resist compressive forces inducing hoop stress on the tube


20


. However, since the tabs


228


are highly compliant in bending by comparison with a closed tube


20


, which must act according to hoop stress theory, the tabs


228


primarily orient the tube


20


and secure it against axial


46


loads and are not primarily responsible for handling hoop stresses. No transfer of loads between tabs


228


is possible, without some intervening element such as a corrugation wall


198


, or the tube


20


itself.




Thus, provided with apertures


226


, the core


22


may provide access for a double-prong tool for fastening, even if corrugations are not required for structural reasons. The provision of tabs


228


provides locations suitable for applying penetrating fasteners or other fasteners (glue, welding, bonding, etc.).




Referring to

FIG. 25

, a stapler


232


may be configured to have one or more prongs


234


,


236


. In the illustrated embodiment the active prong


234


comprises a head


234


or other apparatus for dispensing a fastener


212


. Meanwhile, an opposing prong


236


provides an anvil


236


for receiving the fastener


212


and folding the fastener over. Accordingly, an aperture


30


, or the synchronous corrugations


30


-


191


of an alignment region


210


, in the core


22


provides access for the anvil prong


236


. Otherwise, the single prong


234


or head


234


of the stapler


232


renders the stapler


232


a mere tacker.




Other fastening devises may be similarly operable. For example, the two prongs


234


,


236


in other tools may represent a screwdriver and a wrench, or a wrench and another wrench. Various types of drivers having different head shapes may be suited to different types of fasteners. The prongs


234


,


236


may be wrenches, screwdrivers, other types of shaped drivers, or the like, necessary to operate at both extrema of any particular choice of fastener


212


.




Referring to

FIGS. 26-28

, a tube


20


may be fastened to a tab


228


by a fastener


212


. The fastener


212


may extend radially


44


through the tab


228


first, or through the tube


20


first. In certain embodiments, tabs


228




a


,


228




b


may flank a tube


20


, and thus support both extrema of the fastener


212


. In other embodiments, the tube


20


may be radially


44


outboard of the tab


228




a


, or may be positioned in board radially


44


with respect to the tab


228




b


. If the tube


20


is inboard of the tab


228




b


, then the tab


228




b


may preferably extend from a flange


12


,


14


away from the opposing flange


14


,


12


, respectively.




Referring to

FIGS. 29-30

, other options in corrugating flanges


12


may include corrugating in multiple dimensions. For example, in the embodiment of

FIG. 29

, corrugations


30


have side walls


19


that are themselves undulating or otherwise varying in circumferential displacement along any radial path. The corrugation walls


19


may be configured in any suitable shape. Sinusoidal shapes, rectangular, angular, acute angular, obtuse angular, trapezoidal, and the like may be suitable configurations. Moreover, the wall


19


need not extend at right angles with respect to a surface


90


. The side walls


19


may be applied to any corrugation shape discussed herein.




One of the benefits of the process of corrugating the sidewall


19


is the possibility of enhancing selective breakage and distortion in order to render the entire reel


10


more survivable. That is, catastrophic failure wherein the flange


12


separates from the tube


20


or wherein the flange


12


breaks, separating the core


22


from the outer region


200


, or wherein the tube


20


breaks, releasing its containment of the stranded material held thereon. Catastrophic failure is to be avoided. Distorted, damaged, chipped, partially fractured, and other conditions of flanges


12


,


14


may leave a flange highly serviceable, so long as the tube can exert radial force on the core


22


,


190


, and so long as the outer portion


200


may exert axial restraint on the stranded material.




In certain embodiments, ribs


244


may actually be corrugated in multiple dimensions. A flange


12


may effectively provide recesses


191


flanked in a circumferential direction by adjacent ribs


244


. The adjacent ribs


244


are corrugated in any suitable shape, whether sinusoidal, circular, curved, angular, and so forth as described with respect to the embodiment of FIG.


29


.




The embodiment of

FIG. 30

may necessarily provide less stiffness in certain orientations. Nevertheless, the flange


12


of

FIG. 30

may be modified in certain embodiments to render a base


240


, fastenable to a closure


242


thereof as a second piece for stiffening and bonding. Thus, the closure


242


may bond to the base


240


, boxing in the ribs


244


, and producing significantly more stiffness. Since maximum stress is located at the outermost fiber of any structure in bending, the base


240


and closure


242


provide members suitable for supporting the bending loads experienced by the flange


12


.




A cavity


246


between the base


240


and the closure


242


renders the recess


191


a completely closed box. Contact regions


248


may include the core


22


, and specifically the cap portion


23


, bonded or otherwise secured to the closure


242


. Likewise, the edge


16


may provide a suitable contact region


248


for the base


240


and the closure


242


. The ribs


244


may be bonded to the closure


242


, or may be left free. One advantage of leaving the ribs


244


nonbonded to the closure


242


, may be to reduce stiffness that might otherwise provide catastrophic failure. The ability of the ribs


244


to move independently from the closure


242


may increase controlled, limited fracture to selectively absorb a certain amount of drop energy in order to effectively maintain the dimensions and serviceability of a flange


12


.




Referring to

FIGS. 31-39

, the twin sheet concept may be considered as an optional alternative to the embodiment of FIG.


30


and may be implemented in numerous configurations. In general, a base


240


may be formed in any suitable shape. A closure


242


may be formed in any complementary shape.




The cavities


246


resulting from the fastening, securing, bonding, or otherwise positioning the base


240


and closure


242


together, may be completely empty, or may be provided a rib


244


parallel to the plane of cross-section illustrated. Such a rib


244


may be angled at any suitable angle, but may preferably be designed to completely fill the cavity


246


, extending to the closure


242


. In this way, additional stiffness may be selectively added as appropriate in any given design.




In general, each base


240


may secure to a closure


242


over several suitable contact regions


248


. A fastener may extend through the base


240


and closure


242


, or a bonding method may be implemented. For example, glue, solvent, welding, contact pressure, melting, rivets, screws, bolts, staples, or other fastening means may be effective to secure the closure


242


structurally to the base


240


.




Referring to

FIG. 31

, while continuing to refer generally to

FIGS. 31-39

, the wall


250


may be suitable for use in the corrugated core


190


, the outer region


200


, both, or for the entire region extending between an arbor aperture


32


and the edge


16


. In general, the cross-section illustrated may be regarded as either a circumferential or radial view (line of sight of a viewer), with differing results. That is, increased stiffness is typically expected when the cross-sections illustrated (see

FIGS. 31-39

) is normal to a radius of the flange


12


.




In certain embodiments, the wall


252


may be both rectangular in cross-section, and symmetric in construction. That is, the base


240


and the closure


242


may have matching, mirror-image structures providing contact regions


248


, and enclosed cavities


246


.




Referring to

FIG. 33

, anon-symmetric wall


254


relies on a rectangular cross-section for the base


240


, is secured to the closure


242


in a contact region


248


to form a wall


254


of increased stiffness. The dimensions of the base


240


and closure


242


in each of the embodiments illustrated herein may be selected to provide the precise stiffness and strength desired. Accordingly, wall thicknesses, specific dimensions of corrugations, and the overall width of the wall


250


-


272


may be selected to optimize the use of materials, the overall weight, the structural strength, and the ability to selectively fail in a particular region of a flange


12


in order to preserve the overall integrity of a reel


10


containing a strand of material.




Referring to

FIG. 34

, a wall


256


may be offset or counter-symmetric. That is, the wall


240


and the closure


242


may be identical. According to certain embodiments described herein, the base


240


and the closure


242


may have a certain right-handedness or left-handedness. Accordingly, even if not offset in a circumferential direction, the base


240


and closure


242


may not be mirror images of one another, rather, they may be identical, and have a right or left handed orientation, resulting in a counter-symmetric arrangement.




In certain embodiments, the wall


256


may be viewed as having two parts


240


,


242


which in the region of the outer portion


200


, or in the region of the core


190


, or in the region from the arbor aperture


32


out to the edge


16


of the flange


12


, may be mirror images of one another. Nevertheless, by rotating about an axis


50


of the flange


12


, the base


240


and closure


242


become somewhat offset from one another. Thus, certain flexibility and certain stiffness considerations may be balanced against one another as compared to a symmetric wall


252


, or non-symmetric wall


254


.




Referring to

FIG. 35

, a wall


258


may be constructed to provide a base


240


having ribs


244


producing cavities


246


, which may or may not be filled with cross ribs


244


for extending substantially parallel to the cross-sectional plane of the wall


258


illustrated. In general, a closure


242


may have contact regions


248


associated with each rib


244


, and with other selected points of contact in the flange


12


.




Referring to

FIG. 36

, in an alternative embodiment, a wall


260


may be provided with symmetric or counter symmetric construction. That is, the base


240


and the closure


242


may each be provided with ribs


244


and contact regions


248


between respective ribs


244


and the opposing part


242


,


240


. Thus, the parts


240


,


242


may actually be identical to one another or may be symmetric with respect to one another, or may be made in a suitable arrangement for interleaving, so to speak, the ribs


244


of the base


240


and the closure


242


.




Referring to

FIG. 37

, in one alternative embodiment, a triangular cross-section in a wall


262


may include non symmetric portions, a base


240


and a closure


242


. The contact region


248


may be large or small, and may include an elongation of contacting vertices in order to preclude overly sharp angles or limited sizes of contact regions


248


. In certain embodiments, two bases


240


, or a closure


242


similar to a base


240


may be configured to produce a diamond shape. Nevertheless, in most applications of reels


10


, the desire for a flat surface along an inside face


90


of a flange


12


militates in favor of a substantially flat surface


90


, or a surface that is sufficiently small in void fraction that stranded materials do not bulge into a recess


31


of a corrugation


30


in the outer region


200


.




Referring to

FIG. 38

, a wall


264


provides a construction illustrating both a closure


242


that can be completely filled in, as well as a wall


240


, which may serve as a closure


242


having a very small void fraction. Thus, the uneven distribution of the cavities


246


on alternating sides of the base


240


minimizes the opportunity for a stranded material to bulge into the cavity


246


, while still providing substantial stiffness.




Referring to

FIG. 39

, a comparison of alternative embodiments of reels


266


,


268


,


270


,


272


or walls


266


,


268


,


270


,


272


of reels


10


illustrates orientations that may be relied upon.

FIGS. 32-38

represent radial views of cross-sections (viewer looking along a radius of a reel


10


), whereas the views of

FIG. 39

are circumferential views. Accordingly, spiral corrugations as described hereinabove, may be implemented according to the embodiments of FIG.


39


. Furthermore, cross-sections at specific radii that do not vary may be alternative embodiments for which the cross-sections of

FIG. 39

are suitable.




The wall


266


has a rectangular cross-section from a circumferential view. Similarly, the cavity


246


may include a rib


244


substantially parallel to the cross-section illustrated. However, such a rib


244


can help according to the extent of its particular filling or bracing across the cavity


246


, and may be angled at any suitable angle in any of three dimensions, in order to provide the right balance of manufacturability, stiffness, strength, and selective fracture or distortion in order to protect the integrity of the reel


10


.




The wall


268


illustrates a trapezoidal construction with an optional rib


244


, which may be deleted in certain embodiments. In the embodiments shown, the tab


228


may be replaced with a recess


286


such that the tube


20


will penetrate the flange


12


, rather than vice versa. In this embodiment, the optional rib


244


provides additional stiffnless since bending moments applied to the wall


268


may reveal weak spots in the contact regions


248


.




In the wall


270


, the base


240


and the closure


242


are parallel. That is, the base


240


and closure


242


extend radially parallel to one another. Alternatively, in the wall


272


, the base


240


tapers as it extends in a radial direction


44


away from the axis


50


to minimize the space in the cavity


246


or the weight of the rib


244


, if the cavity


246


is filled with an optional rib


244


at periodic locations. One may note that the base


240


may be configured to occupy the space of the closure


242


, and a closure


242


may be constructed to occupy the place of the base


240


. Nevertheless, in general, a flat surface is desired for supporting the stranded material on a reel


10


.




Some of the parameters available for varying the structural stiffness, strength, weight, and over all performance, as well as the resistance to distortion may rely on altering the geometries of the walls


266


-


272


. For example, a wall thickness


274


may be varied by selecting a size for corrugations


30


,


192


and recesses


31


,


192


that will maximize spacing distance, in order to maximize stiffness. Alternatively, a balance may be achieved, in which a wall thickness


274


and the thickness


276


of the base


240


, along with the thickness


278


of the closure


242


may be balanced against one another to provide a combination of weight, stiffness, and strength in tension, bending, compression, and buckling.




Similarly, the inner radius


280


, outer radius


282


and flange radius


284


may be selected to balance the strength of the tabs


228


against the strength of the overall wall


250


-


272


in view of the strength of a tube


20


, and the fasteners


212


. Other parameters that may be considered are the size of fastened contact regions


248


. The degree or extent of bonding or fastening may be provided in order to allow the base


240


to separate selectively from part of the closure


242


, thus absorbing impact energy and preventing catastrophic failure.




Various plastic molding techniques may produce flanges in accordance with the invention. These techniques may include blow molding, injection molding, vacuum forming, roto-molding, and fabrication from various shapes of stock including sheet stock, pressing, die stamping, and the like. Conventional molding techniques lack the regions of closed cross-section wherein a base layer


240


may be secured by a suitable method such as bonding to a closure layer


242


over an extensive contact region in order to make corrugated, closed cross-sections as contemplated for the invention.




Individual layers


240


,


242


may formed by any method individually, and later assembled. Alternatively, in selected processes, such as blow molding and roto-molding, care must be exercised in the spacing of the mold in the contact region. That is, in conventional molding, the distances required for the extensive lengths of a contact region may compromise structural integrity if left at conventional sizes. Accordingly, a mold may be fashioned having suitable dimensions to support the proper structural integrity over extended lengths and widths of contact regions


248


during molding. These distances may typically not be distances used conventionally for the molding techniques identified.




From the above discussion, it will be appreciated that the present invention provides a method and apparatus for balancing strength, stiffness, fracture, and toughness in reels and spools, incorporating material properties. Accordingly, corrugations may be adapted to several configurations and a design process calculated to protect stranded materials contained on a spool or reel.




Cost of material, molding speeds, and the like may all be affected as desired by selection of specific design criteria in accordance with the invention. Spools and reels from small unitary sizes on the order of inches or smaller may be produced according to the invention. Likewise, reels of substantial size for supporting large amounts of heavy materials such as wire, cable, wire rope, and the like may be designed in sizes having an order of magnitude on the order of feet.




The present invention may be embodied in other specific forms without departing from its basic structures, methods, or other essential characteristics as broadly described herein and claimed hereinafter. The described embodiments are to be considered in all respects only as illustrative, and not restrictive. The scope of the invention is, therefore, indicated by the appended claims, rather than by the foregoing description. All changes coming within the meaning and range of equivalency of the claims are to be embraced within their scope.



Claims
  • 1. An apparatus for receiving, storing, and dispensing a stranded material, the apparatus comprising:a tubular member having an inner surface, an outer surface, an axial direction and a radial direction, and configured to receive a stranded material wrapped therearound; a first flange configured to engage the tubular member and comprising a core portion, having an arbor aperture therein and configured to support the apparatus on an arbor through the arbor aperture; and an outer portion extending radially away from the core portion to an outer edge and configured to restrain the stranded material in an axial direction; a fastener to secure the tubular member to the first flange; and the first flange further formed to have an inner access void extending axially into the core portion and an outer access void extending axially into the outer portion to be radially opposite one another with respect to the inner and outer surfaces of the tubular member to introduce the fastener radially through at least one of the inner and outer surfaces.
  • 2. The apparatus of claim 1, wherein the fastener is selected from the group consisting of a screw, a bolt, a staple, a rivet, and a combination comprising at least one thereof.
  • 3. The apparatus of claim 2, wherein the inner and outer access voids are sized, shaped, and aligned to provide access for a double prong tool to introduce the fastener.
  • 4. The apparatus of claim 3, wherein the inner and outer access voids provide access for a double pronged stapler.
  • 5. The apparatus of claim 3, wherein the inner and outer access voids provide access for a double pronged riveter.
  • 6. The apparatus of the claim 3, wherein the inner and outer access voids provide access for a pair of pliers.
  • 7. The apparatus of claim 1, wherein the inner and outer access voids are further configured to receive double prongs of a stapling tool axially extending into the core portion and the outer portion simultaneously for dispensing the fastener substantially radially through the tubular member.
  • 8. The apparatus of claim 1, wherein the first flange further comprises a first sleeve extending axially with respect thereto and configured to fit against at least one of the inner surface and the outer surface.
  • 9. The apparatus of claim 8, wherein the first flange further comprises a second sleeve configured to fit, radially opposite the first sleeve, against the tubular member.
  • 10. The apparatus of claim 1, wherein the first flange further comprises a first tab, circumferentially discontinuous and extending axially with respect to the flange to fit radially against at least one of the inner surface and the outer surface.
  • 11. The apparatus of claim 10, wherein the first tab is configured to receive a fastener extending substantially radially therethrough and radially through the tubular member.
  • 12. The apparatus of claim 10, wherein the first flange further comprises a second tab configured to fit, radially opposite the first tab, against the tubular member.
  • 13. The apparatus of claim 12, wherein the first and second tabs are configured to receive a fastener extending substantially radially therethrough for retaining the tubular member therebetween.
  • 14. The apparatus of claim 1, wherein the inner and outer access voids are openings selected from the group consisting of an axial through aperture, a recess corresponding to a corrugation, and a combination of an aperture and a recess.
  • 15. The apparatus of claim 1, wherein the core portion and the outer portion are homogeneously molded as a single piece.
  • 16. The apparatus of claim 1, wherein the core portion and the outer portion are discrete, separable pieces configured to be held together with the tubular portion in the apparatus by a fastener extending through the core portion, the outer portion, and the tubular portion.
  • 17. The apparatus of claim 1, wherein the first flange is formed to have radially extending corrugations and further comprises a closure configured to stiffen the first flange by creating a closed cross-section in the corrugations.
  • 18. The apparatus of claim 1, further comprising a second flange configured to engage the tubular member, the tubular member further configured to secure to the first and second flanges to support an axial tensile force therebetween.
  • 19. The apparatus of claim 1, wherein the first and second access voids are configured to provide simultaneous access to a space located radially inside the inner surface and a space located radially outside the outer surface for a double prong fastening tool.
  • 20. An apparatus for receiving, storing, and dispensing a stranded material, the apparatus comprising:a tubular member, having an axial direction and a radial direction, to receive a stranded material wrapped therearound; and a first flange engaging the tubular member and comprising a core portion, having an arbor aperture therein to support the apparatus on an arbor through the arbor aperture, an outer portion extending radially away from the core portion to an outer edge to restrain the stranded material in the axial direction, the core portion being corrugated to comprise a plurality of web portions, each web portion of the plurality of web portions being offset axially from an adjacent web portion, and a plurality of connecting walls, each connecting wall of the plurality of connecting walls extending between two adjacent web portions of the plurality of web portions, the plurality of connector walls further having a plurality of corrugations alternatingly displaced in a circumferential direction along a radial path.
  • 21. The apparatus of claim 20, wherein the first flange further comprises a base, having corrugations, and a closure having corrugations, and wherein the closure stiffens the first flange by creating a closed cross-section in corrugations of the base.
  • 22. An apparatus for receiving, storing, and dispensing a stranded material, the apparatus comprising:a tubular member, having an axial direction and a radial direction, to receive a stranded material wrapped therearound; a first flange engaging the tubular member and comprising an arbor wall defining an arbor aperture to support the apparatus on an arbor through the arbor aperture, and an outer portion extending radially away from the arbor wall to an outer edge to restrain the stranded material in the axial direction; the first flange wherein the outer portion has a plurality of corrugations in which at least one corrugation thereof extends from substantially the arbor wall to substantially the outer edge; and the corrugations of the outer portion further comprise outer webs, offset from one another, and connector walls extending between adjacent outer webs, the connector walls having a plurality of corrugations alternatingly displaced in a circumferential direction along a radial path.
  • 23. The apparatus of claim 22, further comprising a second flange engaging the tubular member, the tubular member further being secured to the first and second flanges to support an axial tensile force therebetween.
RELATED APPLICATIONS

This Patent Application is a continuation in part of U.S. patent application Ser. No. 09/434,609 filed on Nov. 5, 1999 and issued as U.S. Pat. No. 6,179,245 on Jan. 30, 2001.

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Entry
Beacon Reel Co. brochure, date unknown, received by Applicant at Interwire Trade Exposition, May 2001, Atlanta, Georgia.
Sonoco Crellin brochure, date unknown, received by Applicant at Interwire Trade Exposition, May 2001, Atlanta, Georgia.
Sonoco Crellin brochures, pp. 1-29, date unknown, received by Applicant at Interwire Trade Exposition, May 2001, Atlanta, Georgia.
GMP-Genpak brochures, pp. 1-7, date unknown, received by Applicant at Interwire Trade Exposition, May 2001, Atlanta, Georgia.
Reel Core brochures, pp. 1-8, date unknown, received by Applicant at Interwire Trade Exposition, May 2001, Atlanta, Georgia.
Enviroreel brochures, pp. 1-14, date unknown, received by Applicant at Interwire Trade Exposition, May 2001, Atlanta, Georgia.
The Ru-Wood Co brochure, date unknown, received by Applicant at Interwire Trade Exposition, May 2001, Atlanta, Georgia.
Reel Options brochure, date unknown, received by Applicant at Interwire Trade Exposition, May 2001, Atlanta, Georgia.
Mossberg Industries, Inc. brochures, pp. 1-9, date unknown, received by Applicant at Interwire Trade Exposition, May 2001, Atlanta, Georgia.
The George Evans Corp. brochure, date unknown, received by Applicant at Interwire Trade Exposition, May 2001, Atlanta, Georgia.
Pittsfield Plastics Engineering, Inc. brochures, pp. 1-8, date unknown, received by Applicant at Interwire Trade Exposition, May 2001, Atlanta, Georgia.
Pittsfield Plastics Engineering, Inc. brochure, date unknown, received by Applicant at Interwire Trade Exposition, May 2001, Atlanta, Georgia.
Madem brochure, date unknown, received by Applicant at Interwire Trade Exposition, May 2001, Atlanta, Georgia.
R-2 Systems brochures, pp. 1-11, date unknown, received by Applicant at Interwire Trade Exposition, May 2001, Atlanta, Georgia.
Woodland Container Corp. brochure, date unknown, received by Applicant at Interwire Trade Exposition, May 2001, Atlanta, Georgia.
P & R Speciality brochure, pp. 1-4, date unknown, received by Applicant at Interwire Trade Exposition, May 2001, Atlanta, Georgia.
Carris Coilpack brochure, date unknown, received by Applicant at Interwire Trade Exposition, May 2001, Atlanta, Georgia.
Continuation in Parts (1)
Number Date Country
Parent 09/434609 Nov 1999 US
Child 09/774389 US