1. Field of the Invention
This invention relates to a lightweight, collapsible reel for supporting cable, conduit or tubing wound therearound and especially to a reel collapsible to a thickness no greater than approximately the thickness of the two side by side circular end flanges of the reel. The components of the reel are especially adapted for fabrication of synthetic resin material which results in an extremely lightweight reel that retains its load bearing properties and characteristics after repeated in-field use of individual reels.
Collapsible reels for supporting products such as elongated stretches of a cable, conduit or tubing wound around the core of the reel are known but have not heretofore gained widespread recognition in the field. Although deficiencies in marketing of past collapsible reels may have been a contributing factor in limited customer demand for prior reels, the inability of such reels to fully collapse and the excessive weight of the reels even when collapsed no doubt has been a limiting deterrent to widespread adoption and use.
2. Description of the Prior Art
Brown, in U.S. Pat. No. 3,791,606, illustrates a cable spool said to be collapsible but as illustrated in
Similarly, in Culp U.S. Pat. No. 5,649,677, the patentee provides a collapsible spool having a plurality of foldable arms 16 which fold into a state of maximum collapse, as illustrated in
The present invention provides a lightweight, collapsible reel for cable, conduit or tubing in which a pair of opposed, relatively thin, generally circular, coaxially end flanges of substantially equal diameter are interconnected by at least three foldable cable, conduit or tubing support units. The reel, when fully collapsed, is no thicker than twice the thickness of each individual end flange. The support units, which each include a pair of hingedly interconnected end-to-end leg segments that cooperate in their fully extended, straight-line positions, to present a generally triangular cage internal of the space between the flanges for wrapping of cable, conduit, tubing or the like around the support units.
The end flanges and support units are designed and especially adapted to be individually molded as one-piece from synthetic resin material. Preferably, the flanges in the leg segments of the support units are molded of a synthetic resin material in prefabricated molds utilizing a resin such as polypropylene containing a conventional blowing agent so that a thin, relatively tough, abrasion resistant outer skin is formed from compaction of the resin at the surface of the part while the lower density resin produced by the blowing agent serves as an internal support for the skin.
In order to minimize the overall weight of the reel without sacrifice of its utility and strength characteristics, each of the unitary flanges has an inner relatively flat face, and an outer cellular face defining a plurality of weight saving spaces. In a preferred embodiment, the outer portion of each of the flanges includes an outer annular band of end-to-end rectangular pockets, an intermediate annular section of web defining trapezoidal spaces, and an innermost central section of generally polygonal areas.
The leg segments of the support units are preferably molded to define a series of elongated, side by side ribs which increase the beam strength of the individual segments while saving weight. The flanges are provided with a series of elongated recesses located to complementally receive the rib portions of respective leg segments of the support units. When the reel is collapsed by folding of the support units, the rib portions of the leg segments of each support unit, which face outwardly relatively, are fully received in respective recesses in the flanges so that the inner faces of the flanges move into interengaging, side by side relationship. The result is a reel when collapsed that is no thicker than the thickness of the side by side flanges.
The leg segments of respective support units are pivotally interconnected by a pin. Individual leg segments, which are all of identical construction, are all molded separately. Each of the ribbed leg segments has openings at opposite ends thereof. Pivot pins are inserted in the openings in one end of three leg segments. The three leg segments with the inserted pins, are then placed in a mold for a respective end flange with the pivot pins located 120° apart in spaced relationship as required for formation of the triangular cable, conduit or tubing cage to be defined by the support units. The leg segments with the inserted pins are located in the mold such that the ribbed surfaces face inwardly of the mold cavity. The mold also incorporates cavity defining surfaces for the cellular outer face of each of the molded flanges. By molding the individual leg segments along with the flange itself, the ribs of the leg segments form indentations or recesses in the inner surfaces of the flange so that the leg segments which are pivotally connected to the flange are inherently complementally received in the formed recesses. It is to be understood in this respect that a mold release agent is applied to the ribbed surfaces of the leg segments that are pivotally joined to a respective flange so that upon removal of the molded part from the mold, the leg segments that have been molded in place may readily be pivoted to their open, outwardly extended positions.
Upon completion of two molded flanges with incorporated leg segments, the leg segments of both flanges are extended outwardly and pivot pins inserted within aligned holes in what becomes end-to-end leg segments of respective support units.
The end flanges are provided with central openings which are coaxial in the completed reel so that a guide rod or pipe may be inserted through the aligned openings to guide or support the reel as a cable, conduit or tubing is unwound from the expanded reel.
An important advantage of the present collapsible reel is the fact that manufacture of the reel of synthetic resin material as explained permits recycling of the reel at the end of its useful life, which in most instances should be at least the order of fifty cycles of use. Another advantage is the minimal thickness of a fully collapsed reel, which is ⅙th to {fraction (1/7)}th that of a conventional reel. The no more than 2× flange thickness of each collapsed reel results in significant savings in return transportation costs of empty reels in collapsed condition from a space standpoint, in that a significantly larger number of reels may be transported in the space that would have been taken up in the transport vehicle by conventional reels. In addition, minimization of warehousing space required for empty reels provides significant cost savings. The collapsed reels are much easier to handle and maneuver because of the decreased weight as compared with conventional plywood reels.
The collapsible reel, broadly designated by the numeral 10 in the drawings, is especially adapted in its expanded condition, as shown in
For simplicity, in view of the identical nature of flanges 16 and 18, the same component parts of each of the flanges 16 and 18 are given the same number in the drawings. Thus, as is apparent from
Three foldable cable, conduit or tubing support units 24 are hingedly connected to opposed inner faces 20 of end flanges 16 and 18. Each support unit 24 includes a pair of identical leg segments 26 and 28 which are joined end-to-end by respective pivot pins 30 as best shown in
The ends of leg segments 26 and 28 which are an end-to-end relationship as shown in
The extremity of each of the ribs 32b of leg segments 26 and 28 remote from cylindrical portions 36 has a circular end surface 32b′ while the extremities of ribs 32a and 32c of each leg segment 26 and 28 have integral, semi-circular end caps 32a′ and 32c′. The end caps 32a′ and 32c′, and the ends of ribs 32b terminating in circular surfaces 32b′ of each of the leg segments 26 and 28 are provided with a series of aligned coaxial pivot pin receiving openings 40. The cross-openings 40 through end caps 32a′ and 32c′, and the end surfaces 32b′ of leg segments 26 and 28 respectively have aligned, coaxial pivot pin receiving openings 40. The aligned openings 40 at the outer ends of each of leg segments 26 and 28 receive elongated pivot pins 42, each of which projects outwardly beyond the outer surfaces of end caps 32a′, as shown in
Inner faces 20 of end flanges 16 and 18 are defined by relatively thin, planar panel portion 44 (
The wall structure of end flanges 16 and 18 includes outwardly facing cell defining component portions which project in opposite directions from respective panel portions 44, include an outer, annular cellular band 46 made up of a plurality of end-to-end generally rectangular open pockets 48 defined by the outer annular rim portion 50, and inner rim portion 52 and a series of circumferentially spaced, radially extending wall portions 54. The pockets 48 are approximately 1¼″ deep.
A central outboard cellular section 56 of the flanges 16 and 18, best shown in
An intermediate outboard cellular section 62 in each of the flanges 16 and 18 surrounds central cellular section 56 and has a series of generally radial, spaced webs 64 that cooperate with the inner rim portion 52 and web segments 58 to define a plurality of circumferentially extending open trapezoidal areas 66. The areas 66 are also approximately 1¼″ deep.
In those instances where three foldable support units 24 are provided between and pivotally connected to flanges 16 and 18, three radially extending and circumferentially spaced cavity areas 68 are provided in the wall structure panel portion 44 of each of the flanges 16 and 18. The cavity areas 68 have a series of elongated, parallel, transversely spaced recesses for the respective ribs 32a, 32b and 32c of leg segments 26 and 28 of supports units 24 when the support units 24 are in their fully collapsed condition. As is most evident from
When the support units 24 are unfolded to provide an extended reel as shown in
Upon depletion of the supply of cable, conduit or tubing 12 carried by reel 10, the reel 10 may be collapsed to the condition illustrated in
It is also to be seen from
A preferred procedure for manufacture of reel 10 involves pre-molding of a supply of leg segments 26 and 28, which it is to be observed are of identical construction and configuration. The leg segments 26 and 28 may be molded of a suitable synthetic resin such as polypropylene whereby the leg segments 26 and 28 are solid throughout the thickness of the individual leg segments 26 and 28, or in the alternative, leg segments 26 and 28 may be fabricated of a synthetic resin composition in which a resin such as polyproplyene contains an amount of a blowing agent that is compatible with the resin. If formed, for example, from polypropylene which includes a quantity of a blowing agent, during molding of the parts, gases generated by the blowing agent cause the outer surface of the part to become denser than the interior portions of the part, thereby defining a tough, homogeneous, substantially void-free outer skin layer. The thickness of the skin layer will nominally be of the order of 0.060″ to about 0.100″. The overall thickness of the wall structures of flanges 16 and 18 will nominally be about ¼″.
The outer rim portion 50 of each of the end flanges 16 and 18 which define the overall thickness of respective flanges 16 and 18 nominally or about 1½″. The leg segments 26 and 28 generally are about 1⅛″ thick overall. A fully collapsed reel 10, as shown in
The faces of the three leg segments 26 or 28 of support units 24 which face outwardly to define cage 14 when reel 10 is unfolded, are sprayed with a mold release agent. The treated leg segments 26 or 28 with pins 42 in place in openings 40 are strategically placed in the mold for end flanges 16 or 18 with the outer surface of planar bottom portions 34 of leg segments 26 and 28 lying in a plane that is planar with the face 20 of the end flanges 16 or 18 to be molded.
Next, a synthetic resin, such as polypropylene which contains a blowing agent, is introduced into the mold for a respective end flange 16 or 18. The polypropylene/blowing agent composition is then allowed to expand into the cavity of the mold defining an end flange 16 or 18. As previously explained, expansion of the polypropylene by the blowing agent incorporated into the resin formulation causes a relatively tough, homogeneous, substantially void-free outer skin layer to be formed throughout the extent of the end flange 16 or 18, which fully encloses the cellular synthetic resin interior of the part. It is believed that the density of the resin making up the interior of the formed flange decreases in a direction away from the outer skin toward the center of the part.
By forming each of the flanges 16 and 18 with the support units 24 in their normal folded positions thereof, support units 24 may readily be swung outwardly from the finished part because of the release agent that was applied to the surfaces of the leg segments 26 and 28 which face inwardly of the mold during the fabrication of a respective flange 16 or 18. It is important to note in this respect that by molding of the leg segments 26 and 28 in place during forming of the end flanges 16 and 18, the pivot pins 42 are also correctly molded in position. It would be difficult and more expensive to locate the pivot pins 42 in flanges 16 and 18 after molding of the flanges than is the case with molding of the pivot pins in place in flanges 16 or 18.
In addition, molding of the end flanges 16 and 18 with a leg segment 26 and 28 positioned in the flange mold results in the outer surfaces of ribs 32 accurately forming complemental recesses for ribs 32 of each leg segment 26 and 28 when the support units 24 are folded to collapse the reel 10 and thereby bring the faces 20 of end flanges 16 and 18 into proximal interengaging relationship.
The synthetic resin used for molding of leg segments 26 and 28 of support units 24 should be of characteristics and properties such that the formed leg segment part is capable of withstanding and not be deformed by the elevated temperature environment within the interior of the mold(s) used to fabricate end flanges 16 and 18.
Although polypropylene is the preferred resin for fabrication of reel 10, other resins may be employed such as high-density polyethylene. Suitable blowing agents for the resin include thermally decomposable foaming agents such as sodium bicarbonate, azodicarbonamide and the like, an inert gas such carbon dioxide, nitrogen and the like, or an organic compound having a low boiling point such as butane and the like. Additives may also be incorporated in the resin to enhance the physical characteristics of the formed reel, such as glass fibers or the like, particularly in the skin layer of the formed components, and inorganic fillers such as talc, silica, and the like added as a nucleating agent for the forming foam cells. A conventional flexiblizer component may be added to the resin if desired.
Although the preferred reel 10 is constructed as illustrated and described having a cellular outer face in order to save weight and decrease the cost of the reel 10, it is to be understood that if desired the wall structure of end flanges 16 and 18 may be essentially of solid construction except for the recesses receiving the ribs 32 of leg segments 26 and 28. Similarly, support units 24 may be constructed as essentially flat components without the provision of ribs 32. In these instances, the end flanges 16 and 18, and support units 24 would desirably be molded of a synthetic resin having a blowing agent incorporated therein to produce end flanges and support units having a high strength to weight ratio.
When formed of the defined resin and constructed of the dimensions described, a 30″ diameter reel having a fully opened width approximating that of the diameter of flanges 16 and 18 will hold at least about 400 pounds of cable, conduit or tubing wound therearound.
Number | Name | Date | Kind |
---|---|---|---|
2909340 | Whitaker | Oct 1959 | A |
3791606 | Brown | Feb 1974 | A |
5649677 | Culp | Jul 1997 | A |
Number | Date | Country | |
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20050051664 A1 | Mar 2005 | US |