Patent Grant
7048226
This invention relates to packaging materials generally, and is more specifically related to reels or spools for packaging.
Reel packages and spool packages are used for the packaging of products which are produced in a continuous and connected manner and are packaged in large number or high count continuous lengths for long run use, including automated use. These products are typically packaged in a “ribbon wound” (layer on layer) or convolute manner on a central core of a size closely matching the width of the manufactured product, so that the user of the product may unwind the product in an orderly, controlled manner for use or installation in other products.
Products having a narrow face width may be wound so as to traverse the center core, alternately reversing direction within the confines of the sidewalls. The resulting package has multiple layers of product wound over the core, and between the sidewalls. Long, unbroken lengths of product may be packaged and stored by use of the elongated core with product that is traverse wound. Reels or spools that are useful with this type of packaging may have cores that are relatively long, and/or of relatively large diameter.
Products which are packaged on reels and spools are made of a wide variety of raw materials including metals, plastics, textiles and other products. The stiffness of some continuous products is such that the package must have a core with a large circumference (6 to 20″) to prevent undesired curling or bending of the manufactured product. Additionally, packages for these products have sidewalls or flanges which act as retainers to keep the product from slipping off and becoming twisted, bent, damaged or difficult or impossible to use. The sidewalls for larger reels used for relatively rigid products range in size from 10″ to 48″, and are made of corrugated board, solid fibreboard, Masonite, plastic, plywood, or other suitable materials. While there are technical differences between spools and reels as these terms are used in the art, the term “reel” is used herein to indicate reels and spools used for packaging.
The cores of prior art reels are made of a number of substrates such as pre-formed and pre-cut styrofoam discs, or pressed wood, plywood discs, or other suitable materials. Another embodiment employs rings of paper tubing cut from pre-made large diameter spiral or convolute paper tubes of a size or width which very nearly matches the width of the product being packaged or in the case of traverse wound products, a size which allows for appropriate winding area considering the weight and volume of the package. The sidewalls or flanges are then attached or fastened in a manner which protects the product from external damage, confines the product to minimal sidewise movement, and keeps the product wound in a controlled convolute or traversed package, thereby allowing for orderly unwinding of the product by the user.
The methods employed in the prior art for joining sidewalls or flanges to cores are varied. Since some of the cores are discs with solid sides (such as styrofoam or pressed wood), adhesives are applied to these sides and the sidewalls of paper and corrugated board are brought into contact and unitized by the curing of the adhesive.
Other packages are of such large diameter that factors such as weight and cost make solid cores impractical. In such cases, cores are formed of paper rings of appropriate diameter and face width (matching the product to be convolutedly or traverse wound) which are centered on sidewalls with holes punched to accept flat head threaded bolts or rods of a length appropriate to the width of the reel (with allowance for the thickness of the sidewall substrates). The bolt holes are positioned in close proximity to the rings, so that when they are tightened, they eliminate, or minimize, rotation of the ring. The second sidewall is positioned, and bolts are pressed through both sidewalls, and capped head or “T” nuts are attached to the bolts and tightened, creating a circular package or reel customized to the product's winding method and load area. The load area is the area from the ring or core to the outside diameter of the flange or sidewall is the load area.
The use of such bolts or rods produces a strong package. However, these packages are relatively expensive due to the cost of the bolts or rods, and due to the assembly time and labor required.
The sidewalls or flanges often have punches or apertures for different functions positioned on its face such as:
The present invention is an improvement of reel or spool packages. The package of the present invention comprises opposing sidewalls or flanges formed of the appropriate material. A core is positioned between the sidewalls. An insert is positioned into a center aperture of the core. A flowable adhesive material is injected through an aperture in the sidewall and into a chamber that is a formed between the insert, the core and the sidewall. The flowable material, upon setting, connects the sidewalls and core to form the package. The resulting package is extremely strong, and will replace most applications that incorporate packages reinforced by the use of bolts or rods.
It may not be desirable to form, or fill, the length of an elongated core with polyurethane. In one embodiment of the invention, the reel package of the present invention comprises opposing sidewalls 2, 4 or flanges formed of the specified or appropriate substrate.
A core 6 is present between the sidewalls. The core may be elongated, hollow and cylindrical, or tubular. The core is positioned to be concentric with the sidewalls. The core may be formed of wood, paper or plastic, or other suitable material.
A pair of inserts 8 are present within the core, and at opposite ends of the core, as shown in
The first end 10 is of a diameter that allows the insert to be received by the center aperture of the core. The first end should be of sufficient diameter so that there is no material gap between the core and the first end that will permit a large amount of flowable material to be transported out of the expansion chamber. In a typical embodiment, the core will have a circular cross section, and the first end will also be circular, and is preferred to have a void therein. Other geometric configurations of the chamber(s) or void(s) may be incorporated to accommodate specific user requirements.
The second end 12 of the insert is smaller than the first end. The second end concentrically engages an aperture in the sidewall or flange 2 when the insert is fully inserted into the core, and positions the sidewall relative to the core. Alternatively, the second end of the insert may abut the end of the sidewall.
A center trunk 18 connects the first end and the second end. The center trunk may be hollow as shown, with a center aperture traversing he center trunk from the first end of the insert to the second end of the insert. The use of a hollow center trunk reduces the amount of flowable material that is required, which reduces the cost of the reel, and also reduces the weight of the package. As will be important in some applications, the center trunk allows an axle 20 to traverse the center of the reel, since such axles are used to wind and unwind the product relative to the reel.
At least one aperture is formed in the insert for receiving the flowable material. As shown, three apertures 22 are present in the second end. One or more of the appropriately shaped apertures in the sidewalls allow for injection of the flowable material, and serve as an attachment feature that enhances bond strength of the sidewall to the core. The apertures may be conically shaped voids. The use of the inverse frusto-conically shaped voids as shown in
The flowable material is a liquid or semi-liquid material, which will harden or set to bond the components of the reel or spool. The flowable material acts as adhesive to connect the insert to the core. The second end of the insert holds the sidewall in place against the core, and the package is formed.
The flowable material is preferred to be comprised of two-part expandable polyurethane foam. Polyurethanes are formed by isocyanates, which are reacted with agents having a hydroxyl group, such as polyols. These materials may be produced as foam that expands as it is dispensed, and which sets after reaction of the components.
The foam 24 may be delivered through the apertures 22 into the expansion chamber 14. The expansion chamber is defined by the void formed between the insert, the inside diameter of the core and the portion of the sidewall that bounds the inside of the core. The foam is delivered in a metered dosage. The foam expands and fills the chamber, and the reaction of the components causes the foam to set and become solid in the shape of the chamber. The chemistry of the foam formulation may be altered to change density, rigidity and flexibility as required by package stresses. The expanded foam is a very aggressive and effective adhesive medium. As the foam cures, it adheres to each of the sidewalls, it performs the dual function of reinforcing the core and connecting the sidewalls and core to form the completed reel.
The use of an insert 8 on each end of the core 6 avoids filling the entire center of the core with flowable material, which reduces the cost of material and reduces filling time, while adding strength to the package. A hollow area 26 is present within the core and between the inserts. The length of the hollow area is dependent upon the overall length of the core.
Another embodiment is shown in
As with the embodiment discussed above, the reel package comprises opposing sidewalls 102 or flanges formed of the specified or appropriate substrate.
A core 106 is present between the sidewalls. The core is typically hollow and cylindrical, and is concentric with the sidewalls. The core may be made of paper or plastic, or other suitable material, as discussed above
Inserts 108 are present within the core as shown. The insert is positioned into a center aperture of the core through a center aperture in the sidewall, with an end 110 of the insert engaging the center aperture of the core. The opposite end 112 of the insert abuts the outside surface of the sidewall 102. An expansion chamber is present 114 between the insert, the core and the sidewall.
The first end 110 of the insert has a diameter that allows the insert to be received by the center aperture of the core. The first end should be of sufficient diameter so that there is no material gap between the core and the first end. The use of a curved lip 116 around the perimeter of the first end facilitates insertion of the insert into the core, while retarding removal of the insert.
The second end 112 of the insert is larger than the first end. The second end abuts the sidewall when the insert is fully inserted into the core, holding the sidewall against the core.
A center trunk 118 connects the first end and the second end. The center trunk may be hollow as shown. The use of a hollow center trunk is as discussed above.
At least one aperture is formed in the insert for receiving the flowable material. The flowable material is applied to the expansion chamber as discussed above.
The invention works well with reel packages having diameters of 10 inches to 48 inches, and is particularly cost effective with regard to larger reels. Other applications of the process of the invention lend themselves to the dramatic cost savings in eliminating components and complexity of assembly. For example, plywood sided reels or spools that currently use the “Bolt-Thru” method of assembly may be formed by the method herein. The formulations achievable with the foam and the light wallpaper tubes to compartmentalize the application are very effective low cost replacements for the cores and assembly processes of the prior art, without changing the plywood used as the sidewall medium. The bond strength and variable density features are ideal for many heavy-duty applications.
Since the polyurethane foam is a highly effective bonding agent, plastic spools that require solvent bonding and complex tooling to impart strength and gain dimensional integrity are unnecessary. The use of simplified sidewalls bonded to a high strength core according to the present invention is an effective replacement. The elimination of harmful solvents is considered a benefit to the safety of the work place. The urethane foam is a safe bonding agent, and has an enviable record in industrial applications.
This Application is a continuation in part of application Ser. No. 10/042,687 filed Aug. 21, 2001, which is a continuation of application Ser. No. 09/383,908, filed Aug. 26, 1999, U.S. Pat. No. 6,341,745 B1.
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| Number | Date | Country | |
|---|---|---|---|
| 20050001087 A1 | Jan 2005 | US |
| Number | Date | Country | |
|---|---|---|---|
| Parent | 09383908 | Aug 1999 | US |
| Child | 10042687 | US |
| Number | Date | Country | |
|---|---|---|---|
| Parent | 10042687 | Aug 2001 | US |
| Child | 10447807 | US |
