1. Field of the Invention
The present invention relates to zipper assemblies for reclosable packages which are large bags, particularly zipper assemblies which achieve high burst strengths, and the methods for manufacture thereof. These zipper assemblies may include sliders or may have a press-to-close configuration.
2. Description of the Prior Art
Large packages, bags or pouches, such as those used for pet food, charcoal, cat litter and similar items are typically filled and sealed shut, with no reclosure mechanism. These packages may be formed by form fill and seal (FFS) or by other methods. Prior attempts to incorporate a zipper reclosure mechanism have been unsatisfactory due to the unique requirements of a large bag with a relatively heavy load. In particular, filling from the bottom places all of the load on the reclosure during filling. This load can cause the zipper reclosure to fail and open. Similarly, dropping a filled bag onto a pallet or similar rough handling during transportation, as well as exposing a bag to elevated temperatures during transportation, can cause the zipper reclosure to fail.
The prior art has addressed these deficiencies by folding over the end of the package, particularly a multi-wall package, using an expensive label as tape thereby allowing successful filling and transport. Similarly, the prior art has addressed these deficiencies by using a liner peel seal below the zipper and a solid tear line in the zipper flange to provide a fill and transport system that does not rupture and spill the contents. However, these methods have slow rates of production, as well as increased costs of production, and frequently do not result in a satisfactory product for the consumer.
Some farther examples of the prior art which are not entirely satisfactory are found in U.S. Pat. No. 6,979,482 entitled “Multiwall Bag with Zipper and Fin” issued on Dec. 27, 2005 to Hartzell et al. and U.S. Pat. No. 7,090,904 entitled “Enhanced Slider Zipper Multiwall Bag and Associated Methods” issued On Aug. 15, 2006 to Hartzell et al.
Typical prior tamper-evident zipper assemblies are disclosed in U.S. Pat. No. 6,354,738 entitled “Tamper Evident Reclosable Plastic Bag” issued on Mar. 12, 2002 to Buckman et al.; U.S. Pat. No. 4,647,063 entitled “Reclosable Bag with Laminated Liner and Method” issued on Jan. 13, 1987 to Sullivan; and U.S. Pat. No. 5,509,735 entitled “Closure Arrangement Having a Peelable Seal” issued on Apr. 23, 1996 to May.
It is therefore an object of the present invention to provide a zipper assembly for reclosable packages, particularly large bags, formed by form fill and seal or other methods, which provides for high burst strength in bottom filling or top filling configurations, to allow the bags to withstand dropping or shock loading without the zipper reclosure bursting open.
It is therefore a further object of the present invention to provide such a zipper assembly without significant increases in manufacturing and related costs.
It is therefore a still further object of the present invention to provide a method of manufacture for a product achieving the above objects.
These and other objects are attained by providing a zipper assembly for reclosable packages, particularly large bags, wherein the flanges are sealed together with a peel seal or other frangible seal, and one of the flanges is folded so as to be sealed to itself above the peel seal. This causes the external forces on a bag from bottom filling or shock loading (or forces from within the bag, typically created when the bag is dropped on its top or side) to be directed toward the hard seal and redirecting the peel seal from a peel position to a shear position. As the force required to separate a peel seal in a shear position is several times greater than the force required to separate the peel seal in a peelable position, the load-bearing capacity of the package or bag is increased.
These and other objects are similarly obtained by providing a zipper assembly for reclosable package, particularly large bags, wherein one of the flanges is provided in two segments in a T-configuration, with the intersection of the two segments being above the peel seal.
These and other objects are similarly obtained by providing a zipper assembly for a reclosable package, particularly large bags, with a folded flange with a peel seal above the fold and a tear line or other frangible connection at the fold.
The slider zipper is thereby manufactured. In order to subsequently manufacture the reclosable package, the zipper assembly is subjected to a slider zipper process whereby the zipper is provided from a spool. The flanges on this ribbon are then spread open, typically by a vacuum or similar device, and an adhesive which is compatible with the bag substrate is applied to the inside face of the flanges. The zipper with adhesive is placed over a series of packages or bags and sealed thereto via a temporary application of pressure, typically with clamps, over the adhesive coated flanges. End stomps (typically two at a time) are formed on the zipper and sliders are sequentially mounted on the zipper. The portions of the flanges between the successive bags are heat sealed, glued, or ultrasonically bonded to each other. The zipper segment, and hence the completed package or bag, is then cut from the ribbon. For a gusseted package or bag, the gussets are glued or otherwise connected so that the gussets are under the zipper flange.
Adhesive sealing methods, particularly hot melt, cross-linkable adhesive (such as hot melt cross-linkable polyurethane reactive adhesive) sealing methods, may be preferred over heat sealing methods in order to reduce the electrical power requirements for the production site.
Further objects and advantages of the invention will become apparent from the following description and from the accompanying drawings, wherein:
Referring now to the drawings in detail wherein like numerals indicate like elements throughout the several views, one sees that
Bottom 110 may be sealed shut, or folded over and then glued. Reclosable package 100 is typically bottom filled, so that the seal or glued fold may be formed after filling. However, other methods of filling, such as top filling before the complete application of zipper assembly 10, are equally applicable to the present invention and are disclosed herein.
A longitudinal seal or seam 111, which can be a lap or fin seal or seam, may optionally be formed in a central longitudinal location on rear wall 104 and is shown in phantom on
Mouth 112 is formed at the top of the reclosable package 100 of
As shown in
Peel seal 24 is formed between central locations of first and second flanges 18, 22. Peel seal 24 may be replaced by other frangible (and therefore tamper-evident) seals, or even a rip-cord (either supplementing or substituting for the peel seal 24). Peel seal 24 is more resistant to shear forces than to peeling forces. Peel seal 24, or any substitutes therefor, particularly when loaded in a shear configuration, is typically sufficiently strong to support the loads required by bottom filling. Peel seal 24 is typically pre-activated, but may be activated at the time of package or bag conversion. Additionally, first flange 18 in
In the alternative embodiment of
In the configuration of either embodiment, as shown in
Extension segments 46, 48 are typically formed with nominal 6 mil film, but those skilled in the art will recognize a range of equivalents after review of this disclosure. Extension segments 46, 48 are joined, typically by adhesive, to front and rear walls 102, 104, respectively. The embodiment of
The alternative embodiment of
The alternative embodiment of
The manufacturing process of reclosable package or bag 100 is illustrated in
The adhesive layer is typically applied to flanges 18, 22 in a path divergent or parallel to the bag supply so that the flanges 18, 22 are subsequently guided from the divergent or parallel path to a position wherein the bag walls are captured within the flanges 18, 22.
Zipper 10 is stomped at stomp locations 68 at package-width intervals, typically two stomps 68 at a time, by stomper 220 and slider 15 is inserted therebetween by slider inserter 222 as shown in
The zippers are then cut at cutting station 226 to achieve the package 100 illustrated in
Alternative embodiments may cut the zippers prior to the application of the adhesive, may include pre-mounted sliders, or sliders inserted and stomps formed prior to the gluing process. Walls 102, 104 may be folded to form gussets prior to the securing of the zipper assembly 10 thereto. Similarly, gussets may be attached below or within the flanges 18, 22 by glue dots or similar connection methods. To reinforce the gussets underneath the zipper assembly 10, glue may be applied in between the inside faces of the gussets or in between the outside faces of the gussets.
With respect to the adhesive used by nozzle 210 to fasten the zipper assembly 10 to the walls 102, 104 of package 100, it has been found that hot melt, cross-linkable adhesives (such as hot melt polyurethane reactive adhesive which are cross-linkable) have been found to be superior to ordinary hot melt adhesives, both for multi-wall paper and woven polypropylene walls. Likewise, this adhesive has been found superior for the construction of all seams of package or bag 100, including bottom seam 110 and longitudinal seam 111. This was determined by tests in which the package 100 was loaded with 2.5 times its rated load and hung upside down (that is, with the load bearing on the zipper assembly 10) and placed in 140 degree Fahrenheit environment (which is representative of temperatures which may be encountered during shipping) for seventy-two hours. The package 100 was considered to have passed this test if the package 100 maintained its integrity during this period.
Likewise, this test can be performed for the same load (2.5 times rated load) and period (seventy-two hours) at negative 20 degrees Fahrenheit (−20° F.) for simulation of cold environments which may be encountered during transportation and storage in some climates. The hot melt, cross-linkable adhesives (such as hot melt polyurethane reactive adhesive which are cross-linkable) have likewise been found to be superior under these tests and can be applied to all seams of packages, with or without a reclosable zipper.
Similarly, it has been found that pre-treatment of the olefin structures of the walls 102, 104 (particularly if made from woven polypropylene) and zipper flanges, typically by corona discharge or plasma treatment of the walls and flanges, improves the adhesion bond of the hot melt, cross-linkable adhesive (such as hot melt cross-linkable polyurethane reactive adhesive) between the walls and zipper flanges, particularly for film structures having a non-polar surface energy of less than 40 dynes per square centimeter.
Additionally, heat sealing may be effective in instances wherein the bag surface includes resin binder type inks.
As shown in
As shown in
Those skilled in the art will recognize a broad range of possible contents for the packages 100, including, but certainly not limited to, charcoal, pet food, livestock or other animal food, cat litter, fertilizer, seeds, plant bulbs, rock salt, and foodstuffs.
Thus the several aforementioned objects and advantages are most effectively attained. Although preferred embodiments of the invention have been disclosed and described in detail herein, it should be understood that this invention is in no sense limited thereby and its scope is to be determined by that of the appended claims.
This application is a continuation of application Ser. No. 11/728,477 filed Mar. 26, 2007 which claims priority under 35 U.S.C. §119(e) from provisional application Ser. No. 60/839,447, filed on Aug. 23, 2006, entitled “High Burst Slider Zipper for Large Bags and Method of Manufacture”, the contents of which are hereby incorporated by reference. Application Ser. No. 11/728,477 was filed simultaneously with application Ser. No. 11/728,405 filed Mar. 26, 2007 entitled “Method of Producing High Burst Zipper Assemblies for Large Reclosable Packages” and application Ser. No. 11/728,413 filed Mar. 26, 2007 entitled “Hot Melt Adhesive Systems for Zipper Assemblies on Large Bag Constructions of Various Substrates”.
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