The present invention relates generally to primary packaging and more particularly, to easy-open flow-wrap packages formed from flexible packaging film which includes a peelable resealable heat-seal seam so that they may more readily be torn open through the seam.
Flow-wrap type packages are often used for shipping and storage of a variety of food products and non-food products. Flow-wrap packages are typically formed from a continuous polymeric film or web to envelop a product during assembly or formation of the package. The continuous film is formed into a tube through a folding box and after the forming of this tube, a set of rotating sealing wheels makes a longitudinal seal called a fin seal by application of sufficient heat and pressure to the film to cause the two bonding surfaces of the film to heat seal or fuse together. Methods and equipment for forming heat seals are well known to those skilled in the art. A fin seal is an “inner-face to inner-face” abutment or seam where a first section of the interior surface of the package is heat sealed to a second section of the interior surface of the package, in opposition to an overlap or lap seal, which is an “inner-face to outer-face” abutment where an interior surface of the package is heat sealed to the exterior surface of the package. Conventional fin seals have a symmetric heat-seal interface where the film structure sealed to one side of the interface is a mirror-image of the film structure sealed to the other side of the interface. A longitudinal fin seal usually extends along a rear face of the package. Once the product is placed into the tube, the cross-seals (or end seals) in the form of a fin seal are formed through the cross-sealing jaws. In most applications, the end fin seal of the package is formed together with the beginning seal of the following package. During the sealing operation, the film is cut to split the adjacent package and the cutting knife is generally built into the sealing jaws. Flow-wrap type packages can be used in vertical form-fill-seal and horizontal form-fill-seal packaging applications.
Conventional flow-wrap packages are opened by tearing an end fin seal or cross-seal. This tearing is generally not guided and does not cross-over the longitudinal fin seal of the package. Consequently, the tearing is stopped by the longitudinal fin seal and further tearing often results in a random breaking of the package.
Peelable resealable polymeric packaging films are well known in the art. These films have been described for example in U.S. Pat. No. 7,422,782 (Haedt et al.), U.S. Pat. No. 7,927,679 (Cruz et al.), U.S. Pat. No. 8,283.010 (Cruz et al.), U.S. Pat. No. 8,283,011 (Cruz et al.), and U.S. Pat. No. 8,329,276 (Cruz), all of which are incorporated herein by reference. They have been constructed with one or more frangible layers which are designed so that they fail within their respective structures when a peeling force is applied. Such failure being by delamination of a multilayer polymeric film or by rupture within the thickness of one or more layers of the polymeric film. However, the use of these peelable, resealable films in flow-wrap packaging applications has been fraught with undesirable consequences. For example, when such film is heat sealed to itself, the seam that is formed includes at least two frangible interfaces because both sections of film on either side of the seal interface are mirror-images of each other. When the seam is pulled apart to open the package, these interfaces exhibit excessive “webbing”, i.e., the creation of thin strings of polymeric fibers stretching between the two sealing surfaces. Excessive webbing is unsightly and may significantly affect the resealability of the package.
Therefore, there is a definite need to provide flow-wrap packages having a peelable resealable heat-seal seam without experiencing the problems discussed above.
The present invention is directed to a peel-open, reclosable package formed from a single thermoplastic laminate comprising a first film laminated to a second film. The laminate has a first side, an opposing second side, a top surface and a bottom surface and comprises a first sealing section having an interior surface, and a second sealing section having an interior surface. The package includes a first side edge, an opposing second side edge, a third side edge, and an opposing fourth side edge.
One important aspect of the present invention is that the package include a peelable, resealable heat-seal seam adhering an interior surface of a first sealing section of the package to an interior surface of a second sealing section of the package.
Another important aspect of the present invention is that there is an asymmetric cross-sectional seal interface formed within the peelable, resealable heat-seal seam by disjoining a segment of the first film from the first sealing section prior to heat sealing the first and second sealing sections together.
In one preferred embodiment, the package is formed from two webs of a single thermoplastic laminate and comprises a first fin seal positioned proximal to the first side edge wherein the peelable, resealable heat-seal seam is formed within the first fin seal. The peelable, resealable heat-seal seam includes an asymmetric cross-sectional seal interface. In this embodiment, the package also includes a second fin seal positioned proximal to the opposing second side edge, a third fin seal positioned proximal to the third side edge, and a fourth fin seal positioned proximal to the opposing fourth side edge. It is also contemplated that the peelable, resealable heat-seal seam may not be formed within the first fin seal. In an alternative embodiment, the peelable, resealable heat-seal seam having an asymmetric cross-sectional seal interface is offset from the first fin seal and positioned adjacent to the first fin seal In order to facilitate the opening of this embodiment of the present invention, there may optionally be included either a score line cut into the laminate or a tear strip both of which are positioned between the peelable, resealable heat-seal seam and the first fin seal.
In another preferred embodiment, the package of the present invention may be formed by folding a single thermoplastic laminate upon itself thereby defining a first fold located at the second side edge of the package. The package also includes a first fin seal positioned proximal to the first side edge, a second fin seal positioned proximal to the third side edge and a third fin seal positioned proximal to the opposing fourth side edge. In this embodiment, the peelable, resealable heat-seal seam is formed within the first fin seal and includes an asymmetric cross-sectional seal interface.
In another preferred embodiment, the package of the present invention may be formed by folding a single thermoplastic laminate upon itself thereby defining a first fold located at the first side edge rather than at the second side edge of the package. The package of this embodiment includes a first fin seal positioned proximal the second side edge and opposite to the first fold. This embodiment also includes a second fin seal positioned proximal to the third side edge, and a third fin seal positioned proximal to the opposing fourth side edge. In this embodiment, the peelable, resealable heat-seal seam is not formed within the first fin seal, but is offset from the first fold. The peelable, resealable heat-seal seam includes an asymmetric cross-sectional seal interface. This embodiment may optionally further comprise either a score line cut into the laminate or tear strip each of which is being positioned between the peelable, resealable heat-seal seam and the first fold to facilitate the opening of the package.
In yet another preferred embodiment, the package may be formed by folding a single thermoplastic laminate upon itself thereby defining a first fold located at the first side edge and a second fold located at the second side edge. The package of this embodiment includes a first fin seal positioned between the first and second folds, and a peelable, resealable heat-seal seam formed within the first fin seal. The package also includes a second fin seal positioned proximal to the third side edge, and a third fin seal positioned proximal to the opposing fourth side edge. The peelable, resealable heat-seal seam includes an asymmetric cross-sectional seal interface.
In still yet another preferred embodiment, the package may be formed by folding a single thermoplastic laminate upon itself thereby defining a first fold located at the first side edge and a second fold located at the second side edge. The package of this embodiment includes a first fin seal positioned between the first and second folds, a second fin seal positioned proximal to the third side edge, and a third fin seal positioned proximal to the opposing fourth side edge. This embodiment includes a peelable, resealable heat-seal seam which is not formed with a fin seal, but is offset from the first fold. The peelable, resealable heat-seal seam includes an asymmetric cross-sectional seal interface. This embodiment may optionally further comprise a score line cut into the laminate or tear strip both of which being positioned between the peelable, resealable heat-seal seam and the first fold to facilitate the opening of the package.
In accordance with an important aspect of the present invention, the packages are both peelable and reclosable. In one embodiment, the first film comprises an interior frangible layer comprising a pressure sensitive adhesive resin.
Further features and advantages of the present invention will become apparent from the following detailed description, taken in combination with the appended drawings, in which:
A preferred embodiment of the peel-open, reclosable package of the present invention is made from a single thermoplastic laminate 10 which includes a first laminate side 10a, an opposing second laminate side 10b, a top surface 10c and a bottom surface 10d as depicted in
Referring now to
Package 100b is formed by folding laminate 10 upon itself connecting first laminate side 10a to second laminate side 10b by heat sealing sides 10a and 10b together to produce a first package wall 114a, an opposite second package wall 114b (not shown), a first fin seal 115a positioned proximal to a first side edge 118a, and a first folded edge 119a located at a second side edge 118b. In this preferred embodiment, package 100b also includes a second fin seal 115b positioned proximal to a third side edge 118c, and a third fin seal 115c positioned proximal to a fourth side edge 118d. As can be seen, first fin seal 115a is perpendicular to both second fin seal 115b and third fin seal 115c. In this embodiment, package 100a includes a peelable, resealable heat-seal seam 101b configured within first fin seal 11Sa of the package. As depicted, peelable, resealable heat-seal seam 101a extends substantially from the first package end 118a to the opposing second package end 118b and includes an asymmetric cross-sectional seal interface 500 illustrated in
Alternatively, the present invention can be illustrated in
Referring now to
Alternatively, the present invention can be illustrated in
As used herein, the term “frangible layer” refers to one layer or more layers which exhibit adhesive failure, i.e., separation or delamination at an interface from an adjoining layer by application of a pulling or peeling force, or cohesive failure, i.e., separation within the frangible layer by application of a pulling or peeling force. “Peelable seal” and like terminology are used herein to refer to a seal, and especially heat seals, which are engineered to be readily peelable without uncontrolled or random tearing or rupturing the packaging materials which may result in premature destruction of the package and/or inadvertent contamination or spillage of the contents of the package. A peelable seam is one that can be manually peeled apart to open the package at the seal without resort to a knife or other implement to tear or rupture the package. The force required to affect adhesive or cohesive failure of a frangible layer may be measured by its “peel strength” in accordance with ASTM F-904 test methods. A frangible layer is adapted to remain secure and unbroken during package fabrication, distribution and storage, and yet may be relatively easily ruptured. Accordingly, the peel strength of a frangible layer is between 500 gram-force/inch (87.6 Newton/meter) and 5000 gram-force/inch (875.5 Newton/meter) as measured in accordance with ASTM F-904 test method. As used herein, the term “resealable” refers to a film interface formed by adhesive failure between the frangible layer and an adjacent layer and/or cohesive failure within the frangible layer which is adapted to re-adhere to itself after separation. The force required to “reseal” these interfaces is proportional to the manual pressure exerted on the film. Consequently, a peelable and resealable interface will exhibit a first interfacial peel strength and a second interfacial (or re-tack) peel strength. The peelable, resealable fin seals of the present invention will have a first peel strength of between 500 gram-force/inch (87.6 Newton/meter) and 5000 gram-force/inch (875.5 Newton/meter) and a second peel strength of between 350 gram-force/inch (61.3 Newton/meter) and 1000 gram-force/inch (175.1 Newton/meter) as measured in accordance with ASTM F-904 test method.
As used herein, the phrase “asymmetric cross-sectional sealing interface” refers to an “inside-inside” fusion bond or heat seal formed from a single multilayer laminate where there are two “different” structural film sections on either side of the bond interface. As used herein, the term “different” refers to a first structural film section which is not a mirror-image of a second structural film section bonded together at the sealing interface. For example, an asymmetric cross-sectional sealing interface may be represented by the following: A/B/C//B/C/A where “//” is the bond interface, A/B/C is a first structural film section having layer compositions A, B and C; and B/C/A is a second structural film section having the same layer compositions A, B and C as the first section, but are arranged in a different layer sequence. An asymmetric cross-sectional sealing interface may also be represented by the following: A/B/C/D//D/C where is the bond interface, A/B/C/D is a first structural film section having layer compositions A, B, C and D; D/C is a second structural film section having an identical layer compositions C and D as the first section but omits layers A and B. An asymmetric cross-sectional sealing interface may still further be represented by the following: A/B/C/D//D/C/E where “//” is the bond interface, A/B/C/D is a first structural film section having layer compositions A, B, C and D; D/C/E is a second structural film section having an identical layer compositions C and D, but omits layer A and B, and includes layer E which is not present in the first section.
Referring now to
The total thickness of first film 1100 of the present invention is generally from about 12.7 μm (0.5 mil) to about 254 μm (10 mil), most typically from about 25.4 μm (1 mil) to about 127 μm (5 mil).
In this particular example, second film 1200 includes a mono-layer structure comprising an oriented material or paper. Oriented materials may include, but are not limited to oriented polyethylene terephthalates, oriented polypropylenes and oriented polyamides. In another embodiment, second film 1200 may include additional layers as desired. In a preferred embodiment, layer 1200 is an oriented polyethylene terephthalate film having a total thickness of between 48 gauge and 142 gauge (12.2 μm and 36.1 μm).
This example also includes a lamination layer 1300. In one embodiment, lamination layer 1300 includes a material which adheres first film 1100 and second film 1200 together. In one preferred embodiment, lamination layer 1300 is heat sealable to both first film 1100 and second film 1200. Materials suitable for use in heat sealing first film 1100 and second film 1200 together may include but are not limited to low density polyethylenes, very low density polyethylenes, ultra-low density polyethylenes, linear low density polyethylenes, ethylene α-olefin copolymers; ethylene vinyl acetate copolymers; ethylene methacrylate copolymers, and blends thereof. Lamination layer 1300 may also include blends of anhydride modified polyethylenes and un-modified polyethylenes. The total thickness of lamination 1300 is generally from between about 0.1 mil and 1.0 mil (2.54 μm and 25.4 μm) and typically from between 0.3 mil and 0.75 mil (7.62 μm and 19.1 μm).
In the following example, the film structure for first film 1100 was produced using a blown film co-extrusion apparatuses, and methods which are well known to those skilled in the art. The blown film co-extrusion film apparatus includes a multi-manifold flat die head for film through which the film composition is forced and formed into a flat sheet. The sheet is immediately quenched e.g., via cooled water bath, solid surface and/or air, and then formed into a film.
In the production of Example 1 as illustrated in
Example 1 is one embodiment of laminate 2000 of the present invention having a structure and layer compositions as described below and as illustrated in
Layer 1107: 85 wt.-% of a linear low density polyethylene (LLDPE)-Sclair® FP619-A (Nova Chemicals Corporation, Calgary, Alberta, Canada), 9 wt.-% of an anhydride modified polyethylene-Tymax® GT4300 (Westlake Chemical, Houston, Tex., USA) and 6 wt.-% of a polyethylene masterbatch containing processing additives.
Turning now to
The above description and examples illustrate certain embodiments of the present invention and are not to be interpreted as limiting. Selection of particular embodiments, combinations thereof, modifications, and adaptations of the various embodiments, conditions and parameters normally encountered in the art will be apparent to those skilled in the art and are deemed to be within the spirit and scope of the present invention.
Filing Document | Filing Date | Country | Kind |
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PCT/US14/50859 | 8/13/2014 | WO | 00 |