The present invention relates to shrink films for various articles, and in particular, to shrink sleeves for containers having closures.
Shrink films, such as shrink sleeves and shrink wraps, are used in labeling, often as an alternative to pressure-sensitive labels, heat-transfer labels, in-mold labels, and other labels. Shrink labeling involves sizing a shrink film, which may be a tubular shrink sleeve, to a particular article. Then one shrinks the film to snugly wrap the article within the shrink sleeve. The shrinking process is generally accomplished by the application of heat or steam to the shrink sleeve. Further processing may include heat-sealing any unsealed portions of the shrink sleeve and/or covering the article contents with a shrink cover. The material used for shrink films, such as a shrink sleeve, may depend on the shape and weight of the article and its contents. The shrink sleeve may be polyethylene terephthalate, polyethylene terephthalate glycol, polyvinyl chloride, or oriented polystyrene, for example. The film has an inherent tension that is released by heating the film from the outside in a shrink oven. Shrink films may be produced in forms that may be oriented monoaxially (in a single direction). As the film cools, it shrinks snugly around the article. This shrinkage applies a very slight pressure to the article, which aids in holding the shrink film to the article.
Graphics, such as pictures, logos, and text for labels, may be reverse-printed on the shrink films and the shrink films then seamed, thereby forming a shrink sleeve. In general, shrink films are reverse-printed using flexographic and rotogravure printing technology. A master roll of shrink film is prepared with a number of label copies across its surface. The particular number of labels depends upon the size of the label copy and the width of the master roll. The printed rolls are then slit-cut, thereby forming individual rolls containing one copy of the label only. The slit rolls are then folded and overlapped, and seamed at the edge, forming a shrink sleeve that is wound on a core. The finished rolls are packaged and delivered to a particular location where each of the shrink sleeves will be applied to an article. These shrink sleeves are commonly used for full body decoration and tamper-evident applications.
When a shrink sleeve is used in tamper-evident applications, perforations may be provided in the shrink film. Generally, these perforations are provided on the shrink sleeve at a position that will be proximal to an opening of the article being labeled. In such a position, a portion of the shrink sleeve above the perforations will contact and confront a closure of the article, and a portion of the shrink sleeve below the perforations will contact and confront a body portion of the article. In use, the closure, such as a cap on a bottle, is removed by applying a twisting or rotating force (i.e., a torsional force) to the closure. As this occurs, the torsional force is also applied to the portion of the shrink sleeve confronting the closure of the article, while not being applied (at least without as much force) to the body portion of the article. As a result, the closure and the portion of the shrink sleeve contacting the closure are removed from the body portion of the article as the tamper-evident portion of the shrink sleeve (i.e., the portion contacting the closure) separates from the remainder of the shrink sleeve along the perforations. It is desirable that the portion of the label below the perforations stay bonded to the article after the consumer opens the article. In order to prevent slippage between the shrink sleeve and the body portion of the article, adhesives may be used to bond the body portion of the shrink sleeve and the body portion of the article to one another.
However, while adhesives may be applied to the portion of the shrink sleeve that contacts the body portion of the article, they are not applied to the portion of the shrink sleeve that contacts the closure of the article (i.e., the tamper-evident portion of the shrink sleeve “above” any perforation). This is because it is desired that the portion of the shrink sleeve confronting the closure be completely separated from the closure and discarded. This prevents any shrink sleeve from remaining on the closure where it could interfere with access to the contents of the article, or interfere with reattachment of the closure to the article.
Further, since the portion of the shrink sleeve that confronts the closure in tamper-evident applications is designed to be separated from both the closure and the remainder of the shrink sleeve, that portion generally is not labeled or otherwise decorated. Further, large closures, such as those found on containers of laundry detergent, often include ridges and grooves, which make it difficult for a label to adhere to the side surface of the closure. And, if any shrink sleeve were shrunk against such a closure, the shrink film would conform to the multiple ridges and grooves, thereby disrupting the appearance of any decoration thereon. Of course, previously, this has not been problematic, since in tamper-evident applications, one does not want the shrink film to adhere to the side of the closure, and shrink films have not otherwise been used on the side surface of closures.
While shrink sleeves have been used on closures in tamper-evident applications, other types of materials (nonshrink films) have been used on closures for purposes other than tamper-evident applications. For example, pressure-sensitive labels have been positioned on the “land” (i.e., the top) of closures, such as caps for bottles. These labels may include decorations and/or labels. However, labels, such as the decorated pressure-sensitive labels, have not been applied to the sides of closures for various reasons. One reason is that the side surfaces of closures often include features like ridges or flanges that disrupt the ability of the label to adhere to, or otherwise associate with, the side of the closure, and also may interfere with the presentation of any decoration. Further, any label, such as the shrink sleeves described above, is easily separated from the closure due to the torsional forces applied when removing the closure from the container body. Thus, any label information is lost. Further, the appearance of an article having a label or other decoration removed due to these torsional forces may be unaesthetic.
In view of the above, it would be desirable to provide a decorated closure for an article having a shrink sleeve label that is associated with the side surface of the closure. Further, it would be desirable for the shrink sleeve to have decorations that are visible and intelligible (even on irregularly-shaped closures). It would be further desirable that such a decoration be impervious to torsional forces applied to the closure during use.
The present invention overcomes and eliminates the drawbacks described above in the Background of the Invention. The present invention does so by providing a decorated closure for an article, such as a container used to package an item or items. The decorated closure includes a shrink sleeve and a closure for an article. The closure has a top end, a bottom end, and a side surface. The closure may further include a centerpoint of the top end and a centerpoint of the bottom end with a longitudinal axis passing therethrough. The shrink sleeve is shrunk around at least the side surface of the article, and includes a plurality of layers, one of which may be a heat-activatable expandable layer including a thermally expandable composition.
The heat-activatable expandable layer may include a plurality of microcapsules containing the thermally expandable composition. This thermally expandable composition may include a “foaming” agent having an easily volatilizable hydrocarbon, and a binder resin. When subjected to high temperatures during the process of applying a label, the microcapsules rupture, and the thermally expandable composition “foams,” and can intercalate into the grooves defined by the ridges on a closure, such that the label can withstand even greater torsional forces applied to the closure.
Additionally, the expandable composition can provide a texture to the label, and can raise or surround the graphics (i.e., an ink layer) of the label. Alternatively, the thermally expandable composition can be patterned in such manner that, when activated, the resulting raised texture can itself appear in a pattern or a design, thereby further adding to the aesthetics of the label. The textured label can offer aesthetic benefits by matching the nonglossy texture of container materials along with imparting its own design, and can create a friendly-to-the-touch type of label. Thus, the textured surface of the laminate, due to the thermally expandable layer, provides a more comfortable and enhanced grip to the user.
Further, the thermally expandable composition can impart a thermal barrier property to the label. Thus, the raised textured surface creates increased resistance to heat loss, providing a thermal barrier should any heated materials be placed within the container, or should any materials within the container be subsequently heated.
Furthermore, since the expandable layer is heat-activated, it will be recognized that the textured attributes of the label are induced by heat as opposed to other stimuli (e.g., pressure). Since the use of heat is already an integral part of labeling applications such as heat transfer and shrink sleeve labeling, the labeled article would not have to be subjected to any additional processes. This is advantageous because any additional process steps would decrease label application throughput.
The present invention further provides an adhesive for application proximal to an inner surface of a shrink sleeve. In particular, this adhesive may be applied to the inner surface of the shrink sleeve and may be adapted to contact a surface of the closure. The adhesive binds the shrink sleeve to the closure such that it can withstand the torsional forces generally applied during removal of the closure. The adhesive also allows the shrink sleeve to withstand any linear forces, which may otherwise cause the shrink sleeve to be “lifted” off the closure. Further, when bound, the shrink sleeve can withstand the torsional forces generated during a filling and capping process (such as when closures are predecorated—prior to filling of the article—and then attached to the article following filling).
Further, as described above, one problem with prior inks used on shrink sleeves is that the inks are of a formulation that can absorb the adhesive, thus detracting from the ability of the shrink sleeve to properly adhere to a surface. This problem is especially pronounced in a shrink sleeve in contact with a portion of an article that is subjected, often repeatedly, to torsional forces (i.e., the closure). To eliminate this problem, the present invention provides an ink having a formulation that does not absorb any adhesive used. In particular, the ink may include a nitro-acrylic based resin including a pigment comprising TiO2, and a plasticizer having a wax additive. Further, the ink may not include calcium carbonate in its formulation.
Thus, using the shrink sleeve film, adhesive, and inks described above, the present invention also provides a laminate including a film for a shrink sleeve, an ink layer disposed on an inner surface of the shrink sleeve, and an adhesive layer disposed on the ink layer. The ink layer, as described above, includes a plasticized nitro-acrylic based resin including a pigment load (such as TiO2), and a wax additive. The wax additive promotes the adhesive layer to lay out smoothly on the surface of the ink layer, rather than seeping into the ink layer. This, in turn, promotes adhesion of the laminate to an article to which it is applied. Further, the ink layer, in certain embodiments, does not include calcium carbonate. In an alternate embodiment, the laminate includes a film for a shrink sleeve, an ink layer disposed on or proximal to an inner surface of the shrink film, a heat-activatable expandable layer, and an adhesive layer.
Finally, the present invention also provides a method of applying a shrink sleeve over a closure for an article. The method includes providing a shrink sleeve having an axis of symmetry and at least one decoration visible on an outer surface of the shrink sleeve. One also provides a closure for an article, the closure having a top end, a bottom end, a side surface, and a longitudinal axis passing through a centerpoint of the top end and a centerpoint of the bottom end. The article is oriented such that the longitudinal axis is substantially parallel to the axis of symmetry. The shrink sleeve is positioned over and around the closure such that at least a portion of the closure is disposed within and substantially surrounded by the shrink sleeve. And the shrink sleeve is shrunk such that the shrink sleeve constricts around at least a portion of the side surface of the closure, thereby positioning the shrink sleeve such that the at least one decoration is visible on an outer surface of the shrink sleeve. As the shrink sleeve is shrunk (such as by heat), the increased temperature may cause a heat-activatable expandable layer to “foam” and intercalate into any grooves or other surface irregularities on a closure.
As a result of the present invention, brand recognition can be developed by including a shrink sleeve with decoration (such as a brand label) on a closure because the consumer's eye is drawn to the closure. Further, the present invention allows maximum use of the “real estate” on a container, since closures were not previously a surface used in labeling. And further still, the use of the shrink sleeve on the closure reduces costs for a customer company by removing the need for a colorant for the closure.
Additional characteristics of the shrink sleeve of the present invention will be apparent from the following detailed drawings and description of the invention.
The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and, together with the general description of the invention given above and the detailed description of the embodiments given below, serve to explain the principles of the present invention.
Referring now to the Figures, the present invention provides a labeled article 10 for packaging an item or items. This labeled article 10 includes a shrink sleeve 12 and an article 10 including a closure 14. In particular, and referring to
As shown in
The shrink sleeve 12 is shrunk around at least the side surface 20 of the closure 14 of the article 10, and includes at least one visible decoration 32 on a surface of the shrink sleeve 12. Such a decoration 32 may be provided by various inks well known to those skilled in the art. These may be reverse-printed on or proximal to the inner surface 34 of the shrink films (i.e., the surfaces that will be applied toward the surface of the closure 14). Alternatively, the inks may be applied on or proximal to the outer surface of the shrink films. “Applied on,” as used here, means there is direct contact between the inks and the surface of the shrink film. “Applied proximal to,” as used here, means that although the inks are applied to the same side as a surface of the shrink film, it is not necessary that there be any direct contact between the inks and the surface (although there may be). For example, another layer, or layers, may be disposed between the inks and the surface that the inks or inks are “applied proximal to.”
In the illustrated embodiment (as seen in
Further, and referring now to
Additionally, a portion of the shrink sleeve 12 may confront a bottom surface of the closure 14 (although this embodiment is not shown in the figures). In particular, a portion of the bottom end of the shrink sleeve 12, in an amount of at least 1 mm, may confront the bottom surface of the closure 14. This contact occurs as the shrink sleeve 12 is shrunk against the closure 14. As the shrink sleeve 12 is placed around the side surface 20 of the closure 14, the length of the shrink sleeve 12 may be greater than the vertical length of the side surface 20 of the closure 14. Thus, a portion of the shrink sleeve 12 proximal the bottom portion of the shrink sleeve 12 extends past the side surface 20 of the closure 14. As heat is applied to the shrink sleeve 12 it shrinks about the side surface 20 of the closure 14 and the extra portion at the bottom may shrink about a portion of the bottom surface of the closure 14. The portion of the shrink sleeve 12 that overlies, and thus contacts, the bottom of the closure 14 may further assist in holding the shrink sleeve 12 to the closure 14. This may occur regardless of the presence of any adhesive 40 on or proximal to the inner surface 34 of the shrink sleeve 12.
In the illustrated embodiment, as shown in
Referring now to
During shrinking of the shrink sleeve 12 to the closure 14, temperatures generally need to be high enough to cause shrinking of the film, and yet low enough to avoid deforming, or otherwise damaging, the closure 14 and/or article 10. Thus, the adhesive 40 needs to activate in a temperature range similar to the temperatures used to shrink the film. The adhesive 40 activates at a temperature lower than a temperature that would cause deformation of the closure 14 and/or article 10. In one embodiment, the adhesive 40 may activate between about 140° F. and about 190° F. Alternatively, the adhesive 40 may begin to activate at about 140° F., and fully activate at about 190° F. After being shrunk against the closure 14, the shrink sleeve 12 may withstand up to about 135 inch pounds of torque without being separated from the closure 14.
Further, additional layers may be included with the shrink sleeve 12. Referring still to
The solvent, such as water, for example, is used with an emulsifying agent to prepare an emulsion including the binder resin. This emulsifying agent may be a surfactant. In general, the binder resin is fragmentized, by methods well known to those skilled in the art. The fragmentized binder resin is then emulsified using the surfactant and solvent by methods also well known to those skilled in the art. The function of the binder is to impart cohesive film strength and interlayer adhesion within the laminate of the shrink film 13, heat-activatable expandable layer 41, and any other layers. Upon the application of heat, the expandable composition undergoes an expansive or “foaming” effect. This expansive or “foaming” effect could be disruptive to the other layers of the laminate of the shrink sleeve 12. Thus, the binder resin is useful to hold any layers adjacent to the expanding layer to one another in order to maintain the integrity of the laminate of the shrink sleeve 12, to prevent any such disruption.
Additionally, the heat-expandable composition may also include a colorant. The colorant may be present in a range of about 1% by weight to about 5% by weight of the expandable layer. One function of the colorant may be to match the color of the heat-activatable expandable layer 41 to the closure 14 receiving the shrink sleeve 12.
Another function of the colorant may be to facilitate the opacity of the shrink sleeve 12 itself. For example, the shrink sleeve 12 may include a removable portion (not shown), such as a perforated portion, that could be used for a coupon or a piece of a game or promotion. The opacity of the shrink sleeve 12 is therefore important in preventing revealing the information printed on the removable portion. By using the colorant in the heat-expandable composition, one may facilitate the opacity of the shrink sleeve.
The heat expandable composition of the heat-activatable expandable layer 41 may further be disposed on an outer surface of a plurality of microspheres. These microspheres may be present in a range of about 10% by weight to about 50% by weight of the heat-activatable expandable layer 41. The microspheres are held together to form the heat-activatable expandable layer due to the binder resin of the expandable composition on the outer surface of the microspheres. The microspheres are designed to rupture to allow expansion of the heat expandable composition upon the occurrence of a particular event, such as heating to a particular temperature. In order to rupture, the microspheres may be constructed from an easily volatilizable hydrocarbon. In a particular embodiment, the microspheres may be constructed from Foamcoat A7810 AY, commercially available from Sovereign Specialty Chemical, of Chicago, Ill. However, as will be recognized by those skilled in the art, the microspheres can be constructed from any material, as long as the microspheres can be adaptable to rupture at the proper moment (such as due to a temperature) to result in expansion of the heat-activatable expandable layer. Additionally, the microspheres may include an interior compartment. A gas, such as isobutane, may be microencapsulated in the interior compartment encapsulated by the microspheres. The gas expands on the application of heat, causing the microspheres to rupture and the expandable composition to expand.
Thus, in one particular embodiment, the microspheres may be heat-rupturable. In embodiments wherein the microspheres are heat-rupturable, they may be adapted to rupture at temperatures at or above about 180° F. When subjected to temperatures above about 180° F. during the process of attaching the shrink sleeve 12, the microcapsules rupture and the composition “foams,” causing the layer to expand. The expandable lacquer is the only layer that foams/expands when heated. In particular, the microcapsules rupture, releasing a gas, such as isobutane, which expands the coating. The material is then held in the expanded state by the binder resin. By using microspheres that are heat-rupturable, the laminate is amenable to use in labels that are subjected to heat during the application process, such as shrink sleeve labels. This may eliminate the need for a separate heating step. However, it will be recognized by those skilled in the art that the laminate having a heat-activatable expandable layer 41 as in the present invention, may be used for other types of labels, such as pressure-sensitive labels.
The term “microencapsulated” or “microencapsulation” is to be taken to mean the packaging by encapsulation of certain liquids or solids in a paste form in an enclosed solid shell. The walls of the microcapsule must be chemically inert to the contents of the capsule and must possess the required stability with respect to the surrounding medium. Further, the capsules must be sealed and must be sufficiently fracture-resistant for the application in question, and also sufficiently temperature stable. The size of the capsules depends on the production process and extends from a diameter of about 2 microns to about a diameter of about 30 microns; however, a size of about 2 to about 20 microns is mostly used. In the microcapsules of the present invention, a substance that may be contained within the capsule is isobutane. The remaining expandable composition (i.e., binder, surfactant, and water emulsion) is coated on the outer surface of the microcapsules. Upon the application of heat, the isobutane causes the microcapsules to burst and also provides the expansive “foaming” characteristic to the expandable composition.
The binder resin and solvent (and optional colorant) of the heat-activatable expandable layer 41 may be chosen from various materials. For example, the binder resin may be chosen from acrylic binders, vinyl acrylic copolymer binders, vinyl acetate homopolymer binders, styrene acrylic binders, and phenoxy binders. More specifically, the acrylic binder may be selected from, but is not limited to, the following Rhoplex binder resins, commercially available from Rohm and Haas, of Philadelphia, Pa.: B15R, B60a, B85, B88, B959, GL618, GL623, HA12, P554, and SP100. Further, the vinyl acrylic copolymer binder may be selected from, but is not limited to, the following Polyco binder resins, commercially available from Rohm and Haas: 3103NP, 3250, and 6107. Further, the vinyl acetate homopolymer binder may be selected from, but is not limited to, the following Polyco binder resins, commercially available from Rohm and Haas: 2149A and 2152. Further, the styrene acrylic binder may be selected from, but is not limited to, the following binder resins, commercially available from Rohm and Haas: P308, P322, and P376. And finally, the phenoxy binder may be, but is not limited to, InChem PKHW34, commercially available from InChem Corporation, of Rock Creek, S.C.
The solvent may be chosen from any substance that is an efficient solvent for the heat-expandable composition, but which also does not cause the microcapsules to rupture. Thus, the solvent may be chosen from distilled water and isopropanol, for example.
The colorant may include a nonionic water-based dye. However, it should be recognized that this dye is merely exemplary. Other types of dyes may be suitable for the present invention, such as anionic dyes. In one particular embodiment of the present invention, the colorant may be added to the expanding layer to add “tint” to the textured portions of the shrink sleeve 12.
The laminate of the shrink sleeve 12 may further include a wax component. The wax component may be in a separate wax layer (not shown) in the laminate of layers of the shrink sleeve, or alternatively, may be part of another layer, such as the heat-activatable expandable layer 41.
The wax component may include various materials. Such materials may result in a matte finish or in a gloss finish. For examples of suitable materials for a wax component, see U.S. Pat. No. 4,536,434, the disclosure of which is incorporated by reference herein in its entirety and U.S. Pat. No. 4,581,266, the disclosure of which is incorporated by reference herein in its entirety. The '266 patent describes an exemplary formulation for the wax component, including paraffin and a montan wax, and which may also include a minor amount of microcrystalline wax. In addition to these waxes, the formulation may include a tackifying resin and suitable binder. With proper selection of tackifier resin, the total amount of crystallinity of the paraffin wax can be reduced.
Paraffin wax, a petroleum derived product, typically has a molecular weight between about 254 to 450 and is composed essentially of linear saturated hydrocarbons ranging from C18H38 to C32H66. Paraffins typically have a melting point from about 110° F. to 150° F. (“Melting point,” as used herein, refers to drop melting point).
Paraffin wax suitable for use in wax component is sold in various grades that differ chiefly in melting point. Commercial grades of paraffin wax that may be used are commonly designated as refined, semi refined, and crude grade waxes. Paraffin wax of refined grade is obtainable from a number of sources, one of which is the Petrolite Corporation, Bareco Division, of Tulsa, Okla.
The microcrystalline component may be composed of saturated hydrocarbons of higher melting point than those of paraffin wax. Microcrystalline waxes characteristically contain between about C34H70 to C60H120 hydrocarbons having molecular weight between about 478 and 840. Microcrystalline waxes (microwaxes) are characterized by an increased amount of branching; although they contain straight chain molecules, they are not as linear a saturated hydrocarbon as paraffin wax. Also compared to paraffin wax, they contain a greater portion of cyclic ring molecules. The crystalline structure of the microcrystalline wax contains predominantly malcrystalline and needle-like crystals having very small, undefined form when compared with the plate-like crystalline structure of paraffin wax under the same magnification. Thus, the crystalline structure of microcrystalline wax is small and irregular when solidified from the melted wax. In solvents, microcrystalline wax discloses no well-formed crystals of any size.
The classes of microwaxes vary principally in their melting point range. For example, the so-called hard microwaxes have a melting point between about 190° F.-210° F.; the plastic microwaxes a melting point between about 145° F.-175° F.; the emulsifiable crystalline waxes between about 190° F.-225° F.; and modified microwaxes between about 165° F.-220° F. All of these various types of microwaxes may be employed in the present formulation. An illustrative, commercially available microcrystalline wax that is particularly suitable in the present formulation is available under the Victory White trade name from the Petrolite Corporation.
The montan wax component for wax release layer 16 is a coal (lignite)-derived wax characterized by high concentration of montanic acid (C28H56O2). A particularly suitable type of montan wax is an oxidized, esterified, partially saponified montan wax as disclosed in U.S. Pat. No. 3,616,015, herein incorporated by reference. Montan waxes of this type have melting points (drop points) typically between about 50° F.-110° F., saponification values between about 25 and 150, acid values between about 5 and 40, and penetrometer hardness (ASTM-D5-52) below about 15 as measured with 100 grams for 5 seconds at 25° F. These montan waxes also have relatively high melt viscosity. An illustrative oxidized, esterified, partially saponified montan wax is available under the trade name Hoechst OP or Hoechst X55 modified montan wax from the Hoechst Chemical Company, Frankfurt, Germany. Hoechst OP modified montan wax has a drop point (ASTM D127) of 212° F.-221° F., a congealing point (ASTM D938-49) between 165° F.-175° F., an acid number of 10 to 15, and a saponification number of 100 to 115. Hoechst X55 has a drop point of 208° F.-218° F., a congealing point of 167° F.-176° F., an acid number of 10 to 15, and a saponification number of 90 to 110. These waxes have melt viscosities of at least about 150 centipoise at a temperature of about 25° F. above their solidification point.
Referring still to
The invention of the illustrated embodiment thus includes an adhesive layer 40 disposed proximal to the ink layer 42, such that the ink layer 42 is disposed between the inner surface 34 of the shrink sleeve 12 and the adhesive layer 40 (see
The ink of the present invention thus eliminates the absorption problem. It will be recognized by those skilled in the art that the “background white ink” is merely exemplary, and any ink that is going to contact the adhesive 40 can be prepared as an ink without calcium carbonate. Additionally, or alternatively, such ink may be prepared with plasticized nitro-acrylic-based resin with a pigment load (such as TiO2), and a wax additive.
Thus, using the shrink sleeve film, adhesive 40, and inks described above, the present invention also provides a laminate 44 including a film for a shrink sleeve 12, an ink layer 42 disposed on the inner surface 34 of the shrink sleeve 12, and an adhesive layer 40 disposed on the ink layer 42. The ink layer 42, as described above, includes a plasticized nitro-acrylic based resin including a pigment (such as TiO2), and a wax additive; and the ink layer 42 does not include calcium carbonate.
Referring now to
The method of the present invention also includes providing a closure 14 having a top end 16, a bottom end 18, a side surface 20, and a longitudinal axis 26 passing through a centerpoint 22 of the top end 16 and a centerpoint 24 of the bottom end 18. This closure 14 is then oriented such that the longitudinal axis 26 of the closure 14 is substantially parallel to the axis of symmetry 46.
Next, the shrink sleeve 12 is positioned over and around the closure 14 such that at least a portion of the side surface 20 of the closure 14 is disposed within and substantially surrounded by the shrink sleeve 12. Finally, the shrink sleeve 12 is shrunken such that the inner surface 34 of the shrink sleeve 12 constricts around a portion of the side surface 20 of the closure 14.
In general, the method of the present invention also allows for applying shrink sleeves 12, which may include labels, to closures 14 by moving the closure 14 into proximity with a source of shrink sleeve 12 film, positioning a strip of tubular shrink sleeve 12 around each closure 14, and heating the shrink sleeve 12 to shrink it against the closures 14. Additionally, the method includes severing the shrink sleeve 12 between adjacent closures 14 to separate them into individual shrink sleeves 12, each associated with one such closure 14. In one particular embodiment of the invention, the shrink sleeves 12 are heat-shrunken on the articles 10 using hot air in a shrink tunnel 48, through which the closures 14 and associated shrink sleeve films 12 are moved.
In the illustrated embodiment of the present invention, the shrink sleeve apparatus includes a roll 50 from which the plastic shrink sleeve 12 is dispensed, an air source 52, a mandrel 54, a cutoff device 56, and a shrink tunnel 48. In particular, a master roll 50 of shrink film is prepared with a number of label copies across its surface. The particular number of labels depends upon the size of the label copy and the width of the master roll 50. The printed rolls 50 are then slit-cut, thereby forming individual rolls 50 containing one copy of the label only. The slit rolls 50 are then folded and overlapped, and seamed at the edge, forming a shrink sleeve 12 that is wound on a core.
In operation, an article 10, such as a bottle including a closure 14, is guided underneath the air source 52 and mandrel 54. The mandrel 54 is aligned with the shrink sleeve film 12, which is obtained from the roll 50. A shrink sleeve 12 is pulled from the roll 50 and is blown open into its tubular form by air from the air source 52. This tubular shrink sleeve 12 is then positioned over and slipped past the mandrel 54 in order to maintain its tubular form and to guide the shrink sleeve 12 over the closure 14 of the article 10. In the present invention, as the closures 14 are positioned proximal to the shrink sleeve 12 and mandrel 54, they are positioned such that the longitudinal axis 26 of each closure 14 is substantially parallel to the axis of symmetry 46 of the shrink sleeve 12. After the shrink sleeve 12 is guided and positioned around the closure 14, a cutoff device 56 is used to sever the shrink sleeve 12 from the remainder of the roll 50 of film. Next, the closure 14 and the loose plastic shrink sleeve 12 proceed through the shrink tunnel 48, which shrinks the shrink sleeve 12 against the closure 14 through the application of heat. The heat for shrinking may be provided by steam. Alternatively, heat may be provided by a hot air manifold. Also, heat may be applied by a combination of these methods, for example, steam heat coupled with air movement. A constant heat may be applied to the shrink sleeve 12 and closure 14. Alternatively, the shrink sleeve 12 and closure 14 may experience gradations of temperature as they move through the shrink tunnel 48. In one embodiment, heat may be applied to the shrink sleeve 12 and closure 14 at a temperature in the range of about 140° F. to about 190° F. Such a shrink sleeve apparatus is commercially available from Nippon Automatic Fine Machinery Company of Anaheim Hills, Calif.
The desired temperature within the shrink tunnel 48 depends upon a number of factors, such as the speed at which the closure 14 and plastic shrink sleeve 12 are moved through the tunnel 48, and also the particular composition and thickness of the plastic film. In general, in one embodiment, heat should be applied that will reduce the size of the shrink sleeve 12 from 40% to 70%.
Following shrinking, the closure 14 and shrink sleeve 12 may then be cooled by subjecting the shrink sleeve 12 to ambient temperatures to allow for a gradual cooling process. Alternatively, the shrink sleeve 12 may undergo other cooling steps, such as subjecting the shrink sleeve 12 to cool air or liquid.
While the present invention has been disclosed by reference to the details of preferred embodiments of the invention, it is to be understood that the disclosure is intended as an illustrative rather than in a limiting sense, as it is contemplated that modifications will readily occur to those skilled in the art, within the spirit of the invention and the scope of the amended claims.
This application is a continuation-in-part of U.S. patent application Ser. No. 11/253,044, entitled “Shrink Sleeve for an Article Closure,” filed Oct. 18, 2005, the disclosure of which is incorporated by reference herein in its entirety.
Number | Date | Country | |
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20070087144 A1 | Apr 2007 | US |
Number | Date | Country | |
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Parent | 11253044 | Oct 2005 | US |
Child | 11358546 | Feb 2006 | US |
Parent | 11260528 | Oct 2005 | US |
Child | 11358546 | Feb 2006 | US |