Abstract:
A container for protectively encapsulating a product, such as a perishable food product, during shipment and display. The container includes a tubular body constructed of a composite sheet material and defining a receptacle for receiving the food product. An outer surface of the body defines an edge surrounding an entrance of the receptacle. An end closure abuts the edge of the tubular body so as to extend over the entrance. Extending over the end closure and the outer surface of the body is a film sleeve that serves to secure the end closure to the body. An adhesive can be used to seal the film sleeve to the end closure and body so as to hermetically seal a juncture between the end closure and the body. A score line on the film sleeve facilitates opening of the container while extending only partially through the film sleeve to preserve its barrier properties.

Description:
BACKGROUND OF THE INVENTION  
         [0001]    1. Field of the Invention  
           [0002]    The present invention relates to composite containers for food products, and more particularly, to multiple-ply tubular containers including a paperboard ply, an inner liner ply and an outer polymeric sleeve.  
           [0003]    2. Description of Related Art  
           [0004]    In the packaging of perishable food products, a container is required that is rigid enough to retain its shape when subjected to internal pressure produced in the container while tightly sealing the food product to protect against deterioration, leakage and contamination. Thus, perishable food products are often packaged in composite tubular containers that are sealed at both ends. The tubular body portion of these containers conventionally includes three separate plies or sets of plies.  
           [0005]    At least one structural body ply made of paperboard material is included which is formed into a tubular structure by wrapping a continuous strip of body ply paperboard material around a shaping mandrel. The body ply strip may be spirally wound around the mandrel or passed through a series of forming elements so as to be wrapped in a convolute shape around the mandrel to form the tubular structure. As it is formed, the tubular structure is advanced to a cutting station. At the cutting station, the tube is cut into predetermined lengths at the downstream end of the mandrel and fitted with one end closure to prepare the container for shipping to the customer. The can is then filled and the other end closure is applied.  
           [0006]    The completed container includes a heat-sealable liquid impermeable ply (“the liner ply”) adhered to the inner surface of the paperboard ply. The liner ply seals the food product, such as potato crisps, chips, refrigerated dough or juice, within the container, and also prevents liquids, which may possibly contaminate the food product, from entering the container. Some liner plies are also gas and vapor impermeable, so as to not only prevent food product odors from escaping the can, but also prevent atmospheric air and water vapor from entering the container and spoiling the food product. Thus, while the purpose of the body ply is to provide necessary structural properties to the container, the liner ply provides barrier properties necessary to protect and maintain the perishable food product. The liner ply is typically integrated into the can during the mandrel winding process.  
           [0007]    A label ply, which is typically a paper-based ply, is included and adhered to the outer surface of the paperboard body ply. The label ply serves two primary functions. First, a composite can label is a source of information. The label carries the graphical matter that conveys product information, instructions, and regulatory compliance information. The label is also preferably decorative and aesthetically pleasing to the consumer, which enhances shelf appeal and increases consumer interest in the food product. In particular, the gloss of a label is important for consumer appeal, with high and even gloss being preferable. The label is commonly integrated into the can during the mandrel winding process, although convolute labels may be applied at a later time.  
           [0008]    The graphics included on conventional paper labels are either rotogravure or flexographically printed and may require thermosetting-type overlacquers over the inks to protect the inks used in the label printing process. However, the overlacquers may not absorb evenly into the paper resulting in inconsistent gloss characteristics. In addition, paper labels have a relatively high surface roughness which reduces the smoothness of the label even after application of the overlacquer.  
           [0009]    In addition to being a source of information, the composite can label imparts physical characteristics to the can. For example, the wet strength of the label ply can be an important factor in composite container design. If the container is exposed to moisture and the paperboard ply gets wet, the strength of the can may be compromised. Such moisture is sometimes encountered during shipping. At other times, condensation may form on the surface of the can if the can is refrigerated, or otherwise exposed to cold temperatures, and then moved to a warmer, humid environment. If the wet strength of the label ply is low, then the label will provide little additional strength to the body ply to prevent the premature rupturing of the container.  
           [0010]    The wet strength of conventional paper label plies is especially important when the plies are used in conjunction with composite cans for dough. Composite dough cans are designed differently from other composite containers such that most of them can be opened by forcefully striking container against a sharp surface, such as the edge of a kitchen counter. Others are designed to self-open immediately once the label has been peeled off. The edges of the body ply strip are typically abutted and held together with an unadhered, or weakly adhered, joint or seam. Accordingly, when the label ply is removed the internal pressure of the dough, and in the case of non self-opening cans the force of the impact against a sharp edge, causes the body ply seam to separate. Separation of the body ply seam causes failure of the liner ply and allows removal of the dough product from the can. The label ply is thus designed to provide a substantial component of the total strength of the can necessary to prevent the can from prematurely opening. Exposure of the paperboard ply, which has a low wet strength, makes the strength of the label ply even more critical.  
           [0011]    U.S. Pat. No. 6,290,119 to Reese et al. (“Reese”), commonly assigned and incorporated herein by reference, discloses a composite container  10  having a polymer film label ply. As shown in FIG. 1 of Reese, the composite container includes a tubular body ply  12 , a liner ply  13  adhered to the inner surface of the tubular body ply, and a film label ply  14  adhered to the outer surface of the tubular body ply. A pair of end closures  16 ,  18  are secured to opposite ends of the composite container.  
           [0012]    During assembly, the liner and tubular body plies are wound around a mandrel  26 , as shown in FIG. 6 of Reese. The film label ply includes reverse-printed indicia and a heat-sealing adhesive coating on its inner surface. The film label ply is passed through a heater  44  which activates the adhesive coating. Once heated, the film label ply is applied to the outside of the body ply so as to form a continuous tube. The continuous tube is cut into discrete lengths in register to label graphics at a cutting station  48 , one end closure is applied to each of the discrete lengths for shipping to, and later filling and application of the second end closure at, the customer.  
           [0013]    Advantageously, the film layer increases the gloss of the label ply and protects the indicia applied to its inner surface. In addition, the film label ply is relatively strong and isolates the body ply from moisture to prevent premature opening of the can. Despite these advantages, additional improvements in the strength, durability and protective ability of composite cans are highly desirable.  
           [0014]    Therefore, it would be advantageous to have a composite can that protectively contains perishable food items and isolates the food items from the environment. It would be further advantageous if the can had a glossy outer surface bearing indicia so as to be easily handled and attractive to consumers. It would be further advantageous if the composite can had an outer ply that provides additional strength to the can and inhibits premature opening of the can.  
         BRIEF SUMMARY OF THE INVENTION  
         [0015]    The present invention addresses the above needs and achieves other advantages by providing a container for protectively encapsulating a product, such as a perishable food product, during shipment and display. The container includes a tubular body constructed of a composite sheet material and defining a receptacle for receiving the food product. An outer surface of the body defines an edge surrounding an entrance of the receptacle. An end closure abuts the edge of the tubular body so as to extend over the entrance. Extending over the end closure and the outer surface of the body is a polymeric film sleeve. The polymeric sleeve has a glossy outer surface, and durable, appealing graphics through reverse printing on its interior surface. An adhesive can be used to seal the film sleeve to the end closure, or to seal the film sleeve to both the end closure and the body, so as to hermetically seal a juncture between the end closure and the body. Opening of the container may be facilitated by laser scoring a spiral liner score line onto the film sleeve that extends only partially through the film sleeve to preserve its barrier properties. Alternatively, a tear strip or notch may be incorporated on the edge of film which may have a spiral or linear tear preference.  
           [0016]    In one embodiment, the present invention includes a container for protectively encapsulating a product during shipment. The container includes a body, at least one end closure, a film sleeve and an adhesive. A receptacle is defined within the body and the body includes an outer surface. The outer surface of the body defines an edge surrounding an entrance of the receptacle. The receptacle and the entrance are sized and shaped to receive the product. Abutting the edge of the body is the end closure which extends over the entrance of the receptacle. The end closure includes an outer end closure surface wherein adjacent portions of the outer end closure surface and outer body surface form a juncture. The film sleeve covers the body and extends over the juncture between the body and outer end closure surfaces. The adhesive adheres the film sleeve to the outer surface of at least the end closure so as to seal the juncture between the end closure and the body.  
           [0017]    In another embodiment, the present invention includes a container for protectively encapsulating a perishable food product during shipment and display. The container includes a tubular body constructed of a composite sheet material including a body ply and an inner liner ply. Also, the tubular body has an outer surface and defines a cylindrical receptacle having a pair of opposing end entrances. Defined by the outer surface of the body is an edge that surrounds each entrance to the cylindrical receptacle. The cylindrical receptacle and at least one of the entrances are sized and shaped to receive the perishable food product. An end closure is shaped to abut the edge of the tubular body and extend over one of the entrances of the cylindrical receptacle. The end closure includes an outer end closure surface wherein adjacent portions of the outer end closure surface and outer body surface form a juncture. A film sleeve covers the body and extends over the juncture between the body and the outer end closure surfaces.  
           [0018]    In another aspect, the end closure has a circular shape and is sized to abut the circular shaped edge defining the entrance to the receptacle. The other end of the tubular body also has a circular shape and the container includes a second end closure having a circular shape. The second end closure is sized to abut the circular shaped edge of the other end of the tubular body. Similar to the first end closure, the second end closure has an outer end closure surface with a portion adjacent to a portion of the outer body surface so as to form a second juncture. The film sleeve extends over the second juncture and the adhesive adheres the sleeve to at least the outer surface of the second end closure. Additionally, the film sleeve may be adhered to the outer body surface.  
           [0019]    In yet another aspect, the outer ply is a paperboard ply and the inner liner ply is at least partially impermeable to fluids, gasses and vapors. The inner liner ply may include a metal foil, or a metalized film layer.  
           [0020]    The adhesive may include several types of material. Preferably, the adhesive is an ethylene acrylic acid dispersion. Optionally the adhesive may be any one of a number of materials such as a latex acrylic, an ionomer dispersion, a heat-activated urethane, a heat-activated acrylic or a heat activated PVDC (polyvinylidene dicholoride). The film sleeve may also be constructed of different types of materials such as oriented polyethylene terephthalate, oriented polypropylene, oriented polyvinyl chloride or oriented polystyrene or oriented polyethylene terphthalate glycol. A perforation or score line may also be defined by the sleeve to facilitate opening of the container, wherein the sleeve extends between the ends of the body. The score line may be accompanied by a tear strip to further facilitate opening of the container, or a blank container may have an eyespot line along the body ply seam that is used to register the scored film line to the body ply seam. Preferably, the film sleeve is shrink-fit onto the end closures and the body so as to create a hermetic seal between the film and the end closures.  
           [0021]    In still another aspect, coupons or game pieces may be incorporated under or inside the film sleeve, especially between the film sleeve and one of the end closures.  
           [0022]    Among the advantages of the present invention is the benefit of a container hermetically sealed by a shrink wrapped, polymeric sleeve, and adhesive applied thereto, against the passage of gasses, vapors and fluids that might contaminate the products, such as perishable foods, enclosed therein. This is especially useful in refrigerated environments that are moist and can discolor, or cause mildew to grow on, the paperboard or other materials of the tubular body. In addition, the polymeric sleeve has an increased ability to contain internal pressures and guard against premature opening as compared to conventional labels. Generally, the container can be manufactured at a lower cost than conventional composite containers having fluid permeable outer labels. For instance, the increased strength of the sleeve, and its ability to block the passage of fluids that weaken the tubular body plies allows the use of generally weaker (and less expensive) paperboard and liner materials. Further, the polymeric sleeve is generally cheaper to manufacture than conventional containers having multiple foil layers, such as an outer label constructed of a foil material. The advantage of shifting application of the polymeric sleeve to the filler is that there is no need to stock multiple types of printed cans at the filler. Each can is labeled as it is filled, allowing quick changes for short-run promotions.  
       
    
    
     BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING(S)  
       [0023]    Having thus described the invention in general terms, reference will now be made to the accompanying drawings, which are not necessarily drawn to scale, and wherein:  
         [0024]    [0024]FIG. 1A is a perspective view of a composite container of one embodiment of the present invention;  
         [0025]    [0025]FIG. 1B is a sectional view of the composite container shown in FIG. 1A demonstrating a film label sleeve sealed over a crimped end closure and body of the composite container using an adhesive;  
         [0026]    [0026]FIG. 2 shows an enlarged sectional view of the film label sleeve shown in FIGS. 1A and 1B;  
         [0027]    [0027]FIG. 3 is a fragmentary and enlarged view of the film label sleeve shown in FIGS. 1A and 1B demonstrating graphical matter on at least a portion of its inner surface;  
         [0028]    [0028]FIG. 4 is a reverse fragmentary and enlarged view of a film label sleeve of another embodiment of the present invention demonstrating graphical matter and the adhesive in a dot pattern on an inner surface of the film label sleeve;  
         [0029]    [0029]FIG. 4A is an enlarged view of the adhesive in a dot pattern on the inner surface of the film label sleeve shown in FIG. 4;  
         [0030]    [0030]FIG. 4B is an enlarged view of an adhesive on the inner surface of the film label sleeve in a strip pattern of another embodiment of the present invention;  
         [0031]    [0031]FIG. 5 is a greatly enlarged sectional view of the adhesive in a dot pattern taken along line  5 - 5  of FIG. 4A;  
         [0032]    [0032]FIG. 6 is a plan view illustrating a method for making a tubular body of the composite container shown in FIG. 1A;  
         [0033]    [0033]FIG. 7 is a front elevation view of a sleeving machine for applying the film label sleeve around the filled and capped tubular body to form the composite container shown in FIG. 1A; and  
         [0034]    [0034]FIG. 8 is a side elevation view of the sleeving machine of FIG. 7 including a film sleeve supplier.  
     
    
     DETAILED DESCRIPTION OF THE INVENTION  
       [0035]    The present inventions now will be described more fully hereinafter with reference to the accompanying drawings, in which some, but not all embodiments of the invention are shown. Indeed, these inventions may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will satisfy applicable legal requirements. Like numbers refer to like elements throughout.  
         [0036]    The present invention includes a sealed, composite container  10  for protectively encapsulating a consumer product during shipment and display, as shown in FIG. 1A. The container includes a tubular body  11  constructed of a composite sheet material, which in the illustrated embodiment includes a body ply  12 , and an inner liner ply  13  adhered to the inner surface of the body ply. The tubular body  11  has a pair of open ends  14 , the open ends being covered by a pair of end closures  15 ,  16 . A film ply or sleeve  17  extends over the outer surface of the body ply  12  and further over a juncture  18 , or seam, between the body  11  and the end closures  15 ,  16 .  
         [0037]    Although illustrated as having a circular cross-section, the tubular body  11  may have any cross-sectional shape which can be formed by wrapping the composite sheet material around an appropriately shaped mandrel. One example is a generally rectangular shaped tubular body having rounded comers. The container  10  of the present invention is particularly advantageous when used to encapsulate perishable goods that should be isolated from the environment to ensure freshness, such as dough or potato crisps. The container  10  of the present invention may also be used to encapsulate other consumer products that are sensitive to the environment, such as tennis balls or grass seed.  
         [0038]    The body ply  12  of the composite container  10  of one embodiment of the present invention is preferably formed of a paperboard material. The film sleeve  17  is adhered to the outer surface of either, or both, of the end closures  15 ,  16 . Optionally, the film sleeve  17  is adhered to the outer surface of the body ply  12  and extends over the end closures  15 ,  16 . Adherence of the film sleeve  17  to the paperboard material of the body ply  12  seals the tubular body  11  against the passage of liquids, gasses and vapors. Adhering the film sleeve  17  to both of the end closures  15 ,  16  seals each juncture  18  against entrance or exit of fluids, vapors and gasses. Preferably, extension of the film sleeve  17  over the body ply  12  and each juncture  18  is combined with fluid, gas and vapor impermeable end closure  15 ,  16  materials. For instance, the end closure materials may include a metal, such as a tin-free chrome plated steel, or a barrier plastic sufficiently strong to withstand external and internal pressures on the container  10 . In this manner, the entire container  10  can be hermetically sealed against the environment to provide improved protection for the perishable food product enclosed therein.  
         [0039]    The film sleeve  17  is preferably constructed of a polymeric material that can either be transparent or opaque, and includes an inner surface  17 A and an outer surface  17 B, as shown in FIG. 3. One type of film sleeve  17  that can be used is oriented polyvinylchloride (PVC) that has an attractive gloss and predictable tear characteristics, such as 200 gauge, SR-AE PVC film from Bonset America Corporation of Browns Summit, N.C. During formation, oriented polypropylene is stretched a number of cycles in a machine direction and different number of cycles in a cross-machine direction under selected heating conditions. Such differential stretching gives the material a preferred orientation that promotes predictable tearing patterns facilitating its use as an outer ply in dough containers that must be split open. Other materials that may be used for film sleeve  17  include oriented polyethylene terephthalate, oriented polyethylene terephthalate glycol, oriented polypropylene, oriented polystyrene and laminates thereof.  
         [0040]    In one embodiment, the inner surface  17 A of the film sleeve  17  is printed with graphical matter  20 , such as product information, package opening instructions, and regulatory compliance information. The graphical matter is preferably printed on the inner surface  17 A of the film sleeve  17 , instead of on the outer surface  17 B of the film sleeve, by a reverse printing process. Reverse printing the graphical matter  20  on the inner surface  17 A of the film sleeve, which is adhered to the outer surface of the body ply  12 , advantageously protects the graphical matter from exposure to outside elements. The graphical matter  20  can be rotogravure or flexographically printed, with an overlacquer (not shown) included over the graphical matter to further protect its ink. Generally, the overlacquer is not necessary on reverse printed film sleeves and labels.  
         [0041]    As shown in FIG. 4, the inner surface  17 A of the film sleeve  17  also preferably includes an adhesive  22  for adhering the film sleeve to the outer surface of the body ply  12  and the end closures  15 ,  16 . The adhesive  22  is preferably an ethylene acrylic acid dispersion which is a water-based adhesive that bonds well to both metal, paperboard and films. Additional adhesives that may be used include temperature-activated urethane and acrylic heat seal coatings, and cold seal coatings which are activated by pressure. Still other adhesive compositions that can be used include a latex acrylic which bonds well to plastic as a cohesive material, or an ionomer which is an acid polymer revitalized with a metal salt.  
         [0042]    The adhesive  22  can be applied to the entire inner surface  17 A of the film sleeve  17  and over the printed graphical matter  20  as shown in FIG. 2. Alternatively, the adhesive  22  can be applied to a portion of the inner surface  17 A of the film sleeve  17  in a pattern of dots  23 , as shown in FIG. 4A, or in a pattern of strips  24 , as shown in FIG. 4B. The adhesive strips may also be printed in an angular pattern as is prompted by the helical construction of the tubular body  11  so as to influence or enhance the tear properties of the film sleeve  17 . Further, the adhesive may be applied in a continuous strip at the edges of the film for adhesion to the metal end closures  15 ,  16 . As shown in FIGS. 2 and 5, the adhesive  22  is disposed on the inner surface  17 A of the film sleeve  17 , but over the reverse-printed graphical matter  20 . An adhesive could also be separately applied to the body ply  12  and the film sleeve  17  during manufacture such as with rollers and the like. For example, adhesion can be promoted by applying the ethylene acrylic acid to both the body ply  12  and the film sleeve  17 .  
         [0043]    FIGS.  6 - 8  illustrate a method of making a multiple ply composite tubular body for use in the present invention. A continuous strip of body ply  12  (preferably a paperboard ply) is advanced toward a shaping mandrel  26 . As the body ply  12  is advanced toward the shaping mandrel  26 , the body ply is advanced through a wet-bond adhesive applicator  28  which applies an adhesive  30  to the inner surface of the body ply, as shown in FIG. 6. The liner ply  13  is also continuously advanced toward the shaping mandrel  26  as a lubricant from a roller  38  is applied to its inner face. The optional lubricant allows the liner ply  13  to slide smoothly along the mandrel  26 . The liner ply  13 , which is preferably constructed of a heat sealable material, is heated by an air-knife heater (not shown) causing it to become sealed to itself as it is wound around the mandrel  26 . The mandrel may be chilled to promote the self sealing of the liner ply  13 .  
         [0044]    It will be understood to those skilled in the art that various liner constructions with various barrier materials or properties could be employed depending upon the item being packed in the composite container  10 . The liner ply  13  may be wider than the body ply  12  depending upon the amount of liner overlap that is desired.  
         [0045]    The body ply  12 /liner ply  13  laminate is then wrapped around the shaping mandrel  26 . The laminate is first wrapped under the mandrel  26  and then back over the top in a helical fashion with the liner ply  13  wound against the surface of the mandrel  26 . As the body ply  12 /liner ply  13  laminate advances back under the mandrel  26  after one complete revolution, its trailing edge is brought into contact with the leading edge of the ensuing portion of the body ply/liner ply laminate, which is first coming into contact with the mandrel. The edges become abutted together to form a continuous, spirally wound tube that advances along the mandrel  26 .  
         [0046]    The tube is then advanced down the mandrel  26  by a winding belt  40  that extends around a pair of opposed pulleys  42 . The winding belt  40  not only rotates and advances the tube, but applies pressure to the overlapping edges of the body ply  12  and the liner ply  13  to ensure a secure bond between the respective ply edges. Instead of the “same side winding” process described above, however, the body ply  12  and liner ply  13  could be brought together at the mandrel  26  from opposite sides of the mandrel in a process known as “opposite side winding.” The pressure of the winding belt  40  causes the body ply  12  and liner ply  13  to be adhered together. After the body ply and liner ply are adhered together on the mandrel  26 , the continuous tube is cut into discrete lengths at a cutting station  48  and then removed from the mandrel. Each discrete length, i.e., each tubular body  11  has one end  15  attached and then may be filled with dough, or other consumer products. The filled body then has its second end  16  attached by crimping one or both end closures  15 ,  16 , as illustrated in FIG. 1B, or in a manner well-known in the art, such as by conventional double-seam end application.  
         [0047]    Once the tubular body  11  has been filled with product, and the end closures  15 ,  16  have been applied (typically, one of the ends has been applied before filling), the tubular body is ensleeved by a continuous feed sleeving machine  50 , as shown in FIG. 7. The sleeving machine is fed by an input conveyor  74  or other conventional feeding apparatus. The filled tubular bodies may be transported in a single-file fashion or via a flood feed. The tubular body  11  is picked up by a timing screw  70  at one of its furrows, so that only one tubular body is transported to a pedestal system  64  at any one time. The timing screw  70  is constructed so as to engage the tubular body  11  at its center of mass so that there are few torques upon the tubular body. The tubular body may be trapped between the timing screw  70  and a rail or guard on the opposite side. The tubular body  11  is then moved onto a pedestal  66  of the pedestal system  64 .  
         [0048]    As the filled tubular body  11  makes its transition onto the pedestal  66 , a sleeved iris carrier  54  moves synchronously with the tubular body. As the tubular body  11  travels on the pedestal system  64 , the iris carrier  54  with its film sleeve  17  (not shown in FIG. 7 for clarity) descends about the tubular body. As the iris carrier  54  approaches the middle portion of the tubular body  11 , the film sleeve  17  is disposed about the tubular body  11 , end closure  15  and end closure  16 . Fingers present on the iris carrier  54  contract, causing the top of the sleeve  17  to engage the exterior of the filled tubular body  11 . The film sleeve  17  begins to adhere to the sides of the tubular body  11  by friction fit and by the cold, minimally tacky adhesive  20  applied thereon.  
         [0049]    The fingers of the iris carrier  54  are generally smooth to provide a low-friction surface engaging the interior surface of the film sleeve  17 . As the sleeve slightly adheres to the side of the tubular body  11 , the iris carrier  54  and its sleeve-carrying fingers begin to disengage the sleeve  17 , leaving it behind on the tubular body. As the iris carrier  54  continues to descend towards the bottom of the tubular body  11 , having either the end closure  15  or end closure  16  attached thereto, the fingers increasingly disengage the sleeve, leaving it to circumscribe the exterior of the tubular body and the end closures.  
         [0050]    The iris carrier  54  descends until the sleeve-carrying fingers completely disengage the sleeve  17 . At this point, the fingers then dilate, moving outward to expand the central aperture of the iris carrier  54  and the iris carrier begins its upward ascent about the tubular body  11  from its base to its top. In so traveling, the iris carrier  54  may help the tubular body  11  make the transition from the pedestal system  64  to the exit conveyor  76 . Once the iris carrier  54  has fully disengaged the tubular body  11  by ascending past its top, the iris carrier is ready to receive another sleeve from a sleeve feeder  52 .  
         [0051]    It should be noted that the embodiment of the sleeving machine  50  described above is considered to be exemplary. Other apparatuses known to those of skill in the art may also be employed and still achieve the objective of positioning the sleeve  17  about the filled tubular body  11  and the end closures  15 ,  16 .  
         [0052]    The sleeving machine  50  is continuously supplied with tubular film sleeves each having an opening therethrough sized to receive the tubular body  11  and a length greater than the tubular body. Preferably, the length of the “un-shrunk” film sleeve  17  is sufficient to also extend past the end closures  15 ,  16  attached to the ends of the tubular body  11 . The tubular film sleeves may be supplied in a number of ways known to those of skill in the art. For example, the sleeve feeder  52  includes a stepper motor  104  that controls a nip roller  106  that receives a ribbon  108  of pre-printed, adhesived sleeve material, as shown in FIG. 8. The ribbon  108  is held on one, or more, spools  112  each mounted on a shaft  116  which is supported by a stand  114 . The nip roller  106  controls the travel of the unspooled ribbon  108  into the sleeving machine  50 . The stepper motor  104  controls the length and rate of travel of the ribbon  108 . The stepper motor  104  causes the ribbon to pause briefly so that it may be cut by a guillotine-type cutter. As a discrete sleeve  17  is being cut, it is engaged and opened by a pair of sleeve feeding arms  120  which release it onto the iris carrier  54 .  
         [0053]    The ribbon  108  is constructed of a continuous sheet of polymeric material. The graphical matter  20  is pre-printed on the sheet&#39;s inner surface. The adhesive  22  is also applied to the inner surface of the polymeric sheet material, but over the graphical matter. The adhesive  22  is gravure-applied continuously, or in a pattern, depending upon the portions of the tubular body  11 , closure  15  and end closure  16  to which the sleeve  17  is meant to adhere. Other methods of applying the adhesive  22  and graphical matter  20 , and the machines for such application, are known to those of skill in the art and are therefore not described herein in further detail. The sheet of polymeric material is then shaped into a tube, flattened and wound into spools  112  as is also known to those of skill in the art.  
         [0054]    Once the sleeve  17  has been disposed over the tubular body  11 , the filled tubular body and its sleeve is advanced into a heat tunnel. The heat tunnel generates heat, such as through the use of resistive heating elements and laminar airflow, or the generation of steam, that causes the sleeve  17  to shrink about the tubular body  11  and end closures  15 ,  16 . In addition to causing the polymeric material of the sleeve  17  to shrink, the heat causes the temperature of the adhesive  22  to rise and become tacky. Once tacky, the adhesive causes the sleeve  17  to adhere to a portion of the outer surfaces of the end closures  15 ,  16 . Closely adhering the fluid and gas impermeable sleeve  17  to the end closures  15 ,  16 , which are also preferably constructed of fluid, vapor and gas impermeable materials, hermetically seals the composite container  10 . Optionally, the adhesive  22  can be applied over the juncture between the end closures  15 ,  16  and the body ply  12 , for additional barrier protection. Further optionally, the adhesive can be applied to the entire inner surface  17 A of the film sleeve  17 , for even more barrier protection and/or body ply strength enhancement.  
         [0055]    As yet another option, the polymeric sleeve  17  may be scored, such as during or after application of the sleeve, to facilitate opening of the container  10 , as shown in FIG. 1A. For instance, a double-line peel tab  122  may be positioned at one end of the container  10 . Extending from the peel tab  122  is a parallel set of score lines  124  that generally follow the directional tearing tendency of the polymeric material, especially if it is oriented material such as OPP, extending in the direction of the other end of the container  10 . The score lines  124  may be formed by a conventional cutting apparatus, or are preferably formed using a laser that can cut the polymeric sleeve  17  material to a half depth, thereby preserving its barrier properties.  
         [0056]    The score lines  124  may also be registered with the seam between the abutting edges of the spirally wound plies  12 ,  13  of the tubular body  11 . During the sleeving operation, registration of the score lines  124  with the seam of the body  11  can be facilitated by marking spots on the body ply  12 . These “eye spots” are positioned along one of the edges of the body ply  12  material and allow the use of a sensor to track the ply edges and register them with the score lines  124 . Other score line configurations may also be used, such as a single, linear score line between the ends of the container  10 , or multiple score lines without the use of a peel tab. The peel tab  122  could also be combined with a thickened strip of polymeric material extending between parallel score lines  124  to further facilitate opening of the container  10 . As yet another option, the peel tab  122  could be employed without the score lines  124  and be initiated with starter notches.  
         [0057]    Among the advantages of the present invention is the benefit of a container  10  hermetically sealed by a shrink wrapped, polymeric sleeve  17 , and adhesive  22  applied thereto, against the passage of gasses, vapors and fluids that might contaminate the products, such as perishable foods, enclosed therein. This is especially useful in refrigerated environments that are moist and can discolor, or cause mildew to grow on, the paperboard or other materials of the tubular body  11 . In addition, the polymeric sleeve  17  has an increased ability to contain internal pressures and guards against premature opening. The container  10  can be manufactured at a lower cost than conventional composite containers. For instance, the increased strength of the sleeve  17 , and its ability to block the passage of fluids that weaken the tubular body plies  12 ,  13  allows the use of generally weaker (and less expensive) paperboard and liner materials. The container with the polymeric sleeve  17  is also cheaper to manufacture than conventional containers having foil layers, such as an outer label constructed of a foil material. The polymeric sleeve  17  has a glossy outer surface, and durable, appealing graphics through reverse printing on its interior surface. The polymeric sleeve  17  allows flexibility with selected opening methods, such as the peel tab  122  and dual score lines  124 .  
         [0058]    Many modifications and other embodiments of the inventions set forth herein will come to mind to one skilled in the art to which these inventions pertain having the benefit of the teachings presented in the foregoing descriptions and the associated drawings. Therefore, it is to be understood that the inventions are not to be limited to the specific embodiments disclosed and that modifications and other embodiments are intended to be included within the scope of the appended claims. For instance, the polymeric film could be adhered over the tubular body  11 , the closure  15  and the end closure  16  by being spirally wound similar to the construction of the plies of the tubular body, and then heat shrunk. However, sleeved application of the polymeric material generally has improved barrier properties for blocking the passage of fluids and gasses into, and out of, the container  10 . Although specific terms are employed herein, they are used in a generic and descriptive sense only and not for purposes of limitation.