To preserve products such as fresh foods, it is desirable to package these products in air-tight or hermetically sealed containers. This prevents the ingress of gasses, liquids and solids that could otherwise degrade or spoil the products. Such packaging container typically comprises a thermoformed tray made of plastic polymer and a lid made of heat-sealable plastic film, wherein the plastic polymer contributes to both barrier and structural properties of the finished container. Paperboard has been widely used as a packaging material due to its low cost and biodegradability. However, paperboard has poor barrier properties and requires at least one barrier layer to impart barrier performance.
U.S. Pat. No. 5,009,939 discloses a gas-tight container made of a folded paperboard structure that is blow-molded with a barrier film. The paperboard blank with scored fold lines (as shown in
UK Patent Application No. GB 2 155 770 discloses a gas-impermeable container comprising a molded rigid porous tray having a gas-impermeable composite plastic coherently bonded to the inner surface of the tray, and a lid comprising a gas-impermeable composite plastic secured around the rim of the container. The gas-impermeable composite plastic comprises of three layers: a layer made of gas-impermeable thermoplastic polymer sandwiched between two layers of ionomeric polymeric materials. The gas-impermeable composite plastic is coated onto the inner surface of the tray by drawing-down or vacuum-forming techniques.
Another known container suggested for hermetically sealed or gas-tight applications utilizes a paperboard sheet that is pre-coated with a polymer film using an extrusion process. After being coated, the paperboard is then pressed to form a container structure. Such containers comprise creases or pleats, and in these regions, the polymer film of the pre-coated paperboard will follow the valleys of the creases or pleats and cause gaps or channels between sealing film and tray flange. This particular drawback is addressed in the U.S. Pat. No. 6,651,874. A cardboard blank is first surface-coated with a gas barrier coating, and then the pre-coated blank is pressed into the tray cardboard structure. During the press forming process, the cardboard layer and the soft weld coating layer melt together by means of heat or friction so that the valleys of the creases or pleats on the pressed cardboard structure are smoothed out, allowing the cardboard and coating layers to be welded together in a gas-proof manner.
There is still a need for hermetically sealed containers with enhanced barrier and seal performances that may be produced by a process that is more effective and economical for the in-plant system.
A hermetically sealed container is disclosed that may be produced by an effective and economical process for an in-plant system. The container comprises a coated unitary tray component having a base portion, a side wall portion, and a flange portion; and a lid component hermetically sealed to the flange portion of the tray component. A selected composite polymer film is blow-molded onto an interior surface of the pre-shaped unitary tray structure to provide the coated unitary tray component having its interior surface seamlessly, creaselessly and integrally bonded with the polymeric film.
The present disclosure now will be described more fully hereinafter, but not all embodiments of the disclosure are necessarily shown. While the disclosure has been described with reference to exemplary embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the disclosure.
In addition, many modifications may be made to adapt a particular situation or material to the teachings of the disclosure without departing from the essential scope thereof.
The hermetically sealed container of the present disclosure comprises:
The term “pre-shape unitary tray structure” refers to a unitary and intact structure that, once formed, does not require any external influence to maintain the structure in its intact and usable state.
Various known packaging materials may be used for forming the pre-shaped unitary tray structure. Examples of such materials include, but are not limited to, paper, paperboard, cardboard, fiberboard, plastic, laminates, paper/plastic composites, polystyrene foam, polymeric foam, and aluminum. Furthermore, the packaging material may be pre-treated prior to formation of the unitary tray structure. For example, when paperboard is used for the pre-shaped unitary tray structure, the paperboard may be extrusion coated with a selected material before being formed into the tray structure. Alternatively, in some embodiments, the paperboard may be uncoated when being formed into the tray structure. In one exemplary embodiment, the unitary tray structure is formed from a clay-coated SBS (solid bleached sulphate) sheet of paperboard having an approximately thickness of 0.45 mm (0.018″), with the clay-coated side providing the exterior surface of the tray and the non-coated side providing the interior surface of the tray.
It will be understood that in other embodiments of the present disclosure the nature and material properties of the packaging materials used for forming the pre-shaped unitary tray structure may be modified and optimized according to the end use applications of the hermetically sealed container. The thickness of the materials used for formation of the unitary tray structure may be varied depending on the end use and desired properties of the disclosed hermetically sealed container. For example, when paperboard is used for the pre-shaped unitary tray structure, the thickness of the paperboard may be selected to satisfy the rigidity and durability requirements of the final container. When desired, the paperboard with a thickness range of 250 micron (10 mils) and 750 micron (30 mils) may be used.
The disclosed containers may be in numerous shapes and formats. Examples of container shapes may include, but are not limited to, round shape, rectangular shape with round corner, elliptical shape, and oval shape.
In one embodiment, the packaging material may be formed into the pre-shaped unitary tray structure by press-molding process. However, other known techniques for the formation of tray structure may be used. When desired, the pre-shaped unitary tray may be molded in a shape that comprises round or fillet corners rather than sharp creased joints.
Due to the blow-molding process of disposing the polymer film 20 onto the interior surface of the pre-shaped unitary tray structure 10, the thickness of polymer film 20 across the interior surface may not be uniform. Other processing techniques for depositing the polymer layer may result in more uniform and less varied polymer film thickness across the surface of the tray structure 10. For the purposes of hermetic sealing, it may be less important that the polymer film 20 is applied in a homogenous manner and more important that the polymer film covers the tray structure 10 in the areas where the tray structure 10 in itself is or will not be gas-tight once sealed. It is also important that the polymer film 20 covers the flange portion 12 for enabling a hermetic seal to be created between the tray structure and a lid component of sealing film 22. As shown in
In one embodiment, the composite polymer film 20 may be a co-extruded material and melted at an approximate temperature of 490° F. for blow-molding process onto the interior surface of the pre-shaped unitary tray structure 10. In other embodiments, rather than using a co-extruded polymer film 20; a composite polymer film 20 may be disposed onto the interior of the pre-shaped unitary tray structure 10 by sequentially blow-molding of one polymer layer after the others.
In other embodiments, the composite polymer film 20 may comprise any number of layers from a single layer to a multiple layer composition. If desired, a tie layer may be positioned between these polymer layers to aid adhesion of one polymer layer to another and to aid adhesion of one polymer layer to the pre-shaped unitary tray structure. When appropriated, the tie layer may offer an additionally benefit in that it imparts a removable bond between the composite polymer film and the pre-shaped unitary tray structure such that the two parts may be separated for recycling purposes after use.
It will be understood that the composite polymer film for the interior coating of the unitary tray structure may be modified and optimized to accommodate the desired packaging performance. The composite polymer film may include a variety of polymers. Examples of these polymers include, but are not limited to, PET, LDPE, nylon, poly ethylene-vinyl alcohol copolymer (EVOH), polypropylene, and combinations thereof.
Various composite polymer films may be used in the disclosed hermetically sealed container. Examples of such composite polymer compositions include, but are not limited to, tie layer/PET; tie layer/LDPE/tie layer/PET; tie layer/EVOH/tie layer/PET; tie layer/nylon/tie layer/PET; tie layer/LDPE/tie layer/EVOH/tie layer/PET; tie layer/LDPE/tie layer/nylon/tie layer/PET; tie layer/nylon/tie layer/EVOH/tie layer/PET; tie layer/EVOH/tie layer/nylon/tie layer/PET. When desired such as for the non-dual ovenable applications, polypropylene could be substituted for the PET in any of the exemplary compositions provided above.
After the composite polymer film is applied to the pre-shaped unitary tray structure and optionally after the trimming of the excess flange portion, the coated unitary tray component may be shipped to a converting plant where the coated unitary tray component may be loaded with articles to be packaged, such as fresh food-stuffs or personal care items. At the converting plant, a lid component 22 may be affixed to the coated flange portion of the coated unitary tray component. Several known techniques may be used to seal the lid component to the coated unitary tray component. Examples of such techniques include, but are limited to, adhesion bonding, mechanical fastening, or combinations thereof.
In one embodiment, the lid component may be adhered to the flange portion of the coated unitary tray component by heat-sealing process. The lid component may be made of heat sealable materials. When desired, at least a flange portion of the coated unitary tray component may be additionally coated with heat sealable materials to further enhance the sealing performance.
In one exemplary embodiment, the lid component may be made of PET polymer. When desired, the lid component may be coated with heat-seal coating composition to enhance the sealing performance of the lid component and the unitary tray component. Examples of such coated films include, but are not limited to, Mylar® OL and Mylar® RL heat-sealable polymer films. Both exemplary heat-sealable polymer films are commercially available from DuPont-Teijin Films. In other embodiments of the disclosure, the lid component may be made of PET with additional barriers applied and with or without a heat seal coating applied. When appropriate such as for non dual-ovenable applications, non-PET sealing film may be used for the formation of the lid component. It will be understood that the selection of sealing film compositions for the lid component depends on package requirements. Many polymers and other plastics materials are known in the art for sealing performance, and the specific polymer materials listed in this specification are provided as examples only.
Once the lid component is applied to the loaded unitary tray component, a hermetically sealed package containing preserved article is produced. The exact nature of the seal created depends upon the application of the container. For food articles, it may be required that the unitary tray and the lid components impermeable to critical volumes of gases that could cause degradation of the packaged product within an unacceptable time scale. Throughout the present disclosure, the term “hermetic seal” is used to refer to any sufficiently leak-free or any sufficiently airtight seal that will offer suitable protection of the packaged products. As such, the terms “hermetic seal” and “hermetically sealable” are used to cover any perfect seal as well as any seal comprising microscopic leaks or imperfections that are small enough not to cause unsatisfactory degradation of the packaged products and are approximately of the same order of magnitude as the permeation through the packaging materials.
In one embodiment, the disclosed container further includes a top cover positioned over the lid component to impart rigidity and sturdiness to the lid component and consequently the disclosed container. The top cover may be made of a rigid or semi-rigid material. For example, the top cover may be made of paperboard. In one embodiment, the top cover may be adhered to the lid component by heal sealing process. When desired, heat sealable materials may be coated to at least the rim portion of the top cover to enhance the heat seal adhesion between the top cover and the lid component.
In one embodiment, the disclosed hermetically sealed container may be produced by a process comprising steps of:
When desired to further enhance the sealing performance, a layer of heat-sealable coating may be applied at least onto the flange portion of the coated unitary tray component prior to the hermetic sealing of the lid component.
It will be understood that the specific embodiment described represents only some examples of how the present disclosure may be put into effect. One skilled in the art will readily recognizes that many variations in the materials used, material combinations, material properties, as well as size and shape of container are possible.
It will be recognized that as used herein, directional references such as “top”, “bottom”, “front”, “back”, “end”, “side”, “inner”, “outer”, “upper” and “lower” do not limit the respective panels to such orientation, but merely serve to distinguish these panels of the container from one another.
While the disclosure has been described by reference to various specific embodiments, it should be understood that numerous changes may be made within the spirit and scope of the inventive concepts described. It is intended that the disclosure not be limited to the described embodiments, but will have full scope defined by the language of the following claims.
This non-provisional application relies on the filing date of U.S. Provisional Application Ser. No. 61/180,943 filed on May 26, 2009, the entire contents of which are incorporated herein by reference.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US2010/036014 | 5/25/2010 | WO | 00 | 10/25/2011 |
Number | Date | Country | |
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61180943 | May 2009 | US |