The present disclosure relates to paper-based container lids and, particularly, lids of the type used for fluid containers, such as cups or bowls, to hold hot liquids, such as coffee or soup, for example.
Plastic coffee cup lids, such as those used by restaurants, convenience stores, and coffee houses, are known. They commonly fit onto the top of paper cups to keep the contents from spilling out. Such lids are not made from a single paperboard blank because they do not effectively seal around the container's rim. The problem is in manufacturing paperboard lids. Substantial crimps in the lid's sealing ring form during manufacturing causing gaps in the paperboard. When the ring attaches to the rim of a cup or container, these gaps are a source of fluid leaks. This is why molded plastic remains the material of choice for cup lids.
The present disclosure describes a departure from plastic cup lids in favor of a paper-based board lid and method for manufacture of the same. These paperboard lids are manufactured without the substantial crimps formed in their sealing rings. The result is an effective paperboard container lid. This disclosure also contemplates using water-resistant coated paper such as a polycoated paper or board. It is appreciated that embodiments of the present disclosure may have nominal crimps on the outside surface of the sealing ring, but not on the inside portion of the ring sealing the container.
An illustrative embodiment of this paperboard lid includes a circular channel that formingly secures or “snaps-on” to a rim conventionally used at the open edge of a paperboard container, such as on a coffee or soup cup. An embodiment may also include a stacking ring that allows the bottom of a cup to be fitted onto the paperboard lid. This better secures cups stacked on top of each other.
A further illustrative method of manufacture of these lids includes providing an unformed lid blank. In one illustrative embodiment, the blank can have radially-extending grooves to aid in forming a sealing channel adjacent the periphery of the lid. The blank is then positioned inside a press that uses compression forces to form the final shape of the lid. A combination of draw and pressure rings hold the blank in place while male and female mold components compress the blank. Because the lid is to fit around the rim of a cup, the lid blank does not remain flat, but forms a three-dimensional shape having a sealing channel that receives the rim of the cup. Consequently, as the draw and pressure rings hold the paper blank, slides located at the periphery of the male and female mold components draw in laterally with respect to the blank adding lateral pressure. The multiple slides converge around the male and female mold components. In addition, the shape of the slides illustratively corresponds to the shape of the rim of the cup. This ensures the resulting sealing channel in the lid conformingly secures to the cup and seals it. Without the draw and pressure rings, however, portions of the paper blank can get caught between the slide segments causing substantial crimps in the wall of the lid's sealing channel. These substantial crimps may limit the sealability of the lid on the cup. In this illustrative embodiment, the draw and pressure rings holding the blank while being pressed into the lid prevents it from getting substantially caught between two adjacent sliders to cause the substantial crimp. It is contemplated that in some embodiments a slight crimp may be formed on the lid's outer surface using this process, but not to the extent of it affecting the sealability of the lid on the cup or being unsightly.
Another illustrative embodiment of this disclosure provides a substantially crimpless and monolithic paperboard container lid comprising a single contiguous molded paperboard body configured to conformingly couple to a top periphery of a container for covering the container's opening. The body comprises a sealing ring located adjacent the body's periphery. The sealing ring includes a sealing channel composed of a radiused cross-section that extends to a tangent ring terminating with a tab ring. The radiused cross-section and tangent ring are configured to at least partially wrap around the top periphery of the container. The radiused cross-section has a radius greater than 180 degrees to assist providing a snug friction fit between the lid and the container. Despite being made from paperboard, the lid does not include one or more substantial crimps in the sealing ring. Having no substantial crimps, the lid fits onto the container and prevents fluid from leaking between the container's periphery and the lid. It is, nevertheless, appreciated that substantially crimpless does not mean there can be no minor crimp on the exterior surface of the lid, rather, the crimp cannot inhibit sealability of the lid. Lastly, the tab ring flares outward from the tangent ring providing a lip for grasping the lid.
In the above and other illustrative embodiments, the substantially crimpless and monolithic paperboard container lid may further comprise: the lid's size along with the sealing channel being configured to accommodate the circumference of the bottom of the container to assist in allowing the lid to serve as a stackable surface for additional containers; an emboss formed on a surface of the lid for adding strength to the lid; the shape of the lid simulating the shape of a conventional plastic lid; a poly coating applied to one surface of the paperboard lid; a clay coating applied to a surface of the paperboard lid opposite the surface with the poly coating applied thereon to accommodate printing of indicia on the lid; the paperboard thickness being from about 0.012 inch to about 0.030 inch; the shape of the paperboard being modifiable to accommodate the shape of the sealing ring of the container; the radiused cross-section of sealing ring can be either round, square, rectangular, oval, or oblong to conformingly fit the periphery of the container.
Another illustrative embodiment of the disclosure includes a method of manufacturing a crimpless and monolithic paperboard container lid. The method comprises the steps of: providing a press configured to make the crimpless and monolithic paperboard container lid, wherein the press comprises a male flange, a draw ring, a blank stop, a pressure ring, shoulder bolts, a female flange, a base, a male body, a plurality of slides, a support, and a plurality of springs; wherein the male flange is located over the draw ring, the blank stop extends from the pressure ring which receives the draw ring, wherein the shoulder bolts connect the female flange to the pressure ring with the base sandwiched in between, wherein the plurality of slides are positioned around the periphery of the support with the springs biasing thereagainst, the support includes a surface having a channel surface configured with the shape of at least a portion of the container lid, the base is configured to engage the plurality of slides on an angled plane relative to an axis of movement of the male body, wherein the plurality of slides include a contact surface that forms at least a portion of a sealing channel on the blank when forming the container lid, wherein the male body includes a contact surface having protrusions that correspond to the surface of the support, the channel surface, and the slide's contact surface, wherein the female flange supports a cavity support via spring members and the base; seating a blank on the female pressure ring; holding the blank on the press with the blank stop; lowering the male draw ring and male body against the support and pressure ring to sandwich the blank between the female support and male body; holding the blank between the female support and male body; moving the female support relative to the support; moving the plurality of slides against the container lid subsequent to sandwiching the container lid between the female support and male body, wherein movement of the female support relative to the support causes movement of the plurality slides, and wherein the movement of the plurality of slides is transverse to the movement of the male draw ring and male body; compressing the blank from both vertical and lateral directions to form the shape of the container lid; and preventing a substantial crimp to be formed in a sealing channel portion of the container lid by reducing any seam between the plurality of slides and limiting the amount of material from the blank that can fit between adjacent slides as the plurality of slides compress to form the container lid by holding the blank between the female support and male body.
In the above and other embodiments, the method may further comprise the steps of: retracting the male body toward the draw ring after the container lid is formed, prying the container lid from the male body by the draw and pressure rings holding the lid as the male body is moved, and moving the plurality of slides away from the female support; moving the support to overcome the bias force and the surface of the plurality of slides to conform to the surface of the male body to fully form the container lid's final shape, and moving the plurality of slides away from the support via the springs allowing loading and unloading of the container lid under non-compressive conditions.
Additional features and advantages of the container lid and method will become apparent to those skilled in the art upon consideration of the following detailed description of the illustrated embodiment exemplifying the best mode of carrying out the container lid and method as presently perceived.
The present disclosure will be described hereafter with reference to the attached drawings which are given as non-limiting examples only, in which:
a-c are perspective, top, and side cross-sectional views of a formed paperboard lid;
a and b are a side cross-sectional and detail views of the press demonstrating how the container lid is stripped off;
Corresponding reference characters indicate corresponding parts throughout the several views. The exemplification set out herein illustrates embodiments of the container lid and method, and such exemplification is not to be construed as limiting the scope of the container lid and method in any manner.
Perspective and cut-away views of fluid container 2, such as a coffee or soup cup and a paperboard lid 4 coupled thereto, are shown in
Perspective, top, and side cross-sectional views of a formed paperboard lid 4 are shown in
As can be appreciated from these views, the illustrative embodiment includes sealing channel 10 composed of a radius top 18 illustratively extending to a tangent 20 that terminates with a tab 22. Radius top 18 and tangent 20 wrap around sealing ring 6 located at the peripheral rim of cup 2. Radius top 18 in this embodiment illustratively includes a radius greater than 180 degrees. Tangent 20 assists extending radius top 18 over ring 6. Tab 22 flares outward from tangent 20 providing a contact surface or lip for removing lid 4 from cup 2. It is further appreciated that channel 10 is sized to fit over ring 6 providing a snug friction fit between lid 4 and cup 2, similar in character to conventional mating between paper cups and plastic lids. It will also be appreciated that the radius or cross-section of cup 18 can be modified to accommodate the shape of sealing ring 6 on cup 2. For example, in alternate embodiments, the cross-section of sealing ring 6 may be square, rectangular, oval, or oblong. Top 18 can similarly be conformingly modified to fit over those cross-sections.
A top view of an illustrative embodiment of lid 4 as a circular “blank” is shown in
In an illustrative embodiment, lid 4 in blank form is pre-scored. A scoring tool can be used to form grooves 26 into lid 4 that are approximately 3/16 to ⅜ inches long and about 0.002 to about 0.005 inches deep. There may be anywhere from about 24 to about 60 scores positioned radially and extending the circumference of blank 4, such as grooves 26 shown in
The views in
Also shown in this view is female flange 54 supporting cavity support 64 via springs 66 and base 56. In an illustrative embodiment, fasteners 68 are disposed through base 56 and extend into channels 90 of support 64. Slide 70, or a plurality of slides 70, is (are) illustratively positioned around the periphery of support 64 with springs 72 biasing thereagainst, as illustratively shown. It is appreciated that slides 70 may be composed of any number of slides members. (See
In this embodiment, support 64 includes a surface 80 that illustratively includes a channel surface 82 that receives lid 4 to form emboss 14. (See
The view shown in
A cross-sectional perspective view of press 30, shown in
The cross-sectional view shown in
As shown therein, flange 32 extends downward in direction 88 compressing springs 66 (not shown, see
A cross-sectional perspective view of press 30 is shown in
The perspective elevation view shown in
The detail view shown in
The view shown in
Although the present disclosure has been described with reference to particular means, materials, and embodiments, from the foregoing description, one skilled in the art can easily ascertain the essential characteristics of the present disclosure and various changes and modifications may be made to adapt the various uses and characteristics without departing from the spirit and scope of the present invention as set forth in the following claims.
The present application claims priority as a Divisional Patent Application to U.S. patent application, Ser. No. 12/729,355, filed on Mar. 23, 2010, entitled “Cup Lid Manufacturing Process,” and claims priority to U.S. Provisional Patent Application, Ser. No. 61/162,900, filed on Mar. 24, 2009, entitled “Cup Lid Manufacturing Process.” To the extent not included below, the subject matter disclosed in that application is hereby expressly incorporated into the present application.
Number | Date | Country | |
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61162900 | Mar 2009 | US |
Number | Date | Country | |
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Parent | 12729355 | Mar 2010 | US |
Child | 14522683 | US |