This invention relates to egg cartons, and more particularly to egg cartons made of transparent polymeric materials.
Conventional egg cartons in wide use today are typically made either of a fibrous material, such as cardboard, or a foamed polymeric material, such as foamed polystyrene (Styrofoam™). While these materials are inexpensive to prepare they share the same disadvantage of being opaque, requiring a consumer to open the lid of the egg carton to inspect the eggs for damage.
Egg cartons made of a transparent polymeric materials, such as poly ethylene terephthalate (PET) polymers have also come into use, although to a more limited extent than cardboard and foamed polystyrene cartons. Such transparent egg cartons exhibit various disadvantages that result from the properties of the materials used. For example, while these materials are recyclable, they are not biodegradable. In addition, most plastic materials, such as PET, have too much resiliency to easily operate as a crease type hinge between the lid of the carton and the tray that holds the eggs.
One method of solving the hinge problem with transparent egg cartons is illustrated in
Another problem with hinge junctions for egg cartons made of transparent plastics relates to difficulty in securely interlocking the lid onto the tray. In the typical cardboard or foamed polystyrene carton, a front flap is provided on the front of the tray and the flap also has a crease hinge along the junction between the flap and the tray. The flap contains two tabs positioned to fit into two holes formed in corresponding positions of the front surface of the lid, each positioned about ⅓rd the length of the flap from the edge. Because transparent polymeric materials tend to be relatively pliable, a full egg carton made with a flap and two tabs would tend to bend downwardly when grasped by the end, causing failure of the carton or premature release of the tabs from the lid. Moreover, because the resiliency of transparent polymeric materials is relatively large, a creased hinge for the flap has the same problems as a creased hinge for the lid.
One method to overcome this problem illustrated in
Another problem with resiliency in egg cartons made of transparent plastic materials is difficulty for a consumer to release the lid form the interlocking tabs and holes. In the cardboard or foamed polystyrene designs, the consumer typically pulls the front of the lid forward from the center to clear the holes from the tabs and rotates the lid upward to open the carton. However, if the flap and lid are made of typical transparent polymeric materials, which are more pliable than cardboard or foamed polystyrene, pulling the front surface of the lid forward from the middle creates a bow action that results in bowing of the middle of the flap outward and the lateral sides of the flap inward, making it difficult to release the lid from the button tabs on the flap. One method of overcoming this problem exemplified by U.S. Pat. No. 4,463,894 is to make the lateral portions of the flap thicker than the central portion to reduce the bowing effect. A problem with this design is that more material is required to form the flap.
Accordingly there is a need in the art to provide transparent egg cartons that have the advantages of cardboard and foamed polystyrene egg cartons while lacking the disadvantages inherent to cartons made of transparent polymeric materials.
Provided herein are transparent egg cartons of improved design. In one aspect there is provided an egg carton that includes a tray with a plurality of egg compartments, a lid hingedly connected to the tray, and a closure flap hingedly connected to a front surface of the tray. In various embodiments, the tray, lid and flap are all made of a transparent polymeric material and at least one of the lid and flap are connected to the lid by either a “W” shaped hinge or a box hinge.
In another aspect there is provided an egg carton formed of a transparent polymeric material selected from the group consisting of a polylactic acid polymer, a poly glycolic acid polymer, and a polylactic-glycolic acid co-polymer. Polylactic acid is one of the preferred transparent materials. Use of these biodegradable materials is made possible by the various design features provided herein including any one, or preferably a combination of features that include: use of the “W” shaped hinge or box hinge, the provision of lattice struts in the flap, the provision of three button tabs in the flap with the lateral buttons being located about ⅛th the length of the flap from the edge, or the provision of vertical ribbing in the lid to provide additional mechanical strength to egg cartons made of these otherwise fragile materials.
In one exemplary embodiment, there is provided an egg carton made of polylactic acid and that includes: a tray having a lower portion defined by a plurality of egg compartments configured for receiving eggs, the tray having a tray front surface, a tray rear surface and tray end surfaces and an upper portion that defines a tray rim with a tray edge extending above the lower portion. Also included is a reversibly closeable lid configured to cover the tray when closed, the lid having a top surface, a lid front surface, a lid back surface and lid end surfaces, each of the front, back and end surfaces of the lid having a lower portion defining a lid rim with a lid edge. The lid is formed with vertical ribbing along its downwardly extending surfaces and has an undulated perimeter that provides additional strength to the lid by increasing the lineal footprint thereof. Also included is a flap rotatable along an axis parallel to the front surface of the tray, the flap having a rear edge connected to the tray, and a front edge opposite the rear edge and a width defined by a distance between the front and rear edges of the flap. The flap includes three tab buttons for interlocking with the lid, with the lateral tabs being located about ⅛th the length of the flap from the end. The flap also includes lattice struts to increase the lateral strength of the flap. A “W” shaped hinge or box hinge is used to connect the flap to the front surface of the tray and the lid to the back surface of the tray.
In the following detailed description of exemplary embodiments of the invention, reference is made to the accompanying drawings, which form a part hereof, and in which are shown, by way of illustration, specific exemplary embodiments in which the invention may be practiced. In the drawings, like numerals describe substantially similar components throughout the several views. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. Other embodiments may be utilized and structural, logical, electrical, and other changes may be made without departing from the spirit or scope of the present invention. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is defined only by the appended claims.
Described herein are various features for a transparent egg carton 10, which is suitable for embodiments using a variety of transparent polymeric materials, including, but not limited to relatively pliable recyclable polymeric materials such as polyethylene terephthalate (PET), which is an amorphous polyester; clarified polypropylene (CPP), which is polypropylene containing nucleating agents to increase clarity; styrene butadiene copolymers (SBC) without impact modifiers; copolymer blends of SBC with crystal polystyrene (cPS), which is commercially known as “K-Resin/Crystal™, oriented polystyrene (OPS); polyvinyl chloride (PVC); styrene acrylonitrile polymer (SAN); polymethyl methacrylate (PMM) and copolymers thereof, commercially known as plexiglass; and polycarbonate (PC). In advantageous embodiments, the features of the egg carton 10 are also suitable for a newer class of transparent polymeric materials that are recyclable and biodegradable. Examples of such polymeric materials include polylactic acid (PLA), polyglycolic acid (PGA) and polylactic acid-glycolic acid copolymers (PLGA). Until the present invention, such materials were not suitable for egg cartons because of their relatively low tensile strength and brittle properties. Surprisingly, however, in advantageous embodiments, the egg carton 10 is preferably made of PLA, PGA, or PLGA.
The egg compartments 7 have interiorly directed side ridges 2 that contact the eggs keeping them away from the interior side walls 6 of the egg compartment 7. The egg compartments 7 also have a lower platform ridge 5 that prevents the bottom of the eggs from contacting the interior surface of the bottom of the egg compartment 7. The side ridges 2 and bottom ridges 5 are typically shaped so that the exterior side of the ridges 2, 5 form a generally concave contour and the interior side of the ridges 2, 5 that contacts the egg have a generally convex contour. As illustrated in the cut-away front view of
Within the interior of the tray 12 a plurality of tower elements 17 are formed between the egg compartments 7 in such a way that an interior facing surface 19 of the towers 17 are continuous with the interior surfaces 6 of a plurality of the egg compartments 7 to support the upper portions of the eggs in adjacent compartments 7. The interior facing surfaces 19 of the towers 17 are separated by tower support ridges 15. The lower portion of the tower ridges 15 are interconnected or integral with the bracing elements 44 between the egg compartments 7. The towers 17 are made of a sufficient height so that an upper surface of the towers 17 contacts an interior side of the top surface 16 of the lid 14 when the lid 14 is closed, thereby providing additional mechanical support to prevent the egg carton 10 from being crushed from above, for example, when multiple cartons are stacked on one other after being filled with eggs.
Referring again to
In certain embodiments, such as depicted in
In certain other embodiments, such a depicted in
The lid 14 has a top surface 16, a front surface 18, a rear surface 20 opposing the front surface and opposing side surfaces 22, each of which extend downwardly from the from top surface 16. Three features of the lid 14 provide additional strength to the carton 10 to resist crushing when multiple cartons are stacked on one another, which is particularly advantageous for cartons made of pliable transparent materials. First, the front 18, rear 20 and side 22 surfaces of the lid 14 are heavily corrugated forming a plurality of parallel support ribs 21 separated by outwardly bulging areas 27 each extending vertically along the front 18, rear 20, and side 22 surfaces of the lid 14 between the top surface 16 and the lid rim 4. As illustrated in the top view of
Referring to
The lid 14 and the tray 12 are also constructed to form vents 25 when the egg carton 10 is closed. Eggs are typically packed into the egg carton 10 in a warm condition, then quickly moved to a refrigerated chamber to cool the eggs. This causes condensation to occur on the eggs if the egg carton 10 is not vented. Accordingly, the vents 25 are provided in the egg carton 10 to allow moisture to exhaust from the interior thereof. The vents 25 are formed by tray recesses 23 formed in the tray rim 3, which are correspondingly opposed to lid recesses 27 formed in the lid rim 4 so that the vent is formed when the lid 14 is closed.
Referring now to
These problems are addressed herein by providing at least three additional features to the flap 50. First, the flap 50 is formed with a plurality of lattice struts 54 that extend across the flap 50 from a point at, or adjacent to, a front edge 56 of the flap to a point at or near a rear edge 58 of the flap 50. The lattice struts 54 are comprised of a vertical portion 55 and a horizontal portion 57 transversely oriented to the vertical portion 55. The vertical portion 55 extends across at least about 75% or at least about 80% or at least about 90% the width of the flap 50 between the front edge 56 and the rear edge 58. In the advantageous design depicted in
A second feature of the flap 50 provided herein, which is contrary in principle to the design of egg cartons generally, is the provision of at least three button tabs 52a, 52b, and 52c rather than two as in conventional egg carton designs. The button tabs 52 are adapted to fit into corresponding button holes 65 formed in the front surface 18 of the lid 14 to lock the lid 14 into place over the tray 12. In certain embodiments not illustrated herein, the button holes 65 may be replaced by closed pockets configured with a shape that corresponds to the shape of the button tabs 52. As a general principle in egg carton design according to the prior art, it was desirable to use only two button tabs 52a and 52c disposed on lateral sides of the flap 50, because egg cartons with additional button tabs 52 such as centrally located button tab 52b would generally be more cumbersome to open. However, it has been discovered that when the egg carton is made of a pliable transparent polymeric material such as PET or PLA, a third, centrally located button tab 52b prevents the egg carton 10 from bending downward when held at the end. In addition and surprisingly, the third button 52b actually makes the lid 14 easier to open, especially when used in combination with the other features of the transparent egg carton 10 described herein.
A third feature of the flap 50 is the location of the most lateral buttons 52a and 52c. In conventional egg cartons using only two buttons, these are each placed about ⅓rd the length of the flap 50 from the edge. In the designs provided herein, the lateral buttons 52a and 52c are located at about 1/10th to ⅙th, and most advantageously, about ⅛th length of the flap 50 from edge. This location of the lateral buttons increases the overall strength of the closed egg carton 10, helping to prevent the closed egg carton 10 from buckling when grasped from the end.
Another advantageous feature of the egg carton 10 is the use of a “W” shaped hinges 70 and/or box hinges 80 to connect the flap 50 and/or the lid 14 to the tray 12. Referring to
As illustrated in
The “W” shaped hinge 70 and box hinge 80 of the egg carton 10 provides a variety of advantages to egg cartons made from pliable and/or resilient transparent polymeric materials. First, when the “W” shaped hinge is closed so that the walls of the derepressions 72, 74 meet at the obtuse angle, the walls of the inner depression 72 bear a portion of the weight of the attached lid 14 or flap 50. Second, the “W” shaped hinge and box hinge 80 are relatively easy to mold from a variety of transparent polymeric materials. Third, the “W” shaped hinge and box hinge 80 each extend outwardly from the from the front and rear surfaces of the rims 4, 11 of the lid 14 and the tray 12, respectively, which increases longitudinal rigidity of the egg carton 10. Fourth, these hinge types are suitable with transparent polymeric materials of different levels of pliability, such as PLA which is relatively more brittle and PET, which is relatively more pliable, because with these types of materials, the “W” shaped hinge 70 and box hinge 80 provide less resilience than a typical creased hinge of the prior art, making the carton 10 easier to open and close.
Another feature of the egg carton 10 is that the front surface 18 of the lid 14 along the lid rim 4 is formed with an awning portion 30 that extends outwardly from the front surface 18 of the lid rim 4. As illustrated in the detail of
From the foregoing it will be appreciated that, although specific embodiments of the invention have been described herein for purposes of illustration, various modifications may be made without deviating from the spirit and scope of the invention. Accordingly, the invention is not limited except as by the following claims.
Number | Name | Date | Kind |
---|---|---|---|
2771233 | Cox | Nov 1956 | A |
2990094 | Reifers | Jun 1961 | A |
3131846 | Whiteford | May 1964 | A |
3138314 | Reifers et al. | Jun 1964 | A |
3613987 | Laidman | Oct 1971 | A |
3643855 | Donaldson | Feb 1972 | A |
3643857 | Noguchi | Feb 1972 | A |
3648916 | Commisso | Mar 1972 | A |
3712532 | Alroy | Jan 1973 | A |
3771712 | Richards | Nov 1973 | A |
3779370 | Snow et al. | Dec 1973 | A |
4553692 | Padovani | Nov 1985 | A |
5494164 | Ramirez | Feb 1996 | A |
5760118 | Sinclair et al. | Jun 1998 | A |
6323307 | Bigg et al. | Nov 2001 | B1 |
6740731 | Bigg et al. | May 2004 | B2 |
Number | Date | Country |
---|---|---|
6-329182 | Nov 1994 | JP |
Number | Date | Country | |
---|---|---|---|
20050178689 A1 | Aug 2005 | US |