Patent Application
20060118552
This invention relates to a method for optimizing microwave heating of containers of foodstuff products, to prevent superheating of certain particles of foodstuff, and for minimizing the inherent microwave activity associated with heating foodstuffs. Optimization of heating and reduction of microwave activity is achieved by selectively placing microwave shielding material around or in portions of side walls of the product container.
Microwaveable packaging technology enables development of new and unique food products to suit various consumer needs. While convenience and time efficiency are obvious advantages of many of today's microwaveable food products, certain quality issues exist relating to minimizing superheating using presently available technology. It is commonly known that microwaving foods, whether in a retail package or in special cookware, often results in a final product that has portions which are superheated, and/or which exhibits microwave activity during heating. The phrase “microwave activity” refers to movement of the container, the generation of audible noises, and occasional splatter during heating, activity that inherently occurs during the microwave heating of foodstuffs. “Superheating” refers to overheating at least a portion of foodstuffs. Superheating and microwave activity detract from the eating experience and enjoyment of microwaved foods and may lead to consumers avoiding consumption of microwaveable products. Furthermore, while a user can always remove a container of food from the microwave, stir it, and replace it for additional heating, such extra steps result in delay and inconvenience to the consumer and reduce user satisfaction with available products. Additionally, stirring and replacing the container of food for further heating will not prevent microwave activity or superheating from occurring.
Accordingly, it is an object of this invention to provide a package for microwaveable foodstuffs which optimizes heating of the foodstuff and reduces microwave activity during heating.
It is another object of this invention to provide a package for a microwaveable foodstuff such that the foodstuff is conveniently consumable right out of the package.
It is another object of this invention to provide labeling for foodstuff containers which selectively shield microwaves.
These and other objects of the invention are achieved by providing a container for microwaving foodstuffs comprising microwave shielding material, the container having a bottom and side walls and including a foodstuff, said shielding material arranged together with a portion of the side walls, whereby heating of said foodstuff is optimized. The invention also provides for a method for reducing microwave activity associated with subjecting a foodstuff in a container to microwaves, the container having a bottom and side walls, said method comprising affixing shielding material together with a portion of the side walls of said container.
The invention relates to a microwaveable container for foodstuffs in general, and convenience food products in particular, which optimizes the heating of microwaveable products and reduces microwave activity during heating. The term “convenience food products” as used herein means foodstuffs which are directly consumed out of the microwaveable container. Microwave activity is reduced, in part, when superheating of foodstuff contents is reduced (i.e., when heating is optimized).
The band comprises material that blocks microwaves (i.e., reflects, deflects, or absorbs microwaves). By including such material, the package controls the microwave energy that reaches the foodstuff within the container. By selectively placing the bands together with the container (e.g., either affixed to an external surface or integrally incorporated with the side wall) the heating of the foodstuff is controlled, or moderated, so that the product within the container is heated more uniformly. Additionally, it has been found that the microwave activity which inherently occurs during cooking is also reduced. Suitable materials for use in the invention that block microwave energy include but are not limited to metals. A preferable metal is aluminum. The selection of shielding materials, whether for use without any other materials or layers, or for use together with other materials or layers, is readily within the knowledge of those skilled in the art. The metal used can be in the form of a foil, film, tape, or other form. The material can be made by any suitable process, including but not limited to pressing or chemical deposition of the metal onto another material. The layer thickness can be any thickness usable for shielding purposes. The thickness and microwave opacity of any other material should be chosen to be suitable for microwave uses, and will be readily determinable by those skilled in the art. Microwave opacity is a commonly used measure of a material's blocking ability known to those skilled in the art. Typically microwave ovens generate microwaves having a frequency of 2.45 GHz. Microwave opacity corresponds to the degree to which microwaves transmit through a material. A suitable microwave opacity is 50% or more, preferably 90% or more. The aluminum used in the examples hereinbelow was in the form of foil or tape, with a thickness of about 5 mil., and had a microwave opacity of about 90-100%.
A band may include materials other than the microwave shielding material. For example, the band can include a layer or laminate of plastic material. The plastic material can be any type of plastic suitable for the purpose. In embodiments where the plastic will not come into contact with the foodstuff, issues of interaction between the plastic and foodstuff are not a concern. The plastic, or other material, can also serve as labeling for the packaged product. For example, a Plastishield label can be used. Plastishield is a coextruded polystyrene product made by American Fuji Seal. However, any suitable additional material can be used together with the material which shields microwaves.
FIGS. 6(a) and 6(b) is a schematic illustration of a top and side view, respectively, of a typical overcap for a microwaveable container with 4 central vent holes (8).
The exact location of the shielding band may vary. Optimization of heating can be achieved by having a shielding band around the top portion of the side wall of the container (i.e. top band (4)), around the bottom portion of the side wall of the container (i.e. bottom band (5)), or around both the top and bottom portion of the side wall of the container (i.e. top band (4) and bottom band (5)).
The bands can be regular in shape, such as the continuous ribbon-like shape shown in the
Preferably, the band is incorporated onto the exterior of the container and does not directly contact the foodstuff. The attachment can be accomplished by any means commonly known by those skilled in the packaging arts. Methods can include gluing or integral incorporation during fabrication of the container. Shrink wrap techniques may be used to affix the shielding band to the container. Alternatively, a shielding band can be incorporated more intimately with the container during container manufacture. Intimate incorporation of a shielding band(s) can be achieved with an “insert molding” process.
Insert molding is a molding process whereby resin or plastic is injected or formed into a cavity around an insert piece, such as a piece of microwave shielding material, which is placed into the same cavity prior to molding. The result is a single piece with the insert adhered by the resin or plastic. The insert, generally, can be made of metal or another plastic. In this invention, the insert is any material suitable to achieve microwaving shielding. Insert molding can be accomplished with a wide variety of materials, including polyethylene, polystyrene, polypropylene, polyvinyl chloride, thermoplastic elastomers, and many engineering plastics.
The insert, and plastic or resin, can be held together (i.e., bonded) by either molecular or mechanical means. For molecular bonding, best results are achieved when the insert material is the same or similar to the encapsulating resin or plastic. Mechanical bonding can be achieved by shrinking resin or plastic around the insert while the resin or plastic cools down during the insert molding process. Alternatively, mechanical bonding can occur when resin or plastic covers irregularities in the surface of the insert material. The end result of insert molding, as applied to this invention, is the intimate incorporation of microwave shielding material to the inner and/or outer portion of the package used to contain the foodstuff. “Insert molding” and other suitable processes will be recognized by those skilled in the packaging arts. See http://www.devicelink.com/mddi/archive/96/04/010.html, which is hereby incorporated by reference.
The width of the band may vary, depending on container size. As a general, but non-limiting, guidance, for a container having a side wall height of about 4 inches, the shielding band will be generally from about ½ inch to about 1½ inches wide, more preferably from about ¾ inches to about 1¼ inches wide. The corresponding surface area coverage of the side walls will vary generally from about 15 to 65%, more preferably from about 20 to 55%.
While two bands are illustrated, any suitable number of bands may be used. The bands may be in the form of vertical strips extending generally from the top to the bottom of the container. Furthermore, the strips or bands used can be regular or irregular in shape. Where bands are used around a bottom portion of a rounded-bottomed container, the dimensions of the band will vary from the top part of the band toward the bottom part of the band, to accommodate the curvature of the rounded corner.
The container of this invention may optionally include an overcap. The overcap can be a standard overcap or a locking overcap. The overcap may optionally have vent holes in the top surface of the overcap. The preferred placement of the holes includes holes located around the perimeter region of the top of the overcap and/or in the central region of the top of the overcap. Vent holes of varying diameters can be used, and the number of vent holes around the perimeter can also be varied, depending on the cap size and foodstuff. The vent holes in the examples below had a diameter of about 5/32 of an inch. Again, the size may vary, but will be readily determinable by routine methods. Shielding material may also be located on the overcap. The shield may cover from 0% to about 90%, preferably 20% to 90%, most preferably 50% to 90%, of the top surface area of the overcap. Such an overcap shield may, but need not, have vent holes.
Preferred embodiments of the invention will be further described by the following Examples which are illustrative only and do not limit the invention. The container used in the examples below had a rounded bottom edge. The containers used were made from Polypropylene manufactured by Rexam. The containers are known as a “401” container. The containers had a Plastishield label, and the shielding material, in the form of a band, was placed on top of the label, except for a few examples, as indicated, where the shield was placed underneath the label. For shielding, aluminum foil or aluminum tape of about 5 mil. thickness was used. Placement of the shield is as indicated in the examples. Where bottom shields were used, since the containers had a rounded bottom-edge, the bottom bands covered part of the side wall, and extended downward to cover part of the bottom of the container. The bottom shields never completely covered the bottom of the container, so that a central portion of the bottom was left uncovered.
Overcaps with or without vent holes were used, as indicated in the specific examples. Location of the vent holes, which were about 5/32 of an inch in diameter, were located either around the general perimeter of the top of the overcap, in the general center of the overcap, or both. In some examples, overcaps had shields. When used, the shielding on the overcap covered about 90% of the top surface area of the overcap. When shields were used on the overcap, and vent holes were also incorporated, the vent hole perforations were made in both the overcap and the overcap shield.
Various soups were used for the examples below. Containers were placed on the outer area of the microwave turntable. Samples were heated in either a 900 watt microwave (Panasonic) at high power or a 1200 watt microwave at high power. After heating for about 2 minutes, samples were stirred for 15 seconds, after which temperature was measured with a digital thermometer at various randomly chosen locations to obtain a high and low temperature. Other observations reflecting optimization of heating and microwave activity were also noted. The use of shielding reduced the activity (e.g., splatter, movement of container, generation of audible noises) during heating, as indicated in the Examples provided. This reduction in microwave activity reflects that heating had been optimized in comparison to the controls.
Although preferred embodiments are specifically illustrated and described herein above, it will be appreciated that many modifications and variations of the present invention are possible in light of the above teachings and within the purview of the appended claims without departing from the spirit and intended scope of the invention.
This application claims the benefit of priority of U.S. provisional application 60/632,464 filed on Dec. 2, 2004 which is incorporated by reference herein.
| Number | Date | Country | |
|---|---|---|---|
| 60632464 | Dec 2004 | US |
