Microwave food package and method

Information

  • Patent Grant
  • 6259079
  • Patent Number
    6,259,079
  • Date Filed
    Tuesday, January 18, 2000
    24 years ago
  • Date Issued
    Tuesday, July 10, 2001
    23 years ago
Abstract
Apparatus for and method of controlling heating of a foodstuff using microwave energy having a food package with a microwave shielding layer containing a plurality of apertures therein sized to permit entry of both evanescent microwave energy and propagating microwave energy into the interior of the package with the microwave shielding layer being moved outward as the package expands due to generation of water vapor such that an interior volume of the package is subsequently protected against substantial evanescent microwave irradiation of the foodstuff during completion of the microwave heating cycle using propagating microwave energy to further heat the foodstuff.
Description




FIELD OF THE INVENTION




This invention relates to the field of microwave heating of foodstuffs, in particular to packaging designed for influencing the heating of the foodstuff as it is irradiated with microwave energy. More particularly, the present invention relates to the use of both evanescent and propagating microwave energy to control heating of foodstuffs.




BACKGROUND OF THE INVENTION




With respect to microwave foods, it is often desirable that the microwave heating be controlled in order to prevent overheating of the food. One example is microwave heating and popping of popcorn. If popped kernels are subjected to prolonged microwave heating, scorching occurs. Currently, microwave popcorn is packaged in flexible paper bags. Embedded in the popcorn bag is a susceptor used to absorb microwave energy and aid popcorn heating and popping. Typically in packaging microwave popcorn, a slurry including popcorn kernels are located on top of the susceptor, the bag is folded over itself to a compact size. When the bag is placed in the microwave oven, instructions typically call for at least partial unfolding of the bag and placing the bag on a microwave transparent shelf or floor of the oven with the susceptor below the popcorn. When the popcorn bag is heated in the microwave oven, steam or water vapor from the popping popcorn causes the bag to further unfold and inflate. With the current bag designs, popped kernels are unprotected from microwave irradiation after popping. When heated above about 210° C., popped kernels begin to scorch. The present invention overcomes this shortcoming of prior art popcorn bags (and other microwave-related food packages) by providing a bag or package that initially exposes the popcorn (or other food load) to a controlled combination of both propagating and non-propagating (evanescent) microwave irradiation to pop the kernels or otherwise heat the food load and thereafter reduces the microwave irradiation to the bulk of the popped kernels (or other heated food load), to reduce the possibility of scorching (and other undesirable results of overheating) that would otherwise occur. When a popcorn load is referred to herein, it is to be understood that it generally refers to a load that includes a popcorn kernel hybrid engineered for desired agronomic and microwave popping properties and consistent with generally available major commercially available microwave popcorn offerings, together with a butter type slurry having major constituents of soybean oil, salt, colorings, flavorings and the like. These components combine (in a typical load) to a weight of approximately 100 grams with about 80% or more (by weight) being the popcorn kernels themselves.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a perspective view of a popcorn bag useful in the practice of the present invention shown in a first state prior to popping under the influence of microwave irradiation.





FIG. 2

is the popcorn bag of

FIG. 1

shown in a second state with a substantial amount of popcorn popped.





FIG. 3

is a simplified perspective view of a conducting sheet with apertures useful in the practice of the present invention.





FIG. 4

is a side view of the perforated conducting sheet of

FIG. 3

, along with a simplified graph of evanescent microwave propagation power decay after microwave energy transits the sheet.





FIG. 5

is a schematic or simplified pictorial view of a generic version of the bag of

FIG. 1

corresponding to the first state to illustrate certain features of the present invention.





FIG. 6

is a schematic or simplified pictorial view of a generic version of the bag of

FIG. 2

corresponding to the second state to illustrate certain aspects of the present invention.





FIG. 7

is a perspective view of an alternative embodiment of a package useful in the practice of the present invention and shown in an expanded condition.





FIG. 8

is a top plan view of the package of

FIG. 7

illustrating a microwave shielding layer with apertures therein in an unfilled, flat condition, with portions broken away.





FIG. 9

shows a cross sectional view of the package of

FIG. 7

according to section line


9





9


of

FIG. 7

, with the popped popcorn removed and the microwave shielding layer with apertures therein shown for illustration.





FIG. 10

shows a side view of the package of

FIG. 7

in an opened condition.





FIG. 11

is a view similar to

FIG. 1

, except that the popcorn bag is generally enclosed by a microwave shielding layer with apertures only in a limited region thereof and with the unpopped popcorn load omitted for clarity.





FIG. 12

is a view according to

FIG. 1

, except showing the popcorn bag in the second state and with the popped popcorn load omitted for clarity.





FIG. 13

is a bottom plan view of the bag of

FIG. 12

in the second state.





FIG. 14

is a plan view of an alternative lattice arrangement for an aperture pattern useful in the practice of the present invention.





FIG. 15

is a perspective view of the popcorn bag of the embodiment of

FIG. 1

shown in an a completely folded state.





FIG. 16

is a perspective view of the popcorn bag of

FIG. 15

shown in a partially unfolded state.





FIG. 17

is a graph of the transmitted propagating and evanescent mode microwave intensity plotted against aperture size for a first bridge width and showing an example metal sheet with apertures forming a rectangular lattice grid.





FIG. 18

is a graph of the transmitted propagating and evanescent mode microwave intensity plotted against aperture size for a second bridge width





FIG. 19

is a graph of the transmitted propagating and evanescent mode microwave intensity plotted against aperture size for a third bridge width





FIG. 20

is a graph of the transmitted propagating and evanescent mode microwave intensity plotted against aperture size for a fourth bridge width





FIG. 21

is a graph of the transmitted propagating and evanescent mode microwave intensity plotted against aperture size for a fifth bridge width





FIG. 22

is a graph of the average microwave transmission coefficient plotted against aperture size with bridge width shown as a parameter.





FIG. 23

is graph of evanescent mode microwave energy plotted against aperture size with bridge width shown as a parameter.





FIG. 24

is a graph of the penetration depth of evanescent mode microwave energy plotted against aperture size with bridge width shown as a parameter.





FIG. 25

is a graph of microwave energy distribution downstream of a grid comparing total energy, evanescent energy, and propagating energy.





FIG. 26

is a pair of graphs comparing square shaped apertures to circular apertures in a square lattice.





FIG. 27

is pair of graphs comparing hexagonal shaped apertures to circular apertures in a triangular lattice





FIG. 28

is a pair of graphs comparing a square lattice to a triangular lattice, each having circular shaped apertures.





FIG. 29

is an example of a triangular lattice formed of apertures in a metal sheet.











DETAILED DESCRIPTION OF THE INVENTION




Referring now to the Figures, and most particularly, to

FIGS. 1

,


2


,


11


,


12


,


15


and


16


,a food package


20


useful in the practice of the present invention may be seen. Food package


20


is in the form of a modified conventional microwave popcorn bag having wings


21


,


23


in which the unpopped popcorn


22


is vended or sold for consumers to place in a microwave oven and pop the popcorn. It is to be understood that the unpopped popcorn load


22


typically will include fat, oil, salt, colorings, flavorings or the like in addition to the popcorn kernels, forming a mass or slurry


24


, typically positioned on a microwave susceptor


26


. Susceptor


26


may be a conventional susceptor as is well known to use for microwave heating, especially for popping popcorn.




In the practice of the present invention, it has been found desirable to admit both evanescent, or non-propagating, microwave energy and propagating microwave energy into the interior of the food package, with both forms of energy controlled by the package. By allowing controlled entry of the propagating and non-propagating (evanescent) microwave energy inside the food package, the total performance of the food package can be balanced. Using both propagating and non-propagating energy allows more control over the simultaneous reduction of scorching, improvement in popping volume and unpopped kernel reduction. For the purpose of reducing scorching, one would ordinarily minimize propagating energy and reduce the depth of evanescent energy penetration into the food package. However, to maintain or even improve popping volume or to reduce unpopped kernels, it may be desirable to utilize a certain fraction of propagating wave energy in addition to using evanescent energy in a controlled fashion as is described herein.




It is believed desirable to use propagating energy throughout the heating cycle when the load is characterized by a substantial mass or bulk that is not agitated or dispersed (in contrast to popcorn). An example is to use propagating energy to heat the center of food such as a pie. With a pie, for example, it may be desirable to utilize evanescent energy to heat or brown the crust of the pie.




Referring now also to

FIGS. 5 and 6

, as well as the Figures already referred to, in this embodiment the package


20


is preferably a flexible, inflatable bag. Bag or package


20


can be made from any desired material but is preferably formed of paper, one or more polymers, or a combination thereof, including but not limited to base coated paper or similar polymer structures or the like. It is to be understood that

FIGS. 5 and 6

show an “idealized” package to illustrate certain aspects of the invention.




The package


20


preferably includes one or more septic layers


28


such as paper or plastic to provide a clean or sanitary environment and a suitable external appearance for the foodstuff during vending and handling. In addition, as part of the septic layer, (or as a separate layer) package


20


also has a water vapor barrier layer (e.g., interior layer


28


) for reasons which will become apparent. It is to be understood that the water vapor barrier layer is desirably similar or identical to that used in conventional popcorn packaging intended for use heating in microwave ovens. It is to be further understood that this layer is sealed sufficiently to cause or allow the bag to inflate as is conventional in the microwave popping of popcorn, for reasons to be explained infra.




Unlike conventional packages for microwave popcorn, the package


20


of the present invention further includes a layer


30


that is effective to provide at least partial microwave shielding. Layer


30


may be formed of metal. Referring now also to

FIGS. 3 and 4

, the microwave shielding layer


30


has a plurality of apertures


32


therein, with each aperture sized to permit a controlled amount of both conventional propagating microwave energy and evanescent or non-propagating microwave energy to enter the package. In the preferred embodiment, layer


30


is desirably thick enough to prevent the transmission of microwave energy therethrough [and is desirably thick enough, i.e., a thickness greater than the penetration depth, to avoid layer


30


functioning (generally) as a susceptor]. It is believed that conventional susceptors are in the range of tens to hundreds of Angstroms in thickness. For conventional metals such as copper and aluminum (not acting as susceptors, but instead providing microwave shielding) the penetration depth is about a few microns.




The shape and size and pattern or lattice of the apertures are preferably chosen to limit transmission of microwave energy to control the entry of both propagating and evanescent microwave energy when the microwaves transit the layer


30


. This is achieved primarily by maintaining the maximum dimension


36


of each aperture


32


to be sufficiently small to limit the transmission of propagating modes of microwave energy through layer


30


to desired levels. In comparison, and as a figure of merit, for a long waveguide with square cross section, the microwave energy is limited to an evanescent mode when:






i a<λ/2  (1)






where “a” is the linear dimension of the waveguide cross section, and λ is the free space wavelength.




In general in the prior art relating to waveguides and the like, “evanescent mode” has been used to refer to operation below cutoff, i.e., λ>λ


c


, where λ


c


is the cutoff wavelength, and the guide wavelength λ


g


is given by Equation (2):






λ


g


=λ/(1−


v




2


)


½


  (2)






where v is the normalized wavelength, given by Equation (3) as the ratio of the wavelength of interest, λ, to the cutoff wavelength:








v=λ/λ




c


  (3)






The free space wavelength is about 12.24 cm for 2450 MHz.




As used herein, the term “evanescent” is believed to be consistent with, but an extension of, the use of that term in the prior art. Typically, in a microwave oven, the cavity is “overmoded,” unlike conventional waveguide operation. Since the food package of the present invention is exposed to the overmoded field in order to carry out the present invention, the term “evanescent” here is used by analogy or extension to prior art use and refers to decaying, as opposed to propagating microwave energy passing through the grid or aperture pattern of the microwave shielding layer


30


.




Returning again to conventional prior art systems, such as waveguides below cutoff, the microwave energy decays generally exponentially with a depth of penetration


49


given by Equation (4):








D




p


=(


a/


2π)[1−(2


a


/λ)


2


]


−½


  (4)






As is illustrated generally in

FIG. 4

, the microwave power transiting sheet or layer


30


having apertures


32


therein is limited to being evanescent or non-propagating when the maximum dimension of the apertures


32


is below a length permitting propagating power to pass through such apertures. For square or rectangular apertures, the maximum dimension is a diagonal


36


. For apertures of other geometries, the maximum dimension is characteristically the longest “free” dimension of the aperture, e.g., for an ellipse, the chord through the two vertices (along the major axis) is the maximum dimension. Curve


38


is an illustration of the power decay of evanescent microwave energy plotted with energy on the ordinate axis


40


and distance from the layer


30


along the abscissa


42


. It is to be generally understood, that the smaller the maximum dimension of the apertures, the more rapid the power decay, provided that other design parameters are held constant. The evanescent mode of microwave energy transiting the apertured layer


30


will form a spatially limited zone of microwave energy beyond the outer surface of layer


30


. The depth of the zone beyond the layer


30


can be adjusted by varying the dimensions (especially the maximum dimension) of the apertures in the layer, or by adjusting the shape or pattern of the apertures. In the practice of the present invention, apertures


32


in layer


30


create a spatially controlled “penetration zone”


44


(see

FIGS. 5 and 6

) for microwave heating within package


20


.




In

FIG. 5

it will be noted that when the package or bag


20


is collapsed in its initial configuration, the evanescent penetration zone may extend substantially across the entire interior of the package, thus permitting substantial microwave irradiation both from above and below, in effect providing an “overlap” of the evanescent penetration zone extending down from the top layer with the evanescent penetration zone extending up from the bottom layer. In the alternative, the upper and lower evanescent penetration zones may abut each other, or it may be desirable (for other reasons) to have the evanescent penetration zones not overlap, e.g., in the event the food load is desirably or necessarily thicker than the sum of the depths or thicknesses the desired evanescent penetration zones.




In

FIG. 6

, with the bag expanded or inflated, the evanescent penetration zone


44


extends only a predetermined, limited distance within layer


30


, with the boundary of the evanescent penetration zone


44


indicated by dashed line


46


. In the idealized images shown in

FIGS. 5 and 6

, it is to be understood that apertures


32


extend across substantially all of the surface of layer


30


of package


20


, and a controlled amount of propagating energy may be admitted, as desired, to the interior of the bag, in a manner described infra.




While the pattern of apertures


32


may extend across the entire package (as is illustrated in an alternative embodiment in FIGS.


8


and


9


), alternatively, the microwave shielding layer


30


may extend across substantially all of the surface


62


of the food package


20


, with one or more patterns of apertures


32


extending across only one or more predetermined, limited regions, for example, a region made up of sub-regions


34


,


48


of the food package


20


, as is shown in

FIGS. 11 and 12

. In

FIG. 12

, sub region


48


is located on surface


62


of shielding layer


30


, while sub-region


34


is located on a lower surface of shielding layer


30


adjacent susceptor


26


. As a still further embodiment, various regions may have different sized or shaped or spaced apertures to selectively control either the evanescent microwave energy or both the evanescent and propagating microwave energy passing through layer


30


and into the interior of package


20


. To that end, it has been found that altering not only the dimensions of the apertures themselves, but also (or in addition) altering the spacing between apertures can be used for such microwave energy control. In particular, using a varying spacing between apertures can be made to be less restrictive to the passage of microwave energy through the apertured layer


30


. As used herein, it is to be understood that “lattice” refers to the geometrical arrangement of apertures, particularly the spacing between adjacent rows or columns (or both) of the apertures


32


in layer


30


. It is believed that various forms of lattice variation schemes, such as monotonically varying, periodically varying and even random (or pseudo-random) varying lattice arrangements are of use in the practice of the present invention.




It is to be understood that it is within the scope of the present invention to use offset lattices in the practice of the present invention. Such offset lattices can be periodic or non-periodic, and different regions of the microwave shielding layer can have different lattice arrangements in addition, or as an alternative, to changing the shape and size of individual apertures. In

FIG. 14

, a triangular lattice


64


is formed by the pattern of individual apertures


32


, and is illustrative of an alternative to the regular square lattice or pattern of apertures shown with respect to the earlier Figures. It is also within the scope of the present invention to use other aperture shapes in such alternative lattice arrangements, as well.




Turning now to the embodiment shown in

FIGS. 11

,


12


and


13


(which correspond to the embodiment of FIGS.


1


and


2


), the evanescent and propagating microwave energy penetrates layer


30


in an upper surface initially only in a region


48


corresponding to the food load


22


. It is to be understood that the propagating energy will ordinarily extend further into the package


20


than will the evanescent energy, since the evanescent energy will be limited to the evanescent penetration zone as previously described. The propagating energy, while typically attenuated, will generally progress throughout the interior of the package, until absorbed by the food load.




At the same time, microwave energy is continuously applied through region


34


of a lower surface to heat the food load


22


. It is to be further understood that the microwave energy entering through region


34


may be limited to evanescent, or may be a combination of evanescent and propagating energy, as may be the energy entering through region


48


.




In this embodiment, package


20


thus includes a predetermined region containing the plurality of apertures that includes both isolated or non-contiguous sub-regions


48


and


34


on one or more than one surface of the food package or bag


20


. Initially, in this embodiment, the predetermined region is preferably generally congruent to the food load


24


as it exists prior to being heated. As the food load


24


is heated, the bag


20


inflates due to the steam or water vapor generated by microwave heating of the food load, such as, but not limited to popcorn popping, moving region


48


away from the food load


22


, thus limiting penetration of evanescent microwave energy through apertures


32


to the evanescent penetration zone adjacent the interior of region


48


, while at the same time restricting or attenuating propagating microwave energy entering through region


48


. In this embodiment, the food load such as, but not limited to the bulk of the popped popcorn, will be shielded by layer


30


from further exposure to evanescent microwave energy entering through region


48


, while the food load


22


adjacent region


34


will be continuously exposed (through sub-region


34


) to the microwave energy entering therethrough to complete heating (e.g., popping, in the case of microwave popcorn). Furthermore, gravity will move the popped kernels away from the sub-region


48


, even though continued popping will jostle the popped kernels. Referring now again to

FIG. 6

, the depth


49


of the evanescent penetration zone


44


can be controlled and varied from place to place along the bag or package


20


(or


50


) by using different sizes or shapes or numbers or spacing of apertures


32


in different sub-regions of layer


30


around the bag


20


. For example, and not by way of limitation, the evanescent penetration zone


44


can have a depth of penetration or thickness of ¼ inch adjacent sub-regions


48


and


34


, and a lesser depth of penetration


51


of ⅛ inch in the remainder of the interior of the food package


20


. Referring now again to

FIG. 4

, the example numerical values for the depths of penetration


49


,


51


are relative figures of merit, for example, and not by way of limitation, the half-power points corresponding to distance


55


away from ordinate axis


40


(representing the outer surface of layer


30


) where level


53


is one half the peak power


57


of curve


38


.




Referring now most particularly to

FIGS. 15 and 16

, the embodiment of

FIGS. 1 and 2

is shown in fully folded and partially folded configurations.

FIG. 15

shows bag or package


20


with first and second wings


21


,


23


in a fully folded configuration.

FIG. 16

shows bag


20


in a partially folded configuration with wing


21


folded and wing


23


unfolded. It is to be understood that bag


20


is preferably fully folded when packed for shipment and sale. In the practice of the present invention, bag


20


may be placed in a microwave oven fully or partially folded, or fully unfolded (as illustrated in

FIGS. 1 and 11

) prior to exposure to microwave irradiation. However, it is preferred that the bag


20


be fully unfolded as shown in

FIG. 1

prior to microwave irradiation. As with conventional bags, if a susceptor


26


is used, bag


20


is preferably oriented with the surface containing the susceptor located on the bottom.




The present invention, in the embodiments shown, provides a bag for reducing scorching while still enabling popping of popcorn, or popping, puffing, or otherwise heating other foodstuffs, by allowing significant penetration of microwave energy into the bag, delivering sufficient energy to pop the popcorn while the bag is in a collapsed or folded condition. After popping has inflated the bag, the majority of the food package interior (i.e., the region beyond, or interior of, the penetration zone) is protected from further entry of significant evanescent microwave energy, while still permitting entry of propagating energy. Thus at least a portion of the foodstuff has the microwave shielding layer moved away from close proximity thereto after the package and the foodstuff (in this case, popcorn) is irradiated with at least a predetermined amount of microwave energy. This is accomplished by selecting one or more sizes of apertures


32


to permit passage of a predetermined amount of evanescent (i.e., non-propagating) microwave energy modes into the interior of the bag, while at the same time, sizing the apertures to permit a controlled amount of propagating energy into the bag. In the practice of the present invention wherein the susceptor


26


is interior of layer


30


, there is preferably a region


34


in layer


30


on the bottom surface of the package


20


at least substantially congruent to the susceptor


26


to permit microwave energy to reach and heat the susceptor


26


as the energy enters from the bottom of the package. If susceptor


26


is located exterior of layer


30


, it may still be preferable to have a grid or perforated region


34


on the bottom of the package to enable microwave energy to pass through susceptor


26


and heat the food load located inside the package. In either event, the lattice or grid of region


34


is desirably arranged to permit evanescent mode energy and a predetermined amount of propagating mode microwave energy into the interior of package


20


. This may be accomplished by providing a pattern of apertures


32


adjacent to the susceptor


26


. It is to be understood that the susceptor


26


may be located interior or exterior of the microwave shielding layer


30


, (or even may be omitted) as desired.




Referring now to

FIGS. 7 through 10

, an alternative embodiment of the present invention may be seen. In

FIG. 7

, the package


50


of this embodiment is shown in an expanded condition. The package or bag


50


is generally circular in plan as may be seen most clearly in FIG.


8


. As with the previously described embodiment, bag


50


is preferably formed of a flexible, but non-extendable material such as paper or similar cellulose material


52


, with a microwave shielding or reflective layer


54


laminated thereto. The various panels or walls making up bag


50


are preferably sealed to trap the water vapor created within the bag


50


during microwave heating thereof, while at the same time allowing selective rupture when desired to permit access to the interior of the bag when the food is to be consumed. It is preferred to provide an annular adhesive strip


56


to secure the walls of bag


50


together, using heat and or pressure.




It is to be understood that it is preferable to form bag


50


as a generally planar assembly when collapsed.

FIGS. 8 and 9

illustrate that the microwave shielding layer


54


is perforated with apertures


32


across substantially all of the surface thereof, with the possible exception of the adhesively secured seams


58


and


59


. As in the first embodiment, it is to be understood that the microwave shielding layer may be invisible to a consumer user, being laminated between other layers forming a sanitary or septic food package. In

FIG. 9

a susceptor


60


is shown, preferably secured to bag


50


. As with the first embodiment, susceptor


60


can be exposed to the full effect of microwave irradiation by being located exterior of the microwave shielding layer


54


, or it may be attached interior of the apertured microwave shielding layer


54


. Bag


50


is preferably loaded with a charge of unpopped popcorn, and fat or oil, with flavorings and colorants optionally included. Bag


50


is preferably folded into a generally rectangular configuration for shipping and vending, and, in its folded configuration, may be of a size and shape similar to the first embodiment or other conventional microwave oven ready popcorn packages.




Bag


50


also preferably has a removable cover


92


overlapping an opening


94


in the upper surface thereof. Cover


92


preferably has an adhesive seam


59


which is openable by a consumer once the popcorn is popped, as is illustrated in

FIG. 10. A

non-adhered flap


96


preferably is formed integrally with cover


92


to assist in opening the bag


50


. It is to be understood that cover


92


may have an aesthetically pleasing outer layer


52


formed, for example of a heat stable polymer or paper and an inner microwave shielding layer


54


, with apertures therein, as is illustrated in

FIGS. 8 and 9

.




It is to be understood that the contents of the food package of the present invention may be popcorn kernels or any suitable grain such as rice, maize, barley, sorghum, or the like for being popped or puffed when heated or reheated in a microwave oven.




When subjected to microwave heating, the susceptor will convert microwave energy to heat, and the food load will be subjected to direct heating until sufficient water vapor is released to expand the bag sufficiently to move the upper apertured microwave layer away from the food load by a distance greater than the depth of penetration of the evanescent microwave energy. As popping or puffing continues, the food package will inflate or expand further, enlarging the volume protected from substantial evanescent microwave irradiation interior of the evanescent penetration zone. It is to be understood that the evanescent penetration zone may extend substantially across the entire interior surface of package


50


. While propagating microwave modes may be desirably admitted to the interior of the food package, the protected volume interior of the evanescent penetration zone will reduce the chance of overheating or burning the load (e.g., scorching if the load is popcorn). Fortunately, however, for popcorn loads the jostling of the popped popcorn will constantly move peripheral popped kernels into and out of the evanescent penetration zone, also reducing the chance of scorching. Static loads will not have the jostling movement, however, and the ability to protect the volume interior of the evanescent zone from excessive microwave irradiation using the present invention provides a useful and important design tool in the practice of the present invention.




The grid pattern for square apertures in the practice of the present invention is preferably in the range of ½ to 2 inches in linear dimension (the length of each side of an aperture). In order to create evanescent microwave energy interior of the microwave shielding layer, the thickness and width of the grid pattern forming the apertures must be greater than the penetration depth δ of the conducting material. For a material of conductivity σ, the penetration depth is given by Equation (6):






δ=


c


/(2πσω)


½


  (6)






where c is the speed of light, and ω is the microwave (radian) frequency.




The width of the grid is desirably greater than the penetration depth (a few microns, depending on material) and less than about ½ inch. It is to be emphasized that the shape of the apertures can be regular or irregular, and can include, but is not limited to square, triangular, round, elliptic and even irregular or amorphous (if limited in its maximum dimension to achieve the evanescent microwave mode). The grid or aperture pattern can be regular across the surface of the package or it can be interrupted or irregular, as desired to achieve the proper heating effect for the particular food load carried by the package. The microwave shielding layer can be formed of any material capable of reflecting microwave energy, including, but not limited to, most metals and alloys, such as aluminum, nickel, copper, silver, iron, stainless steel, and the like.




Referring now to

FIGS. 17 through 21

, the relative microwave transmission through a grid formed of apertures may be seen. The graphs of these figures were arrived at through modeling of a propagating microwave field with normal (i.e., perpendicular) incidence to the plane of the sheet of a metal grid containing the apertures. The microwave field was modeled using a wavelength of 12.3 cm. The modeling was performed according to the teachings of C. C. Chen,


IEEE Transactions on Microwave Theory and Techniques


, January, 1973, pages 1-6. In the graphs of these figures, the transmission coefficient T 66 is the averaged intensity just behind an opening as a fraction of the incident intensity. It is a measure of the microwave energy transmitted through the sheet or plane of the grid. (7)




The microwave field distribution after passing through a metal grid is given by Equation (7):








E




Transmission




=TE




0




e




jkz




+ΣA




n






x






n






y




cos(2π


n




x




x/L




x


)cos(2π


n




y




y/L




y


)


e




−z/2Δn






x






n






y




  (7)






where the summation is from n


x


,n


y


=0, not both zero to ∞, and x and y are respectively orthogonal directions, here horizontal and vertical with respect to the sheet


70


of

FIG. 17

, where “a” represents the aperture width


76


and L represents the center to center distance


74


between adjacent apertures


32


, and w represents the bridge width


72


; thus: L


x


=a


x


+w and L


y


=a


y


+w, in the horizontal and vertical directions, respectively. It is to be understood that “vertical” and “horizontal” as used here are intended solely as an aid in viewing and interpreting the sheet


70


of

FIG. 17

with respect to the Equations (7)-(9) and are not intended to be otherwise limiting, since the plane of the sheet


70


may be oriented otherwise than vertical as is depicted in

FIG. 17

, and in fact, the sheet may not form a plane, but instead be a curved or irregular surface in practice.




For Equation (7), T is the transmission coefficient of propagating wave. E


0


and k are the electric field and wave-number of the incident microwave, respectively. A


n






x






n






y




and Δ


n






x






n






y




are the coefficient and penetration zone depth of the (n


x


,n


y


) evanescent mode, respectively,




The penetration zone depth for individual evanescent modes is given by Equation (8):






Δ


n




x




n




y


=½[(2π


n




x




/L




x


)


2


+(2


πn




y




/L




y


)


2


−(2π/λ)


2


]


−½


  (8)






where λ is the wavelength of the microwave energy in free space. Equation (8) gives the penetration zone depth of the various evanescent modes.




If L


x




22


L


y


, then the maximum penetration zone depth is given by Equation (9):






Δmax=Δ


1,0


=(


L




x


/4π)[1−(


L




x


/λ)


2


]


−½




≈L




x


/4π, for L


x


<<λ  (9)






For Lx=Ly=1.5″≈3.8 cm, the Penetration Zone depth for respective individual modes is given by Table 1:
















TABLE 1











n


x






n


y






Δn


x


n


y


(in mm)













1




0




3.18







1




1




2.19







2




0




1.53







2




1




1.37







2




2




1.08







3




0




1.01







3




1




0.96







3




2




0.84















evanescent mode





penetration







indices





zone depth















It is to be understood that the formulae and table values are for free space behind the grid. If other media are present, that will change the formulae and table values.




The primary parameters for controlling propagating and evanescent microwave energy transmission through a metal grid are the thickness of the metal forming the grid, and the size, shape and arrangement pattern of the apertures forming the grid.




The thickness of the metal controls the shielding quality of the metal. In general, it is preferred to have the thickness of the metal be greater than the skin depth of microwave penetration to provide good shielding properties. The skin depth of a typical metal such as aluminum is in the range of 1˜2 microns. In the practice of the present invention, it is generally preferred that the metal function as a good shield to microwave passage. For this reason, the preferred metal thickness is something greater than the skin depth. Of course, other considerations, such as manufacturability and durability of the metal layer will also be significant, and may dictate a thickness greatly in excess of what is needed for microwave shielding purposes.




Aperture size is considered one of the most important parameters for controlling microwave energy in the practice of the present invention. In

FIGS. 17-21

the relative microwave field intensity T


66


is plotted on the ordinate (vertical axis) against aperture size “a”


76


plotted (in centimeters) on the abscissa (horizontal axis) for various bridge widths for the model metal grid shown in sheet


70


in FIG.


17


. In each of

FIGS. 17-21

, it is to be understood that the apertures


32


are square shaped and the aperture arrangement pattern or lattice or grid pattern


68


is also square, all as shown in the grid


68


of FIG.


17


. Each of

FIGS. 17-21

shows the calculated transmitted (propagating) wave intensity on curve


78


and evanescent wave intensity on curve


80


as a function of aperture size (related to the aperture width a


76


and the maximum dimension h


36


), with the center to center distance


74


between apertures


32


held fixed over the data in a particular Figure. For very small aperture sizes, i.e., with the characteristic dimension a <1 cm, very little microwave energy penetrates through the grid. Both propagating and evanescent modes have low intensity. As the aperture size increases, initially both propagating and evanescent field intensities increase. However, beyond a certain aperture size, evanescent energy begins to decrease with aperture size. Using

FIGS. 17-21

, it is possible to select an aperture size to maximize evanescent mode energy in relation to the propagating mode microwave energy.





FIG. 17

is for a bridge width w


72


of 0.1 cm.

FIG. 18

is for a bridge width w


72


of 0.2 cm.

FIG. 18

is for a bridge width w


72


of 0.2 cm.

FIG. 19

is for a bridge width w


72


of 0.35 cm.

FIG. 20

is for a bridge width w


72


of 0.5 cm.

FIG. 21

is for a bridge width w


72


of 0.8 cm.




Referring now to

FIG. 22

, the square of the absolute value


82


of the transmission coefficient 66 is shown plotted against aperture width “a”


76


for various bridge widths. Curve


84


is for a bridge width of 0.1 cm. Curve


86


is for a bridge width of 0.2 cm. Curve


88


is for a bridge width of 0.35 cm. Curve


90


is for a bridge width of 0.5 cm. Curve


92


is for a bridge width of 0.8 cm. The effect of varying the bridge width on the square of the absolute value of the transmission coefficient is shown as a parameter, illustrating that average transmission of the propagating mode increases with decreasing bridge width, for any given aperture size in the range illustrated.




Referring now to

FIG. 23

, the evanescent wave (mode) intensity EWI


94


in free space immediately behind or downstream of the grid is plotted against aperture width “a”


76


for various bridge widths. Curve


96


is for a bridge width of 0.1 cm. Curve


98


is for a bridge width of 0.2 cm. Curve


100


is for a bridge width of 0.35 cm. Curve


102


is for a bridge width of 0.5 cm. Curve


104


is for a bridge width of 0.8 cm. As may be seen, increasing bridge width w


72


while holding everything else constant will result in an increase in evanescent energy passing through the grid


68


. These curves may be used to help design the evanescent energy component desired to be delivered through the package to the load.




Referring now to

FIG. 24

, the penetration zone depth of the combined evanescent modes, D


z




106


, is plotted against aperture width “a”


76


for various bridge widths. Curve


110


is for a bridge width of 0.1 cm. Curve


112


is for a bridge width of 0.2 cm. Curve


114


is for a bridge width of 0.35 cm. Curve


116


is for a bridge width of 0.5 cm. Curve


118


is for a bridge width of 0.8 cm. As may be seen, increasing bridge width w


72


while holding everything else constant will result in an increase in penetration zone depth


106


of the evanescent energy passing through the grid


68


. It is to be understood that the penetration zone depth D


z


differs from the penetration depth D


p


in that D


z


is for all evanescent modes behind (downstream of) the grid, in contrast to D


p


which is typically used in the context of only a single evanescent or cut off mode in an infinitely long waveguide.




Referring now to

FIG. 25

, the averaged microwave energy distribution behind the grid is plotted as |E|


2




120


on the ordinate and distance from the grid


122


in cm on the abscissa. The top three curves are for total energy. The three straight line (horizontal) curves are for propagating modes and the bottom three curves are for evanescent modes. Curves


124


,


134


and


136


correspond to a bridge width of 0.16 cm with an aperture size (diameter, in the case of circular apertures) of 2.38 cm. Curves


126


,


132


, and


138


correspond to a bridge width of 0.32 cm with an aperture size of 2.38 cm. Curves


128


,


130


and


140


correspond to a bridge width of 0.5 cm with an aperture size of 2.38 cm.




In the design of a package for microwave popping of popcorn, it has been found desirable to have the strongest level of combined propagating and evanescent mode energy in the zone adjacent the grid for good popping performance, while at the same time, minimizing the amount of propagating mode energy progressing to the volume interior of the evanescent zone in the package to reduce scorching of the popped popcorn. It is therefore desirable to select an aperture size to optimize microwave energy transmission characteristics for a balanced performance of popped volume and scorch resistance. For a square aperture shape in a square lattice pattern, the optimum aperture size is believed to be in the range of ½ to 2 inches, and preferably about 1 inch for each side of the square aperture.




Referring now to

FIG. 26

, the effect of changing the shape of individual apertures on microwave transmission through the grid may be seen for square and circular shaped apertures in a square lattice pattern. Using the model of a plane microwave incident in the normal direction to the metal grid indicates that for a given level of propagating mode energy, chart


142


illustrates the results obtained with square apertures in a square lattice. The center to center distance L


74


is 2.69875 cm for both charts. The relative propagating mode wave intensity is shown by curve


78


in chart or graph


142


, while the evanescent mode wave intensity is shown by curve


80


, with aperture size “a”


76


plotted along the abscissa. The effect of circular apertures is shown in a square lattice


68


(similar to the embodiment of sheet


70


shown in

FIG. 17

, except for the shape of the apertures) in chart


144


. Here the relative intensity


78


of the propagating mode is substantially reduced from that of chart


142


for corresponding values of “a.” Similarly, the magnitude (and characteristic shape) of the evanescent mode intensity


80


is altered by the change of aperture shape. It is to be understood that “a”


76


in chart


144


refers to the diameter of the circular apertures.




Referring now to

FIG. 27

, the effect of changing the shape of individual apertures on microwave transmission through the grid may be seen for hexagonal and circular shaped apertures in a triangular lattice pattern. A triangular lattice pattern


154


is shown in

FIG. 29

for square shaped apertures. Again using the model of a plane microwave incident in the normal direction to the metal grid indicates that for a given level of propagating mode energy, chart


146


illustrates the results obtained with hexagonal shaped apertures in a triangular lattice. The center to center distance L


74


is 2.69875 cm for both charts. The relative propagating mode wave intensity is shown by curve


78


in chart


146


, while the evanescent mode wave intensity is shown by curve


80


, with aperture size “a”


76


plotted along the abscissa. It is to be understood that “a” as used here, refers to the diameter of the circular apertures and to the minor “diameter” of the hexagonal apertures, i.e., the perpendicular distance between two opposing, parallel, sides. The effect of circular apertures is shown in a triangular lattice in chart


148


. Here the relative intensity


78


of the propagating mode is substantially the same, although slightly reduced from that of chart


146


for corresponding values of “a.” Interestingly, the magnitude (and characteristic shape) of the evanescent mode intensity


80


in charts


146


and


148


is very similar for “a” between 1.5 cm and about 2.3 cm. As is apparent, there is a pronounced maximum in the evanescent mode intensity


80


in chart


148


. It is to be understood that “a”


76


in chart


148


refers to the diameter of the circular apertures.




Referring now to

FIG. 28

, the effect of aperture pattern arrangement may be seen. In

FIG. 28

, chart


150


illustrates circular apertures in a square lattice, the same as in chart


144


of FIG.


26


. Chart


152


illustrates circular apertures in a triangular lattice similar to the embodiment of sheet


70


shown in

FIG. 29

, except for the shape of the apertures. The square lattice arrangement delivers higher evanescent energy intensity


80


than the triangular lattice arrangement, but very close to the same propagating mode intensity


78


.




Two experiments were performed to test the influence of grid design on microwave popcorn performance. A trapezoid-shaped box was constructed of steel and used to simulate the shield in a popcorn bag. The bottom of the box was open, but covered with a one of several metal grids, differing from each other in the size and geometry of openings in the grid. The dimensions of the box were as follows. The height was 15 cm, the top rectangle was 20 cm by 16 cm, the bottom rectangle was 15 cm by 11 cm, and the thickness of the steel was 1 mm. The box formed an inverted, truncated four-sided pyramidal structure with the 15 cm sides forming the bottom edges of the sides having the 20 cm top edge length. The replaceable grids were used to form the bottom wall. Two grid patterns were tested and compared: (1) Square holes in a square lattice with a hole size of 1″ and a bridge width of {fraction (3/16)}″ and (2) Round holes in a square lattice with a hole diameter of 1″ and a bridge width of {fraction (3/16)}″.




Pop-Secret brand microwave popcorn (as is widely available in retail food stores) was used in the experiments. The microwave oven used in the experiments was a Sharp 900 Carousel II oven. The oven was pre-heated by popping at least 3 bags of popcorn before starting the experiments.




Pop performance is characterized through three attributes: pop volume, scorch resistance and unpopped kernels. In each experiment, the popcorn was subjected to full power microwave energy for 90 seconds past the consumer end point. The consumer end point is defined as the point when popping has slowed to more than 5 seconds between two consecutive pops.




Pop volume was measured in cups. Unpopped kernels (UPK) was measured in terms of grams of popcorn that failed to pop during the experiment. Scorch resistance is measured using an Agtron calorimeter. The Agtron calorimeter device measures the color reading of the popped corns. Un-scorched popped popcorn kernels characteristically have high Agtron readings (usually above 80), while scorched popped popcorn kernels have lower Agtron readings (a reading below 75 is noticeable scorching, below 70 is considered severe scorching). Table 2 shows the experimental results.

















TABLE 2











Grid opening




Pop Volume




Agtron scorch




UPK







shape




(cups)




resistance reading




(grams)













Square holes




2700




72.1 




0.9







Round holes




2300




80.23




2.4















The experiments show that compared to the round hole grid, the square hole grid gives higher pop volume, less scorch resistance and less unpopped kernels. This is consistent with the prediction in

FIG. 26

that both propagating wave and evanescent wave intensities are reduced when changing shape from square to round holes.




It is to be further understood that the present invention is suitable for selective heating of foods other than popcorn and other puffed foodstuffs. For example, and not by way of limitation, a filled pastry that gives off water vapor when heated, may be heated and a topping such as frosting may be melted using a food package according to the teachings of the present invention. In such an application, the filling may be prevented from being overheated while the outer surface of the foodstuff can be heated and even browned, if desired, using the evanescent penetration zone of the present invention to selectively heat an exterior region or surface of the foodstuff, preventing overheating by inflation of the package during microwave irradiation to remove the evanescent heating, all the while allowing a controlled amount of propagating energy to enter the package and heat the foodstuff simultaneously.




As another example, and not by way of limitation, the present invention may be used to selectively and controllably heat or cook a pizza using microwave irradiation, where the food package for the pizza may have relatively small apertures in a lower surface to admit evanescent energy only (or primarily) to the pizza crust below the toppings while the upper grid or region above the pizza food load may have apertures suitable for sufficient, but not excessive, heating or cooking of the toppings, followed by a movement of the upper grid away from the pizza (as a result of the water vapor generated) to prevent overheating of the toppings. This approach may be utilized with or without a susceptor to achieve desired browning of the crust, and to simultaneously achieve desired cooking of the toppings, without overcooking. This approach can benefit from the controlled introduction of conventional, propagating microwave energy along with the selective application of the evanescent energy.




The invention is not to be taken as limited to all of the details thereof as modifications and variations thereof may be made without departing from the spirit or scope of the invention.



Claims
  • 1. Apparatus for controlling heating of a foodstuff with microwave energy comprising:a. a food package having a microwave shielding layer with a plurality of apertures therein, with the apertures sized to permit entry of both evanescent and propagating microwave energy into the interior of the package; b. a foodstuff contained in the food package with the foodstuff initially located in close proximity to the microwave shielding layer; c. means for moving the microwave shielding layer away from close proximity to at least a portion of the foodstuff after the package and the foodstuff are irradiated with at least a predetermined amount of microwave energy such that the evanescent microwave energy entering the package is insufficient to over heat the foodstuff when the microwave shielding layer is moved out of close proximity to the foodstuff, while the propagating microwave energy continues to heat the foodstuff and the combination of evanescent microwave energy and propagating microwave energy is balanced to achieve a desired heating of the foodstuff.
  • 2. The apparatus of claim 1 wherein water vapor is generated by the microwave energy and the means for moving the microwave shielding layer away from close proximity to at least a portion of the foodstuff is a water vapor barrier layer sufficiently impermeable to water vapor and operative to inflate the package in response to the generation of water vapor.
  • 3. The apparatus of claim 2 wherein the foodstuff is popcorn.
  • 4. The apparatus of claim 1 wherein the food package further comprises a microwave susceptor located interior of the microwave shielding layer.
  • 5. The apparatus of claim 1 wherein the food package further comprises a microwave susceptor located exterior of the microwave shielding layer.
  • 6. The apparatus of claim 1 wherein the food package further comprises a septic layer located adjacent the microwave shielding layer.
  • 7. The apparatus of claim 1 wherein the plurality of apertures extend substantially across the entire food package.
  • 8. The apparatus of claim 1 wherein the plurality of apertures extend across a predetermined, limited region of the food package.
  • 9. The apparatus of claim 8 wherein the predetermined, limited region includes non-contiguous sub-regions.
  • 10. The apparatus of claim 9 wherein the predetermined, limited region extends over more than one surface of the food package.
  • 11. The apparatus of claim 8 wherein the limited region is generally at least congruent to the foodstuff as it exists prior to heating.
  • 12. A method of controlling heating of a foodstuff with microwave energy comprising the steps of:a. providing a food package having a microwave shielding layer with a plurality of apertures therein, where the apertures are sized to permit evanescent microwave energy and a controlled, limited amount of propagating microwave energy into the interior of the package; b. initially locating a foodstuff within the food package in close proximity to the microwave shielding layer; c. irradiating the package and foodstuff with microwave energy; and d. moving the microwave shielding layer away from close proximity to at least a portion of the foodstuff after the package and the foodstuff is irradiated with at least a predetermined amount of microwave energy such that the evanescent microwave energy is insufficient to over heat the foodstuff when the microwave shielding layer is moved out of close proximity to the foodstuff, while the propagating microwave energy continues to heat the foodstuff.
  • 13. The method of claim 12 wherein water vapor is generated by the microwave irradiation.
  • 14. The method of claim 13 wherein the water vapor expands the package to move the microwave shielding layer away from close proximity to at least a portion of the foodstuff after the package and the foodstuff is irradiated with at least a predetermined amount of microwave energy.
  • 15. The method of claim 14 wherein the foodstuff is popcorn.
  • 16. The method of claim 12 wherein the step of providing a plurality of apertures in the microwave shielding layer further comprises locating the plurality of apertures to at least a predetermined, limited region of the food package.
  • 17. The method of claim 16 wherein the step of providing a plurality of apertures in the microwave shielding layer further comprises locating the plurality of apertures generally at least congruent to the foodstuff as it exists prior to heating.
  • 18. The method of claim 12 wherein step a further comprises providing the plurality of apertures across substantially all of the food package.
  • 19. The method of claim 12 further comprises providing a susceptor in the food package, wherein the microwave shielding layer has apertures adjacent the susceptor.
  • 20. The method of claim 12 wherein step a further comprises providing the food package with a water vapor barrier layer substantially impermeable to water vapor.
  • 21. The method of claim 12 wherein step a further comprises providing the food package with a septic layer sufficient to maintain a sanitary environment for the interior of the food package.
  • 22. A food package apparatus for controlling the entry of evanescent and propagating microwave energy to the interior of the package apparatus comprising:a. a microwave shielding layer extending over at least a portion of the food package apparatus with a plurality of apertures in a predetermined region thereof, with the apertures sized to admit and control both evanescent microwave energy and propagating microwave energy into the interior of the package apparatus, b. a foodstuff contained in the food package apparatus with the predetermined region of the microwave shielding layer initially located in close proximity to at least a portion of the foodstuff; c. means for moving the predetermined region of the microwave shielding layer away from close proximity to the portion of the foodstuff after the package apparatus and the foodstuff is irradiated with at least a predetermined amount of microwave energy such that the evanescent microwave energy passing through the predetermined region of the microwave shielding layer is insufficient to over heat the foodstuff after the microwave shielding layer is moved out of close proximity to the portion of the foodstuff, while the propagating microwave energy continues to heat the foodstuff.
  • 23. The food package apparatus of claim 22 wherein water vapor is generated by the microwave energy and the means for moving at least the predetermined region of the microwave shielding layer away from close proximity to at least a portion of the foodstuff is a water vapor barrier layer sufficiently impermeable to water vapor and operative to provide relative movement to increase the spacing between the foodstuff and at least a part of the predetermined region of the microwave shielding layer.
  • 24. The food package apparatus of claim 23 wherein the foodstuff is popcorn.
  • 25. The food package apparatus of claim 22 wherein the food package apparatus further comprises a microwave susceptor.
  • 26. The food package apparatus of claim 22 further comprising a septic layer located adjacent the microwave shielding layer.
  • 27. The food package apparatus of claim 22 wherein the predetermined region containing the plurality of apertures extends substantially across the entire food package apparatus.
  • 28. The food package apparatus of claim 22 wherein the predetermined region containing the plurality of apertures includes non-contiguous sub-regions.
  • 29. The food package apparatus of claim 28 wherein the predetermined region including the non-contiguous sub-regions extends over more than one surface of the food package apparatus.
  • 30. The food package apparatus of claim 22 wherein the predetermined region is generally at least congruent to the foodstuff as it exists prior to heating.
  • 31. A microwave popcorn package for popping popcorn in a microwave oven comprising:a. a bag having: i. a microwave shielding layer with a plurality of apertures therein with the apertures sized to permit both evanescent microwave energy and a controlled, limited amount of propagating microwave energy to enter the interior of the bag, and ii. a water vapor barrier layer generally impermeable to water vapor; and b. a mass of popcorn in the bag with the popcorn located adjacent the apertures in the microwave shielding layer prior to popping the popcorn; wherein the bag is initially in a deflated condition, permitting entry of both the evanescent and propagating microwave energy sufficient to cause the popcorn to pop, andwherein the bag is subsequently inflated by the water vapor resulting from the popcorn popping, creating an internal volume of the bag shielded from the evanescent microwave energy to reduce scorching of the popped popcorn in the shielded volume.
  • 32. The package of claim 31 wherein the bag further includes:iii. a susceptor located adjacent the mass of popcorn and exposed to microwave irradiation when the bag is placed in an operating microwave oven.
  • 33. The package of claim 32 wherein the bag further includes:iv. a septic layer to provide a sanitary environment interior of the bag.
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Entry
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