AU2001264846A1 - Food Portion Consisting of Two or More Food Items, and Processes for Making and Packaging Same - Google Patents
Food Portion Consisting of Two or More Food Items, and Processes for Making and Packaging SameInfo
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- AU2001264846A1 AU2001264846A1 AU2001264846A AU2001264846A AU2001264846A1 AU 2001264846 A1 AU2001264846 A1 AU 2001264846A1 AU 2001264846 A AU2001264846 A AU 2001264846A AU 2001264846 A AU2001264846 A AU 2001264846A AU 2001264846 A1 AU2001264846 A1 AU 2001264846A1
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Description
FOOD SLICE CONSISTING OF TWO OR MORE FOOD ITEMS, AND PROCESSES FOR MAKING AND PACKAGING SAME
Background Art
The invention generally relates to a food slice and processes for making and packaging it. More specifically, the invention provides a food slice consisting of two or more food items, such as nut butter and jelly, and a method for making and packaging the food slice. The food industry has seen a large number of new products over the last few decades. Many of these products take traditional foods and place them in a variety of package formations. The package formation may facilitate convenient storage and handling, ease of use and application, or portability and portion control. Attempts have been made, for example, to develop food products and packaging configurations that combine foods that are customarily combined and consumed by the consumer. Examples include peanut butter and jelly, chocolate and marshmallow, or catsup and mayonnaise. While products such as these are manually mixed and enjoyed by the consumer, precombining these products into a single food product is highly desirable from a marketing and consumer time savings standpoint. Yet it presents many problems, including processing, product stability, moisture migration, and color stability. A variety of formulations known as peanut butter and jelly are consumed when spread on bread or toasted bread. The current majority of peanut butters and jellies are packaged in jars and are portioned with either knives or spoons onto bread.
Peanut butter, in combination with the sweetness and flavor of a grape jelly, for example, makes a simple, inexpensive topping or sandwich when used upon a grain-based bakery item such as crackers or bread, and presents itself as an attractive folk recipe. It will also be appreciated that the science of sensory evaluation of mastication and the expectation of flavors, texture, and sensation demands that the peanut butter and jelly remain relatively unmixed within the sandwich until consumed.
Examples of precombined products and package formulations are described in U.S. Patent Nos. 3,772,038 to Ayres; 5,312,641 to Castillo; and 5,567,454 and 5,855,939 to Bogdan; Canadian patent application CA 2233097 to Chenn; and an article, Food Product Development, McCormick, R.D. Vol. 9:9, pages 11 , 12, 14 (1975) ("FPD article"). This literature discloses peanut butter, or peanut butter and jelly, in a slice form. However, the inventors are not aware of commercially available packaged food slices consisting of a single cohesive mass of two or more food slice items, such as peanut butter and jelly, or such food slices that are made using continuous, high-speed processes or that provide convenience, portion control, and similar sensory characteristics to those of the traditionally consumed, manually-combined counterpart food items.
Providing a combined food product that can be processed in a high speed, commercially viable manner is difficult. While creating layers of food material on a bench-top offers a myriad of possibilities because of very few demands on quality or performance, providing commercially successful product formulas and processes are much more demanding. Commercial-scale equipment requires ingredients that are cohesive yet pumpable. Equipment of this nature runs continuously which disallows processes requiring long firming or body modification times.
Further, folk recipes rarely require a shelf life of greater than a day, so that shelf life and the detrimental effects of storage for products consisting of two or more food items which are manually combined by the consumer are rarely considered. But it is readily apparent to persons with ordinary skill in this food processing art that a shelf life of many months, such as 3-6 months or more, at
refrigerated temperatures is desired in order to meet retail distribution requirements. However, it is also known that combining two food items having dissimilar moisture contents will cause the water to migrate from the food item with higher moisture to the food item with lower moisture. Water migration, in the specific case of jelly next to peanut butter, for example, causes darkening and a noticeable flavor change within the peanut butter.
Attempts have been made to deal with the water migration problem. For example, U.S. Patent No. 3,969,514 to Tiemstra describes precombined products, such as a nut spread and a jelly or jam, in which an adjustment is made to the water activity of one of the food items to increase the time period in which the food items are maintained as separate and discrete. U.S. Patent No. 3,552,980 to Cooper describes a hydrophilic spread such as peanut butterwhich is packaged in contact with a sweet aqueous spread that is similar to jelly. The sweet aqueous spread is modified with a non-aqueous edible liquid viscosity reducing agent such as glycerin to enable the products to remain stable with reduced moisture migration over time. Both the Tiemstra and Cooper patents disclose food items packaged in jarred containers.
Oxidation of the peanut oil in peanut butter is also a problem, causing the peanut butter to deteriorate and decreasing its shelf life. Accordingly, it is an object of the present invention to provide a food slice consisting of a single cohesive mass of two or more food items, such as peanut butter and jelly, which may be wrapped in a packaging film, sealed and produced on a commercial scale.
It is another object of the invention to provide commercially viable, high speed, continuous processing methods for making and packaging food portions, including individually wrapped food slices. A related goal is to ensure that the food portion is on the one hand cohesive, while on the other hand pumpable and extrudable. It is particularly desirable that the invention be compatible with high speed, continuous processing equipment such as individual wrap slice machines described in U.S. Patent Nos. 5,440,860 and 5,347,792 to Meli, for example.
Those knowledgeable in the art will realize that this machinery described in these
patents, suitably modified as described below, as well as other similar processing equipment, may be used for the production and packaging of food portions consisted of combined food items according to the present invention.
It is yet another object to provide such food portions in a variety of configurations, such as bi- or tri-laminates, stripes, variegated, or other shapes encased in flexible packaging materials.
It is a further object to provide a food product that combines two or more different food items, such as peanut butter and jelly, in a simple package that provides portion control, allows easy removal from the package, and dispenses with the need to use a utensil for manually combining or spreading the food items. Preferably a packaged slice would be provided that permits complete manual release from its flexible packaging material and that is integral enough to allow for some manipulation before consumption.
It is still another object to provide a convenient, single cohesive mass of food product that combines two or more different food items, while enabling the food product to be manually removed from its wrapper and held, manipulated, eaten or applied elsewhere using only the fingers, and without the product disintegrating or deteriorating in an unusable or unsightly manner. A related goal is to provide a combined food product with organoleptic and textural semblance to its traditional manually-combined counterpart.
It is yet another object to manipulate component viscosity through composition, shear, and temperature to prevent excessive mixing and commingling of multiple components during processing.
Still a further object is to provide a high barrier film to minimize oxygen migration and subsequent product degradation during packaged storage.
Another object, in order to maximize shelf life of the combined, conformed food product, is to modify water activity to achieve maximum stability of the food components during packaged storage.
Definition of Claim Terms
The following terms are used in the claims of the patent as filed and are intended to have their broadest meaning consistent with the requirements of law.
Where alternative meanings are possible, the broadest meaning is intended. All words used in the claims are intended to be used in the normal, customary usage of grammar and the English language.
"Acidulants" means food acidulants, including food grade acids such as citric acid. "Co-extrusion" means pushing two or more food products through one or more different orifices at roughly the same time. "Conformed" means two or more food product streams that are coextruded and shaped within a flexible packaging material into a food portion.
"Extrusion" means pushing a product through an orifice.
"Food portion" means any food product, regardless of size, shape or configuration, including bricks, chunks, loaves, bars, slices, etc. "Fruit juice" means fruit juice, fruit juice concentrate, dried fruit juice, or reconstituted forms thereof.
"Gel" or "gelling agent" means substances that qualify as gels as that term is normally used in the art of food science, and refers to a colloid in a form more solid than a sol. "Hardness" means the Texture Profile Analysis test of plunging a cylinder into the food product and measuring the maximal force achieved during elastic compression to just before failure of the food item as determined by gel disruption.
"Jelly" means gelled food products including all types of jellies, fruit spreads, jams, preserves, marmalades, fruit butters, dessert gels, gelatin slices, and the like. "Jelly" may be made from sugars, pectins, gelatin, gelling agents and/or acidulants. "Jelly" may be flavored from the juice of fruits, concentrated fruit juice, natural flavor, artificial flavor or any combination of those flavors. The extract or puree of any food source may also be used in "jelly" to impart both function and flavor. "Jelly" is not limited as defined within the U.S. Code of
Federal Regulations, §§ 21 :150.140, 21 :150.160.
"Maintaining individual product identity" means two or more different food items provided together in the same package and present in discreet phases such that each of the separate food items may be visually discerned at the surface of the food portion by the consumer. "Nut butter" means any food product made from nut solids and vegetable fats plus other ingredients such as stabilizers, flavorants, flavor enhancers, bulking agents, emulsifiers, and sweeteners. "Nut butter" also includes items termed "peanut butter", such as food items prepared from clean, sound, shelled peanuts by grinding roasted, mature peanut kernels from which the seed coats have been removed, and to which sugar, dextrose, and/or salt may be added to enhance the flavor, and to which hydrogenated vegetable oils may be added to prevent oil separation and to promote consistency. "Nut butter" is not limited to any definitions for "nut butter" or "nut spread" or "peanut butter" as defined within the U.S. Code of Federal Regulations, § 21 :164.150. "Organoleptic attributes" mean the tactile, olfaction and gustation qualities of a food, as identified in the field and science of measuring human response to foods.
"Package" means any encapsulation or covering for a food product. "Peanut flour" means a food item prepared from raw shelled peanuts that have been cleaned, blanched and sorted to remove any damaged or discolored nuts along with any foreign materials. The nuts are then roasted and hydraulically pressed to remove some of the peanut oil content. The product is then crushed and milled to a desired fineness. "Set " means for a gelled product to reach a substantially constant viscosity.
"Slice" means a food product having an area/height ratio of greater than 20:1. "Sugar" means any sugar, as well as any sugar syrup, including any carbohydrate- derived mixture including mono-, di-, and higher saccharides either in their naturally occurring state or derived by hydrolysis, and including mixtures containing sufficient water to be present in a liquid or fluid state.
"Texture" means the physical sensation of a food product as it interacts with the human senses, including its appearance and its mouth-feel upon mastication.
"Thickeners" mean constituents for increasing the viscosity of a food product, including gelling and non-gelling agents, such as proteins, polysaccharides and hydrocolloids.
"Water activity" means the ratio of partial vapor pressure of water, measured above the food item in question, to the vapor pressure of pure water at a given temperature.
Disclosure of Invention
The objects mentioned above, as well as other objects, are solved by the present invention, which overcomes disadvantages of prior art precombined food products and processes for making and packaging them, while providing new advantages not previously obtainable with such food products and processes.
The present invention solves many attendant problems arising from attempts at precombining two or more different food items into a single food product, including problems relating to continuous processing, rheologic criteria, shelf stability, removal of the food item from the package, and consumer expectations relative to the traditional products and their use.
This invention has its genesis in two surprising findings. The first involves fruit jelly formation. Many trials were carried out in which a fruit gel was found not firm enough to prevent mixing with the peanut butter during extrusion. The typical problem experienced was that as concentrations of a carbohydrate sweetener were increased to build body and thickness, and to lower water activity, the finished product gel tended to be sticky with poor gel formation, even with increased levels of gums. However, it was found that by using corn syrup to disperse the gum without any water addition, a sufficiently firm body was achieved to enable extrusion, with acceptable film separation in the final product. Also, the water activity was lowered significantly.
The second surprising result was discovered when corn syrup was added to peanut butter to increase the water activity of the peanut butter to more closely match that of the jelly. Even mild agitation of the peanut butter and corn syrup mixture caused separation of oil from the product, leaving a solid residue too thick to pump. This may be referred to as an irreversible protein interaction, and particularly became apparent during larger pilot plant scale trials. Surprisingly, it was found that the late addition of the corn syrup material, together with in-line mixing just prior to extrusion provided a smooth-flowing mixture that remained stable throughout processing and packaging. These two findings were key steps in producing an acceptable, coextruded product suitable for high speed, continuous commercial applications.
An emulsifier was also added into the peanut butter ingredients during mixing and prior to cooking, to add robustness and process tolerance to the mixture, and to provide some delay in the water-induced thickening of the mixture by stabilizing the emulsion.
While formulations and processing steps for peanut butter or peanut butter spread, and jelly or jelly spread, are specifically discussed, the scope of the present invention encompasses other food products which may be combined. These products may range from juice-free jellies and peanut-free butters to foods unrelated to jelly, such as cheese, or a condiment, chocolate and marshmallow, catsup and mayonnaise, etc.
A unique feature of the combined food items of the present invention is the cohesive nature of the formed products. Unlike some prior art products which rely upon jars or containers for handling and support, the cohesive nature of the slice product of the present invention allows it to be handled both within and without the flexible packaging material. Thus, the wrapper can be removed and the product held, manipulated, eaten or applied elsewhere using only the fingers, and without the product disintegrating or deteriorating in an unusable or unsightly manner. In general, useful jelly formulations for the present invention may be prepared from combinations of juice, juice concentrate, sugar, corn syrup, pectin,
gelatin, carrageenan and Konjac flour. Additional sugars such as fructose, glucose, and high fructose corn syrup have been found useful. Vegetable oil may be used to help in release from the packaging film and to reduce foaming during cooking. Starch may also be used to form a gel to provide a stiffer body, also aiding in release of the food product from the film. Some types of pectin and carrageenan are more effective in extrusion performance than others.
Gelatin forms excellent finished product gels but has a tendency to discolor with reducing sugars over time. Gelatin has the characteristic of remaining fluid at high temperatures. Very slow gel formation is then observed as the temperature decreases. Gel formation is often independent of other gelling agents, making it useful in a two-stage gelling system in which a primary gel is followed by a secondary gel. Functionally, gelatin is particularly useful for slice formation, possessing properties of flexibility, elasticity, and clarity.
Peanut butter is a combination of roasted and ground peanuts, sweetener, and stabilizers. Peanutflours are the portion ofground peanuts after part of the oil has been removed. Salt is added for flavor, although it must be of a fine grind or it may have a gritty mouthfeel, particularly in a low moisture product. It has been found that peanut butter combined with peanut flour has a body and texture sufficiently firm for extrusion into slices. In a preferred embodiment of the present invention, when peanut butter is combined with high- moisture jelly, the addition of sugar syrup such as high fructose corn syrup is used to reduce water migration from the jelly to the peanut butter.
In order for jelly to be successfully utilized in an extruded slice preparation, viscosity has to be carefully controlled. This can be achieved by using a two-step gel formation as described in co-pending U.S. Serial No.
09/356,786, titled "Multi-Stage Thickening Composition For Use With Packaged Food Items And Process For Using Same", incorporated by reference herein in its entirety, as further described below.
In order to produce food products with novel shapes or to introduce multiple streams simultaneously out of the fill head, specialized nozzle devices are provided. For a laminated slice with peanut butter on one side and jelly on
the other, with each encompassing the entire surface area on their respective sides, nozzles are expanded and flattened to provide a ribbon-like sheet of material. A set of two nozzles placed side by side provides a laminated ribbon as the material exits the nozzles. To create a striped product configuration, individual fill tubes may be arranged side-by-side with each tube supplying one stripe of the slice.
To create a variegated, e.g., dappled or "polka-dot", product configuration, spheres or nuggets of, e.g., jelly are formed instead of a continuous column or ribbon. The spheres or nuggets are mixed into the peanut butter prior to the slice-forming belt. As the mixture is flattened, the jelly spheres or nuggets take the shape of a disk or dot surrounded in two dimensions by peanut butter. Of course, the opposite configuration is possible, i.e., dots of peanut butter surrounded by jelly.
A purpose of this invention is the incorporation of the above extrusion devices into machines and methods for forming sealed packaged food slices, as described in U.S. Patent Nos. 5,112,632; 5,440,860; 5,701 ,724;, 6,058,680; 5,347,792; 5,619,844; and 5,800,851 , each of which are incorporated herein by reference. With the machine described in the '860 patent, for example, a web of thermoplastic material is first formed into a tubular arrangement with a hermetic longitudinal seal. The plastic material is folded or wrapped and a hermetic seal is formed on the open longitudinal edge of the folded or wrapped web. Additional devices and means are provided to flatten the food mass to form a continuous web. Hermetically sealed cross-seals transverse to the longitudinal forward moving direction of the web are used to portion the slices which are eventually cut into slices. Suitable modifications to the individually wrapped slice equipment described in the '860 Meli patent for beneficial use with the present invention are described below.
Level and speed control devices are also provided to enable continuous production of these multiple food items. Control of material flow supplying any of the nozzle supply lines is important in maintaining a consistent slice appearance. Weight control is also important from a quality, packaging, and cost
standpoint. Constant feedback to supply pumps is important as consistency of the food materials may vary, requiring continual adjustments of speeds and pressures. A feedback control device is required to keep supply pumps running at the correct levels. Another aspect of the invention is the use of high oxygen barrier films, compared to those currently popularly used for packaging process cheese, to limit oxygen permeability and reduce oxidation over time. This reduces subsequent product degradation during packaged storage. In general, all food configurations according to the present invention may share the following characteristics, though these need not be a requirement of the invention: (1 ) the food slice approximates the size of a slice of bread; (2) each food slice is individually packaged within either a hermetically sealed or non-hermetically sealed flexible packaging material over-wrap; and (3) the food slice requires little effort on the part of the user to separate from the flexible packaging material. In one preferred embodiment of the present invention, a process is provided for continuously preparing food portions consisting of two or more different food items wrapped in a flexible film. The food items may be separately mixed using ingredients for each of the food items, or the food items may be pre- combined. These food items are separately delivered, such as by pumping, to an extrusion location, and extruded or coextruded and combined into the food portion.
Most preferably, the individual food items within the food portion retain their individual product identity and organoleptic attributes. The jelly, for example, may be completely surrounded or enrobed by the peanut butter, but need not be. If the jelly is not enrobed then, if a tri-laminate slice is provided, for example, in which a jelly slice is surrounded by two nut butter slices, the jelly may only be visible at the edges of the slice.
The food portion may be shaped, such as into a slice configuration, and wrapped within the flexible film. The flexible film may be sealed, such as hermetically sealing the film longitudinally and along cross-seals, to form individual packets of the food portions that are sealed within the packaging film.
The individual food items may be provided in laminate, striped, variegated or other forms within the food portion. Preferably, the wrapped food portion has a refrigerated shelf life of greater than about six months.
In one preferred process, the food items may be heated into a soft, molten mass priorto their extrusion, and cooled aftertheir extrusion, though the heating and cooling steps may be omitted given the food item formulations used. When food slices are packaged within flexible film, such that longitudinal and cross seals, whether lap or fin seals, are formed, the cooling step may be performed either before or after cross-sealing. Preferably, the resulting food slices, each containing two or more differentfood items, are wrapped and hermetically sealed within the flexible film.
The water activity of the food items, such as nut butter and jelly, for example, may be modified in a predetermined manner, such as by the addition of sugar. Preferably, the differential water activity of the nut butter and jelly within the wrapped food slice is less than about 0.5 and, most preferably, is less than about 0.2.
Preferably, the food portions, such as food slices, are sufficiently cohesive to permit removal of the food slice from the sealed wrapper while retaining textural and shape characteristics of the slice. This may be accomplished by adding two-stage thickeners, such as two-stage gels, to the food items. Preferably, the first thickener causes a food item, such as jelly, to have a viscosity of less than about 5,000 centipoise during its extrusion, and the second thickener causes the jelly to have a viscosity of greater than about 100,000 centipoise following extrusion of the jelly and after setting of the second thickener.
Preferred nut butter and jelly formulations have been found particularly useful in the present invention. For example, the nut butter may include, by weight, about 50 - 90% peanut butter; 1 - 40% peanut flour; 0.5 - 5% stabilizer; 0 - 10% sucrose; and 0 - 2% salt. Hard fat may be added to the nut butter. The nut component of the nut butter may be created by combining nut flour with an edible oil. In an alternative formulation, the nut butter may include, by weight,
about 40 - 85% peanut butter; 0-10% peanut flour; 0-10% maltodextrin; 0-40% corn syrup; 0.5-5.0% stabilizer; 0.5-4.0% emulsifier; 0.1-3.0% salt; 0-35% fructose; 0-20% dextrose; and 0-40% water.
In a preferred formulation, the jelly may include, by weight, about 5 - 20% fruit juice; 0.5- 5 % high methoxyl pectin; 0.5- 5% low methoxyl pectin; 0.1 - 3% acidulants; and 0 - 2.5% vegetable oil. In an alternative formulation, the jelly may include, by weight, about 5 - 20% fruit juice; 20-40% corn syrup; 15-35% fructose; 5-20% dextrose; 0.25-4.0% konjac flour; 0.05-2.0% carrageenan; 0.5- 4.0% high methoxyl pectin; 0.1-3.0% citric acid; and 0-2.5% vegetable oil. Shaped extrusion nozzles may be used to provide the food items and food portions with various configurations and shapes. For example, two or more generally planar-shaped extrusion nozzles may be used to provide a laminate food slice. One or more divider plates, which are preferably coated with a substance having a low coefficient of friction, such as Teflon, may be used to maintain separation of the food items immediately following their extrusion. A plurality of extrusion nozzles, carrying alternating food items, may be used to provide food portions with striped food items. Concentric extrusion tubes may be used for extruding the food items in a variegated format.
Using high-speed individual wrap slice machines, such as those disclosed in the Meli '860 or Meli '792 patents, food portions such as food slices may be continuously sealed and wrapped at rates in excess of 300 slices/minute; in excess of 700 slices/minute; and in excess of 1 ,000 slices/minute.
Sensing mechanisms, such as mass flow meters, transducers and level sensors, may be employed to maintain or regulate weights of each of the two or more food items, so that each of the two or more food items within a food portion may be maintained within predetermined ratios.
In a preferred nut butter and jelly slice configuration, the hardness of the nut butter within the finished food slice is in the range of about 0.25-4.0 Kg/cm2 at 43 °F, and most preferably about 0.5-1.5 Kg/cm2 at 43 °F; the hardness of the jelly within the finished food slice is in the range of about 0.25-4.0 Kg/cm2 at
43 °F, and most preferably about 1.0-2.5 Kg/cm2 at 43 °F.
A preferred flexible film may include polypropylene having an ethylene vinyl alcohol oxygen barrier layer and one or more sealant layers comprising polypropylene, polyethylene and polybutylene. The flexible film may also include polypropylene and a glycerol monostearate release agent. A casting process may also be employed for continuously preparing food portions consisting of two or more different food items according to the present invention, in which the food items are wrapped in a flexible film, and maintain their individual product identity and organoleptic attributes. Each of the two or more different food items are first prepared, which may include mixing and cooking steps. The food items are then continuously deposited upon a sanitary surface, which may be covered with a flexible film. The food portions are then wrapped within the flexible film and sealed within the wrapper.
Brief Description of the Drawings The novel features which are characteristic of the invention are set forth in the appended claims. The invention itself, however, together with further objects and attendant advantages thereof, will be best understood by reference to the following description taken in connection with the accompanying drawings, in which: FIGURES 1-6 are perspective views of various forms of a food slice consisting of two different food items, according to the present invention;
FIGURE 7 is a schematic view of a preferred individual wrap slice machine for forming food slices according to the present invention, which employs five extrusion lines with different, alternating food items; FIGURES 8 and 10 are food slices similar to FIGURES 1 and 2, respectively;
FIGURE 8a is a cross-sectional view along reference line 8A-8A of FIGURE 8;
FIGURE 9 is a schematic view of a machine similar to FIGURE 7, but with two extrusion lines;
FIGURE 11 is a cross-sectional view along reference lines 11-11 of FIGURE 10;
FIGURES 12-14 are partial, perspective views of various forms of extrusion tubes according to the present invention; FIGURE 15 is a cross-sectional view along reference line 15-15 of
FIGURE 13; FIGURE 16 is a partial perspective view of a preferred embodiment of the individual slice wrapping machine and individual product pumps suitable for forming striped slices according to the present invention;
FIGURE 17 is a partial, perspective view of fill tubes and flattening belts of the preferred slice forming machine;
FIGURES 18 and 19 are enlarged side and front perspective view showing the fill tubes, divider plate and upper portion of the flattening belts;
FIGURE 20 is a partial side perspective view showing the wrapped ribbon of striped food product during passage through a preferred individually wrapped slice forming machine of the present invention;
FIGURE 21 is a partial side perspective view of the filled web leaving the drum (cross) sealer of the preferred individually wrapped slice apparatus;
FIGURE 22 is a schematic view of one preferred form of biasing mechanism for the fill tubes; FIGURE 23 is a schematic view of a preferred process for preparing and processing laminate food portions consisting of (e.g.) peanut butter and jelly according to the present invention;
FIGURE 24 is a perspective view of a preferred blender/cooker useful for blending high fructose corn syrup into the nut butter, prior to extrusion, in a preferred nut butter formulation of the present invention;
FIGURES 25-26 are schematic views of lap and fin seals, respectively, which may be used for sealing packaged food slices, as is well known in the art;
FIGURES 27 and 28 are perspective and enlarged perspective views, respectively, showing, among other items, a preferred bubble level control device for use with the preferred individual wrap slice machine of the present invention;
FIGURE 29 is a partial perspective view showing one embodiment of an extrusion nozzle and divider plate configuration for making tri-laminate slices; and
FIGURE 30 is a cross-sectional view taken along lines 30-30 of FIGURE 29.
Best Mode of Carrying Out the Invention
Set forth below is a description of what are currently believed to be the
preferred embodiments and/or best examples of the invention claimed. Future
and present alternatives and modifications to these preferred embodiments are
contemplated. Any alternatives or modifications which make insubstantial
changes in function, in purpose, in structure or in result are intended to be
covered by the claims of this patent.
Preferred jelly formulations
The purpose of the jelly component of the present invention is to emulate
the sensory characteristics found in the traditional counterpart fruit jelly, i.e. the
sweetness level, tartness, and volatile fruit flavors. Additionally, texture, and the
manner in which the gel yields to stress during consumption, allows for another
characteristic release of flavor and tactile sensation similar to traditional jelly.
Examples may be fracturing of the gel, not being overly chewy, and a melt-like
breakdown when chewed. Conversely, the gel must also be able to release
sufficiently from the packaging while being opened such that it remains intact as
an integral slice and may be manipulated such that it can be eaten as a snack
or manipulated or applied to another food item prior to consumption. These
aspects then define a range of performance that the slices preferably conform
to, and the formulations and process steps used become an important
consideration.
Viscosity must be carefully controlled for jelly formulations according to
the present invention. Techniques, methods and processes are now disclosed
for doing so. Sugar may be either hydrated as a stock solution, or hydrated in
the cooker with water and steam. Gums may also be hydrated by adding them
directly to high fructose corn syrup followed by heating. With calcium-induced
gelling agents, sugar may be used to disperse the gum. When direct steam is
used, part of the high fructose corn syrup may be replaced partially by dry
sugars. Grape juice may be added after cooking and dissolving of sugars.
Calcium may be added if needed. However, calcium from the juice is often
sufficient for gel formation. Acid may be added last, as is the normal practice.
Low methoxyl pectin and kappa carrageenan are particularly useful in
forming the first gel in the two-step process. The purpose of this first gel is to
create sufficient viscosity to flow through the extruder nozzle with integrity but
without gel structure damage. A second slower gel-forming agent then is
preferably used to firm the gel sufficiently for slice formation, stacking, handling,
and packaging. Slow set high methoxyl pectin, gelatin, Konjac flour, starch or
carageenan are useful in the second gel formation. After the first gel formation,
agitation is reduced to avoid excessive gel breakage. As cooling increases gel
strength and the likelihood of breakage of the gel structure, transfer pipes are
jacketed to reduce heat loss. In addition, excessive shear at lower temperatures
contributes to air incorporation, a cloudy appearance, and poor gel formation.
Some gel structure breakage is normal, but with sufficient secondary gel
formation and shear and temperature control, the final slice develops a uniform,
unbroken structure.
While the preferred jelly and nut butter formulations described below
involve a separate heating step, it will be understood that certain food items,
such as dessert fruit gels, yogurt and fruit slices, etc. gel without the separate
addition of heat, and "cold" extrusion may be provided for this purpose, within
the scope of this invention.
Jelly Example 1 — High Aw Jelly
A grape jelly formulation found useful in the present invention has the
following ingredients:
This formulation corresponds to a traditional type jelly except for the types of
pectins used. Due to viscosity requirements during formation of the slices, the
low methoxyl pectin adds thickness while the jelly is hot and flows well. As the
packages are filled, formed into a slice, and then cooled, the slow set pectin then
provides the proper finished texture in the slice. The two types of pectins are
thought to operate at different temperature ranges, but each may contribute to
the primary viscosity function of the other. The concentrations listed above were
found to be optimal given the cooking, conveying, and extruding systems
described here, but may be modified to conform to a particular forming system
or to different product performance criteria.
It is believed that this jelly formulation of Example 1 could be changed, by
raising the sucrose level to 45% by weight, such that the formulation could
conform to the definition of "fruit jelly" as described in the U.S. Federal Code of
Regulations, § 21 :150.140.
Jelly Example 2 — Low Aw Jelly
Another grape jelly formulation found useful with the present invention,
but which does not conform to the definition of "fruit jelly" as described in the
U.S. Federal Code of Regulations, § 21 :150.140, has the following ingredients:
This grape jelly spread formulation emulates traditional jelly for flavor and mouth
feel while providing a lower water activity with excellent separation and
manipulation qualities. Due to viscosity requirements in making the slices, the
konjac/carageenan mix (Nutricol® DG474, FMC, Inc., Philadelphia, PA)
provides excellent viscosity enhancing properties in a high sugar carbohydrate
environment. The use of high fructose corn syrup and the use of the two
granular sugars at a fixed ratio provide a system of maintaining sweetness while
the amounts of dry and wet sugars may be easily adjusted to compensate for
fruit juice moisture variations. As the packages are filled, formed into a slice, and
then cooled, the slow set pectin then provides the proper set texture in the slice.
The konjac/carageenan mixture and the slow set pectin are thought to operate
at different temperature ranges, but each may also contribute to the primary
viscosity function of the other. Vegetable oil provides enhanced lubricity and
facilitates release from the packaging film. Again, the concentrations listed here
were found to be optimal given the cooking, conveying and extruding systems
described here, but may be modified to conform to differing forming systems or
product performance criteria.
Preferred nut butter formulations
The purpose of the nut butter component of the present invention is to
emulate the sensory characteristics found in the traditional counterpart peanut
butter, i.e., earthiness, oiliness, slightly sweet, slightly salty, roasted peanut-like
flavor. Additionally, texture and the manner in which the nut butter yields to
stress during consumption allows for another characteristic release of flavor and
tactile sensation similar to traditional peanut butter. An example may be the
stickiness while being consumed. Conversely, the nut butter must also be able
to release sufficiently from the packaging while being opened such that it
remains intact as an integral slice and can be manipulated such that it can be
eaten as a snack or applied to bread or toasted bread before consumption.
These aspects then define a range of performance that the slices preferably
conform to, and the formulations and process steps used become an important
consideration.
Several approaches can be taken to produce a nut butter mixture that will
hold its shape in a slice. In the past, for example, this has been done by
combining egg white protein and peanut flour, as described in U.S. Patent No.
5,312,641 to Castillo. An acceptable slice, whether made to be extruded alone
or in combination with jelly, consists of standard peanut butter, peanut flour,
stabilizers, emulsifiers, and salt. A useful stabilizer is hydrogenated vegetable
oil, while useful emulsifiers may include mono and diglycerides. The nut butter
ingredients may be blended at ambient temperature and then heated to 165° F
with indirect steam. However, the water activity of this product is very low, at
between 0.1 and 0.2. High fructose corn syrup is found useful in raising the
water activity to the 0.4 to 0.5 range. The product has good flavor enhanced by
the added sweetness. However, as the product was scaled up for continuous
production, it was found to be particularly sensitive to shear. It is believed that
irreversible protein interactions cause the oil to separate and the remaining
solids to become too firm to pump or handle. This problem is found to be time
and shear dependent. By adding corn syrup just prior to extrusion, it was found
that the viscosity of the nut butter mixture could be controlled and oil separation
could be avoided. Additional robustness during transport is provided by the
addition of emulsifiers. This enables the formation of a combined nut butter and
jelly spread food product in which the nut butter and jelly spread exhibit water
activities within 0.1 unit of each other, thus providing enhanced storage stability.
It is believed that this combined formulation will have a refrigerated storage life
of at least about 3 months or more and, most preferably, about 6 months or
more, even without the addition of food preservatives such as, but not limited to,
sorbates.
Nut Butter Example 1 — Low Aw Nut Butter
A preferred nut butter formulation according to the present invention
which also conform to the definition of "peanut butter" described in the U.S.
Federal Code of Regulations, § 21 :164.150, has the following ingredients:
Peanut flour provides a firmer slice consistency. The stabilizer used is Grindsted
PS 105 K (Danisco Ingredients, New Century, KS, melting point of 165°F), and
is an example of a hard fat that may be used to prevent oiling-off. It has been
found that the addition of such a stabilizer, in about twice the amount normally
found in commercially available peanut butter, helps to firm the slice and to
control oiling-off during slice formation and cooling.
Nut Butter Example 2 — High Aw Nut Butter
A nut butter formulation which forms another preferred embodiment of the
present invention, but which does not conform to the definition of "peanut butter"
as described in the U.S. Federal Code of Regulations, § 21 :164.150, has the
following ingredients:
The peanut flour and stabilizers have the same identity and uses as described
in the nut butter formulation, Example 1 , above. Maltodextrin and high fructose
corn syrup are also added, and provide water to increase the water activity of the
nut butter. The emulsifier Dur-Em 114 (Loders Croklaan Inc., Channahon, IL),
a mixture of mono- and diglycerides, helps to prevent oiling-off during handling.
The salt should be an extremely fine grind (e.g., average sieve size of 140 mesh)
since very little water is available to dissolve a larger granule into solution.
Texture Profile Analysis
Attempts were made to quantify the texture profile analysis/hardness (see
above definition of "hardness") of two preferred peanut butter and jelly
formulations. A peanut butter/jelly laminate slice made according to the
invention was peeled apart and the peanut butter formulation of Example 2,
above, was analyzed using an Instron machine, Model No. 5542, fitted with a
plastic cylindrical plunger probe. The actual surface area of the probe that
impinged on the product was 5.02cm2. The slices of either jelly or peanut butter
were stacked in a square column and the stack's firmness was determined using
the Instron machine. This peanut butter formulation was found to have an
average "hardness" of 1.02 Kg/cm2 (range of 0.5-1.5 Kg/cm2) when the
temperature of the product was 43°F and 48 hours after manufacturing. The
jelly formulation of Example 2, above, was also analyzed in a similar manner and
was found to have an average hardness of 1.84 Kg/cm2 (range of 1.0-2.5
Kg/cm2) when the temperature of the product was 43 °F and 48 hours after
manufacturing.
Preferred Extrusion Techniques
The finished product form is determined by the type and design of
extrusion manifold through which the food components are extruded. The
previously prepared food components are delivered to the extrusion manifold by
means of positive displacement (metering) pumps. A variety of extrusion
manifolds may be employed to manufacture novel forms of the invention. These
will be detailed in the following examples. Potential food configurations of the
food items of the invention include food slices in laminate, striped (straight or
wavy, marbled) or variegated shapes such as a polka-dot formation, as now
described, though it will be understood that other shapes and configurations are,
of course, possible.
Laminates
One preferred form of food slice 30 of the present invention is a bi-
laminate, as shown in FIGURE 2, such that each slice is composed of a single
layer of nut butter 31 adjacent a single layer of jelly 32, with each layer being
continuous and extending to the full planar dimensions of food slice 30. In this
form, the food slice is preferably continuously co-extruded or co-laminated to
create the finished product format in which the proportions of nut butter and jelly
are approximately 50-50 by volume (quantity). Those knowledgeable in the art
will realize that these proportions can be easily adjusted to deliver a wide range
of possible component ratios depending on the desired finished product flavor
attributes. Further, tri-laminates (two nut butter layers surrounding a jelly layer,
for example) or other laminate shapes may be provided.
The preferred extrusion manifold design used to manufacture the
bilaminate slice form, shown in FIGURES 13, 15, 18 and 19, consists of two
flattened tubes, 40, 41 , semi-elliptical in cross section (FIGURE 15), which are
placed with long axes parallel. As shown, in the preferred embodiment shown
in the drawings, when a slice consisting of nut butter and jelly is to be provided,
for example, both nut butter nozzle 40 and jelly nozzle 41 are of approximately
the same length and terminate immediately above flattening belts 37 with ι gripping ribs 37a (see FIGURES 18 and 19). Alternatively, though less
preferably, the flattening belts may have a smooth and flat outer surface. Since
the ribbons are essentially suspended in air as the materials exit the nozzles
there is opportunity for mixing due to normal slight turbulence. A divider plate
43 made of a non-sticking material or coating placed between the two ribbons
for a short distance enables the laminated ribbons to reach the flattening belts
without mixing together, so that the product maintains distinct sidedness.
Preferably, a Teflon®-coated divider plate is used which extends down and
slightly into the flattening belt region, as shown in FIGURES 18-19.
As shown in FIGURE 22, a biasing mechanism may be used to slightly
cant divider plate 43 to one side or the other, to control the relative thickness of
the slices. Fill tube mounting bracket screw 87 mounts fill tubes 40, 41. A
suitable device is biasing mechanism 45, which may include opposed knurled
knobs 45a attached to threaded shafts 47. Shafts 47 are attached to mounts 46,
and the ends of each shaft 47 is in contact with the side of a fill tube. Rotation
of knobs 45a allows the operator to slightly bias divider plate 43 to left or right,
which has been found useful to permit the operator to regulate the relative
thickness of each (e.g.) bilaminate layer, so that the relative proportions of (e.g.)
two products may be varied.
Striped Slices
Another form of the invention is a "striped" slice such that there are
multiple distinct stripes/bands of nut butter and jelly, as shown in FIGURES 1 ,
6, 8, 17 and 21. These stripes may be formed in a distinct manner such that the
border between the adjacent components shows little (or no) mixing between the
two food systems.
The preferred extrusion manifold design used to create this format
consists of multiple parallel tubes, alternating in the food component delivered,
as shown in FIGURES 12, 14, 16 and 17. In a dual component food slice (e.g.,
nut butter and jelly), every other nozzle delivers one component while the
remainder of the nozzles deliver the other food component, as shown in
FIGURES 12 and 17. This creates a continuously striped pattern of extruded
product. Rounded tube openings are satisfactory as long as the tubes are
positioned close enough to the pinch-point of the flattening/slice-forming belts to
minimize mixing and uneven boundary lines when the columns of material are
flattened. Those knowledgeable in the art will realize that the invention need not
be limited to a dual component system, but rather the possible number of
different food components is only limited by the number of distinct nozzles used
in the construction of the manifold. Referring to FIGURE 12, extrusion nozzles
40, 41 are secured by support 53 and pass through film former 58.
Wavy, Marbled Slices
Alternatively, another format of the invention consists of a striped product
in which the border between the adjacent components does not have to be
"straight" or strictly linear but may be an undulating, irregular, swirled, or "wavy"
border, as shown for example in FIGURE 4.
The extrusion manifold used to create this form is the same as that
described above for the "striped slices". In this application, the rate of delivery
and/or the rate of packaging film feed can be manipulated to provide for a less
than smooth supply of food component. The resulting product has stripes which
show some slight mixing and irregularity in the border between components.
Alternatively, this form can be created by employing the manifold
described above for laminate slices, with minor modifications. If the divider plate
is removed from the twin tube manifold, the two food components will mix after
extrusion and, if contrasting in color, will create a "marbled" appearance in the
finished product, as shown in FIGURE 5.
Variegated slice forms (e.g., "polka-dots")
Yet another format of the invention can be described as a continuous
phase in which one of the food components is interspersed within the other in a
variegated format, as in a "polka dot" or other similarly randomized pattern or
dispersion of pockets of the non-continuous phase within the multi-component
food system (e.g., FIGURE 3). The interface between the two or more different
food systems maintains the aforementioned distinctness of border/margin.
The preferred extrusion manifold design for providing this food
configuration consists of a single flattened tube, elliptical in cross-section, into
which one or more smaller diameter tubes are inserted. The continuous phase
of the food slice may be delivered via the larger tube while the interspersed
component(s) may be conveyed via the inner tube(s). Those knowledgeable in
the art will realize that if the delivery rate of the food component delivered by the
smaller internal tubes is pulsed or metered such that it is supplied at a non-
continuous rate while the food component in the outer tube (continuous phase)
is supplied at a continuous rate, the resultant food slice will contain polka dots
(blobs, patches, etc.) of the non-continuous component surrounded (embedded)
in the continuous component. The number and diameter of the inner tubes as
well as the product flow rate through these tubes will determine the number,
size, and distribution of the polka dotted food component within the food slice.
Slice Formation and Packaging
The components of the food slice are delivered directly into packaging film
sleeve 34a during the extrusion process, as best shown in FIGURES 17 and 18.
It is at this point that one of the slice's dimensions (length) is determined. The
length of the finished product may range, for example, from 2.5" to 5.0".
Alternatively, production machinery is available that determines both the length
and the width of the slice at this point. Finished product dimensions may range
from 2.5" x 2.5" to 4.5" x 5.0", for example.
Referring to FIGURE 7, immediately downstream from the extrusion
manifold, the continuous band of filled packaging material passes through
flattening belt portion 37 of packaging machine 25. It is at this point that the
thickness of food slice 30 may be controlled. The thickness may be in the range
from 0.125" to 0.375", for example.
In the preferred embodiment, and referring now to FIGURE 27, a bubble
control device is used to control the amount of product that enters within the
wrapping/packaging film. This devices maintains a consistent weight of food
product for each slice produced by the machine. Food portions are forced
between the two layers of film by a pump which is driven by an electric motor
and controlled by a variable frequency drive (VFD). The control circuit for this
device includes: a VFD; an AC Motor; a linear variable differential transformer
(LVDT), a sensing device which preferably includes a linear moving shaft 115
and a plastic contact plate 120 that makes contact with the film; and a
programmable logic controller (PLC)). The VFD controls the speed at which the
AC motor rotates which, in turn, controls how much product is pumped between
the layers of film. The LVDT has a scaled voltage range; as the linear shaft
moves, the voltage produced by the sensor changes. The food product pumped
between the film layers causes the film to expand or contract depending upon
the amount of product being forced in. This change recognized by plastic
contact plate 120 that is mounted to the LVDT. The expanding and contracting
film causes the LVDT shaft to move, resulting in a different voltage being read.
The PLC is set up with a table to correspond voltage and weight. A set point for
weight is entered into the PLC through an operator interface or "human machine
interface" (HM I) or similar device. The PLC correlates the voltage from the LVDT
to the set point and, based upon the relation, supplies a signal to the VFD which
causes the motor to increase or decrease its speed. This process of "control"
occurs on the fly and is a continuous state of monitoring and adjustment. The
control circuit described above applies to both weight control of food items such
as jelly and peanut butter, for example, and may also be used for other food
products with similar viscosities. Various devices and manufacturers exist which
are useful for this application, including: PLC ( Allen Bradley SLC family or PLC
5 family processor and analog I/O, or equivalent); VFD (Magnetek 515 GPD or
equivalent); LVDT (Lucas Schaevitz SN 8477, part No GCA-121-250); AC
Motor (Baldor 2HP or equivalent size and brand; employs a gear reducer).
After the food slice has been sized to its desired thickness, it may pass
into chilled water bath 50, as shown in FIGURES 7 and 20, where it may be
cooled. The temperature of this cooling bath determines the product handling
characteristics later in the process. Those knowledgeable in the art will realize
that the preferred bath temperature and corresponding finished product
temperature is dependent upon the bath temperature and the amount of time the
product is exposed to this temperature (residence time is proportional to line
speed/throughput). The target temperature of a combined nut butter/jelly
product, for example, as it exits the cooling bath is found to be optimal when it
is in the range of about 50°-70°F. Other combined food products may require
different cooling periods or, alternatively, ambient temperature cooling may be
sufficient. A suitable roller system is provided for facilitating use of film 34 and
the passage of ribbon 33 through the preferred individual wrap slice machine, as .
partially shown in FIGURES 20, and as well known.
Referring to FIGURE 7, after the wrapped ribbon 33 of product is cooled,
the continuous web of packaging material encased product may pass through
gripping belts 55a, and then through cleated drums 60a, 60b and 60c, where the
cross-seals may be pre-crimped and heat sealed, as disclosed in the Meli '792
patent. A second pair of gripping belts 55b and suitable rollers, such as roller
63, may be used to maintain tension on, pull and guide the web downstream of
the cross-sealing drums. Alternatively, cross-sealing may be accomplished with
a single cross-sealing mechanism, and prior to cooling, as disclosed in the Meli
'860 patent.
The cross-seals may then be cut laterally to separate each individual food
portion from the previously continuous web of product. The individual food
portions, such as food slices, may then be conveyed to a stacking machine
which counts, stacks, and prepares the product for its overwrapping, as for
example is disclosed in U.S. Patent No. 5,114,307. A suitable overwrap may be
provided to a predetermined number of the already packaged food slices, such
as by using a Hayssen overwrapper.
The individual food slices, thus packaged and sealed in a flexible plastic
wrap, may have a longitudinal seal and cross-seals which are hermetic, as
disclosed in the Meli '860 patent, but which need not be. Either overlapping
("lap") or fin/side seals may be provided for this purpose, as shown in FIGURES
25 and 26. The provision of one seal type or the other is well known to those
skilled in the art, depending upon the equipment used. For example, longitudinal
sealer 36 shown in FIGURE 27 has a single bar riding against a facing stationary
plate and produces a lap seal, while the longitudinal sealer with undulating
opposed plates, disclosed in the Meli '860 patent, produces a fin seal. Each seal
type has advantages. For example, lap seals tend to provide the consumer with
a seal having a more conventional appearance. Fin seals allow the package to
be delaminated and the sometimes sticky product removed without the necessity
of the consumer actually touching the food item during opening.
The use of high oxygen barrier packaging films is preferred. A suitable
innerwrap film structure is a 1.5 mil thick multi-layer cast film that has a base
layer made out of polypropylene, a layer of ethylene vinyl alcohol that provides
a good oxygen barrier to prevent oxidation of the food product, and outside
sealant layers made out of a blend of polypropylene, low density polyethylene,
polybutylene and a glycerol mono stearate release agent. An example of this is
a Printpack Inc. packaging film known as Specification No. 98506. It was found
that the presence of peanut oil in the nut butter interferes with the formation of
cross-seals. To overcome this problem, a more aggressive film sealant, such as
found in this Printpack film, is preferably used.
Regulating Water Activity For Jelly/Peanut Butter Slice Formulation
In order to maximize shelf life, water activity of one or more of the food
items is modified. Water activity is a prediction of how moisture differences
between two or more dissimilar products will equilibrate over time. If excessive
moisture migration takes place, discoloration and flavor degradation can occur.
A measure of potential water migration can be determined from water activity,
Aw, as defined earlier. The range of water activity is from 0.00 to 1.00. An
example of a low water activity food is whole milk powder, Aw = 0.20, while an
example of a high water activity food is Cheddar cheese, Aw = 0.90. Traditional
peanut butter has an Aw of about 0.20, while jelly has an Aw of about 0.85.
According to the present invention, the food items to be packaged are preferably
modified to bring their water activities to within acceptable ranges such as, for
peanut butter and jelly, about 0.5 units of each other or less or, most preferably,
within about 0.1 to 0.2 units of each other, which is believed to be an acceptable
amount for achieving combinations of such food items with a stable shelf life and
without excessive discoloration or flavor degradation.
Additional process considerations apply to jelly used with a combination
nut butter/jelly slice product than those which apply when jelly is processed
alone. Thus, there is also a need to control the water activity within such a slice,
to lengthen shelf life, limit product discoloration, etc. Preferably, the water
activity in the jelly is lowered to about 0.6, which is about 0.1 to 0.2 more than
the water activity of the nut butter. However, it has been found that the
preferred jelly formulations described here, when used with the preferred nut
butter formulations described here, provide adequate control over water
migration- related discoloration defects even when the differences between the
water activities are about 0.4 to 0.5.
Preferred Processing Techniques For Nut Butter/Jelly Formulations
Processing techniques for preferred nut butter and jelly spread
formulations to be combined into a combined food slice are now described in
detail.
The nut butter formulation of Example 2, above, is prepared as follows.
Referring to FIGURE 24, peanut butter, maltodextrin, peanut flour, salt,
stabilizer, and the emulsifier are combined in a suitable open mixing vessel 90,
such as a twin screw Reitz cooker with counter-rotating mixing augers 91 , as
shown. Augers 91 may betuming at approximately 60 RPM. These ingredients
are folded together and allowed to mix until the mass achieves a homogenous
appearance. The mixture is then heated to 170°F using the steam injection
jacket of the cooker and with the same mixing conditions. The mixture
temperature should be monitored as it approaches the desired temperature
since the indirect heat will continue to heat the product even after the steam is
turned off. In practice, the steam heat is discontinued once the temperature
reached 162 °F.
Once the peanut butter slurry is heated to the target temperature, the
auger rotation rate is slowed to approximately 10-20 RPM. At this time, the high
fructose corn syrup (HFCS) is added to the mixture and combined with the same
slow agitation. It is important that the amount of mixing the nut butter and HFCS
combination receives is only enough such that the two are commingled until just
homogeneous. If additional shear (mixing) is supplied, there is a risk that the
emulsion formed by the nut butter and HFCS will be broken and the result will
be a sticky mass which will freely exude peanut oil. (Conversely, too little mixing
results in non-uniformity of a product that will not separate cleanly from the
packaging material and will be variable in terms of flavor (sweetness) and
texture.) Once the nut butter and HFCS have been combined, the mixture is
removed from the cooker and transferred to a hot water jacketed static hopper
atop the pump used to supply the nut butter to the extruder. The jacket
temperature of the hopper is preferably maintained at between about 110°-
140°F. The jacketed hopper serves as the reservoir for the finished nut butter
immediately prior to the extrusion process.
It was discovered that the addition of HFCS to peanut butter must be
delayed until just prior to extrusion. Conversely, adding corn syrup early in the
mixing process results in an unpumpable grainy mass with separated oil. It is
believed that the water added to the mixture via the HFCS is partitioned with
HFCS during initial mixing stages. Through heat, diffusion and some degree of
shear during conveyance, a portion of water eventually finds its way to and
adheres to the proteins. The rate of adherence of the water to proteins, and the
resulting textural change, takes time based on these variables. Proteins are
used as part of the emulsion system when found in the low moisture
environment of peanut butter. The proteins aid in holding the peanut oil in
suspension. When presented with eitherwater or oil, the peanut proteins prefer
water. The eventual movement of the water to the proteins then provides some
of the textural attributes found in the finished nut butter slice, but this occurs after
the slice has been formed due to a delayed movement of water bonded on the
HFCS molecules to the protein molecules. It is interesting to note that the
addition of pure water to the nut butter has the almost immediate effect of
providing a very heavy, grainy body that also exhibits oiling-off when mixed or
pumped. The finished nut butter product, made with a late HFCS addition and
having a water content at a high level, does not noticeably become heavy and
grainy. This is believed due to the partition delay in using the HFCS when being
pumped and extruded under high shear and the micro shear environment of slice
cooling and subsequent slice handing. There is also some degree of continued
textural changes in the finished slice for up to about 12 hours. In short, the nut
butter should be given time to set and form its shape before water in the HFCS
is added to it.
It will become readily apparent to those skilled in the art that heated nut
butter, containing only ingredients found in commercially available product that
are filled into jars, will become firm as the temperature cools and the emulsion
has time to set up due to crystallization of fat and other interaction not entirely
know about the food system. It is believed that the interaction of water with
peanut protein in the nut butter formula with the added HFCS enhances texture
and cohesiveness so that the nut butter formulation approximates commercially
available counterparts; this, despite the fact that the addition of added sugars,
bulking agents, etc. would predict a textural interruption and a resulting softened
body.
Alternatively, as opposed to the batch processing steps just described,
the nut butter may be made in a continuous fashion by using a scraped surface
heat exchanger (SSHE) and an alternate means by which the HFCS is added.
In this case, and referring now to FIGURE 23, the initial ingredients added to the
Reitz cooker can be combined in the form of a premix. This premix may be
prepared by mixing these ingredients in a mixing vessel, such as hopper 62,
without heat but with sufficient mixing to insure that all ingredients are well
combined. In practice, the preferred apparatus for this purpose is a twin screw
Reitz cooker, although those knowledgeable in the art will realize that there are
many other means by which the peanut butter premix ingredients could be
combined, such as by using in-line mixing elements, low shear planetary mixers,
vessels/equipment containing augers, or other mixing elements.
The peanut butter premix thus prepared is then cooked via a SSHE using
indirect heating. In practice, a Contherm® SSHE with 4 of the 12 internal mixing
blades in place and a shaft rotational rate of approximately 120 RPM was used
to heat the mixture to 175 + 5 °F. The heated product is then pumped to mixing
vessel/use hopper 65, which also has the recently cooked nut butter with the
desired amount of HFCS. In practice during pilot-scale experiments, the
preferred mixing vessel used was a 45-pound capacity twin screw Reitz
blender/cooker 90, as shown in FIGURE 24 (length, 18"; width: 15.25"; depth:
12"; auger diameter: 7.75") with a variable speed controller to regulate the RPM
of auger 91 although, again, those knowledgeable in the art will realize that
many different mechanical means could be used for this purpose. The HFCS
may be added to a corner of the cooker shown in FIGURE 24, for example, while
the heated nut butter may be added in the middle of the cooker, between the two
augers and about 6-inches back from the front face, for example.
The heated nut butter and HFCS are allowed to mix such that the two
streams are adequately combined, although not so much that the combination
begins to appear "grainy", as this is an indication that the stability of the product
(emulsion) is being compromised. The exact mixing/auger rotation rate and
residence time in the mixer is dependent upon the flow rates of the two streams
and the level within the mixing vessel. The extent of agitation is controlled
visually to prevent deleterious over-mixing. As in the previous procedure, once
the nut butter and HFCS are adequately combined, the mixture is transferred to
a (jacketed) static hopper located atop the pump used to supply the nut butter
to the extruder.
Still referring to FIGURE 23, preferred processing steps for preparing
a jelly formulation according to Example 2, above, begin with the addition of
the HFCS to twin screw Reitz cooker 67. With the augers turning at
approximately 150 RPM, the crystalline fructose, glucose (dextrose), konjac
flour/carageenan blend (e.g., Nutracol® DG474) and pectin are added. These
ingredients are allowed to mix until thoroughly combined, which takes about 1 -
5 minutes (preferably about 3 minutes). The mixture is then cooked, preferably
for about 6 minutes, with the augers still turning at about 150 RPM. Cooking
is achieved by injecting low-pressure live steam into the mixer using the
standard steam injection vents of the Rietz cooker such that the sugars and
hydrocolloid slurry are brought to 200 °F. Once this temperature is reached,
the consistency of the slurry is examined to insure that there are no lumps or
undissolved/undispersed particles. If there are such particles, the slurry is
allowed to mix until they are reduced. The cooker is then opened, and the
augers are slowed to low speed and scraped (about 1 minute). At this point,
the liquid vegetable oil, fruit juice concentrate and citric acid are added to the
mixture. These last components are allowed to mix (about 1 minute) until
homogeneously distributed.
The finished jelly is then transferred to another twin screw Reitz cooker
70 where it is held with slow agitation (10-20 RPM) and with indirect heat
supplied by the cooker's jacketing such that the product remained at
approximately 150°F. Alternatively, any jacketed scraped surface or agitated
mixing vessel may be employed for this purpose. When the jelly is ready for
use, it is transferred from the cooker to the (jacketed) hopper atop the pump
used to supply the jelly to the extruder. To overcome the tendency of the
product to gel when cooled without agitation, only small amounts are
transferred to the hopper at a time. In practice, for pilot-scale experiments, the
hopper had an approximate capacity of 25 gallons. It has been found practical
to limit the amount of jelly in the hopper at any time to 15-20 gallons. This
allows the temperature of the jelly to remain in the 130-150 °F temperature
range and permits a more rapid turnover of product in the hopper. The jelly in
the hopper is kept agitated by means of a manually operated paddle which is
used to stir the product during use and as additional material is added to the
hopper.
Alternatively, the jelly may be prepared without the use of direct steam
injection. Although a slower process, indirect heat supplied by a steam jacket
on the cooker has been found adequate for cooking the jelly component.
Using this technique, all of the water supplied by the steam condensate
(previously described method) must be added directly to the batch in order for
the desired moisture and solids content to be achieved.
With calcium-induced gelling agents, sugar may be used to disperse the
gum. To aid with dispersion, solubalization, and activation of the gelling
agents, the mixture should be heated, during a mild to moderate degree of
shear produced from agitators, to about 200 °F and held there for about 0.5 to
2.0 minutes. When direct steam is used, part of the high fructose corn syrup
may be replaced partially by dry sugars. Following this heating step, the
mixture can then be cooled to a temperature which will provide desired
extrusion viscosity. Grape juice may be added afterthe cooking and dissolving
of sugars and gelling agents. Color shelf stability may be increased by
minimizing heating of the juice; thus, the juice may be added cold to the 200
°F cooked mixture, which immediately drops the temperature of the overall
mixture by about 40 °F. Calcium may be added as needed.
Once both peanut butter and jelly components have been staged for
extrusion, the formation and packaging of the food slices begins. The product
format - whether of the laminate or striped design, for example - is determined
by the extrusion manifold. In the case of the laminate, it has been found to be
easiest to begin extruding nut butter only for the initial process start-up. Once
the extruder and packaging equipment are stabilized, the jelly stream is added
via its extruder nozzle into the product. In the case of the striped format, each
individual extruder nozzle is supplied by its own positive displacement pump.
However, all of the nut butter nozzles and all of the jelly pumps may be
supplied by a common hopper containing their respective food component. It
has been found to be easiest to start the flow of product through all of the
nozzles simultaneously and at a low initial rate. Once the continuous web of
extruded/packaged product is running through the equipment, the desired ratio
of components and individual slice weight may be adjusted.
The ratio of nut butter and jelly and the weight of the finished slice may
be controlled manually on the pilot plant scale experimental equipment. For
the laminate format, the preferred product design is approximately 50% (by
volume) nut butter and 50% (by volume) jelly in the food slice, with a total slice
weight of approximately 1.2 ounces. For the striped format, the ratio of peanut
butter to jelly is more variable and is dependent upon the number of extruder
nozzles for each component and the width of each individual stripe; however,
the target slice weight is still approximately 1.2 ounces.
Actual extrusion parameters are subject to the production rate of the
food slices. In general, the extrusion process conditions are such that the
preferred line pressures at the extruder manifold range from approximately 25-
60 psi for nut butter and 20-50 psi for jelly. Pressures are also subject to line
diameter, product temperature (viscosity) and desired throughput rates.
During extrusion, film 34 passes over forming shoulder 58, as shown in
FIGURE 16, and may be longitudinally sealed using a heated bar, for example,
as disclosed in the 'Meli '860 or '792 patents. Immediately following post-
extrusion, longitudinal sealing of the film and flattening of the slice, the
continuous web of product may be conveyed through a water-filled cooling
bath. In practice, for the nut butter/jelly slice formation, the temperature of this
bath has been approximately 60 °F; however, this is also dependent upon
production rates. The temperature of the bath can be important because it
causes the liquified fats in the nut butter to solidify and the hydrocolloids in the
jelly to gel. As a result, the slice develops a certain "body" and rigidity which
aids in later conveyance and packaging. Faster production rates necessitate
a lower cooling bath temperature or more residence time in the bath to provide
the same cooling effect and textural development. Of course, alternatively,
cooling may follow cross-sealing.
After cooling and extrusion, the continuous web of product, in the
preferred embodiment, may be conveyed through to and through a pre-crimp
apparatus (e.g., belts with ribs, for example) which marks the web such that
individual slices can be formed. In one preferred cross-sealer disclosed in the
Meli '792 patent, the web continues through a series of heated sealing bars
which serve to heat-seal and melt the sides of the plastic packaging film
together in register with the previously formed pre-crimp demarcation. The
temperature required for adequate sealing is dependent upon production rates,
as this determines the amount of residence time the web has on the heated
sealing bars and the amount of time available to form the seal. The
temperature required is also dependent upon the type of packaging film
employed. In practice, pilot plant experimental equipment has been run at
nominal production rates with heater bar temperatures in the range of 280 to
320°F. After the cross-seals are formed, the slices may be cut on the seal
such that the edges of neighboring slices remain sealed and yet exist as
individual slices as opposed to a continuous ribbon. These individual slices
may then be conveyed to machinery which counts/weighs the slices and stacks
them in preparation for a packaging film over-wrap. Once the slices are so
packaged, they can be further packaged into the desired container for shipping
or storage.
Recent technology has been developed, using films with relatively low
sealing temperatures, which seal without the use of external heat, but rather
use the heat of the food product for sealing the film, as disclosed in pending
U.S. Serial No. 09/323,766, filed June 1 , 1999, titled "Product, Apparatus, And
Film For Sealing Food Products Such As Processed Cheese Slices", hereby
incorporated by reference. It is envisioned that this technology may also be
used to make wrapped food portions according to the present invention.
Food portions such as food slices consisting of two or more different
food items may also be provided using casting equipment, as now described.
Such a process that could provide thin layers of nut butter upon jelly, or vice
versa, could use a continuous cooling steel belt or drum. The food items could
be fluidized through heating and then extruded upon the belt or drum with the
aid of manifold orifices. The further flattening and shaping of the food item into
a sheet could then be accomplished through the use of secondary rollers. It
is also conceivable that two or more food items could be coextruded at roughly
the same time upon such a surface to provide a multi-layered food sheet. The
multi-layer item could then be cut after cooling when the product has achieved
enough integrity to enable cutting and further conveyance for wrapping as
either a single serving or as a multi- serving package typical of food service
applications. Additionally, the food items could be coextruded upon a flexible
film which is covering the continuous steel belt or drum. Having the food items
already deposited upon the film would aid with further conveyance and
wrapping.
There are drawbacks to casting methods, however. It has been shown
through extensive historical work using process cheese that this casting
method requires food items having more hardness and elasticity than food
items useable with the coextruded method provided by the modified individual
wrapping machines described above and in the Meli '792 or '860 patents, for
example. For this reason, it is important that the layered food item attempt to
closely approximate the textural and organoleptic attributes of the traditional
food items. Experiments actually performed by the inventors show that harder
and more elastic formulations than the nut butter and jelly described here are
needed when tested within the current capabilities of existing casting
equipment. Additionally, the casting method historically has a higher level of
unsalable rejected product and therefore presents a higher percentage of the
food items as a recycle issue.
A food portion, such as a food slice, made according to the present
invention may be consumed at ambient room temperatures, and need not be
frozen. The food slice, while at room temperatures, may also be readily,
manually removed from its wrapper without compromising, or substantially
compromising, its integrity, such as its texture and shape characteristics, and
while retaining, or substantially retaining, same. Films of the type described
here also provide non-stick surfaces which facilitate release of the food
product. Of course, maintaining the food slice at refrigerated temperatures will
obviously lengthen its shelf life.
To optimize release of the food portion from the packaging film, varying
amounts of setting times following extrusion of the food portions may be
preferred, depending upon the food item formulations used and processing
techniques employed. However, food portions formulated and made according
to the present invention are consumable immediately following extrusion, and
no further mixing or cooking steps are necessary, though they may be
employed.
It will be understood that the processing techniques described here for
providing a food portion or food slice of nut butter and jelly may need to be
modified if other food items are combined. However, the information provided
here is believed sufficient to allow those of skill in the art to provide a variety
of combined, packaged food products.
The above description is not intended to limit the meaning of the words
used in the following claims that define the invention. Rather, it is
contemplated that future modifications in structure, function or result will exist
that are not substantial changes and that all such insubstantial changes in
what is claimed are intended to be covered by the claims.
Claims
1. A process for continuously preparing food portions consisting of
two or more different food items wrapped in a flexible film, comprising the steps
of:
separately pumping each of the two or more food items to an
extrusion
location;
extruding each of the food items and combining them into the
food portion, wherein the combined food items within the food portion retain
their individual product identity; and
wrapping the food portion within the flexible film and sealing each
food
portion within the wrapper.
2. The process of Claim 1 , wherein the water activity of at least one
of the
food items is modified in a predetermined manner by the addition of sugar.
3. The process of Claim 1 , wherein the food portions comprise food
slices
which are sufficiently cohesive to permit manual removal of the food slice from
the sealed wrapper while retaining textural and shape characteristics of the
slice.
Claims (1)
- 4. The process of Claim 1 , wherein the food portions arehermetically sealedwithin their wrappers.5. The process of Claim 1 , wherein the food portions compriseslices and the food items comprise nut butter and jelly.6. The process of Claim 5, wherein the jelly comprises first andsecond thickeners, the first thickener causing the jelly to have a viscosity ofless than about 5,000 centipoise during its extrusion, and the second thickenercausing the jelly to have a viscosity of greater than about 100,000 centipoisefollowing extrusion of the jelly and after setting of the second thickener.7. The process of Claim 5, wherein the water activity of the jelly isreducedby the addition of sugar.8. The process of Claim 5, wherein the water activity of the nutbutter is increased by the addition of sugar.9. The process of Claim 5, wherein a hard fat is added to the nutbutter.10. The process of Claim 5, wherein the nut butter comprises, byweight, about50 - 90% peanut butter; 1 - 40% peanut flour; 0.5 - 5% stabilizer; 0 - 10%sucrose; and 0 - 2% salt.11. The process of Claim 5, wherein the nut butter comprises, byweight, about40 - 85% peanut butter; 0-10% peanut flour; 0-10% maltodextrin; 0-40% cornsyrup; 0.5-5.0% stabilizer; 0.5-4.0% emulsifier; 0.1-3.0% salt; 0-35% fructose;0-20% dextrose; and 0-40% water.12. The process of Claim 5, wherein the jelly comprises, by weight,about 5 - 20% fruit juice; 0.5- 5 % high methoxyl pectin; 0.5- 5% low methoxylpectin; 0.1 - 3% acidulants; and 0 - 2.5% vegetable oil.13. The process of Claim 5, wherein the jelly comprises, by weight,about 5 - 20% fruit juice; 20-40% corn syrup; 15-35% fructose; 5-20%dextrose; 0.25-4.0% konjac flour; 0.05-2.0% carrageenan; 0.5-4.0% highmethoxyl pectin; 0.1-3.0% citric acid; and 0-2.5% vegetable oil.14. The process of Claim 1 , wherein the food portions compriseslices and two or more generally planar-shaped extrusion nozzles are used to provide alaminate food slice.15. The process of Claim 14, wherein one or more divider plates areused tobriefly maintain separation of the food items immediately following theirextrusion.16. The process of Claim 15, wherein the one or more divider platesarecoated with a substance having a low coefficient of friction.17. The process of Claim 16, wherein the one or more divider platesarecoated with Teflon®.18. The process of Claim 1 , wherein the food portions comprise foodslices which are continuously sealed and wrapped at a rate in excess of 300slices/minute.19. The process of Claim 18, wherein the food slices arecontinuouslysealed and wrapped at a rate in excess of 700 slices/minute.20. The process of Claim 18, wherein the food slices arecontinuouslysealed and wrapped at a rate in excess of 1 ,000 slices/minute.21. The process of Claim 1 , wherein sensing mechanisms areemployed tomaintain or regulate weights of each of the two or more food items.22. The process of Claim 1 , wherein the amounts of each of the twoor morefood items within a food portion are maintained within predetermined ratios.23. The process of Claim 21 , wherein the sensing mechanismcomprise massflow meters, transducers and level sensors.24. The process of Claim 1 , further comprising the step of heatingone or moreof the food items into a soft, molten mass prior to their extrusion.25. The process of Claim 1 , wherein the food items are oriented inan alternating, generally stripe-shaped pattern within the food portions.26. The process of Claim 1 , further comprising a plurality of adjacentextrusion nozzles.27. The process of Claim 1 , further comprising two or moreconcentricextrusion tubes for extruding the food items in a variegated format.28. The process of Claim 1 , wherein the wrapped food portion hasa refrigerated shelf life of greater than about six months.29. The process of Claim 1 , further comprising the step of coolingthe foodportions following extrusion.30. The process of Claim 5, wherein the hardness of the nut butterwithin thefinished food slice is in the range of about 0.25-4.0 Kg/cm2 at 43 °F.31. The process of Claim 5, wherein the hardness of the jelly withinthe finishedfood slice is in the range of about 0.25-4.0 Kg/cm2 at 43°F.32. The process of Claim 1 , further comprising the step of separatelymixingingredients for each of one or more of the food items prior to the pumping step.33. The process of Claim 10, wherein the nut component of the nutbutter iscreated by combining nut flour with an edible oil.34. The process of Claim 6, wherein the first and second thickenerseachcomprise gels.35. The process of Claim 1 , wherein the extrusion step is performedcontinuously.36. The process of Claim 1 , wherein the at least one of the fooditemscompletely surrounds another of the food items within the wrapped foodportion.37. The process of Claim 1 , wherein the food portion is consumableimmediately following extrusion.38. A process for continuously preparing food portions consisting oftwo or more different food items wrapped in a flexible film, comprising the stepsof:heating at least one of the two or more food items to a soft,molten mass;separately pumping each of the two or more food items to anextrusionlocation;extruding each of the food items and combining them into thefood portion, wherein the food items maintain their individual product identityand organoleptic attributes; andwrapping the food portions within the flexible film and sealingeach food portion within the wrapper.39. The process of Claim 38, wherein the extrusion step isperformedcontinuously.40. A process for continuously preparing conformed food slicesconsisting of nut butter and jelly wrapped in a flexible film, comprising the stepsof:heating the nut butter and jelly; separately delivering each of the heated nut butter and jelly to anextrusionlocation;coextruding the nut butter and jelly so that each is combinedwithin eachfood slice; andwrapping the coextruded food slices within the flexible film andsealing eachfood slice within the wrapper.41. The process of Claim 40, wherein the nut butter and jelly withineach foodslice retain their individual product identity and organoleptic attributes.42. The process of Claim 40, wherein the food slices are sufficientlycohesive to permit manual removal of the food slice from the wrapper whilesubstantially retaining textural and shape characteristics of the slice.43. The process of Claim 40, wherein the food slices arehermetically sealedwithin their wrappers.44. A food slice wrapped in a flexible film, comprising: nut butter and jelly whose product identity and organolepticattributes are each individually maintained within the slice;the food slice being sufficiently cohesive to permit manualremoval from thefilm while substantially retaining textural and shape characteristics of the slice;wherein the nut butter comprises, by weight, about 40-85%peanut butter;0-40% peanut flour; 0.5-5.0% stabilizer; 0-10% sucrose; 0-3.0% salt; 0-10%maltodextrin; 0-40% high fructose corn syrup; 0-35% fructose; 0-20% dextrose;and 0-40% water.45. A food slice wrapped in a flexible film, comprising:nut butter and jelly whose product identity and organolepticattributes are each individually maintained within the slice;the food slice being sufficiently cohesive to permit manual- removal from thefilm while substantially retaining textural and shape characteristics of the slice;wherein the jelly comprises, by weight, about 40-55% sucrose;5- 20% fruitjuice; 1-5% high methoxyl pectin; 1 - 5% low methoxyl pectin; 0.1-3% citricacid; 0-2.5% vegetable oil; 0-40% high fructose corn syrup; 13-35% fructose;5-20% dextrose; 0.25-4% konjac flour; and 0.05-2% carrageenan.46. The wrapped food slice of Claim 45, wherein the jelly comprises,by weight,about 20-40% high fructose corn syrup.47. The wrapped food slice of Claim 44, wherein the nut buttercomprises, byweight, about 0-40% high fructose corn syrup and the jelly comprises, byweight, about 20-40% high fructose corn syrup.48. The wrapped food slice of Claim 44, wherein the water activity ofone or both of the nut butter and jelly is modified in a predetermined manner.49. The wrapped food slice of Claim 44, wherein the differential wateractivity of the nut butter and jelly within the wrapped food slice is less than about 0.5.50. The wrapped food slice of Claim 44, wherein the differential wateractivity of the nut butter and jelly within the wrapped food slice is less thanabout 0.2.51. The wrapped food slice of Claim 44, wherein sugar is used toincrease the water activity of the nut butter to a predetermined level or to decrease thewater activity of the jelly to a predetermined level.52. The wrapped food slice of Claim 44, wherein the food slice ishermetically sealed within the flexible film.53. The wrapped food slice of Claim 44, wherein the flexible filmcomprises polypropylene having an ethylene vinyl alcohol oxygen barrier layerand one or more sealant layers comprising polypropylene, polyethylene andpolybutylene.54. The wrapped food slice of Claim 44, wherein the flexible filmcomprises polypropylene and a glycerol monostearate release agent.55. The wrapped food slice of Claim 44, wherein the wrapped foodslice has a refrigerated shelf life of greater than about three months.56. The wrapped food slice of Claim 44, wherein the wrapped foodslice has a refrigerated shelf life of greater than about six months.57. The wrapped food slice of Claim 44, wherein the wrapped foodslice includes food items to which food preservatives have not been added,and has a refrigerated shelf life of greater than about six months.58. The wrapped food slice of Claim 44, wherein the hardness of thenut butterwithin the finished food slice is in the range of about 0.25-4.0 Kg/cm2 at 43 °F.59. The food slice of Claim 44, wherein the hardness of the jellywithin thefinished food slice is in the range of about 0.25-4.0 Kg/cm2 at 43°F.60. A process for continuously preparing food portions consisting oftwo ormore different food items wrapped in a flexible film, wherein the food itemsmaintain their individual product identity, comprising the steps of:preparing each of the two or more different food items;separately delivering each of the two or more food items to anextrusionlocation;continuously coextruding the food items and combining them intothe foodportion; andwrapping the food portion within the flexible film and sealing eachfoodportion within the wrapper.61. A process for continuously preparing food portions consisting oftwo or more different food items wrapped in a flexible film, wherein the fooditems maintain their individual product identity, comprising the steps of:preparing each of the two or more different food items;continuously depositing each of the two or more different fooditems upon a sanitary surface;combining the two or more different food items into the foodportion, wherein each of the two or more different food items retain theirindividual product identity and organoleptic attributes; andwrapping the food portion within the flexible film and sealing eachfoodportion within the wrapper.62. The process of Claim 61 , wherein the sanitary surface is coveredwith theflexible film.63. A process for continuously preparing coformed food slicesconsisting of nutbutter and jelly wrapped in a flexible film, comprising the steps of:heating each of the nut butter and jelly;delivering each of the heated nut butter and jelly to an extrusionlocation; continuously coextruding the nut butter and jelly;filling the coextruded nut butter and jelly within the flexible film;longitudinally sealing the film using one or more longitudinalsealing bars;forming the filled film into a slice-shaped form either before orafterlongitudinal sealing of the film;sealing the film at cross-sealing locations; andcooling the filled film either before or after cross-sealing of thefilm;to thereby provide food slices each of which contain the nutbutter and thejelly, the food slices being wrapped and sealed within the flexible film.64. The process of Claim 63, wherein the food slice, while at ambientroomtemperatures, has sufficient cohesiveness such that it may be manuallyremoved from its sealed wrapper while substantially retaining the textural andshape characteristics of the slice.65. The process of Claim 63, wherein the food slices are hermeticallysealed within the flexible film.
Applications Claiming Priority (3)
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|---|---|---|---|
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| US09/609,016 US7060311B1 (en) | 2000-06-30 | 2000-06-30 | Method for packaging a composite food portion |
| PCT/US2001/016660 WO2002001972A2 (en) | 2000-06-30 | 2001-05-22 | Food slice consisting of two or more food items, and processes for making and packaging same |
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| AU2006201432A Division AU2006201432A1 (en) | 2000-06-30 | 2006-04-05 | Food portion consisting of two or more food items, and processes for making and packaging same |
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| AU2001264846A1 true AU2001264846A1 (en) | 2002-04-11 |
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| EP (1) | EP1301094A2 (en) |
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-
2000
- 2000-06-30 US US09/609,016 patent/US7060311B1/en not_active Expired - Fee Related
-
2001
- 2001-05-22 EP EP01939316A patent/EP1301094A2/en not_active Withdrawn
- 2001-05-22 MX MXPA02012552A patent/MXPA02012552A/en unknown
- 2001-05-22 RU RU2003100405/13A patent/RU2278066C2/en not_active IP Right Cessation
- 2001-05-22 WO PCT/US2001/016660 patent/WO2002001972A2/en not_active Application Discontinuation
- 2001-05-22 CA CA002414667A patent/CA2414667A1/en not_active Abandoned
- 2001-05-22 PL PL01365172A patent/PL365172A1/en not_active Application Discontinuation
- 2001-05-22 AU AU2001264846A patent/AU2001264846B2/en not_active Ceased
- 2001-05-22 AU AU6484601A patent/AU6484601A/en active Pending
- 2001-05-22 BR BR0112113-8A patent/BR0112113A/en not_active IP Right Cessation
- 2001-05-22 SK SK110-2003A patent/SK1102003A3/en unknown
- 2001-05-22 NZ NZ523658A patent/NZ523658A/en unknown
- 2001-05-22 JP JP2002506608A patent/JP2004501662A/en not_active Withdrawn
- 2001-05-22 CZ CZ2003221A patent/CZ2003221A3/en unknown
- 2001-05-22 CN CN01812024A patent/CN1458826A/en active Pending
-
2005
- 2005-03-28 US US11/091,798 patent/US20050170053A1/en not_active Abandoned
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