Patent Application
20080038443
Provided herein is an exemplary process for producing frozen potato products having reduced trans-fat levels comprises the steps of providing a stable frying oil with an 18:3 ratio of <2 wt % and a trans-fat level of <3 wt %; par frying potatoes in the blend to produce potato products; and freezing the potato products to produce frozen potato products having reduced trans-fat levels, wherein ≧50% of the oil remaining in and on the frozen potato products freezes at temperatures ≧10° F.
Additionally, provided herein is an exemplary process for preparing potato products having reduced trans-fat levels by providing a blend of sunflower oil and a second oil selected from the group consisting of cottonseed oil and palm oil. By providing a combination of sunflower oil and a second oil, reduced trans-fat as well as reduced clumping of frozen potato products can be achieved.
As used herein, “crystallization temperature” is intended to include an approximate temperature at which crystallization of a liquid begins. In other words, the crystallization temperature of an oil is the warmest temperature at which crystals begin to form in the oil rather than the colder temperature in which the entirety of the oil has crystallized.
As also used herein, a “low” crystallization temperature oil is intended to include oils which crystallize at temperatures below the temperatures reached in a freeze tunnel (e.g., about 10° F. to about 25° F.). On the other hand, “high” crystallization temperature is intended to include oils which crystallize at temperatures which are above those temperatures reached in a freeze tunnel.
Sunflower oil has very low saturated levels and approximately 0 grams trans-fat; however, sunflower oil has a low crystallization temperature of about 5° F. Thus, temperatures of exemplary freeze tunnels in the range of about 10° F. to about 25° F. would not freeze or solidify the sunflower oil, and the sunflower oil remains liquid when exiting the freeze tunnels. In other words, sunflower oil only freezes at lower temperatures, such as that provided in frozen storage at temperatures of about 0° F. This freezing, as mentioned above, causes the sunflower oil to freeze while the potato products are under weight-bearing pressure, and thus causes clumping during frozen storage.
One exemplary sunflower oil is NuSun™, which is registered by The National Sunflower Association. NuSun™ sunflower oil is stable without partial hydrogenation. NuSun™ oil is a mid-oleic sunflower oil with lower levels of saturated fat (less than 10%) than linoleic sunflower oil and with higher oleic levels (55-75%) (the majority of the remainder being linoleic (15-35%)), along with the zero trans-fat that is provided by other sunflower oils. Compared to conventional sunflower oil, it is noted that NuSun™ provides superior stability for frying (i.e., less oil breakdown and thus less off-flavoring by the oil) because of its higher oleic levels and lower linoleic levels, while also providing the desirable low levels of saturated fat and trans-fat; however it also has a low crystallization temperature similar to other sunflower oils, which can cause clumping during frozen storage.
On the other hand, oils with high crystallization temperatures often have undesirable trans-fat levels. Thus, while clumping can be reduced using oils with high crystallization temperature, these oils are less desirable because of their fat content profiles.
As illustrated in
The crystallization temperatures, as used herein, are based upon a phase change from liquid to solid of the oils illustrated. The phase change is represented by changes in slope of a curve, with the crystallization temperatures being determined approximately where a defined change occurs in slope of the curve. The crystallization temperatures are approximate temperatures because oils, similar to other organic compounds, have a range for phase change and thus the approximate initial change in heat capacity is used herein to approximate the crystallization temperature. Preferably, exemplary embodiment oils used herein initiate solidification at temperatures of at least 10° F. Also, in exemplary embodiments, at least 50% of the residual oil in frozen potato products freezes at temperatures of 10° F. or higher.
For example, as shown in
As illustrated in
As also illustrated in
Similarly, in
In addition to providing an oil that can freeze in a freeze tunnel, it is also desired to provide an oil that can remain frozen at temperatures above the temperatures in a freeze tunnel. This is desired because after exiting a freeze tunnel, frozen potato products are often collected into large bins. During this collection of frozen potato products in the bins, the bins and the frozen potatoes being loaded into the bins are often both held at room temperature or colder for short periods of time, which can lead to melting of the frozen oil on surfaces of the potatoes, and more importantly to the defrosting of the oil, which can lead to clumping during subsequent freezing. Thus, to reduce clumping at this stage, high crystallization temperature oils and blends are further desired.
After the bins are full, the bins are transported to frozen storage, wherein if the oil has melted and become liquid, then this will cause clumping during freezing in frozen storage due to the decreased temperature and the possible weight-bearing pressure applied by other products in storage.
Therefore, the cottonseed oil mixed with sunflower oil is desirable because (i) cottonseed oil can be crystallized within the freezing tunnel at temperatures less than 50° F. even though the sunflower oil remains liquid above 5° F., and (ii) the crystallization temperature of cottonseed oil is closer to room temperature it will remain in frozen or crystalline form.
In providing oils with higher crystallization temperatures, the crystallization temperature between these oils and the sunflower oil cannot be too disparate for miscibility purposes. While it is important to provide a blend that allows for crystallization from about 10° F. to about 25° F., the crystallization temperatures of the oils must be close enough to provide sufficient levels of miscibility to reduce separation of oil in the blend and thus the potential for clumping by the separated sunflower oil.
Additionally, exemplary oils are provided at temperatures above their melting temperatures prior to par frying such that the oils can remain in liquid form and can remain mixed. For example, cottonseed oil has a crystallization temperature of about 50° F. By blending cottonseed oil with sunflower oil, which has a crystallization temperature of about 5° F., the cottonseed oil can freeze at a much higher temperature—well above the temperature for a freeze tunnel.
On the other hand, if hydrogenated soy, for example, which has a crystallization temperature of about 135° F. is used in combination with sunflower oil, this dissimilarity in crystallization temperature could not be blended adequately enough such that they react as one oil.
Profiles for exemplary oils and blends of oils are listed in Table 1. In Table 1, the profiles include saturated fat (“SF”) content, trans-fat (“TF”) content and levels of linolenic acid (“18:3,” referring to 18 carbons and 3 double bonds, which indicates the oil's stability as a frying oil; where the higher levels are more unstable for frying) for various exemplary oils and blends of oils. Table 1 also lists the oils and blends of oils at different ratios, wherein the first row illustrates a 25/75 blend, the second row illustrates a 50/50 blend, and the third row illustrates a 75/25 blend. Preferably, oils used herein have an 18:3 level of <2 wt % for frying stability and <3 wt % trans-fat. Even more preferably, exemplary oils used herein may have a trans fat level of <1 wt % and/or an 18:3 level of <1 wt %.
Table 1 includes many oils and blends of oils. Noting specifically NuSun™ in combination with various oils for saturated fat, trans-fat and 18:3 profiles, it appears that the best combinations would be NuSun™ with corn oil, cottonseed oil, and palm oil because they provide low saturated fat and trans-fat levels, while also providing low 18:3 profiles. While it is noted that cottonseed oil and palm oil have desirably low crystallization temperatures, as illustrated in
As mentioned above, the blend of cottonseed oil with sunflower oil can be used to provide a higher crystallization temperature than NuSun™ alone, and as shown in Table 1, exhibits reduced saturated fat and trans-fat levels. Additionally, a 50/50 blend of cottonseed oil in combination with NuSun™ has a crystallization temperature of about 0° C. or 32° F., to provide reduced trans-fat levels with crystallization temperatures high enough to prevent clumping during freezing and melting during high volume storage. Additionally, a combination of cottonseed oil and palm oil can be combined with sunflower oil to provide reduced trans-fat levels with increased crystallization temperature. Thus, a blend of cottonseed oil with NuSun™ would be desirable.
= High Oleic Canola Oil
Similarly, the use of a blend of palm oil with NuSun™, as mentioned above, can provide a higher crystallization temperature than NuSun™ alone and as shown in the Table, also exhibiting reduced saturated fat and trans-fat levels. Additionally, a 50/50 blend of palm oil and NuSun™ has a crystallization temperature of about 35° C. or 90° F. to provide reduced trans-fat levels with crystallization temperatures high enough (i.e., initiating solidification of the oil at temperatures equal to or greater than 10° F.) to prevent clumping during freezing and melting during high volume storage loading. Thus, a blend of palm oil with NuSun™ would be desirable.
Corn oil, although not illustrated in
Sunflower oil, cottonseed oil, and palm oil tend to be miscible with one another and therefore do not tend to separate during par frying, freezing in a freeze tunnel or freezing during frozen storage. Thus, the lower crystallization temperature of sunflower oil does not tend to cause clumping when blended with the other oils, which can be selected from the group of cottonseed and/or palm oil.
Similarly, sunflower oil and cottonseed and/or palm oil can be blended adequately enough to react as one oil due to their miscibility. Thus, upon freezing, the cottonseed and/or palm oil with their higher crystallization temperatures can be frozen and can remain frozen such as to reduce clumping that could otherwise be present if pure sunflower oil were utilized.
To balance the crystallization temperature with the reduction of trans-fat levels, a blend of oils is desired. For example, a blend of about 50/50 sunflower oil and a second oil of selected from the group consisting of cottonseed oil and palm oil is preferred. By providing a 50/50 blend, the blend provides a stable frying oil, and can balance an increased crystallization temperature with reduced trans-fat levels, as well as provide reduced clumping during frozen storage. It is noted that variations from 50/50 ratio (e.g., from about 40 to about 60% of each oil within the blended oil) is contemplated herein.
In addition to the manufacturing benefits and clumping reduction from the use of the blends, aesthetic benefits can also be realized. Frozen potato products par fried in NuSun™ oil alone look fresher and more appealing than, for example, frozen potato products par fried in partially hydrogenated soy-containing oil. For example, frozen potato products par fried in NuSun™ appear bright and clear, albeit oilier; while frozen potato products par fried in partially hydrogenated soy-containing oil appear dull and cloudy. Thus, the use of NuSun™ with frozen potato products is also desirable for aesthetic reasons.
In an exemplary embodiment, a blend of about 50% NuSun™ and about 50% cottonseed oil are provided in a vat. These oils can be: provided individually and mixed within the vat, pre-blended with the blend provided in the vat, pumped in together via separate pipes, etc. These oils can also be held at temperatures above the crystallization temperatures of all of the oils used, and can be provided with a mixer (e.g., a mechanical arm, magnetic stirrer, etc.) to keep the blend mixed.
This blend is heated and potatoes, which can be provided in a number of various forms, such as french fries, tater tots, etc., are par fried therein. After par frying, the potatoes with the blend of oil thereon/therein pass through a freeze tunnel at about 10° F. to about 25° F. to freeze the potatoes and also to crystallize the cottonseed oil.
Next, the frozen potato products can be wrapped in packages or can be loaded into a bin, wherein the cottonseed oil and the potato products can remain frozen. A typical bin is 4′×4′×4′ and can accommodate about 1000 to about 1500 pounds of frozen potato products.
After filling the bin or the wrapped packages, the bin or the wrapped packages can then be placed into frozen storage at about 0° F., wherein the sunflower oil can crystallize, and wherein clumping is reduced because only the sunflower oil will crystallize during frozen storage. Thus, by providing a blend like this, the following advantages can be achieved: reduced trans-fat levels, reduced clumping, and sufficient miscibility of the blend of oils during cooking and freezing to produce a superior frozen potato product.
The term “about” as used here indicates that associated numerical values are not intended to be precise but are intended to have a tolerance of 5% above and below any stated numerical value.
It will now be apparent to those skilled in the art that a novel process for preparing potato products with reduced trans-fat levels has been described. Moreover, it will also be apparent to those skilled in the art that numerous modifications, variations, substitutions and equivalents exist for features of the invention which do not materially depart from the spirit and scope of the invention as defined in the appended claims. Accordingly, it is expressly intended that all such modifications, variations, substitutions and equivalents that fall within the spirit and scope of the appended claims be embraced thereby.
