1. Technical Field
The present invention relates to an improved apparatus and method for making a vacuum microwaved snack food.
2. Description of Related Art
Processed snack foods are generally provided to the consumer in a ready-to-eat form. Such snack foods include a wide variety of foods such as potato chips, corn chips, puffed dough articles, cookies and crackers. Processed snack foods are frequently made from wheat, corn, potato, or other starch-containing ingredients that are deep fat fried. For example, potato chips are prepared by frying thin slices of raw, fresh potatoes.
Savvy consumers have become increasingly health conscious, resulting in an increased demand for healthier, less processed and more natural snack foods. Recent polls have shown that consumers want to try to control the amount of fat in their diet. Further, consumers increasingly regularly or sometimes check nutritional labels for fat content. In many cases, the top barrier to people eating more snack food is the perception that the food is unhealthy. This is supported by the fact that about 59% of consumers believe that baked products are healthy as compared to about 11% who believe that fried foods are healthy. Consequently, a need exists for lower fat snack foods that consumers deem to be healthier.
While artificial or non-natural ingredients have been used to lower the fat content of snack foods, many consumers also have an aversion to such ingredients. For example, consumers increasingly say they prefer foods that are natural and many say they avoid products that contain a high proportion of artificial ingredients or preservatives. Most consumers say they believe food of natural origin is good for their health as opposed to those who say they believe artificial foods are good for their health. Consequently, a need exists for a low-fat snack food having few or no artificial ingredients or preservatives.
Unfortunately, it has proven difficult to make desirable, low-fat shelf-stable snack foods from natural, raw ingredients on a commercial scale. Some proposed solutions to providing more natural shelf-stable snack foods are illustrated by U.S. Pat. Nos. 5,676,989, 5,962,057, and 6,312,745, all directed towards the vacuum microwaving of food products. Such patents, however, fail to disclose a way to make such food products on a commercial scale.
Rotary vacuum microwaves have been used in non-food applications.
The proposed invention comprises a method and apparatus for making a low-fat, shelf-stable, ready-to-eat snack food from raw food ingredients. In one embodiment, the method comprises the steps of providing a raw plant-based food, placing the food into an annular region of rotatable carousel, and dehydrating the food in a vacuum microwave as the carousel rotates.
In one embodiment, the present invention is directed towards an apparatus that can be used to dehydrate a raw food product in a vacuum microwave to make a snack food. The apparatus comprises a rotatable carousel having an annular region for placing a food product. The rotatable carousel can be placed into a microwave under vacuum conditions and rotated during the operation of the microwave. The above as well as additional features and advantages of the present invention will become apparent in the following written detailed description.
The novel features believed characteristic of the invention are set forth in the appended claims. The invention itself, however, as well as a preferred mode of use, further objectives and advantages thereof, will be best understood by reference to the following detailed description of illustrative embodiments when read in conjunction with the accompanying drawings, wherein:
In one embodiment, a plurality of flights 405 can be placed within the tube 410 to further facilitate tumbling. Such tumbling can impart sufficient movement such that food pieces avoid sticking to adjacent food pieces or to any portion of the tube 410. The Figures shown herein are provided for purposes of illustration and not limitation. Other embodiments can be used in accordance with the spirit and scope of the present invention. In the embodiment shown in
The concentric cylinders 101102 shown in
In one embodiment, a portion of the second concentric cylinder 102 is removed (e.g., a first removable covering 152 is removed), food pieces 120 are placed into the respective compartment 110, and the removed portion of the second concentric cylinder 102 is replaced (e.g., the removable covering 152 is reattached) after the compartment is loaded with food pieces 120. This process can be repeated with other portions of the second concentric cylinder 102 that cover the other compartments 110 until the desired number of compartments 110 contains food product. The carousel 100 can then be placed into the vacuum microwave 200.
Microwave energy essentially heats a food product volumetrically. As food pieces 120 are dehydrated in the vacuum microwave 200, the food piece surfaces can become sticky as a result of the moisture that migrates from the interior to the boundary of the food pieces 120. Consequently, in one embodiment, the concentric cylinders 101102 and dividers 105 comprise a non-stick material such as a fluoropolymer to prevent the food pieces 120 from sticking to the cylinders 101102 and dividers 105.
In one embodiment, a compartment 110 is loaded with food pieces 120 to create a food volume that leaves enough void volume in the compartment to permit the food pieces 120 to move when the carousel 100 is rotated. In one embodiment of the present invention, the compartments 110 are loaded such that the food pieces 120 have sufficient movement within the compartment 110 during carousel rotation to avoid sticking to any portion of the carousel 100 including the cylinders 101102 and dividers 105, and to avoid sticking to any adjacent food pieces 120. Sufficient movement of the pieces 120 advantageously limits the time any portion of the outer surface area of the food piece 120 is in contact with an adjacent food piece or a portion of the carousel 100. Consequently, sufficient movement permits moisture to escape from entire outer circumferential periphery of the food piece 120 and reduces stickiness.
In one embodiment, stickiness of the food product is further minimized by applying a non-stick coating, such as by spraying oil to the outer surface of the food pieces 120 and/or the compartment side portions of the cylinders 101102 and the dividers 105 of the carousel 100.
Food pieces 120 that can be used in accordance with the present invention include, but are not limited to, whole or cut pieces of apple, strawberry, blueberry, and melons. Whole strawberries used in accordance with the present invention have yielded a highly desirable, low-moisture shelf-stable food product. As used herein, a shelf-stable food comprises a moisture content of less than about 8% by weight and more preferably between about 2% about 5% by weight. In one embodiment, the food comprises a moisture content of less than about 2% by weight. In one embodiment, the food pieces 120 comprise food pieces cut into halves or quarters from the whole. Some food products may need processing prior to placement into the carousel 100. For example, some fruits such as berries, including grapes, naturally have waxy cuticle on the epidermis to slow the loss of water through evaporation. Thus, some food products can be treated by methods well known in the art (e.g., see U.S. Pat. No. 7,119,261 at col. 1, lines 48-60) to modify the waxy cuticle so that transpiration of water vapor across the cuticle may proceed at a faster rate when in the microwave. In one embodiment, blueberries were sprayed with PAM brand oil to help de-lipify the waxy cuticle surface.
Similarly, oranges are preferably peeled prior to dehydration. Because banana slices are often very sticky, bananas can be cut into ball-shaped spheres to minimize the available surface area for contact between ball-shaped pieces as well as between the ball-shaped pieces and the carousel 100. Sufficient movement within the carousel 100 during dehydration can prevent the banana pieces from sticking together. It is contemplated that food products including, but not limited to peach, nectarine, grape, pineapple, mango, avocado, and raspberry can also be used. Food products such as cheese, pre-cooked meat cubes, and vegetables including, but not limited to, sweet potato pieces can also be dehydrated in the present invention. Like banana, some food products such as cheese, peach, nectarine, and mango may benefit from being cut into a spherical-shaped piece prior to insertion into the carousel 100.
In one embodiment, the rotational direction of the carousel 100 within the microwave is unidirectional e.g., always clockwise or counter-clockwise when the carousel 100 is in the vacuum microwave 200. In one embodiment, the carousel rotation oscillates between a first direction and a second direction. For example, the carousel 100 can rotate a first number of degrees (e.g. 120 degrees, 360 degrees) in a first direction (e.g. clockwise direction) and then a second number of degrees (e.g. 30 degrees, 60 degrees) in a second direction (e.g. the counter-clockwise direction). In one embodiment, the carousel 100 rotates the same number of degrees in both the clockwise and counterclockwise direction.
The compartments 110 disposed in the annular region 103 of the carousel 100 provide circumferential disposition of the food product. One advantage to placing the food product into the annular region 103 is that, unlike the product 12 shown in
Another advantage of placing the food product into the compartments 110 in the annular region 103 is that the food pieces 120 can be gently moved upon rotation of the carousel 100. The carousel 100 is preferably rotated at a rate that imparts sufficient movement of the food pieces 120 such that the food pieces 120 avoid sticking to one another or to any portion of the annular compartments 110. Movement of the food pieces 120 at too high speed, however, can cause undesirable collision damage to the food pieces 120, which can result in undesirable compaction. Undesirable compaction occurs when the microstructure of the food pieces 120 breaks down and can cause the food piece 120 to collapse when the vacuum is released at the end of the drying cycle. Thus, the food pieces 120 need to be moved in a gentle manner so as to avoid undesirable compaction. The desired rotational speed will be dependent upon several factors including the type of food being processed, the stickiness of the food being processed, whether the food being processed has been cut into smaller pieces, the power of the microwave, and any processing that is done that reduces stickiness, such as pre-drying or oil addition. Given this disclosure, one skilled in the art will be able to determine the appropriate compartment size and rotational speed for a corresponding food product.
The food product can be removed from the vacuum microwave based upon one or more factors including, but not limited to, a rise in an internal drum temperature provided by an infrared camera or other suitable measuring device, a pre-determined time based upon type of food product and weight of food product, humidity level, and/or the amount of reflective energy measured in the vacuum microwave drum. The present invention thereby provides an improved apparatus and method for making a vacuum microwaved food product.
Two embodiments of the invention is illustrated in the examples set forth below, where reference to the carousel illustrated in
About 8 pounds of whole strawberries were washed and drained. A 25% sugar solution was used to provide a more ripened flavor in the finished product. However, this step is optional and if ripe strawberries are used, a sugar solution is not necessary. The compartment side of the cylinders 101102 and strawberries were sprayed with PAM brand oil to prevent the strawberries from sticking to one another. She carousel first concentric cylinder 101 had an outer annular diameter of about 15 inches and the second concentric cylinder 102 had an inner annular diameter of about 11.5 inches. Each concentric cylinder 101102 had a length of about 15 inches. The carousel 100 had six evenly spaced compartments. The six compartments 110 were defined by dividers 105 oriented radially around the longitudinal axis of the carousel 100 in the annular region 103 between the first 101 and second concentric cylinders 102. Five of the chambers were each filled with about 1.5 pounds of strawberries and the first 101 and second 102 concentric cylinders comprised perforated polypropylene. The carousel 100 was placed inside a model 0650 μWaveVac vacuum microwave oven 200 sold by Pueschner of Schwanewede, Germany.
The strawberries were then dehydrated under vacuum. Initially, drying occurred at a microwave power of about 4 kilowatts, which corresponded to about 2.7 kilowatts absorbed by the strawberries. The carousel 100 was rotated in an oscillating format the carousel rotated about 120 degrees each direction using speed setting of about 5.0 revolutions per minute. The pressure inside the microwave was maintained at about 30 torr. About 100% of the infrared heat available was used throughout drying process. When the infrared camera mounted to read the temperature inside the microwave drum indicated a temperature range of about 105° F. to about 110° F., the microwave power was reduced to and maintained at about 3 kilowatts until reaching an internal temperature range of about 105° F. to about 110° F., at which point the microwave power was reduced to about 2 KW, then to about 1.0 KW until reaching an internal drum temperature range of about 110° F. to about 130° F., and finally to about 0.5 KW until an internal drum temperature of about 150° F. was indicated and the vacuum microwave oven was turned off. The total drying time was about 50 minutes, and the finished dried strawberries weighed about 0.80 lbs and had a shelf-stable moisture content of about 4% by weight. A hand held infrared thermometer measured a strawberry surface temperature of about 172° F. when the drum was opened after processing. The temperature difference between the strawberry and the internal drum temperature is likely because the infrared camera mounted to measure the inside temperature of the drum is likely measuring the temperature of the first concentric cylinder 101. Because the strawberries were dehydrated under vacuum, the finished shape of each strawberry is similar to its initial starting shape although there is some volumetric shrinkage. The finished strawberries also exhibited excellent fresh-like color though the tone was slightly darker. Subsequently it was found that strawberries could be tumbled more effectively by use of flights inside the tubes. Each cylinder 410 had three flights 405 oriented radially about the circumference of the cylinder 410 and extending inward, Each flight was approximately ½ inch tall and 24 inches long.
Although the example above was conducted on a pilot scale using only 5 out of 6 compartments on a single carousel, such proof of principle indicates that scalability is possible. It is believed that, for example, a larger carousel can be used that can handle about 130 pounds of raw fruit per batch resulting in about 20 pounds of finished product. Utilizing 8 of these carousels in a batch or semi-continuous operation would result in about 160 pounds per hour of dried whole strawberries, which is over about 2,590 28-gram servings.
A total of about 7.4 pounds of Kraft Twist Cheese sticks were quartered into about ¾″ pieces, each having about 50% moisture, and loaded into 6 tubes 410 filling each tube about one-quarter full each. Each tube 410 had an inner diameter of about 4.5 inches. Each cylinder 410 had a length of about 24 inches. No flights were used inside the tubes. The carousel 400 having six cylinder 410 was placed inside a model 0650 μWaveVac vacuum microwave oven 200 sold by Pueschner of Schwaenewede, Germany.
The cheese cubes were then kept in motion by rotating the carousel at 20 RPM and the cheese cubes were then dehydrated under vacuum. Drying occurred at a microwave power of about 6 kilowatts, which corresponded to about 5.3 kilowatts absorbed by the cheese. The pressure inside the microwave was maintained at about 30 tort. About 100% of the infrared heat available was used throughout drying process. Dehydration was completed after 17.5 minutes and the yield was 3.6 lbs of cheese puffs with a shelf-stable moisture content of about 4% by weight. Due to extreme expansion of the cheese pieces during drying virtually the entire volume of each tube was filled with cheese puffs at the end of drying. These cheese cubes did not clump during the drying. The drying rate was about 12.3 lbs finished cheese puffs/hr. It is also possible to dry low fat cheese pieces in a similar fashion. Although the example above was conducted on a pilot scale using only 25% of the volume of each cylinder 410, such proof of principle indicates that scalability is possible.
The present invention has several advantages over the prior art. In one embodiment, the present invention permits vacuum microwave drying to be performed in compartments in an annular region so as to minimize collision forces, establish uniform bed depths, and increase the available capacity in a vacuum microwave drum. In one embodiment, the present invention avoids clumping of food pieces and increases the exposure to microwaves. The present invention permits the bulk handling of vacuum microwave food products and provides an opportunity for easier automation.
While this invention has been particularly shown and described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention. For example, in one embodiment, another heat source such as infrared heat and can be applied before, during, or after the microwave energy is applied to the food product.
This application is a continuation-in-part of co-pending U.S. patent application Ser. No. 11/668,838, filed Jan. 30, 2007, the technical disclosure of which is hereby incorporated by reference.
Number | Date | Country | |
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Parent | 11668838 | Jan 2007 | US |
Child | 11959210 | US |