This invention pertains to methods for portioning foodstuff, and more particularly, for portioning a foodstuff in accordance with a predetermined shape by building a three-dimensional map of the foodstuff and then cutting the foodstuff in three dimensions.
The slaughterhouse industries have traditionally been labor intensive; however, as in other labor intensive segments of industry, attempts are being made to reduce manual labor, increase speed, and improve productivity. A particularly labor intensive task is the portioning of foodstuffs such as meats from beef, poultry or fish. An important goal in food portioning is consistency. For instance, restaurants want to serve portions that will not differ markedly from day to day in size, quality, fat content and/or other criteria. In order to meet minimum weight specifications, a food portion often has to exceed the acceptable minimum weight. This is because restaurants must take into account some of the variation that can exist between portions. In order to assure that all portions meet minimum specifications, it is usually necessary to use a target weight that is somewhat above the minimum. This may be a bonus to consumers but a problem for restaurateurs and others who may end up giving away a significant portion of their profit margin. By having consistent portions, restaurateurs can reduce the amount of excess that is built into the portions they serve, and consumers are more likely to receive the same quantity and quality of meat product.
Up until now, skilled workers usually bore the responsibility of cutting foodstuffs into constant weight or constant sized portions. These methods can and often do result in waste. Workers, in theory, can manually portion meat to about the same size of portions. However, workers, unlike machines, fatigue and the constant repetitive motion involved with butchering may lead to disabling injuries.
Therefore, the industry is aware of the need to increase the productivity of its work, without unduly burdening its workers. Several inventors have sought to devise ways to equally portion meats utilizing automated machinery to reduce manual labor. Therefore, methods and machines have been designed in an attempt to automatically cut food so that portions are of approximately equal weight.
One approach to introduce automation into the food portioning industry is to measure the cross sectional area of the foodstuff and assume that such area remains constant throughout the length of foodstuff. As the conveyer moves forward, a transverse cutting device is activated at equally spaced predetermined time intervals. This method achieves portions of equal thickness, but not necessarily equal weight, as the cross-sectional profile of each succeeding cut can be smaller or larger than the previous one. In order to achieve substantial equal weight portions, this method requires that a human operator trim the foodstuff so that it essentially conforms to a uniform cross-section along the longitudinal axis. Once this step is performed, the machine may proceed cutting at predetermined lengths. This method could lead to a large amount of waste, and inconsistent weight portions.
An improvement over the above method can take into account the cross-sectional area after each cut is made. From this measurement and the assumed density of the foodstuff, the thickness to achieve a desired weight can be calculated by integrating the cross sectional area over the length until the desired weight is reached. As the conveyor advances, its forward progress is monitored and the foodstuff is trimmed in a transverse manner at the point when the thickness corresponds to the calculated thickness. This process is repeated until the whole foodstuff, for example, a primal cut of beef, or a fish is portioned into individualized, nearly equal weight portions. However, this method does not account for indentations, significant contours, or tissue discontinuities appearing throughout the foodstuff, which can often affect the density. Further, these methods do not contemplate cutting in three dimensions, meaning that usually one dimension is always fixed, as happens with chicken breasts or a primal cut of beef. Chicken breasts may be portioned along the length and width, and a primal cut of beef, such as a loin, is cut lengthwise.
Other automated methods are aimed at producing food portions which trim fat to produce portions with acceptable quantities of lean meat in relation to fat. Again, with these methods, portioning is done in two dimensions. As with previous methods, the initial portioning is done by human operators to carve the initial starting block and only then, can the machine proceed. These methods can rely on a scanning apparatus to determine where the demarcations between fat, bone, or cartilage and meat lie. Scanning apparatus require light or X-ray radiation to detect the fat regions. After this determination is made, a machine can trim the fat from the lean tissue. Once the fat is removed, the resultant food portion is weighed and sorted. These methods are “after the fact,” since the weight or size of the individual food portions is not considered in determining the appropriate amount of portioning. The portions are simply sorted according to weight after the trimming operation is complete.
In a variant of a previous method, other methods of portioning involve scanning the foodstuff to determine the thickness of the foodstuff passing directly underneath the scanner. From the scan, a computer will be able to mark the cutting line at which to cut to achieve the predetermined weight or size. The cutting apparatus can move while the foodstuff also moves on the conveyor, or the conveyor may stop at a cutting station and allow the cutting apparatus to cut the portion. These methods are limited in that the only cut that can be made is in the transverse direction. Using this method, one is also limited to a foodstuff portion having the initial thickness.
Other methods are directed at ways of classifying meats to determine which cut will maximize profit, i.e., which cut of meat is selling at the highest price per pound at the current time. A computer may be used to calculate and determine a portioning strategy to maximize the amount of those portions which are selling at the highest price. These methods lack the capability to generate a three-dimensional map and are concerned only with making primal cuts of meat.
Other methods are directed at increasing the speed of the cutting devices, or perhaps cutting the foodstuff in two directions. However, these methods, as with the methods previously mentioned, assume that the foodstuff is fixed in one dimension, most commonly the thickness dimension. This may be unacceptable for a variety of reasons. Heretofore, attempts have not been made to portion foodstuffs automatically along a third dimension to arrive at the desired shape or weight. Portions of meat, particularly chicken breasts, have now increased in size so greatly that two-directional cuts simply are no longer suitable to trim the breasts down to desired portions.
Therefore, to date no method or apparatus has been devised that will build an accurate three-dimensional map of the foodstuff, including the indentations and contours, that is to be portioned, then compare the map to a predetermined form, and then through the use of a computer controlled system automatically cut the foodstuff in three dimensions so as to achieve the predetermined shape or weight. The method of the present invention seeks to accomplish this task. The present invention will further increase productivity in the methods for portioning foodstuffs, particularly those meats, such as beef, poultry or fish which have uneven surfaces, including indentations and contours, to achieve consistent portions.
This summary is provided to introduce a selection of concepts in a simplified form that are further described below in the Detailed Description. This summary is not intended to identify key features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter. The present invention discloses a method for portioning foodstuffs in three dimensions. A step in portioning according to the present invention includes scanning the foodstuff to be portioned. Followed by a step of generating a three-dimensional map of the foodstuff. Then, comparing the generated three-dimensional map of the foodstuff with the desired shape which is stored in the memory of a computer. The computer will then be able to determine the particular cutting path in three dimensions in order to arrive at the predetermined shape or weight. After comparison of the generated map against the map stored in the computer memory, there follows a step of cutting in one direction to fix at least one dimension of the foodstuff. This is followed by a step of determining whether the foodstuff is within the tolerance limits to proceed with another cutting step or whether the foodstuff portion has moved during the first cutting step. If the foodstuff portion has moved, the foodstuff will be scanned in a second scanning step and a second map of the foodstuff will be generated. Optionally, the scan may only include a map in two dimensions since one dimension has been fixed. Thereafter follows a step of determining the cutting path to cut the foodstuff along two dimensions to arrive at a portion that has been trimmed along three dimensions.
A preferred embodiment of a method according to the present invention will include a step to scan the foodstuff to be portioned. Several apparatus are in existence which are suitable for this purpose. The preferred apparatus can use light or X-ray radiation. The radiation is attenuated or otherwise modified as it strikes the foodstuff or passes through the foodstuff in a predictable manner so that a relationship is formed between the attenuation and a physical parameter of the foodstuff. The scanner also includes a receiver portion, capable of receiving the radiation after being attenuated or modified by the foodstuff and capable of converting it into electrical signals which vary as a function of the physical parameter of the foodstuff. The signals are processed to represent a three-dimensional map which accurately depicts the foodstuff in all details including the indentations, contours and discontinuities. Preferably, this step is carried out by a computer, having a CPU and a memory, capable of analyzing the signals sent by the receiver portion of the scanner. Once having created a three-dimensional map, a step of comparing the three-dimensional map with a map of a desired shape of the foodstuff follows. Preferably, this step is also carried out by a computer wherein the desired shape is stored in the memory of the computer. The CPU then executes a predetermined algorithm to fit the desired shape within the generated map. Having established a fit, the cutting path is marked in three dimensions. Thereafter, the foodstuff can be cut in at least one dimension to fix that one dimension, for example the thickness. The cutting device is directed by the computer according to the cutting path. Preferably, the cutting device is a high pressure water jet. After the first cutting step, a determination is made whether the foodstuff is within tolerance limits to proceed to a second cutting step. During the first cutting step, the foodstuff may have moved, thereby rendering the three-dimensional map created in a previous step no longer accurate. The computer is required to know the position of the foodstuff to accurately cut the foodstuff to the desired shape. Therefore, there are limits placed on the amount of movement that can be tolerated during the first cutting step. If the tolerance limits have not been exceeded, the computer will direct the path of the next cutting step. Otherwise, a step follows wherein the foodstuff is scanned and preferably a two-dimensional map is generated, preferably, by devices similar to the devices used in generating a three-dimensional map. The newly generated map is again compared with the desired shape of the foodstuff. Preferably, this step is carried out by a computer wherein the desired shape is stored in a computer memory. The CPU may then execute a predetermined algorithm using any of a number of variables, such as the length, width or thickness, for determining a cutting path. Thereafter follows a step of cutting the foodstuff in at least one dimension to fix that dimension, or two dimensions, for example, the foodstuff may be cut a predetermined length and width, the thickness having already been fixed by a previous step. Therefore, the present invention achieves a desired shape from a foodstuff portioned along three dimensions. This is desirable when, for example, the original foodstuff portion is too big for an intended product.
Another embodiment of the present invention further includes a step of fitting several desired shapes into the generated map of the foodstuff, thereby maximizing the amount of foodstuff that is cut into desired shapes and minimizing the wasting of trailing portions.
A further embodiment of the present invention includes a product cut from a foodstuff using a method in accordance with the present invention. The foodstuff is cut and portioned along three dimensions including the thickness, width and length in two cutting steps.
A further embodiment of the present invention includes a product cut from a foodstuff using a method in accordance with the present invention. The desired final product has a substantially constant thickness, but the foodstuff has an arcuate shape. The foodstuff is cut and portioned along three dimensions including the thickness, width and length in two cutting steps. The product is cut from a foodstuff portion having an indentation. The cutting path used to cut the product is arcuate shaped to cut around the indentation in the foodstuff portion.
A further embodiment of the present invention includes a product cut from a foodstuff portion using a method in accordance with the present invention. The final product has a substantially constant thickness. The foodstuff is cut and portioned along three dimensions including the thickness, width and length in two cutting steps. The product is cut from a foodstuff having an undesirable constituent such as bone, cartilage or fat. The cutting path used to cut the product is skewed or at an angle.
A further embodiment of the present invention includes a plurality of final products cut from a foodstuff using a method in accordance with the present invention. The foodstuff is cut and portioned along three dimensions including the thickness, width and length in two cutting steps. The cutting paths can include multiple pass cuts through the foodstuff while partially controlling the depth of cutting. A plurality of products may be formed from a single foodstuff portion.
An advantage of a portioning method in accordance with the present invention is the elimination of manual labor to perform an initial slicing operation to fix one dimension of a portion of a foodstuff portion. Elimination of manual labor increases the productivity of the butchering industry.
A further advantage of a portioning method in accordance with the present invention is the savings incurred from optimizing a desired cut of meat product.
A further advantage of a portioning method in accordance with the present invention is the capability of cutting irregular shaped foodstuff portions having indentations or undesirable constituents.
The foregoing aspects and many of the attendant advantages of this invention will become more readily appreciated as the same become better understood by reference to the following detailed description, when taken in conjunction with the accompanying drawings, wherein:
A preferred embodiment of a method for portioning foodstuffs in accordance with the present invention is shown in
Referring to
The conveyor belt 202 carries the foodstuff 200 underneath a first scanner system, generally denoted by 204. The scanner system 204 suitable for use in this method will have the ability to generate a three-dimensional map of the foodstuffs. The principle behind the scanner system is the use of radiation, which forms a relationship with a physical parameter of the foodstuff which is being scanned. Any one of several devices are suitable for this method. Several devices in use today employ X-rays or visible light to generate an image of the foodstuff. A scanner according to the present invention will include both a generator 206 to irradiate the foodstuff to be scanned with radiation and a receiver 208 to receive the attenuated radiation. The receiver portion 208 can be integral with the generator 206. Radiation may be electromagnetic radiation throughout the spectrum from high frequency radiation, such as X-rays, to relatively low frequency natural spectrum light.
A scanner can also include the receiver 208 to receive and detect the amount of radiation attenuated by an object. Attenuation can occur by passing through the object or by reflection from the object. When radiation passes through a foodstuff, a certain amount of radiation is absorbed by the foodstuff through which it passes, therefore there will be a relationship in the amount between the radiation sent to the foodstuff and the radiation received after it has passed through the foodstuff. The cause of absorption is believed to reside in the chemical bonds within the molecules of the foodstuff. Radiation once attenuated can be collected, and converted into a useable form. Photodiodes, for example, may be used to convert an amount of radiation in the visible range into a voltage or current signal. For X-rays, a scintillating material may be used to generate visible light capable of detection by a photodiode. This method is described in U.S. Pat. No. 5,585,603, issued to Vogeley, Jr., which is herein incorporated by reference. Other methods teach the use of a video camera to determine the size and/or shape of a foodstuff. These methods and apparatus are described in Reissue Pat. Nos. 33,851 and 33,904, issued to Rudy et al., which are herein incorporated by reference.
The signals generated by photodiodes can then be further processed by a computer to determine a physical quantity which is related to the amount of radiation which is detected. One such quantity may be the mass of the foodstuff. Since the scanner will presumably know the amount of radiation that was sent to the foodstuff and the amount of radiation that was received, the amount absorbed forms a difference which is a direct relationship of the mass of the foodstuff. Once knowing the mass, the volume of the incremental scanned area is calculated by assuming a density. The thickness can be derived once knowing the linear dimensions of the volume.
Any one of the above-described devices currently in use today will be suitable for use in a method in accordance with the present invention. Still, other methods of three-dimensional imaging may use reflective means rather than absorptive means. For example, a receiver may measure the amount of light reflected from a foodstuff rather than the amount of radiation passing through the foodstuff. The areas of foodstuff tissue are distinguishable from areas, such as the conveyor, which surround the foodstuff and have a different reflective index. These differences can be used to determine the shape of a foodstuff. A person of ordinary skill in the art will have knowledge of suitable devices of carrying out this step in accordance with the present invention.
Using a selected method, the scanner may repeat the process in quick succeeding intervals corresponding to one incremental dimensional unit such as by advancing the conveyor, or the scanner may execute a strobe-like effect, or the scanning process may be essentially continuous, with the map being formed as the foodstuff is continually advanced underneath the scanner. The imaging process can be integrated over an entire length of foodstuff to arrive at a three-dimensional map of the foodstuff. The three-dimensional map generated by the computer will have coordinates to fixed points or locations to enable other apparatus to reference these points and trim or portion the foodstuff with reference to these fixed points accurately. Other devices for identifying fat or bony cartilaginous matter and skin may also be incorporated and adapted to the present invention. These methods are also within the scope of this invention.
Step 103 of
Preferably, a computer 210 having a central processing unit 212 (hereinafter CPU) and a memory 214 will be used in the method according to the present invention. Input 106 of
In still other alternate embodiments, the computer 210 can be in communication with a network system 230 which allows the computer 210 to talk and share information with other computers. Computer 210 can also drive other periphery hardware besides the scanner system 204. For instance, computer 210 can direct the operation of the conveyor 202, or cutting devices, generally denoted as 220. Finally, computer 210 can receive information from various sensors 236 to guide or direct a multitude of systems.
In the preferred embodiment of the method of the present invention, the CPU 212 will retrieve the stored map(s), compare the stored map(s) with the generated map, and determine the path of the first cutting step 108 of
In an alternate embodiment, a first comparison and determination of a first unit dimension is made, if the foodstuff is within specifications of one unit dimension of the desired shape, the computer may direct the cutting devices to proceed to cut the food stuff along the predetermined cutting path to arrive at fixing one dimension. In this embodiment, having fixed one dimension, the computer can now proceed to make comparisons in the remaining dimensions and cut to those dimensions accordingly in later cutting steps.
In another alternate embodiment, all comparisons are completed before cutting begins, and following a step for comparing a dimensional unit, the computer may proceed to compare the foodstuff along a second dimensional unit. For example, in a preferred embodiment, the first dimensional unit for comparison is the thickness, followed by width and then the length. However, it should be realized that dimensional comparison may proceed in any order and in any combination. Embodiments of a method in accordance with the present invention contemplates these combinations and are within the scope of this invention. The width of the desired shape being then compared to the width of the generated map. If the width of the desired shape can fit within the width of the generated shape, the computer may proceed to compare the foodstuff along a third dimensional unit. For example, if the generated map has so far met the specification for thickness and width, the computer may analyze or compare for length. In this step, the computer will compare the length of the generated map to the desired shape, once the two other parameters have been established. The computer can manipulate the three dimensions individually or in combination trying to find the best fit for the desired shape into the generated map. The computer may even skew or rotate the desired shape within the generated map to avoid defects or abnormalities in the foodstuff or may adjust one dimension only. The computer may also base the best fit algorithm on other considerations. For example, mass rather than size may be the determining factor. To adjust for mass, the computer will have to set two dimensions and vary the third to arrive at the desired mass or any combination of dimensions. It should also be pointed out that comparisons of dimensional units may proceed on an incremental basis, such that the sum of all increments may produce a rounded or otherwise non-linear cutting path.
In determining the optimal cutting path, the computer may avoid indentations or undesired constituents such as bone or fat in the generated map to avoid having these constituents in the finished product. The devices for determining bone or fat tissue can be incorporated into the present invention for this purpose. Other embodiments may have the computer cut out or around the indentations or undesired constituents.
In still other embodiments, the desired shaped may be optimized, for instance, if longer portions are more valuable than shorter portions, yet both are acceptable to the customer, the computer may adjust the length in order to maximize the length. Other units and dimensions may be selected by the computer or the user in order to maximize the value of the foodstuff portion. Dimensional units which may be used by a computer in comparison, determination and optimization step(s) include units such as length, thickness, width, or weight.
In a preferred embodiment of the method of the present invention, a cutting step 108 will follow the comparison step 104 in
A suitable cutting device in accordance with the present invention will be capable of cutting along one axis, preferably horizontally as shown in
Alternatively, the water jet or other cutting device may make one or more passes to cut the desired thickness, or the water jet may cut from both directions. The cutting device may be mounted on a fixed platform or structure and the conveyer speed may determine the rate of portioning. Alternatively, the cutting device may be carried on a movable track system such as is disclosed in U.S. Pat. No. 5,868,056, issued to Pfarr et al., which is herein incorporated by reference. In a movable track system, the cutting tool may move at a speed faster than the conveyor, thereby enabling more complicated and multiple pass cuts. Cutting devices may also be controlled to achieve a predetermined depth, for example when portioning a foodstuff into several products, the cutting device will need to control the depth of a cut to be able to make several portions from a single larger portion. Any leftover portions may be retained and used for other applications or processed further or discarded.
In a preferred embodiment of the method of the present invention, determining whether the foodstuff portion has shifted from the fixed reference points is performed following the first cutting step in step 110 at
If the device used to detect shifting of the foodstuff signals that the foodstuff has moved from its initial position, the foodstuff portion may be rescanned in a second rescan step 112 as shown in
In a preferred embodiment of a method in accordance with the present invention, rescanning the foodstuff may take place with similar equipment that was described for the earlier scanning step 102.
A second cutting step 120 proceeds from the second rescan step 112, map generation 114 and comparison step 116 of
Referring again to
A further step in a method according to the present invention will cut along a second path to establish a further dimension such as width or length or both as shown in
An embodiment of a foodstuff to be portioned in three dimensions using a method in accordance with the present invention is shown in
Another embodiment of a foodstuff to be portioned in three dimensions using a method in accordance with the present invention is shown in
Another embodiment of a foodstuff to be portioned in three dimensions using a method in accordance with the present invention is shown in
An embodiment of a foodstuff to be portioned in three dimensions using a method in accordance with the present invention is shown in
Another embodiment of a foodstuff to be portioned in three dimensions using a method in accordance with the present invention is shown in
A vacuum can be applied to the interior of the chamber housing 1106 by any one of numerous methods. The vacuum chamber preferably is perforated or slotted along its bottom section 1108 and the adjacent portion of the diagonal section 1112. Also, the belt 1118 is preferably perforated so that suction is applied to the adjacent surface of the foodstuff 1100. Thus, foodstuff 1100 carried by conveyor 1102 becomes attached to the belt 1118 and is carried by the belt after the foodstuff portions leave the conveyor 1102, which occurs as the foodstuff portions move along the diagonal portion 1112 of the vacuum chamber. The upper surface of the foodstuff in essence adheres to the belt 1118.
The foodstuff portions 1100, being carried by the belt 1118, are trimmed to thickness by a band knife 1130, spaced beneath the diagonal section 1112 of the vacuum chamber. Rather than a band knife, another type of knife, such as an ultrasonic knife, may be utilized. The distance between the knife 1130 and the adjacent surface of the housing 1106 can be varied to adjust the thickness of the foodstuff portion 1100 as desired.
The perforations in the housing 1106, in communication with a vacuum source, do not exist past the location of the band knife 1130. Instead, pressurized air is directed through perforations in the diagonal section 1112 of a vacuum chamber housing adjacent end wall 1114, thereby to break the suction between the foodstuff portion 1100 and the belt 1118, thereby to drop the trimmed foodstuff portion onto a conveyor 1132, which then can transport the foodstuff portions to another location to be further trimmed and portioned in accordance with the present invention. As shown in
One type of foodstuff with respect to which the present invention may be particularly useful is chicken breasts that have skin on one surface of the breasts. Preferably, such chicken breasts are placed on the conveyor 1102 with the skin side up, which is believed to provide a better suction contact with the belt 1110 than if the chicken breasts were positioned skinless side up. However, it is to be understood that other types of foodstuff can be trimmed to thickness using the present invention.
While illustrative embodiments have been illustrated and described, it will be appreciated that various changes can be made therein without departing from the spirit and scope of the invention.
This application is a division of application Ser. No. 12/369,715, filed Feb. 11, 2009, which is a division of application Ser. No. 11/747,117, filed May 10, 2007, now U.S. Pat. No. 8,025,000, issued Sep. 27, 2011, which is a division of application Ser. No. 10/361,730, filed Feb. 5, 2003, now U.S. Pat. No. 7,841,264, issued Nov. 30, 2010, which is a division of application Ser. No. 09/619424, filed Jul. 19, 2000, now abandoned, the disclosures of which are incorporated herein by reference in their entirety.
Number | Date | Country | |
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Parent | 12369715 | Feb 2009 | US |
Child | 13291967 | US | |
Parent | 11747117 | May 2007 | US |
Child | 12369715 | US | |
Parent | 10361730 | Feb 2003 | US |
Child | 11747117 | US | |
Parent | 09619424 | Jul 2000 | US |
Child | 10361730 | US |