A processing system (10) and corresponding method (158) are provided for processing workpieces (WP), including food items, to cut and remove undesirable components from the food items and/or portion the food items while being conveyed on a conveyor system (12). An X-ray scanning station (14) is located on an upstream conveyor section (20) to ascertain size and/or shape parameters of the food items as well as the location of any undesirable components of the food items, such as bones, fat or cartilage. Thereafter the food items are transferred to a downstream conveyor (20) at which is located an optical scanner (102) to ascertain the size and/or shape parameters of the food items. The results of the X-ray and optical scanning are transmitted to a processor (18) to confirm that the food item scanned by the optical scanner is the same as that previously scanned by the X-ray scanner. Once this identity is confirmed, if required, the data from the X-ray scanner is translated or transformed onto the data from the optical scanner. Such translation may include one or more of the shifting of the food items in the X and/or Y direction, rotation of the food item, scaling of the size of the food item, and sheer distortion of the food item. Next, the location of the undesirable material within the food item is mapped from the X-ray scanning data onto the optical scanning data. Thereafter, the undesirable material is removed by a cutter(s) (28). The food item may also (or alternatively) been portioned by the cutter(s) (28).

The technology as disclosed herein includes a method and apparatus for deboning a meat item, and more particular for deboning a poultry item including performing an initial shoulder cut for removing boneless breast meat from the poultry carcass or frame. The technology as disclosed and claimed further includes a method and apparatus for removing a tender meat portion from a poultry item. The method and apparatus disclosed and claimed herein is a combination of a robotic arm including an ultrasonic knife implement and/or an annular blade knife implement and a vision system for varying the cut path based on the shape and size of the poultry item. The combination as claimed including the ultrasonic knife can perform a meat cut while penetrating the meat with less force than the typical penetration that occurs when using a traditional knife. The combination as claimed including the annular blade knife implement can remove the tender meat portion for the keel bone and posterior sheath.

An automatic meat cutting apparatus includes: a skewer holding system to hold a skewer with meat in a vertical position and to rotate the skewer about a vertical axis of rotation, a grill unit to grill meat on the skewer, a meat cutting device to cut meat from the skewer, and an actuator system to move the cutting device with respect to the skewer. The automatic meat cutting apparatus further includes: a sensor device arranged to provide a sensor signal representative for a location of the meat on the skewer, and a processing unit to control the actuator system to move the cutting device to a desired cutting position on the basis of the sensor signal.

An image processing device includes an image acquiring unit configured to acquire an image in which a subject including an element to be cut off is pictured, a boundary identifying unit configured to identify a boundary between the element and a part other than the element on the image by performing image processing on the image, and a trajectory determining unit configured to determine a trajectory of a cutting edge when the element is cut off from the subject on the basis of the boundary.

A method and system (10) are provided for automatically portioning workpieces (14) using a rotating blade (22) passing through narrow gap (20) formed between the ends of adjacent conveyors (12) and (18). A scanning system (16) scans the workpieces (14) to physically characterize the workpieces and control the operation of the blade (22), including its rotational speed. The portioning of the workpiece can be carried out in accordance with one or more directly-controlled characteristics (parameter/specifications), such as a cutting path of the blade (22), the rotational speed of the blade (22), and the speed of the conveyor (12). The directly-controlled characteristics may be varied until an acceptable set of one or more indirectly-controlled characteristics is achieved, including, for example, the weight of the cut portions, the quality of the cuts achieved by the cutting blade, and the throughput of the portioning system (10).

This invention relates to method of automatically cutting a meat product, in particular beef tenderloin, having a thumb-like part extending away from a head part of the meat product towards a tail part such that the meat product has a V-shape. The method includes conveying a meat product to be cut, obtaining image data of the meat product, determining a boundary position between a thumb-like part and a head part of the meat product, and utilizing the image data in instructing a cutting unit to cut the meat product into portions, where the cutting includes cutting on both sides of the boundary position such that the resulting portion fulfills a pre-defined criteria including a criteria indicating the extent of the thumb-like part in the resulting portion.

A method and system are provided for automatically portioning workpieces, such as food products, into both shape and other user-defined specification(s). Workpieces are portioned both to shape and weight, such as to a weight-specific uniform shape, by adjusting (e.g., scaling up and down or slightly modifying) a desired template shape until the desired weight is achieved depending on the varying thickness of each workpiece. For example, from a thicker workpiece, a smaller-sized piece having a predefined shape and weight is portioned, while from a thinner workpiece, a larger-sized piece having the same predefined shape and weight is portioned. The system permits a user to scan in and edit a desired (reference) shape to be used as a template in the portioning process.

Method and system for the automatic monitoring of the process for the industrial cutting up and deboning of slaughtered animal bodies with respect to leaving the smallest fraction as possible of meat remaining behind on the bones extracted in the cutting process. For this purpose, images of segments that are detached during the cutting up of large pieces of the slaughtered animal body are recorded by an image recording device on at least one conveyor belt serving for transporting them away. Based on their different colors, images of these segments are differentiated from the conveyor belt, and bone, fat, and meat remaining on the bone of the images within the segments are also differentiated. By determining a quotient between a geometric quantity of the portions identified as meat for one or a plurality of segments and a geometric quantity of the same type determined overall for the same segment or the same segments, the fraction of meat in the separated segments is then determined. Finally, the result is visualized, for example, directly on a display, or/and is further processed for creating reports or for the output of warning signals.

A method of removing a foreign object from a food piece is provided. The method comprises detecting the location of a foreign object in a food piece (10); conveying the food piece to a cutting tool (42); operating the cutting tool to cut around the detected location of the foreign object and subsequently to engage and eject the foreign object from the food piece.

The disclosure relates to methods and systems for carcass processing options based on a primal/subprimal weights and yield training module. In one embodiment, the methods and systems disclosed herein use automated methods to process image data, process the image data using one or more trained modules, and determine carcass processing options based on an estimated weight calculation output from the trained modules, without using a scale-based weight measurement as an input.