A method of processing poultry portions determines at a control unit a target weight of a cut poultry portion; inspects a poultry portion using an inspection unit to determine a mass distribution of said poultry portion and providing said mass distribution to the control unit; calculates a cutting plan of the poultry portion based on the target weight and the mass distribution using the control unit; uses a mechanical gripper so as to grip the poultry portion and arrange said poultry portion for execution of the cutting plan; and cuts the poultry portion using a cutting unit in accordance with the cutting plan so as to produce a cut poultry portion in accordance with the target weight. A system for processing poultry portions is configured to perform the foregoing method, among others.

In an embodiment, an apparatus for processing meat product and a method of using same is provided. A first station includes a scanner which scans features of a meat product. A second station side straps the meat product in accordance with information received from the scan of the features. The second station includes a support, and spaced-apart knifes disposed on opposite sides of the support. Each knife has an axis of rotation that is normal to the longitudinal axis of the support. A position of each knife relative to the support in a direction normal to the longitudinal axis can be varied. A controller is programmed to control movement of each knife in accordance with the information received from the scanner.

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 method and apparatus disclosed and claimed herein is a combination of a robotic arm including an ultrasonic 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.

An arrangement for automatically removing a strip of dark meat from a fish fillet has a conveying unit for transporting the fish fillet from an inlet to an outlet area in a transport direction along a transport path. Starting from the inlet area, successively along the transport path, are provided: a first means for detecting dark meat; a first cutting apparatus for removing a middle partial strip of dark meat; a means for opening up the fillet such that cut surfaces of a ventral-side partial and of a dorsal-side partial strip of dark meat point upwards; a cutting unit for removing the partial strips, the cutting unit comprising second and third cutting apparatuses for removing the ventral and dorsal-side partial strips. A control device is connected to the detecting means and the cutting apparatuses, and all cuts are based on information from the detecting means. A corresponding method is provided.

A system and a method for separating a fore end of a half pig carcass by making a first cut between ribs three and four up to the shoulder blade followed by a second cut through the rest of the carcass. The first cut is made using a regular knife blade, the second cut is made using a scissor blade.

An animal ribcage primal cut having a bone array located therein is portioned into one or more sub primal cuts, each having at least one bone located therein. The primal cut is scanned at scanning station 14 while being conveyed on a conveyor 12 to determine the physical characteristics of the primal cut. A processor 18 determines how to portion the primal cut into desired sub primal cuts in accordance with desired physical characteristics of the sub primal cut and production requirements for the sub primal cuts. A controller controls a cutter to divide the primal cut into one or more sub primal cuts according to the determination previously made on how to portion the primal cut into desired sub primal cuts.

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 method and apparatus disclosed and claimed herein is a combination of a robotic arm including an ultrasonic 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.

An automated saw wherein: the automated saw comprises one or more visual sensors, a meat positioning assembly. The automated saw is configured to analyze an uncut meat and calculate one or more cutting depths for one or more cut portions from the uncut meat. The uncut meat comprises a first end and a second end. The first end of the uncut meat can be analyzed by the automated saw by: capturing a first slice image of the first end, locating a first bone configuration and a configuration of one or more meat portions in relation to the first bone configuration, and measuring portions of the one or more meat portions to categorize which among one or more cuts of meat is presented at the first end of the uncut meat. The automated saw calculates a first cutting depth for a first meat portion.

A cutting apparatus for cutting a food object includes at least one circular blade being rotatable around a first axis through a center of the circular blade. The circular blade is rotatable around a second axis, such that the second axis is parallel and non-coaxial with respect to the first axis. The apparatus includes a measurement device for determining a position of at least a part of the surface of the food object to be cut, such as a height profiler arranged for determining a height profile of the food object, and a processor arranged for controlling an angular speed of the circular blade around the second axis based on the position of at least a part of the surface of the food object to be cut, such as the height profile.

A method is provided of pressing an irregularly shaped, elongated loaf of an elastic material into a strand with a cross-section which is constant along its longitudinal extension. The method includes disposing the loaf in a form tube of the slicing machine, and determining basic data of the loaf before pressing, the basic data comprising at least physical basic data of the loaf before pressing. The method further includes determining a target length change of the loaf between an unpressed state and a pressed state, determining a target cross-sectional change of the loaf between the unpressed state and the pressed state, and pressing the loaf in the form tube in at least one cross direction to the longitudinal extension by a cross press stamp and in a longitudinal pressing direction of the form tube by a longitudinal press stamp, according to the target length change and the target cross-sectional change.