Method and system for optically assessing properties of a body on at least one sectional surface of at least one cut introduced in the body in question. The sectional surface is thereby optically recorded directly during the cutting operation by an image acquisition unit, namely, by means of optical sensors of a blade of a cutting tool that is designed for this purpose. The data resulting from a digitization of the sensor signals that have been converted into electrical signals are then processed in an image processing device to visualize the at least one sectional surface on at least one display or/and to create reports in regard to the characteristics of the body or/and in order to classify the body in accordance with a classification system, or/and to derive control signals for a subsequent further processing of the body or of parts produced by the execution of the at least one cut.

A system (100) for cutting work product (104) into portions (P) and unloading the portions includes a conveyance system (102) for carrying the workpieces and portions, as well as a scanner (110) for scanning the work products. A cutter system (120) composed of cutter assemblies (122) carried by carrier systems (124) may be arranged in an array or series along the conveyance system for cutting, trimming, and portioning the work products (104) into end pieces (P) of desired sizes or other physical parameters. An unloading system (130) composed of one or more unloading assemblies/units/apparatus (132) are carried by the same carrier systems (124) used to carry the cutter assemblies (122) to pick up the portioned pieces (P) and either move them to a different location or replace the portioned workpieces back onto the conveyance system after the trim of the workpiece has been removed.

A cutting apparatus for cutting a food object where inlet and outlet conveyors are arranged in an end-to-end arrangement. A moving mechanism is provided for adjusting the relative position between the ends of the inlet and outlet conveyors, a cutting device is provided having a cutting plane extending between the inlet and outlet conveyors, a detection mechanism is provided for detecting at least one characteristics related to the food object, and a control device is provided for controlling the moving mechanism and the cutting device. Controlling the moving mechanism includes utilizing the at least one detected characteristics in determining a target width of an opening between the ends of the inlet and outlet conveyors, and controlling the cutting device includes subsequently cutting the food object into smaller food pieces. The target width of the opening is selected such that it allows smaller food pieces to fall through the opening.

A system and method for removing a bone from a primal or sub primal meat cut that includes a conveyance system having a continuous conveyor extending along a path of conveyance from an upstream point at the loading end to a downstream point at the discharge. The system includes a pair of opposing support surfaces projecting vertically upward from a first position of the continuous conveyor along the path of conveyance whereby each of the opposing support surfaces of the pair inwardly extend one toward the other, from an upper level downward vertically to a lower level. Each opposing support surface of the pair has a downward slope and each opposing surface of the pair converges at a recessed valley at the lower level.

Workpieces WP are scanned at a scanning station (14) while being transported on a conveyor (12). A control system (18) analyzes the scanning data to develop a three-dimensional model of the workpiece WP and determine how to portion or trim the workpiece as desired. The cutting/trimming paths made through the workpiece is compared with the predetermined cutting paths to quantify the correspondence (or deviance) of the actual cutting paths from the predetermining cutting paths. This information is reviewed to determine whether the system (10) is operating property. If the alignment of the actual cutting/trimming paths with the predetermined cutting/trimming paths are not within a predetermined set point, the control system (18) seeks to determine the cause of the deviation as well as determine what remedial steps to take to restore the alignment of the actual cutting/trimming paths with the predetermined cutting/trimming paths.

A processing system (10) and a corresponding method are provided for processing work products (WP), including food items, to locate and quantify voids, undercuts and similar anomalies in the work products. The work products are conveyed past an X-ray scanner (14) by a conveyance device (12). Data from the X-ray scanning is transmitted to control system (18). Simultaneously with the X-ray scanning of the work product, the work product is optically scanned at the same location on the work product where X-ray scanning is occurring. The data from the optical scanner is also transmitted to the control system. Such data is analyzed to develop or generate the thickness profile of the work product. From the differences in the thickness profiles generated from the X-ray scanning data versus the optical scanning data, the location of voids, undercuts and similar anomalies can be determined by the control system. This information is used by the processing system (10) to process the work product as desired, including adjusting for the locations and sizes of voids, undercuts and similar anomalies present in the work product.

The apparatus for detecting physical characteristics of food products, such as poultry, meat or fish, includes: a conveyor for transporting the products; a floating belt, located above the conveyor so as to define an analysis zone (Z) therebetween; a first and a second detecting device, located on opposite sides of an advancement path, each adapted to acquire a multiplicity of partial profiles of the products in the analysis zone (Z), a processing unit connected to the first and second detecting devices and including a first shape module configured to determine the conformation of the external surface of a first portion of the product, based on the partial profiles acquired by the first detecting device; and a second shape module (62) configured to determine the conformation of the external surface of a second portion of the product, based on the partial profiles acquired by the second detecting device.

A method for processing food products (12) includes transporting the food products by a first conveyor (11), an X-ray unit (13) positioned between the intake end and the discharge end of the first conveyor to acquire a first set of product-specific data relating to the food product transported. At least one first optical camera (17), assigned to the first conveyor, is used to acquire a second set of product-specific data relating to the food product. A control unit (18) is used to receive and integrate the first and second data sets to analyze the composition of the food product and determine parameters for the food product. Based on the determined parameters of the food product, the food product is cut with a cutting unit, under the control of the control unit.

Method and system for optically assessing properties of a body on at least one sectional surface of at least one cut introduced in the body in question. The sectional surface is thereby optically recorded directly during the cutting operation by an image acquisition unit, namely, by means of optical sensors of a blade of a cutting tool that is designed for this purpose. The data resulting from a digitization of the sensor signals that have been converted into electrical signals are then processed in an image processing device to visualize the at least one sectional surface on at least one display or/and to create reports in regard to the characteristics of the body or/and to classify the body in accordance with a classification system, or/and to derive control signals for a subsequent further processing of the body or of parts produced by the execution of the at least one cut.

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.