A loading system for bone-in limb meat according to an embodiment is a loading system for loading a bone-in limb meat to a processing portion, the loading system includes: an image capturing portion for capturing an image of the bone-in limb meat before being loaded to the processing portion; an image processing portion capable of acquiring orientation information of the bone-in thigh meat from the image of the bone-in limb meat captured by the image capturing portion; an openable/closable pair of clamp pieces for holding the bone-in limb meat; an arm supporting the pair of clamp pieces, and capable of controlling a position and orientation of the pair of clamp pieces; and a control portion controlling, based on the orientation information acquired by the image processing portion, an operation of the arm and thereby holding the bone-in limb meat, and loading the bone-in limb meat to the processing portion.

A clamping device for a bone-in limb meat according to an embodiment includes a pair of clamp pieces including a first clamp piece and a second clamp piece, and being openable/closable so as to hold a bone-in limb meat, and rotation suppressing portions for suppressing a rotation of the bone-in limb meat, the rotation suppressing portions being disposed at positions deviated with respect to the pair of clamp pieces in a direction perpendicular to a plane including an opening/closing direction of the pair of clamp pieces. The rotation suppressing portions include a projection portion disposed so as to protrude from the first clamp piece into a space between the pair of clamp pieces and configured to contact the bone-in limb meat when viewed from the direction perpendicular to the plane.

Systems and methods for automated monitoring and control of food processing systems are disclosed. Data from one or more controllers of a food processing system is received during operation of the food processing system at a remote food processing facility. Values of one or more operating parameters of the food processing system are monitored, based on the received data. At least one event of interest occurring during the operation of the food processing system is detected, based on the monitored values of the one or more operating parameters. Control signals for adjusting a configuration of the food processing system are transmitted to the one or more controllers, based on the detected event.

A food processing system and a method, includes: an overhang rail system having a plurality of spaced apart shackles designed for carrying carcass parts such that the carcass parts are at least partly freely hanging, a re-positioning apparatus having an engagement structure selectively moveable by a moving mechanism, and at least one food processing device for performing at least one food processing step on the carcass parts while the carcass parts are conveyed past the at least one food processing device. The plurality of spaced apart shackles and the engagement structure move in a synchronized manner. The engagement structure is configured to engage the carcass parts at a position different from the carrying position of the shackle and adjusting the angular position relative to a vertical axis from an initial angular position to a pre-defined angular processing position.

A meat quality and yield improvement process comprises hanging the hind leg(s) of a carcass and applying an additional pulling force of from 50 to 500 kgf to the leg and back muscles of the carcass. The additional force stretches the muscle filaments of the leg and back muscles and is maintained until rigor is complete. The hind leg(s) of the carcass may be hung at an angle of 90 to 170 degrees to the vertical.

A method of, and an apparatus (1) for, continuously harvesting surrounding meat from a successive plurality animal legs having articulated first and second animal bones and an intermediate joint. The method continuously conveys the animal legs through a path of conveyance, and determines a location of the intermediate joint. Based on the determined location of the intermediate joint, adjusting a position of the intermediate joint and a cutting implement relative to one another, and performing cutting of tissue at a location commensurate with the location of the intermediate joint. The step of determining the location of the intermediate joint is performed contactless, and without interrupting continuous conveyance of the animal legs.

A method and system for receiving, processing, and stunning poultry in a poultry processing facility includes an receiving system for receiving and unloading live poultry from a transport vehicle, a controlled atmosphere stunning system, a stunned poultry hanging station for receiving and transferring stunned poultry to another facility for further processing, such as slaughtering the stunned poultry. Shuttle conveyors and cage pushers coordinate to unload cages of live poultry from the transport vehicle and begin conveying the cages toward the stunning system. Accumulators, cage de-stackers, cage stackers, cage washers, tilted conveyors, and other features may be included with the system.

Systems and methods for automated monitoring and control of food processing systems are disclosed. Data from one or more controllers of a food processing system is received during operation of the food processing system at a remote food processing facility. Values of one or more operating parameters of the food processing system are monitored, based on the received data. At least one event of interest occurring during the operation of the food processing system is detected, based on the monitored values of the one or more operating parameters. Control signals for adjusting a configuration of the food processing system are transmitted to the one or more controllers, based on the detected event.

The present invention provides a method and system for processing insect larvae in an ethical manner and without imposing unnecessary stress on them. The method involves anaesthetising the insects by cooling and then cutting them, thereby destroying the nervous system of the insects. Thus, an energy-saving method of processing insects with minimal stress is provided.

A food processing installation for processing food items includes: a food processing enclosure; a cutting device in the food processing enclosure; a particle capturing enclosure; an exhaust vent connected to the food processing enclosure via a vent inlet and connected to the particle capturing enclosure via a vent outlet; and a spray nozzle arrangement separate from the cutting device and located downstream relative to the vent inlet. The exhaust vent is configured to conduct an exhaust flow of exhaust air comprising food aerosols emitted from the food processing enclosure to the particle capturing enclosure, and the spray nozzle arrangement is configured to eject a spray of droplets that coalesce with the food aerosols. A method is provided for filtering air from a food processing installation and a particle capturing device.