A shredding drum for a cutting and separating device, including a pressure housing, on a first end portion of which an inlet opening is formed and on a second end portion of which an outlet opening is formed, wherein a multiplicity of cutting openings are arranged in a pressure housing portion of the pressure housing and pass right through the pressure housing portion from an inner wall to an outer wall, wherein the cutting openings are oriented with hole axes inclined at an angle (α.sub.O1, α.sub.O2) in relation to the inner wall. The underlying object was therefore to improve a shredding drum in such a way that the cutting performance of the cutting and separating device and the quality of the desired food ingredient are significantly improved. The object is achieved in that the inclination of the hole axes being chosen such that they are facing the inlet opening on the inner wall.

A shredding drum for a cutting and separating device, including a pressure housing, on a first end portion of which an inlet opening is formed and on a second end portion of which an outlet opening is formed, wherein a multiplicity of cutting openings are arranged in a pressure housing portion of the pressure housing and pass right through the pressure housing portion from an inner wall to an outer wall, wherein the cutting openings are oriented with hole axes inclined at an angle (α.sub.O1, α.sub.O2) in relation to the inner wall. The underlying object was therefore to improve a shredding drum in such a way that the cutting performance of the cutting and separating device and the quality of the desired food ingredient are significantly improved. The object is achieved in that the inclination of the hole axes being chosen such that they are facing the inlet opening on the inner wall.

A food processing device includes a feeding structure arranged for the transport of food objects downstream from an inlet to an outflow of a flow path. The feeding structure has a first feeder with a transport auger arranged upstream a knife, and a second feeder arranged downstream a knife, a knife configured to cut the food objects in the flow path to provide a substance of sliced lumps. The flow path defines an unhindered passage between the knife and the outflow to facilitate a free flow of the substance of sliced lumps away from the knife. An inspection unit is configured to detect undesired objects in the substance of sliced lumps. The food object could be meat, fruit, or vegetables. The processing device provides an unhindered flow of the sliced lumps away from the knife, facilitating an easier inspection and removal of undesired objects from the lumps.

A food processing device includes a feeding structure arranged for the transport of food objects downstream from an inlet to an outflow of a flow path. The feeding structure has a first feeder with a transport auger arranged upstream a knife, and a second feeder arranged downstream a knife, a knife configured to cut the food objects in the flow path to provide a substance of sliced lumps. The flow path defines an unhindered passage between the knife and the outflow to facilitate a free flow of the substance of sliced lumps away from the knife. An inspection unit is configured to detect undesired objects in the substance of sliced lumps. The food object could be meat, fruit, or vegetables. The processing device provides an unhindered flow of the sliced lumps away from the knife, facilitating an easier inspection and removal of undesired objects from the lumps.

An emulsion system is provided. The system includes a shaft that supports a plurality of cutting assemblies and screens in alternating order, wherein the cutting assembly rotates with respect to an in close proximity to the screen. The cutting assemblies include a plurality of cutting elements that extend radially outward from a hub and are positioned at consistent radial spacing along the perimeter of the hub. Each cutting element includes front and back edges that cut food particles in conjunction with holes within the screen, wherein the front and back edges are substantially perpendicular.

An emulsion system is provided. The system includes a shaft that supports a plurality of cutting assemblies and screens in alternating order, wherein the cutting assembly rotates with respect to an in close proximity to the screen. The cutting assemblies include a plurality of cutting elements that extend radially outward from a hub and are positioned at consistent radial spacing along the perimeter of the hub. Each cutting element includes front and back edges that cut food particles in conjunction with holes within the screen, wherein the front and back edges are substantially perpendicular.

A system includes a food dispenser, a cooking surface, and an arm assembly. The arm assembly is configured to receive a food product from the food dispenser and transport the food product to the cooking surface. The arm assembly includes an arm portion, an actuator, a cylinder, and a piston. The actuator drives rotation of the arm portion about a first rotational axis. The cylinder is attached to the arm portion and is rotatable relative to the arm portion about a second rotational axis. The piston is axially movable within the cylinder. The piston includes multiple stages. At least one of the stages is movable axially relative to another of the stages between a first position and a second position.

An emulsion system is provided. The system includes a shaft that supports a plurality of cutting assemblies and screens in alternating order, wherein the cutting assembly rotates with respect to an in close proximity to the screen. The cutting assemblies include a plurality of cutting elements that extend radially outward from a hub and are positioned at consistent radial spacing along the perimeter of the hub. Each cutting element includes front and back edges that cut food particles in conjunction with holes within the screen, wherein the front and back edges are substantially perpendicular.

An emulsion system is provided. The system includes a shaft that supports a plurality of cutting assemblies and screens in alternating order, wherein the cutting assembly rotates with respect to an in close proximity to the screen. The cutting assemblies include a plurality of cutting elements that extend radially outward from a hub and are positioned at consistent radial spacing along the perimeter of the hub. Each cutting element includes front and back edges that cut food particles in conjunction with holes within the screen, wherein the front and back edges are substantially perpendicular.

A meat grinder, having a housing, a conveying device, and at least one cutting-unit part. A meat grinder according to the invention comprises a housing, at least one conveying device for conveying material to be ground from an inlet opening to an outlet opening, and at least one cutting-unit part arranged in the housing. At least one transponder is arranged in or on the at least one cutting-unit part and at least one communication device for communicating with the transponder is arranged in or on the housing in such a way that data exchange between the communication device and the transponder is enabled.