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 disgregating device of biological material, comprising: a hollow outer body, defining an inner chamber; a fixed disgregating grid, having a plurality of microholes provided with sharp edges, and housed transversely in the inner chamber so as to define an upper loading chamber apt to be loaded with the biological material to be disgregated and a lower collecting chamber apt to collect the biological material, after it has been disgregated; and a bladed rotor, rotating in the inner chamber, apt to co-operate, rotating, with the fixed disgregating grid, so as to feed and bring the biological material, contained in the upper loading chamber, into contact with the microholes of the disgregating grid and therefore cause the disgregation of the biological material making it pass through these microholes.

A cutting device, a separator and a method for separating food components using a separator compensates the effects which an increasing wear on a cutting tool arranged on a rotating body have on comminuting a foodstuff by movably arranging the cutting tool on the rotating body.

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 tissue mincer includes a canister defining a chamber and an opening, a lid configured to cover the opening, and a tissue cutter. The tissue cutter includes a shaft and a blade assembly. The shaft includes a proximal portion that is configured to be rotated and a distal portion extending into the chamber when the tissue mincer is assembled. The distal portion is coupled to the blade assembly. The blade assembly includes a first disk, at least one blade spaced from the distal portion of the shaft by the first disk, and a disk retainer that encloses at least a portion of the blade. The blade can rotate relative to at least the first disk when the proximal portion of the shaft rotates. The blade includes at least one cutting edge that is configured to cut tissue as the blade rotates.

A cutting knife for a rotating emulsion system is provided. The knife includes a body with a bottom surface and a leading portion, the bottom surface and the leading portion collectively form a cutting edge. The body further comprises a portion that is configured to be inserted within a slot within a cutting assembly with the bottom surface and a portion of the leading portion extending outward from the slot, the cutting assembly configured to be rotated by a shaft that extends through a center hole in the cutting assembly and is fixed to the cutting assembly, wherein the leading portion is a surface of the body that faces the direction of rotation of the body as the cutting assembly is rotated, The cutting edge and the leading portion each form a plurality of serrations along at least a portion of a length thereof.

The invention relates to a reliable cutting set system for a meat mincing machine. The mutually matched coding (14, 24) between knife pins (10) and the cutting set element (20) prevents an incorrect installation of the cutting set element (20) after a cleaning process or during the initial assembly, thereby increasing the operational safety. The invention allows a detection of the correct cutting set element (20) of a cutting set system and thus an unambiguous allocation of the cutting set element to a knife pin (10) of a cutting set system.

The invention relates to a blade, more particularly for a meat grinder. The blade (10) has a collar-type sealing ring (18) between the hub (11) and the inner ends of the blade wings (14). The sealing ring (18) has the same height as the hub (11) as the adjacent sealing ring (18) has or the hub (11) has a smaller height. The hub (11) thus does not impede the rubbing of the cutting edges (16, 17) of the blade (10) or the rubbing of the sealing ring (18).

A meat grinding reclamation system is disclosed herein. The system uses a first meat grinder coaxially coupled to a second meat grinder. The first meat grinder separates meat from undesired material such as gristle, hard fat, connective tissue, sinew, and bone. Most of the meat is ground, while the undesired material is remixed into a small portion of the meat and is moved from the first grinder into the second grinder. The second grinder separates remaining meat and carrier meat from the undesired material, grinding the reclaimed meat and moving it into a bin with the originally separated meat. The waste material is moved to a waste bin. Pressurized air may be used to prevent the waste material from becoming clogged in the system.

A grinding machine includes first feed screw, first head, first center pin, first knife assembly, bushing and first orifice plate. Second feed screw is coupled to first center pin and rotates within second head. Second feed screw is positioned against the bushing such that the bushing acts as a thrust bearing. Second center pin is coupled to second feed screw and is configured to rotate a second knife assembly. Second orifice plate is arranged on second center pin. Second mounting ring can be linearly adjusted relative to second head to axially position second orifice plate between a stop shoulder of second head and a lip of second mounting ring. Second feed screw may include a plurality of flights arranged in a split flight configuration including one or more ingress end flights and one or more egress end flights.