A mincing drum for a cutting and separating device, at the first end section of which there is an inlet opening and at the second end section of which there is an outlet opening, a plurality of cutting openings being arranged in a pressure housing section of the mincing drum and passing continuously through the pressure housing section from an inner wall to an outer wall, each cutting opening having, on the inner wall, a cutting opening edge facing the outlet opening and a drawing-in opening edge facing the inlet opening. The cutting performance of the cutting and separating device and the quality of the desired food component is significantly improved as a feed channel which is recessed relative to the inner wall is situated between the cutting opening edge and the drawing-in opening edge.

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 conveying screw for a cutting and separating device, including a screw shaft having at least one helical screw flight integrally moulded thereon, which, in an installed position, has a front flank for transporting a foodstuff by pushing, a rear flank arranged on the opposite side, and, at its distal end between the front flank and the rear flank, a cylindrical portion, which is formed in the transition region to the front flank of the screw flight with a sharpened cutting edge, the sharpened cutting edge having a positive rake angle (γ) arranged between the front flank and a processing plane oriented at right angles to the screw shaft. The cutting performance of the cutting and separating device are significantly improved as the sharpened cutting edge is formed from a groove made on a distal end of the front flank, the outer contour of which groove cuts into the cylindrical portion.

A stomper for a food grinder comprises a distal end adapted to push food into a receiving tube of a food grinder, a proximal handle end adapted for a user to grasp the stomper while pushing food into the receiving tube of the food grinder, an elongated shaft between the distal end and the proximal handle end, a channel defined in the proximal handle end, and a bayonet projecting from one or more internal walls of the channel. The bayonet is adapted to engage a protrusion on an auger of the food grinder to apply a pulling force to remove the auger from the food grinder.

A system 400 for obtaining a substance from a commodity has a first apparatus 420 with first 422 and second 424 openings, a device 426 for moving the commodity through the first apparatus, and at least one blade 428 for shearing the commodity. The at least one blade 428 is positioned between the first opening 422 and the second opening 424. A second apparatus 440 has a first opening 442 and a second opening 444, with the first opening 442 being fluidly connected to the second opening 424 of the first apparatus 420. The second apparatus 440 includes a device 446 for moving the sheared commodity from the second apparatus first opening 442 to the second opening 444. A third apparatus 460 obtains the substance from the sheared commodity, including a separator 460 having a first opening 462 fluidly connected to the second opening 444 of the second apparatus 440.

A viscous food product dispensing system having a transport section for receiving a particulate food product from a bin, an auger for processing and conveying the received particulate food product from the transport section into an outlet adapter via one or more flutes, a milling device housed in the outlet adapter, and a discharge nozzle in the outlet adapter that pinches off the viscous food product created by the milling device. The auger has a unique design that allows it to engage and break whole nuts.

A grinding machine for grinding food-products, such as meat or the like, includes an orifice plate at the outlet of a grinding head. The orifice plate has collection passages that discharge a mixture of soft material and hard material through the orifice plate. A separator assembly, including a separator screw, separation chamber, metering auger, and metering cone, is located downstream of the orifice plate for separating the soft material from the hard material. The metering auger is fixedly coupled to a distal end of the separator screw and has a reduced diameter relative to the separator screw. The metering auger advances in a downstream direction the hard material of the mixture of soft material and hard material. The metering cone includes an internal conical portion and a metering passageway formed therein, where the metering auger is in communication with the metering passageway, and where a selected diameter of the metering auger defines an amount of the hard material that is advanced in the downstream direction through the metering passageway toward a discharge end.

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.

Disclosed is a meat grinder. According to the technical solution of this disclosure, food is placed into a processing cavity through a material inlet, and after the food is fallen to a side of a propeller away from a cutter head, the propeller is configure to propel the food to a cutter. The food is pressed against the cutter head and the food on the cutter head is cut by the cutter, and the food in discharge holes is squeeze outed by the propeller. Because the propeller is rotatably connected to the cutter head through the wear part, it may prevent an end of the propeller facing the cutter head from rubbing directly against the cutter head and causing black powder, so as to avoid the risk of contamination of the meat and affect the user's experience.