Systems and methods describe continuously and progressively hydrating and post-processing material, such as food material for meat analogue products. First, material is provided to be conveyed through a material passage between an exterior tube and a rotating inner shaft, with the rotating inner shaft including one or more particle resizing features extending around the rotating inner shaft. Concurrently, the material is post-processed, via the particle resizing features, to reduce the material into a plurality of smaller material particles. Also concurrently, water is continuously and progressively provided to the material to produce hydrated material particles.

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.

The present invention relates to a magazine turret attachment for a portioning machine for dividing a strand-like product into individual portions and a portioning machine having such a magazine turret attachment. The magazine turret attachment includes a turret base rotatable about a rotation axis which has at least one chute extending through the turret base and the chute axis of which extends at least approximately parallel to the rotation axis of the turret base; and at least one first chute module which may be reversibly arranged on the turret base in the area of the first chute and which is provided with only one chute extending through said first chute module and the chute axis of which extends coaxially to the chute axis of the first chute of the turret base and the cross-section of which corresponds at least approximately to the cross-section of the at least one chute of the turret base in order to form a first reception chute for a strand-like product.

A system for forming all variants of hamburger steaks, without being dedicated to a single variant, from a mass of meat comprises a mold including at least one cavity for forming hamburger steak, a channel for supplying the meat mass to the mold, and an element for forming an interface between the channel for supplying the meat mass and the mold. The element for forming an interface includes a pipe length having a first end connected to an outlet of the channel for supplying the meat mass and an opposite second end connected to an inlet of the mold, a grinding plate, and edges for holding the grinding plate in a cross section of the pipe length, the edges for holding the grinding plate being discretely distributed along the pipe length.

The invention provides a method for moulding three-dimensional products from a mass of foodstuff starting materials which are suitable for consumption, in particular a meat mass. The method comprises the steps of filling a mould cavity, which is open on one side, with the mass of foodstuff starting materials which are suitable for consumption, which mould cavity is defined by a boundary comprising walls and base, in order to mould a moulded three-dimensional product, and the removal of the moulded three-dimensional product from the mould cavity. In the method according to the invention, during removal the adhesion forces between the moulded product and the boundary are eliminated virtually simultaneously along all the interfaces.

A rotary molding system for molding food products, mold cavities formed when a mold shell rotates mold shapes disposed along the mold shell into a fill position between a fill plate and a wear plate. Molded food products are removed from mold cavities using knock-out cups, the use of air pressure, or the use of a vacuum source disposed below the mold cavity, without the need to slow the rotation of the mold shell. Knock-out cups may be used with a heating system to reduce accumulation of unwanted materials on the knock-out cups. The rotary molding system can also be used to form products with contoured surfaces. A smart tagging system can be used to ensure that compatible sets of mold shells and knock out cups are being used. A vacuum region may be disposed upstream of the fill position to remove air within the mold cavity prior to filling.

The present invention relates to a method and a filling machine for portioning pasty masses for the purpose of food production, wherein a pasty mass is fed by the filling machine into the filling flow divider, where it is separated into a plurality of mass flows and discharged in portions in the discharge direction. At the end of each portion the mass flow is sucked back in a direction opposite to the discharge direction.

A frozen product of minced fish meat frozen into granules includes: 90 wt % or more of meat granules having a substantially columnar shape with a 3 mm to 7 mm diameter; and 10 wt % or less of meat granules with a short diameter of 2 mm or less. A method of producing the minced fish meat frozen into granules includes: raising the temperature of fish meat which has been frozen at 20 C. or less to a temperature of from 10 C. to 5 C.; mincing the fish meat while maintaining the temperature of the fish meat at 10 C. to 5 C. by using a meat mincer having a feed screw, a plate, and a plate knife at a rotation speed of 200 rpm or less; lowering the temperature of minced fish meat to 20 C. or less; and crushing the minced fish meat frozen at 20 C. or less into granules.

High meat content extruded pet foods and methods of preparation thereof, preferably include initial treatment of a high moisture meat slurry to create a dewatered meat fraction and a liquid fraction. The liquid fraction is directed to an extruder, along with typical dry pet food ingredients, in order to create an extruded intermediate. This intermediate is then mixed with the dewatered meat fraction, and the mixture is then extruded and dried to create a final pet food. The methods may be carried out using separate processing systems each including a mixer, an extruder, and a drying assembly, in order to maximize production rates.

A meat dewatering assembly (10) includes a support frame (12), a twin screw dewatering unit (14), a drive assembly (16) coupled with the unit (14), and a perforated housing (60). The unit (14) has a pair of tapered, non-parallel, intermeshed, helically flighted screws (52, 54) presenting nip clearances (59) between the fighting (55). The drive assembly (16) serves to counter-rotate the screws (52, 54). In use, emulsified meat is passed into the housing (60) during counter-rotation of the screws (52, 54), in order to compress the meat within the clearances (59) and thereby express water from the meat. Adjustment collars (38) permit selective size alteration of the nip clearances (59).