A system and method are provided for making strips of edible material. Edible material is contained in a hopper having a discharge opening including a first side and a second side. A discharge shaping roller is positioned so that its surface is adjacent to the first side and said second side. Similarly, a cooling roller is also positioned so that its surface is adjacent to the first side and the second side. Edible material passes between the first side, the second side, the cooling roller, and the discharge roller to from a strip of edible material that is deposited on the cooling roller. The cooling roller then cools the strip of edible material and it is separated from the cooling roller by a blade. Once the strip is separated from the cooling roller it is deposited on a base of edible material such as a cookie or wafer.

A system and method are provided for making strips of edible material. Edible material is contained in a hopper having a discharge opening including a first side and a second side. A discharge shaping roller is positioned so that its surface is adjacent to the first side and said second side. Similarly, a cooling roller is also positioned so that its surface is adjacent to the first side and the second side. Edible material passes between the first side, the second side, the cooling roller, and the discharge roller to from a strip of edible material that is deposited on the cooling roller. The cooling roller then cools the strip of edible material and it is separated from the cooling roller by a blade. Once the strip is separated from the cooling roller it is deposited on a base of edible material such as a cookie or wafer.

Apparatus and methods for bulk processing items on a conveyor belt using an angled axial fan that extends obliquely into a processing chamber and includes a curved back wall forming an air flow chamber. The angled axial fan enhances air flow around a product being processed on the conveyor belt. A heater employs shrouds and a series of baffle plates held together using a connecting pin to heat circulated air in a low-pressure area below the conveyor belt. Baffles in an upper chamber mix and direct heated, circulated air over the conveyed product.

Apparatus and methods for bulk processing items on a conveyor belt using an angled axial fan that extends obliquely into a processing chamber and includes a curved back wall forming an air flow chamber. The angled axial fan enhances air flow around a product being processed on the conveyor belt. A heater employs shrouds and a series of baffle plates held together using a connecting pin to heat circulated air in a low-pressure area below the conveyor belt. Baffles in an upper chamber mix and direct heated, circulated air over the conveyed product.

The present disclosure provides a system and method for fabrication of a three-dimensional edible product having two or more edible components. The system comprises a processor configured to receive an edible product design having pattern coordinates, and to provide pattern address signals, a printing mechanism having a printing head with two or more sets of a plurality of discrete applicators, each one of the two or more sets is configured to receive and dispense a different edible component, each of said discrete applicators being configured to receive and selectively dispense, its corresponding edible component onto a printing support bed in accordance with said pattern address signals, and a driving mechanism configurable to control the position of said printing head with respect to a printing support bed.

A cell (100) for making an anisotropic-structured product from a protein starting material, the cell (100) comprising an inner member (110) and an outer member (120) arranged concentrically along a longitudinal axis (180) to define together a chamber (150) for holding the starting material, wherein the inner member (110) and the outer member (120) are rotatable relative each other about the longitudinal axis (180) for providing the shear force to the starting material and wherein both the inner member (110) and the outer member (120) further define for the cell an inner longitudinal surface (114) and an outer longitudinal surface (124) facing away the chamber (150) such that a normal of each longitudinal surface is transverse to the longitudinal axis (180) characterized in that both members are designed to be exposed to the ambient for allowing a heat exchange between both the inner longitudinal surface (114) and the outer longitudinal surface (124) with the ambient to heat the chamber (150).

A cell (100) for making an anisotropic-structured product from a protein starting material, the cell (100) comprising an inner member (110) and an outer member (120) arranged concentrically along a longitudinal axis (180) to define together a chamber (150) for holding the starting material, wherein the inner member (110) and the outer member (120) are rotatable relative each other about the longitudinal axis (180) for providing the shear force to the starting material and wherein both the inner member (110) and the outer member (120) further define for the cell an inner longitudinal surface (114) and an outer longitudinal surface (124) facing away the chamber (150) such that a normal of each longitudinal surface is transverse to the longitudinal axis (180) characterized in that both members are designed to be exposed to the ambient for allowing a heat exchange between both the inner longitudinal surface (114) and the outer longitudinal surface (124) with the ambient to heat the chamber (150).

The present invention relates to a food production device, configured to provide texture to a mass of viscoelastic food-stuff material, which comprises an outer member (10), an inner member(21), which is disposed in an interior of the outer member (10) and a lid (22). A texturizing chamber (2) of the device is formed between the outer member (10) and the inner member (21), for receiving and retaining the mass of viscoelastic foodstuff material during use, and the lid (22) is configured to close-off the texturizing chamber (2) from its surroundings. The outer member (10) and the inner member (21) are rotatable with respect to each other to effect a shear stress with the outer member (10) and the inner member (21), which is configured to act onto the foodstuff material in the texturizing chamber (2). The outer member (10) comprises a bottom wall (12) at a bottom end of the outer member (10) and a top end opening at a top end of the outer member. The lid (22) is configured to be mounted at the top end of the outer member (10) to close-off the top end opening.

To provide a food product molding device and a food product manufacturing method capable of molding foodstuffs into a food product having stacked plural layers with a simple structure. A mold unit in which a first mold plate and a second mold plate are stacked slidingly moves by a drive unit. Through holes respectively provided in the first mold plate and the second mold plate are linked to form molding hole portions. The molding hole portions move to a first filling position in which upper ends of the molding hole portions are connected to first filling openings, a second filling position in which upper ends of the molding hole portions are connected to second filling openings, and a discharge position in which upper ends of the molding hole portions are connected to pusher ports by the slide movement of the mold unit.

To provide a food product molding device and a food product manufacturing method capable of molding foodstuffs into a food product having stacked plural layers with a simple structure. A mold unit in which a first mold plate and a second mold plate are stacked slidingly moves by a drive unit. Through holes respectively provided in the first mold plate and the second mold plate are linked to form molding hole portions. The molding hole portions move to a first filling position in which upper ends of the molding hole portions are connected to first filling openings, a second filling position in which upper ends of the molding hole portions are connected to second filling openings, and a discharge position in which upper ends of the molding hole portions are connected to pusher ports by the slide movement of the mold unit.