A rotating nozzle assembly for a die machine connectable to a dough extruder has a stationary sleeve with a first end having internal and external annular recesses and an annular stepped seating surface and a second end mountable in the die machine mounting plate. A nozzle has a first end rotatably disposed in the stationary-sleeve first-end internal annular recess, a second end and a radially outwardly-protruding annular ring between the first and second nozzle ends. A ring seal is disposed between the stationary-sleeve first-end annular stepped seating surface and the radially outwardly-protruding annular nozzle ring. A nozzle cap is fixedly attached to the stationary-sleeve first end. The nozzle is rotatably disposed in the nozzle cap. The nozzle second end extends beyond the nozzle cap. An annular stepped axial thrust bearing surface in the nozzle cap prevents relative axial movement of the nozzle while allowing rotation of the nozzle.

A stuffing filling and gas charging system of a dough food product machine is arranged between a stuffing feeding unit and a dough feeding unit of the dough food product machine and includes a stuffing conveyance pipe, and a shaft sleeve, a dough driving rod, and a screw rod support enclosure sleeved over the stuffing conveyance pipe. A first passage is formed between the shaft sleeve and the stuffing conveyance pipe; a second passage is formed between the dough driving rod and the stuffing conveyance pipe; and a third passage is formed between the screw rod support enclosure and the stuffing conveyance pipe. The passages are in communication with each other and are connected to a gas supply unit, so that air flow is introduced into a dough skin during the dough skin being shaped to prevent the dough skin from wrinkling and collapsing before being properly shaped.

A cooling tool (1) for a food or an animal feed extruder (E), the cooling tool has: an inlet end (3) at which extrudate (4) can be led into the cooling tool (1); an outlet end (5) where the cooled extrudate can be discharged; an extrudate flow channel (6) extending from the inlet end to the outlet end; and at least one coolant flow channel (7a, 7b, 7b) connected to the extrudate flow channel in a heat-transmitting manner. In a cross section (X-X) along the primary flow direction (8), the extrudate flow channel is substantially formed as a ring section; and the outer wall (9) of the extrudate flow channel (6) is formed at least from first and second segments (10, 11). The first and second segments are connected to each other by mechanical connection elements (12). The cooling tool is suitable for wet texturing of food and animal feed.

A cooling tool (1) for a food or an animal feed extruder (E), the cooling tool has: an inlet end (3) at which extrudate (4) can be led into the cooling tool (1); an outlet end (5) where the cooled extrudate can be discharged; an extrudate flow channel (6) extending from the inlet end to the outlet end; and at least one coolant flow channel (7a, 7b, 7b) connected to the extrudate flow channel in a heat-transmitting manner. In a cross section (X-X) along the primary flow direction (8), the extrudate flow channel is substantially formed as a ring section; and the outer wall (9) of the extrudate flow channel (6) is formed at least from first and second segments (10, 11). The first and second segments are connected to each other by mechanical connection elements (12). The cooling tool is suitable for wet texturing of food and animal feed.

An apparatus (10) for controlling manufacture of baked products includes a piece forming device (16) configured to form dough pieces b.v reshaping dough lumps, a tunnel oven (22), at least one sensor (28) configured to detect parameters associated with the dough pieces; and a controller (40). The controller (40) correlates parameters associated with the dough pieces (80), target parameters of the baked products, ambient environmental conditions, and settings and conditions of the tunnel oven (22) to generate, based on a multivariate predictive control model, baking parameters of the tunnel oven (22) predicted by the controller to cause the tunnel oven to produce, from the dough pieces inserted into the tunnel oven, the baked products (90) with the target parameters. The controller (40) is also configured to control the tunnel oven (22) to run these baking parameters while the dough pieces are baked in the tunnel oven to produce the baked products having the target parameters.

An apparatus (10) for controlling manufacture of baked products includes a piece forming device (16) configured to form dough pieces b.v reshaping dough lumps, a tunnel oven (22), at least one sensor (28) configured to detect parameters associated with the dough pieces; and a controller (40). The controller (40) correlates parameters associated with the dough pieces (80), target parameters of the baked products, ambient environmental conditions, and settings and conditions of the tunnel oven (22) to generate, based on a multivariate predictive control model, baking parameters of the tunnel oven (22) predicted by the controller to cause the tunnel oven to produce, from the dough pieces inserted into the tunnel oven, the baked products (90) with the target parameters. The controller (40) is also configured to control the tunnel oven (22) to run these baking parameters while the dough pieces are baked in the tunnel oven to produce the baked products having the target parameters.

A large-scale multifunctional rice noodle making machine, along the direction of materials delivery comprises sequentially a rice lifting machine inlet, a rice lifting machine, a fermenter, a rice feeder, a rice-flour outlet, an auxiliary ingredients machine, a continuously mixing and conveying machine, an outlet, a self-ripening and shaping machine, a hot water circulation tank, a rice-flour feeder, an extruding machine, a conveyor of aging machine, a fan, an aging machine, a first noodle loosen machine, a noodle steamer, an out-feed channel, a second noodle loosen machine, a conveyor, an inlet, an inner packaging machine, a conveyor I, a weighing scale, a metal detector, a conveyor II, a sterilizer, and a rice noodle collector. The present invention relates to a large-scale multifunction rice noodle machine, which can automatically and efficiently produce a variety of rice noodles, such as fermented and non-fermented rice noodles.

A large-scale multifunctional rice noodle making machine, along the direction of materials delivery comprises sequentially a rice lifting machine inlet, a rice lifting machine, a fermenter, a rice feeder, a rice-flour outlet, an auxiliary ingredients machine, a continuously mixing and conveying machine, an outlet, a self-ripening and shaping machine, a hot water circulation tank, a rice-flour feeder, an extruding machine, a conveyor of aging machine, a fan, an aging machine, a first noodle loosen machine, a noodle steamer, an out-feed channel, a second noodle loosen machine, a conveyor, an inlet, an inner packaging machine, a conveyor I, a weighing scale, a metal detector, a conveyor II, a sterilizer, and a rice noodle collector. The present invention relates to a large-scale multifunction rice noodle machine, which can automatically and efficiently produce a variety of rice noodles, such as fermented and non-fermented rice noodles.

A dough extrusion machine (10). The machine has a first extrusion unit (1) and a second extrusion unit (2) mounted to a platform (3), wherein the first extrusion unit (1) comprises combining means (12) for combining dough discharged from the first extrusion unit (1) and dough discharged from the second extrusion unit (2), characterized in that the first extrusion unit (1) has a plurality of inlet openings (7) upstream of combining means (12), and that the second extrusion unit (2) has a plurality of outlet openings (4), wherein the outlet openings (4) of the second extrusion unit (2) are coupled to the inlet openings (7) of the first extrusion unit (1) by an array (5) of tubes (6) detachably mounted to the first and second extrusion unit (1, 2).

An machine for kneading and extruding pasta, having a body, a motor having a horizontal output shaft, a transmission from the output shaft to a horizontal driven shaft parallel to the output shaft and coaxial to a shaft of a kneading reel, projecting externally to the body in a dough forming tank. The body includes a load-bearing frame, including a sheet metal plate bent substantially 90 to provide a horizontal base, fixed relative to a support, and a vertical wall, on which the dough forming tank is fixed, and an inner reinforcement having a first vertical plate fixed relative to the horizontal base, parallel to and spaced from the vertical wall, a second vertical plate fixed to the inner face of the vertical wall, and a bearing for supporting the output shaft and the driven shaft relative to the first and second plate.