An automated production system is disclosed herein. One aspect of the present technology, for example, is directed toward an automated system for the continuous production of baked bread. The system can include a priming assembly having a dry ingredients priming unit and a wet ingredients priming unit. The dry ingredients priming unit can include a vertically-oriented hopper and a screw positioned within an interior region of the hopper, wherein the first screw extends along the central longitudinal axis of the hopper and is configured to rotate about its own central longitudinal axis. The system can also include a mixing assembly, a forming assembly, an oven, and a controller. The controller can be coupled to the priming assembly and configured to adjust the amount of dry ingredients delivered from the hopper to the mixing chamber by controlling rotation of the screw.

A powdery-material feeding device is configured to feed a powdery material to a compression-molding machine configured to obtain a molded product by filling a die bore with the powdery material and to compress the powdery material with punches. The powdery-material feeding device includes a detector configured to detect a biologically-originated foreign matter mixedly contained in the powdery material to be fed to the compression-molding machine, and a controller configured to control to remove the powdery material mixedly containing the biologically-originated foreign matter detected by the detector to avoid feeding of the powdery material mixedly containing the biologically-originated foreign matter to the compression-molding machine, or to control to stop the feeding of the powdery material to the compression-molding machine.

A blender has a mixing chamber for reception of materials to be blended. A mixing screw is mounted at a bottom of the mixing chamber for mixing materials within the mixing chamber and delivering mixed materials to an outlet feeding a processing line. Heaters are mounted within the mixing chamber for drying blend material in the mixing chamber.

A mixer (1) comprises a drum (2) having at least one inlet (6) and one outlet (7). The mixer (1) furthermore comprises a drive (3) and a stirring shaft (4), which is arranged in the drum (2) and is coupled to the drive (3). Furthermore, the mixer (1) comprises a conveying device (5), which is arranged in the drum (2) and which is arranged on one and the same axis as the stirring shaft (4).

A mixer (1) comprises a drum (2) having at least one inlet (6) and one outlet (7). The mixer (1) furthermore comprises a drive (3) and a stirring shaft (4), which is arranged in the drum (2) and is coupled to the drive (3). Furthermore, the mixer (1) comprises a conveying device (5), which is arranged in the drum (2) and which is arranged on one and the same axis as the stirring shaft (4).

A powdery-material measurement device includes a sensor probe configured to receive reflected light from mixed-powdery materials passing adjacent thereto or transmitted light through the mixed-powdery materials to measure characteristics of the mixed-powdery materials while the powdery-material measurement device is in operation to deliver the mixed-powdery materials toward an equipment, and a standard sample having known characteristics and facing the sensor probe that is disposed to receive the reflected light from the standard sample or the transmitted light through the standard sample, when the mixed-powdery materials are not present adjacent the sensor probe while the powdery-material measurement device is in operation to deliver the mixed-powdery materials toward the equipment.

A blender has a mixing chamber for reception of materials to be blended. A mixing screw is mounted at a bottom of the mixing chamber for mixing materials within the mixing chamber and delivering mixed materials to an outlet feeding a processing line. Heaters are mounted within the mixing chamber for drying blend material in the mixing chamber.

A stirring and feeding device includes a base seat having a stirring reservoir and a feeding port for engaging a feeding tube, a hopper defining a filling space which is disposed upstream of the stirring reservoir, a rotatable stirring unit extending in the filling space and having a spirally extending blade for guiding the stuffing downwardly to the stirring reservoir, and two rollers defining a rolling space below the blade to roll the stuffing toward the feeding port for preventing clogging.

Means for dispensing a powdery coloring substance onto the surface of a mix comprising stone, stone-like, glass or ceramic material. The means comprise at least one dispensing device for containing and dispensing a powdery coloring substance and at least one spreading device. The spreading device comprises at least one moving perforated plate which receives a metered amount of said coloring substance from the dispensing device and distributes it over the surface of the mix.

A feeder system includes a donut-ring-shaped first wheel having a first groove recessed below its top surface, with a first hopper positioned above to receive material. A first conduit connects the hopper bottom to the groove, defining a feeding path. A mixer unit receives materials, connected to the first groove via a first suction head. A first motor rotates the first wheel, transferring material from hopper to groove to mixer unit. A donut-ring-shaped second wheel includes a second groove, second hopper, and second conduit. A second suction head connects this groove to the mixer unit, while a second motor enables wheel rotation for material transfer. The mixer unit combines both materials. The feeder system implements coaxial wheel arrangement with independent material flow control, enabling independent powder delivery for additive manufacturing applications.