A method and an apparatus for controlling a milling roll machine capable of accurately monitoring a surface temperature of a roll and preventing a high temperature abnormality occurring on a roll surface from being overlooked are provided A temperature sensor S that monitors surface temperatures of a pair of rolls 4 and 5 and a temperature of a milled product after passing through the rolls is provided in the vicinity of the pair of rolls 4 and 5, and opening/closing control of the gap between the rolls 4 and 5 or flow rate control of the raw material stock is performed according to the surface temperatures of the rolls and the temperature of the milled product after passing through the rolls detected by the temperature sensor S.

A rotor (1) for a grinding machine (2) for the foodstuffs and feedstock industry, having an external diameter of between 0.5 and 0.6 m, comprising a plurality of substantially cylindrical, in particular hollow cylindrical, grinding elements (3). One such grinding element (3) has an outer grinding surface (4) substantially in the form of a circular cylinder jacket, and the grinding elements (3) are arranged coaxially above one another and in such a way that a substantially annular air gap (5) is produced between the grinding surfaces (4) of two adjacent grinding elements (3). A ratio between an enveloping surface (H) of the rotor (1) and a total grinding surface of the rotor (1) is greater than 1.05 and less than 1.25.

A rotor (1) for a grinding machine (2) for the foodstuffs and feedstock industry, having an external diameter of between 0.5 and 0.6 m, comprising a plurality of substantially cylindrical, in particular hollow cylindrical, grinding elements (3). One such grinding element (3) has an outer grinding surface (4) substantially in the form of a circular cylinder jacket, and the grinding elements (3) are arranged coaxially above one another and in such a way that a substantially annular air gap (5) is produced between the grinding surfaces (4) of two adjacent grinding elements (3). A ratio between an enveloping surface (H) of the rotor (1) and a total grinding surface of the rotor (1) is greater than 1.05 and less than 1.25.

The exemplary embodiments herein provide a roller grain mill assembly having a lower frame, a plurality of roller grain mills attached to the lower frame, an upper frame extending upwardly from the lower frame, a single electric drive mechanically coupled to each of the roller grain mills, and a cyclone separator placed in gaseous communication with the roller grain mills and located above the electric drive. In some embodiments, a centrifugal scatterer may be suspended from the upper frame and placed in gaseous communication with the roller grain mill. In other embodiments, a cyclone separator may be placed in gaseous communication with the roller grain mill and centrifugal scatterer. An electric drive coupled to each roller grain mill may be cantilevered off the lower frame.

A process for converting spent grain into flour by drying and milling is disclosed. The process includes the steps of introducing a quantity of wet spent grain into a container for removing moisture by the action of gravity. After the gravity drying, the wet spent grain is transferred to a press to mechanically remove additional moisture. The wet spent grain is placed in a fluid bed processor where the grain additional moisture is removed through heating and fluidization. Some embodiments may include a dust collection system in connection with the fluid bed processor, wherein the dust collection system incorporates a separator for separating the grains. Once dried, the dry spent grain is introduced into a mill to be ground into the proper flour consistency. The resulting flour product can then be used for a variety of foodstuff applications.

A method is provided for producing intensified whole-cereal flour by means of pulsed electric fields in collaboration with ultrafine pulverization, which includes: (1) preparing bran, middling and flour by cleaning, modulating and milling cereal grains; (2) performing superfine pulverization on the bran and the middling and performing sieving; (3) preparing a suspension by using water and the sieved bran and middling, and stirring constantly; (4) adding polysaccharide colloids into the suspension, and adjusting the pH to 4.0; (5) performing high-voltage pulse treatment on the suspension to ensure stable flow of the suspension; (6) centrifuging the suspension to separate the supernatant, and drying the obtained precipitate and performing sieving to obtain the treated bran and middling; and (7) mixing the treated bran and middling with flour uniformly to obtain whole-cereal flour.

A method is provided for producing intensified whole-cereal flour by means of pulsed electric fields in collaboration with ultrafine pulverization, which includes: (1) preparing bran, middling and flour by cleaning, modulating and milling cereal grains; (2) performing superfine pulverization on the bran and the middling and performing sieving; (3) preparing a suspension by using water and the sieved bran and middling, and stirring constantly; (4) adding polysaccharide colloids into the suspension, and adjusting the pH to 4.0; (5) performing high-voltage pulse treatment on the suspension to ensure stable flow of the suspension; (6) centrifuging the suspension to separate the supernatant, and drying the obtained precipitate and performing sieving to obtain the treated bran and middling; and (7) mixing the treated bran and middling with flour uniformly to obtain whole-cereal flour.

A flexible polishing apparatus for granulated grains is provided. The flexible polishing apparatus includes a housing, a feeding device, at least one flexible polishing unit, a bran discharging device, and a rice outlet. The flexible polishing unit includes a radial gravity self-flow flexible polishing chamber. The feeding device, the flexible polishing chamber and the rice outlet are sequentially arranged from top to bottom along the gravity direction. The flexible polishing apparatus for granulated grains avoids the shear effect of granulated grains in the polishing chamber, improves the flexible friction effect, and greatly reduces the damage to rice in the polishing process while ensuring that rice bran is cleaned and the rice is polished, thereby improving the rate of polished rice and reducing energy consumption.

A flexible polishing apparatus for granulated grains is provided. The flexible polishing apparatus includes a housing, a feeding device, at least one flexible polishing unit, a bran discharging device, and a rice outlet. The flexible polishing unit includes a radial gravity self-flow flexible polishing chamber. The feeding device, the flexible polishing chamber and the rice outlet are sequentially arranged from top to bottom along the gravity direction. The flexible polishing apparatus for granulated grains avoids the shear effect of granulated grains in the polishing chamber, improves the flexible friction effect, and greatly reduces the damage to rice in the polishing process while ensuring that rice bran is cleaned and the rice is polished, thereby improving the rate of polished rice and reducing energy consumption.

The exemplary embodiments herein provide a roller grain mill assembly having a lower frame, a plurality of roller grain mills attached to the lower frame, an upper frame extending upwardly from the lower frame, a single electric drive mechanically coupled to each of the roller grain mills, and a cyclone separator placed in gaseous communication with the roller grain mills and located above the electric drive. In some embodiments, a centrifugal scatterer may be suspended from the upper frame and placed in gaseous communication with the roller grain mill. In other embodiments, a cyclone separator may be placed in gaseous communication with the roller grain mill and centrifugal scatterer. An electric drive coupled to each roller grain mill may be cantilevered off the lower frame.