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.

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.

Roller packages (IO) for grinding devices (70), comprising a first roll (11), which is maintained by at least one first bearing body (13), and a second roll (12), which is maintained by at least one second bearing body (14). The first bearing body (13) and the second bearing body (14) are prestressed against each other and comprise stop elements (17,19) with stop surfaces (18, 20), the contact of which counteracts a contact of the rolls (11, 12). The rotational position of the first stop element (17) determines the minimum width of the grinding gap. Also disclosed are grinding devices (70), methods for operating a roll assembly (10) and methods for determining the radial force acting between the rolls (11, 12) of a roll assembly (10).

Roller packages (IO) for grinding devices (70), comprising a first roll (11), which is maintained by at least one first bearing body (13), and a second roll (12), which is maintained by at least one second bearing body (14). The first bearing body (13) and the second bearing body (14) are prestressed against each other and comprise stop elements (17,19) with stop surfaces (18, 20), the contact of which counteracts a contact of the rolls (11, 12). The rotational position of the first stop element (17) determines the minimum width of the grinding gap. Also disclosed are grinding devices (70), methods for operating a roll assembly (10) and methods for determining the radial force acting between the rolls (11, 12) of a roll assembly (10).

This invention refers to a grain flaking modular system, a grain flaking system, and a method that produces a grain flake within a predetermined specification. The grain flaking modular system comprises: valves (124); a PLC (130) connected to the valves (124); and an external optimization unit (140) connected to the PLC (130), wherein the external optimization unit (140) is configured to define a pressure reference (A). The grain flaking system (100) comprises: flaking rollers (110); and a programmable logic controller, PLC (PLC), configured to: obtain a pressure reference (A), and control a flaking pressure through the pressure reference (A) obtained. The grain flaking method comprises: obtaining (210) the pressure reference; applying (220) a flaking pressure to a flow of grains, wherein the flaking pressure is defined through the pressure reference obtained; and adjusting (230) the pressure reference.

This invention refers to a grain flaking modular system, a grain flaking system, and a method that produces a grain flake within a predetermined specification. The grain flaking modular system comprises: valves (124); a PLC (130) connected to the valves (124); and an external optimization unit (140) connected to the PLC (130), wherein the external optimization unit (140) is configured to define a pressure reference (A). The grain flaking system (100) comprises: flaking rollers (110); and a programmable logic controller, PLC (PLC), configured to: obtain a pressure reference (A), and control a flaking pressure through the pressure reference (A) obtained. The grain flaking method comprises: obtaining (210) the pressure reference; applying (220) a flaking pressure to a flow of grains, wherein the flaking pressure is defined through the pressure reference obtained; and adjusting (230) the pressure reference.

A system and method for flaking. The system includes a stationary roller, and moveable roller, and an adjustable fixator applying tension between the stationary and moveable rollers. The fixator includes a pressure transducer and a linear indicator. The transducer and indicator allow the fixator to read pressures and make fine adjustments to the fixator to obtain a desired gap between the two rollers.

A system may comprise a frame, a pair of rolls with each of the rolls comprising a roll body having opposite ends and a circumferential surface, a plurality of teeth being formed on the circumferential surface, and at least a portion of the circumferential surface being electrically conductive. The roll may also have a roll shaft having end portions extending from the roll body, with each of the end portions extending from one of the ends of the roll body. The system may also comprise roll supports configured to support the rolls on the frame in a manner such that at least one of the rolls is movable to adjust a separation gap between the rolls, a detection apparatus configured to detect contact between the rolls, and a signaling apparatus configured to produce a signal indicating a change in electrical potential is detected by the detection apparatus.

A system may comprise a frame, a pair of rolls with each of the rolls comprising a roll body having opposite ends and a circumferential surface, a plurality of teeth being formed on the circumferential surface, and at least a portion of the circumferential surface being electrically conductive. The roll may also have a roll shaft having end portions extending from the roll body, with each of the end portions extending from one of the ends of the roll body. The system may also comprise roll supports configured to support the rolls on the frame in a manner such that at least one of the rolls is movable to adjust a separation gap between the rolls, a detection apparatus configured to detect contact between the rolls, and a signaling apparatus configured to produce a signal indicating a change in electrical potential is detected by the detection apparatus.

A self-optimizing, adaptive product processing system and a corresponding method for grinding and/or crushing cereals and seeds. The grinding and/or crushing takes place in at least one roller mill which includes a roller pair. So as to detect the temperature of the surfaces of the rollers, at least two temperature sensors are disposed on at least one of the rollers. The detected temperature measurement values are used for optimal adjustment and signal generation of the roller setting.