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 processes seeds that are present in crop material. The system includes a first shearing surface, a second shearing surface arranged opposite the first shearing surface, and a clearance between the first shearing surface and the second shearing surface. The system passes crop material between the first and second shearing surfaces, where the crop material contacts the shearing surfaces as it passes through the shearing surfaces. Contact with the first and second shearing surfaces damages seeds that are present in the crop material. The system can be installed in an agricultural harvester to damage seeds that are present in crop residue to prevent the seeds from germinating after the crop residue is discharged from the agricultural harvester back into the field.

A crop processor for cracking kernels in a forage harvester, the crop processor including: a housing having an inlet and an outlet; and a first and a second comminuting roll mounted inside the housing, the comminuting rolls being arranged in parallel to define an opening between the rolls, the comminuting rolls being configured to rotate, during use, in opposing rotation directions to transport a flow of harvested crop, received from the inlet, through the opening towards the outlet, wherein the first comminuting roll is configured to rotate at a greater speed than the second comminuting roll; wherein the first and second comminuting rolls each include a plurality of teeth arranged on a circumferential surface of the comminuting roll, each of the plurality of teeth includes a leading edge which faces in the rotation direction of that comminuting roll.

A crop processor for cracking kernels in a forage harvester, the crop processor including: a housing having an inlet and an outlet; and a first and a second comminuting roll mounted inside the housing, the comminuting rolls being arranged in parallel to define an opening between the rolls, the comminuting rolls being configured to rotate, during use, in opposing rotation directions to transport a flow of harvested crop, received from the inlet, through the opening towards the outlet, wherein the first comminuting roll is configured to rotate at a greater speed than the second comminuting roll; wherein the first and second comminuting rolls each include a plurality of teeth arranged on a circumferential surface of the comminuting roll, each of the plurality of teeth includes a leading edge which faces in the rotation direction of that comminuting roll.

The invention is a mill or rolling mill for processing cereals, granular materials, mixtures of cereals and similar products, comprising at least one pair of parallel cylinders (C, C) positioned side by side, wherein each cylinder (C, C) of each pair is provided with a torque motor that in turn is mounted or assembled directly on the shaft of the respective cylinder (C, C), and at least one control circuit (Z) suited to select which one of said two cylinders (C, C) of each pair rotates faster.

The invention is a mill or rolling mill for processing cereals, granular materials, mixtures of cereals and similar products, comprising at least one pair of parallel cylinders (C, C) positioned side by side, wherein each cylinder (C, C) of each pair is provided with a torque motor that in turn is mounted or assembled directly on the shaft of the respective cylinder (C, C), and at least one control circuit (Z) suited to select which one of said two cylinders (C, C) of each pair rotates faster.

Automated grinder systems include several different automatic functions including liquid and substrate soaking, mixing, grinding, fermenting, and cleaning. Example grinders include storages for soaking and draining a substrate for grinding, a water or other fluid reservoir connected to provide soaking material, and a grinder connected to the storage to receive and grind the substrate. A resting unit may receive the ground batter and potentially ferment the same by controlling its temperature, humidity, pH, etc. Jets may be connected to a water reservoir and direct liquid water into the grinder, potentially with soap, to cleanse the same.

Automated grinder systems include several different automatic functions including liquid and substrate soaking, mixing, grinding, fermenting, and cleaning. Example grinders include storages for soaking and draining a substrate for grinding, a water or other fluid reservoir connected to provide soaking material, and a grinder connected to the storage to receive and grind the substrate. A resting unit may receive the ground batter and potentially ferment the same by controlling its temperature, humidity, pH, etc. Jets may be connected to a water reservoir and direct liquid water into the grinder, potentially with soap, to cleanse the same.

To produce flour and/or semolina, raw material is fed into a feed opening of a roller press. The milling gap of the roller press is fixed, or damping of at least one of the rollers with respect to the lateral deflection is set, such that a first subset of the fill containing finer milling material forms a packed particle fill in the milling gap. In addition, the setting is carried out in such a way that individual particles of a second subset of the fill containing coarser milling material are in contact with the first roller and the second roller of the roller press. Subsequently, the bulk material is milled into milled product in the roller press (9) and the milled product is discharged through a discharge opening.