A seed sorting machine contains a feeding area, a plurality of filtration units, a classification assembly, multiple guiding assemblies, a delivery unit, and at least one pressing rod. Each filtration unit includes multiple holding trays, a plurality of first partitions, and each holding tray has a filtering hole. The classification assembly includes a classifying tray, multiple guide sheets, and a plurality of outlets. Each guiding assembly includes a holder and multiple ribs, wherein between any two adjacent of the multiple ribs is defined a slot which corresponds to each of the plurality of outlets. The delivery unit includes a base on which multiple V-shaped grooves and multiple second partitions are arranged. Each pressing rod includes a plurality of rollers and multiple trenches, wherein each of the multiple trenches is defined between any two adjacent of the multiple trenches and corresponds to each of the multiple V-shaped grooves.

A system for shearing bulk material includes a shearing cartridge with an input port and an output port. A first plurality of rotatable blades are disposed about a first shaft. A second plurality of rotatable blades is opposingly offset from the first plurality of rotatable blades.

An apparatus for shredding meat with a hopper and a frame. The hopper has upper and lower rotor assemblies mounted to rotate horizontally within a shredding region. Each rotor assembly is composed of an arbor and fingers arranged in paraxial rows around the arbor. Four rows of pegs extend horizontally into the shredding region. A front row and a back row are each 0.75 inch above and below, respectively, the upper rotor assembly. A back row and a front row are each 0.75 inch above and below, respectively the lower rotor assembly. The hopper is suspended in the frame, which houses the drive mechanism that rotates the rotor assemblies in opposite directions. The upper rotor assembly pushes product dropped into the shredding region into the upper back row to shred the product. The lower rotor assembly pushes the shredded product into the lower front row to further shred the product.

Static plant for preparing feed mixes for ruminant livestock, having a conveyor unit for conveying the feed mix ingredients, chain and/or screw feeders, feeders with weight sensors and supplementary conveyor belt, silos of solid ingredients, and silos of liquid ingredients, independently supplying two or more high-capacity mixers, via the conveyor unit by a dual flow, the mixers including weight control means, laser sensors and strain gauges. The invention allows for mixing to be controlled with increased accuracy and, consequently, improving the quality of the mix, using fully automated continuous operating cycles, the resulting mix being discharged onto any type of known device using discharging means, for its distribution.

A system for shearing bulk material includes a shearing cartridge with an input port and an output port. A first plurality of rotatable blades are disposed about a first shaft, Each of the first plurality of rotatable blades includes a center aperture such that the first shaft extends through the center apertures of the first plurality of rotatable blades to selectively rotate each of the first plurality of rotatable blades simultaneously. A second plurality of rotatable blades is opposingly offset from the first plurality of rotatable blades. Each of the second plurality of rotatable blades includes a center aperture such that the second shaft extends through the center apertures of the second plurality of rotatable blades to selectively rotate each of the second plurality of rotatable blades in a direction opposite the first plurality of rotatable blades to shear and reduce the bulk material.

A shredder includes a strip-cut shredding portion including paired disc-shaped, multi-plate rotary cutters meshing with each other to shred paper in a strip-cut direction, and a cross-cut shredding portion including a fixed cutter and a spiral rotary cutter for further shredding strip-cut waste pieces discharged from the strip-cut shredding portion in a cross-cut direction, the shredder including a unit for detecting that the spiral rotary cutter of the cross-cut shredding portion is not rotating. Shredding by the strip-cut shredding portion is stopped when the sensor unit detects that the spiral rotary cutter is not rotating.

An apparatus for shredding meat with a hopper and a frame. The hopper has upper and lower rotor assemblies mounted to rotate horizontally within a shredding region. Each rotor assembly is composed of an arbor and fingers arranged in paraxial rows around the arbor. Four rows of pegs extend horizontally into the shredding region. A front row and a back row are each 0.75 inch above and below, respectively, the upper rotor assembly. A back row and a front row are each 0.75 inch above and below, respectively the lower rotor assembly. The hopper is suspended in the frame, which houses the drive mechanism that rotates the rotor assemblies in opposite directions. The upper rotor assembly pushes product dropped into the shredding region into the upper back row to shred the product. The lower rotor assembly pushes the shredded product into the lower front row to further shred the product.

A bone grinder may have a grinding chamber, an intermediate zone, and a primary cutting element and a secondary cutting element. The intermediate zone may have a first wall and a second wall within the grinding chamber, and the intermediate zone may separate the primary cutting element from the secondary cutting element. The first wall and the second wall may slope inward such that a distance between the first wall and the second wall generally decreases from the primary cutting element to the secondary cutting element. The primary cutting element and the secondary cutting element may be positioned within the grinding chamber to sequentially perform primary cutting operations and secondary cutting operations on a bone. A drive mechanism may operatively engage the primary cutting element and the secondary cutting element.

A cutting blade assembly establishes a bidirectional and/or multifaceted scissor-type cutting action to efficiently and effectively process various types of debris encountered by the cutting blade assembly. The assembly includes a cutting plate and a cutting hub configured for relative rotation. A cutting slot is formed in the cutting plate and intersects the axial face to define a cutting edge at the intersection of the cutting slot and the axial face. The cutting hub has a cutting arm positioned adjacent to the axial face. When the cutting plate and the cutting hub undergo relative rotation, the cutting arm passes adjacent to the cutting edge to perform a scissor-type cutting action.

A comminuting machine for comminuting a product includes: a cutting device for comminuting the product, which device has at least two cutting units; a drive shaft for driving the cutting units; and a housing in which the cutting units are arranged one behind the other along the longitudinal axis of the drive shaft. The comminuting machine is designed to feed a fluid in the form of a liquid gas into at least one intermediate space which is formed in the housing between two cutting units that are adjacent to one another along the longitudinal axis of the drive shaft.