A crusher having (a) a crusher frame, (b) a crusher rotor with teeth supported on the crusher frame, (c) counter-blade structures within the crusher frame; and (c) upper and lower hatches. The crusher rotor and the counter-blade structures are configured within the crusher so that material fed into the crusher frame can be crushed between the crusher teeth and the counter-blade structures. The upper and lower hatches are hinged to the crusher so that the hatches can be separated to provide an opening through which foreign material may be removed from the crusher while preventing material feeding into the crusher rotor from flowing out of the crusher.

A bale spreader including one or more rotors rotatably attached to a first and second support member is provided. The bale spreader includes an apron that extends below the rotor(s), and may be configured to operatively feed a particulate material into the rotor(s). The rotor(s) may include a plurality of flail knives or hammers configured to chop and/or shred a particulate material as the rotor(s) is/are rotated. The rotor(s) may be rotated by an optimized hydraulic system connected to the auxiliary hydraulic system of an agricultural implement or vehicle. Furthermore, the bale spreader may include a plurality of tines, screen members, and a flop bar configured to secure particulate material within the bale spreader.

A device (1) for mixing which comprises a housing (2) with at least one inlet (3). A first process region (4) mixes the supplied substances which are introduced via the inlet (3) while a second process region (5) discharges the mixture via an outlet (6). A first gap-forming element (7), preferably a rotor, is assigned to the first process region (4) and comprises openings (8), and a second gap-forming element (9), preferably a stator, is assigned to the second process region (5) and corresponds with the first gap-forming element (7), wherein the second gap-forming element (9) comprises openings (10). At least one of the gap-forming elements (7, 9) is rotatable relative to the other gap-forming element (7, 9). The openings (8, 10) of the first and second gap-forming elements (7, 9) are arranged such that a mixture passes through the openings from the first into the second process region.

A comminution device for mechanically comminuting material conglomerates consisting of materials of varying density and/or consistency, including a comminution chamber having a supply side with a supply device above the comminution chamber and a discharge side, which comminution chamber is enclosed by a circular cylindrical and/or conical, downwardly widened comminution chamber wall and has at least two portions in succession in the axial direction, in each of which at least one rotor is arranged coaxial with the comminution chamber, each rotor having a rotor shaft and having striking tools which extend substantially radially into the comminution chamber at least during operation, the rotors having opposite directions of rotation in at least two successive portions, deflection ribs being arranged on the inside of the comminution chamber wall at axial intervals and/or the radius of the comminution chamber wall increases from top to bottom.

A comminution device for mechanically comminuting material conglomerates consisting of materials of varying density and/or consistency, including a comminution chamber having a supply side with a supply device above the comminution chamber and a discharge side, which comminution chamber is enclosed by a circular cylindrical and/or conical, downwardly widened comminution chamber wall and has at least two portions in succession in the axial direction, in each of which at least one rotor is arranged coaxial with the comminution chamber, each rotor having a rotor shaft and having striking tools which extend substantially radially into the comminution chamber at least during operation, the rotors having opposite directions of rotation in at least two successive portions, deflection ribs being arranged on the inside of the comminution chamber wall at axial intervals and/or the radius of the comminution chamber wall increases from top to bottom.

A material collider apparatus includes at least one rotor disposed for rotational movement having a plurality of circumferentially disposed pockets, each of the pockets retaining a portion of a flow velocity regulator and an adjustable retention mechanism. The adjustable retention mechanism includes a first wedge portion and a second wedge portion, the wedge portion each having inclined surfaces that are engaged with one another. An actuating member is disposed through the first and second wedge portions, in which the second wedge portion includes a mounting surface in contact with an edge of the velocity regulator and the first wedge portion includes a mounting surface in contact with an edge surface of the pocket. The second wedge portion is movable relative to said first wedge portion when the actuating member is engaged, thereby permitting tightening and release of the velocity regulator in a defined rotor pocket.

A material collider apparatus includes at least one rotor disposed for rotational movement having a plurality of circumferentially disposed pockets, each of the pockets retaining a portion of a flow velocity regulator and an adjustable retention mechanism. The adjustable retention mechanism includes a first wedge portion and a second wedge portion, the wedge portion each having inclined surfaces that are engaged with one another. An actuating member is disposed through the first and second wedge portions, in which the second wedge portion includes a mounting surface in contact with an edge of the velocity regulator and the first wedge portion includes a mounting surface in contact with an edge surface of the pocket. The second wedge portion is movable relative to said first wedge portion when the actuating member is engaged, thereby permitting tightening and release of the velocity regulator in a defined rotor pocket.

An impact material processing device has a central impact mechanism arranged to rotate about a rotation axis and at least one stator extending circumferentially about the impact mechanism. Each stator has one or more openings through which material impacted by the impact mechanism can pass. A housing extends about the stator and between an upper plate and a base plate. Each stator is located within the housing and can be moved between a first position and a bypass position. In the first position a lower edge of one or more stator is on the base plate and an upper edge extends to at least an inside surface of the upper plate. In the bypass position the stator is moved to where the lower edge of the stator is lifted from the base plate to form a gap through which material entering the device can flow radially beyond the stator.

Disclosed is a nano pulverizing device for processing reconstituted rice flour which includes a bottom plate, support legs are fixedly connected to corners of a lower surface of the bottom plate, a housing is arranged on an upper surface of the bottom plate, and a rotating motor is arranged on the lower surface of the bottom plate. The rotating motor penetrates through the lower surface of the bottom plate and extends to the upper surface of the bottom plate, and a crushing device is rotationally connected to one end, extending to the upper surface of the bottom plate, of the rotating motor. A support frame is fixedly connected to an inner wall of the housing, a support plate is fixedly connected to a lower surface of the support frame, and a flexible plate is fixedly connected to a lower surface of the support plate.

Disclosed is a nano pulverizing device for processing reconstituted rice flour which includes a bottom plate, support legs are fixedly connected to corners of a lower surface of the bottom plate, a housing is arranged on an upper surface of the bottom plate, and a rotating motor is arranged on the lower surface of the bottom plate. The rotating motor penetrates through the lower surface of the bottom plate and extends to the upper surface of the bottom plate, and a crushing device is rotationally connected to one end, extending to the upper surface of the bottom plate, of the rotating motor. A support frame is fixedly connected to an inner wall of the housing, a support plate is fixedly connected to a lower surface of the support frame, and a flexible plate is fixedly connected to a lower surface of the support plate.