A crushing mill includes a crushing chamber and a feed unit to feed the waste to be crushed positioned upstream of the crushing chamber. Upstream of the feed unit a first aperture is positioned for the inlet of the waste to be treated in the feed unit and, downstream of the feed unit, a second transfer aperture is positioned to transfer the waste to be treated toward the crushing chamber. The feed unit includes a member rotatable around a determinate axis and provided with at least a pair of cylindrical sectors angularly offset with respect to the axis, provided with corresponding inlet and discharge apertures of the waste to be crushed and configured so that, in any loading and/or crushing step of the waste to be crushed in the crushing mill, they prevent the first and second apertures from coming into communication with each other.

A crushing mill includes a crushing chamber and a feed unit to feed the waste to be crushed positioned upstream of the crushing chamber. Upstream of the feed unit a first aperture is positioned for the inlet of the waste to be treated in the feed unit and, downstream of the feed unit, a second transfer aperture is positioned to transfer the waste to be treated toward the crushing chamber. The feed unit includes a member rotatable around a determinate axis and provided with at least a pair of cylindrical sectors angularly offset with respect to the axis, provided with corresponding inlet and discharge apertures of the waste to be crushed and configured so that, in any loading and/or crushing step of the waste to be crushed in the crushing mill, they prevent the first and second apertures from coming into communication with each other.

A distribution member may include a distributing plate, a plurality of protecting plates and a second protecting plate. The distributing plate may be connected with a vertical shaft of the vertical shaft impact crusher. The distributing plate may have a first distributing surface having a conical shape, and a second distributing surface. The first protecting plates may be attached to the first distributing surface of the distributing plate. The second protecting plate may be attached to the second distributing surface of the distributing plate. Thus, the distribution member may be semi-permanently used by properly exchanging any one of the first protecting plates and/or the second protecting plate.

A distribution member may include a distributing plate, a plurality of protecting plates and a second protecting plate. The distributing plate may be connected with a vertical shaft of the vertical shaft impact crusher. The distributing plate may have a first distributing surface having a conical shape, and a second distributing surface. The first protecting plates may be attached to the first distributing surface of the distributing plate. The second protecting plate may be attached to the second distributing surface of the distributing plate. Thus, the distribution member may be semi-permanently used by properly exchanging any one of the first protecting plates and/or the second protecting plate.

The invention relates to the method for milling and separation into fractions of solids and granular materials in a controlled airflow. The device for milling and separation of solids and granular materials consists of a round milling chamber with a system of pneumatic separation comprising of a vertical cylindrical body that has an uploading slot for solids and granular materials and unloading channels for the milled products of light, medium and coarse fractions. A rotating disc and a conical divider are located inside a vertical cylindrical body. The rotating disc has plates (hammers) and removable blades of different sizes and configurations. System of pneumatic separation consists of a milling chamber, an air slugcatcher, channels for the milled material, and a chamber of higher pressure. Such construction of the device allows to obtain products of a highest quality, and to improve the separation by dividing the material into three fractions: light, medium and coarse.

The invention relates to the method for milling and separation into fractions of solids and granular materials in a controlled airflow. The device for milling and separation of solids and granular materials consists of a round milling chamber with a system of pneumatic separation comprising of a vertical cylindrical body that has an uploading slot for solids and granular materials and unloading channels for the milled products of light, medium and coarse fractions. A rotating disc and a conical divider are located inside a vertical cylindrical body. The rotating disc has plates (hammers) and removable blades of different sizes and configurations. System of pneumatic separation consists of a milling chamber, an air slugcatcher, channels for the milled material, and a chamber of higher pressure. Such construction of the device allows to obtain products of a highest quality, and to improve the separation by dividing the material into three fractions: light, medium and coarse.

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 material reducing machine includes a rotary reducing drum that is rotatable about an axis of rotation and defines a reducing boundary that extends at least partially around the axis of rotation. The material reducing machine includes an infeed conveyor for transporting material to a front portion of the rotary reducing drum and defines a conveyor plane. The material reducing machine includes a mill box at least partially surrounding the rotary reducing drum and including a mill box lid mounted generally above the rotary reducing drum. The mill box lid has an inlet edge positioned above a rear portion of the rotary reducing drum and an outlet edge positioned above the front portion of the rotary reducing drum. The mill box includes an infeed opening that is configured to receive material from a feed table and has an upper opening defined by the outlet edge of the mill box lid.

A material reducing machine includes a rotary reducing drum that is rotatable about an axis of rotation and defines a reducing boundary that extends at least partially around the axis of rotation. The material reducing machine includes an infeed conveyor for transporting material to a front portion of the rotary reducing drum and defines a conveyor plane. The material reducing machine includes a mill box at least partially surrounding the rotary reducing drum and including a mill box lid mounted generally above the rotary reducing drum. The mill box lid has an inlet edge positioned above a rear portion of the rotary reducing drum and an outlet edge positioned above the front portion of the rotary reducing drum. The mill box includes an infeed opening that is configured to receive material from a feed table and has an upper opening defined by the outlet edge of the mill box lid.

A beating device (1) for inactivating insects in a pourable feedstuff or foodstuff, with a housing (2), which has at least one inlet opening (3) and at least one outlet opening (4) for the material to be treated. A drum (6) is arranged in the housing (2) and rotatably about an axis of rotation (5). A plurality of blade elements (9) of a first type extend approximately parallel to the axis of rotation (5) and have a beating surface (10) arranged between two end parts (7, 8) of the drum (8). The drum is partially (8) circumferentially surrounded by a wall (11) of the housing (2) and the at least one inlet opening (3) and the at least one outlet opening (4) are formed in the wall (11).