Described is a wear-resistant roller component for handling abrasive materials where the component comprises a metal body with at least one surface. It is characterized in that a metal template having a pattern of through-going holes is arranged on the at least one surface of the metal body and in that a cover arranged to cover at least a part of the metal template is located at a distance from the metal template to form a gap between the cover and the metal template and in that a powder material suitable for sintering is introduced into the through-going holes in the metal template through the gap and in that the metal body, the metal template, the cover and the material powder are bonded together by means of a sintering process.

The present invention relates to a method for improving the productivity of grinding plants, wherein, after the optimum wear geometry of the grinding units has been reached by conventional operation of the grinding plant, the optimum wear geometry is preserved by applying a thin wear protection layer to the surface of the grinding units.

A milling roll of a roll mill may have a roll main body and an edge element that is attached to an end region of a roll end of the milling roll and extends in a radial direction beyond a surface of the roll main body. The edge element comprises a base flange and a spacer element that is attached thereto. Wear protection elements can be attached to the spacer element. Furthermore, a roll mill may have a first milling roll and a second milling roll that are arranged opposite one another and can be driven in opposite directions. A milling gap is disposed between the milling rolls, and an edge element on one of the milling rolls may extend over the milling gap and at least partially cover an end side of the opposite milling roll.

A roller mill for comminuting material may include first and second grinding rollers disposed opposite one another and drivable in opposite directions and a milling gap between the grinding rollers. An end region of at least the first grinding roller comprises a peripheral element that extends across the milling gap and at least partially covers an end side of the second grinding roller. A scraping element for at least partially removing material is disposed on the end region of the first grinding roller. A measuring device can determine a layer thickness of ground material on at least one of the grinding rollers and/or determine stress in the peripheral element. A control device connected to the measuring device is configured, based on the determined layer thickness and/or stress, to decrease or increase an amount of space between the scraping element and one of the grinding rollers.

The disclosure relates to a roller crusher including a first grinding roll and a second grinding roll, the first and second grinding rolls being arranged generally in parallel to each other and to define a crushing gap therebetween and drivable in a counter-rotating manner. The roller crusher includes a device of a first type for loosening granular material present on a crushing surface of at least one of the rolls, the device including at least one rotatable disc element. The subject further relates to a roller crusher, wherein the plurality of disc elements is individually rotatable.

The present invention relates to a method for improving the productivity of grinding plants, wherein, after the optimum wear geometry of the grinding units has been reached by conventional operation of the grinding plant, the optimum wear geometry is preserved by applying a thin wear protection layer to the surface of the grinding units.

A cutter wheel includes a drive plate having a first side and a second side opposite the first side. A wear plate is coupled to the first side of the drive plate for rotation with the drive plate. First and second cutters are coupled to the wear plate such that the wear plate is at least partially between the first side of the drive plate and the first and second cutters. Each cutter includes a cutter tip and a fastener-mounting aperture. A first fastener extends through the fastener-mounting aperture of the first cutter, through a first fastener-receiving aperture in the wear plate, and into a first aperture in the drive plate. A second fastener extends through the fastener-mounting aperture of the second cutter, through a respective fastener-receiving aperture in the wear plate, and into a respective aperture in the drive plate.

A mill is formed by a plastic rotating part, a high-hardness rotating part, a high-hardness stationary gear, and a plastic stationary part, such that the high-hardness rotating part and the high-hardness stationary gear are provided with a plurality of teeth complementary to one another for the grinding function. The high-hardness gear and the plastic stationary part advantageously have locking means enabling an automatic assembly of the mill, since the mentioned elements are able to easily rest relative to one another in the suitable position and fit together effortlessly.

Roll crusher, in particular for comminuting material, with two rotatable crush rolls (1) forming a nip (2) into which the material to be processed is fed, wherein at axial ends of the rolls the nip (2) is closed by end plates (3), wherein the end plates each comprise a base plate (5) and a wear-protection layer (6) attached to the base plate (5), wherein the wear-protection layer (6) is formed at least in a first wear zone (6a) of individual wear-protection elements that at least partially are made of a wear-resistant material with a hardness greater than that of the base plate (5)

This roll crusher is characterized in that the wear-protection elements in the first wear zone (6a) are formed by studs (9), in that the base plate (5) in the first wear zone (6a) comprises a plurality of individual recesses (10) incorporated in the base plate (5) and in that an individual stud (9) is seated with its entire length (L) into each recess (10) in such a way that the studs (9) do not project past the recesses (10).

A cutter includes a first end configured to engage an object along a dominant force vector, a second end opposite the first end, a first side, and a second side opposite the first side. The cutter further includes an outer side, an inner side, and an aperture extending from the outer side to the inner side along a fastener axis that is substantially perpendicular to the dominant force vector. The cutter also includes a cutter tip on the first end and having a first cutting edge, a second cutting edge, and a third cutting edge, the cutting edges defining therebetween a cutting face. The cutting face defines a cutting swath having a width between the first cutting edge and the second cutting edge as the cutter rotates with the apparatus. No portion of the first side or the second side extends outside the width of the cutting swath.