An agitator mill, in particular an agitator bead mill having a mill housing, in which an agitator shaft, preferably bearing agitator elements, circulates in such a way that a grinding chamber is configured between the agitator shaft and the mill housing, and into the chamber the grist is fed, transported by a fluid carrier substance, as a rule in the form of a suspension, wherein the grinding chamber is partially filled with grinding media, which are set in motion by the circulating agitator shaft and thereby the grist, carried through the grinding chamber by a fluid carrier substance, is crushed, wherein the grist, transported by the fluid carrier substance, is discharged together with the carrier substance through a sieve, which retains grinding media that arrive as far as the area of the sieve, wherein the sieve consists of several sieve elements arranged one after the other along the longitudinal axis of the agitator mill, the sieve elements being penetrated in parallel manner, with their surfaces flowing from the grinding chamber, and extend diagonally or radially to the axis, around which the agitator shaft circulates.

A stirrer mill for the treatment of flowable grinding stock. The stirrer mill includes a milling container, a milling chamber delimited by the container wall, and a stirring mechanism having a rotor which rotates about a central longitudinal axis and has an inside diameter (d351). Tools, which extend toward the container wall, are attached to the rotor. The stirrer mill also includes an internal stator arranged inside the rotor. A grinding stock discharge channel is formed, between the rotor and the internal stator, through which the grinding stock passes to a separating device and, thereafter, to a discharge line. The milling chamber is at least partially filled with grinding bodies having a diameter (c). Above the internal stator is arranged a separating device with a diameter (d30). The distance (s) between the rotor and the grinding body separating device is given by the relationship: s=0.5.Math.(d351d30)5.Math.c.

A flask for containing mold sand within it prevents any mold shifting or mold dropping. Each of an upper flask 2 and a lower flask 3 includes a body that defines an opening in which a sand mold is to be molded. The body has at least one inlet 101 for introducing the mold sand into the opening. Two flanges 102 are extended from the body such that they are opposed to each other across the opening. Each flange has a through bore. The flask also includes engaging members for engaging an actuator in the outside of the flask such that a force or forces from said actuator could be transmitted to the flask. An upper flask 104 and a lower flask 105 are opposed to each other across a pattern plate 107. They are integrally assembled to make a flask unit by means of a pair of connecting rods 106 that are fitted in each bore.

The invention relates to a multi-layer lifter for semi-autogenous mills or SAG mills with improved durability, made up of: a base formed by a body having a rectangular cross-section, which has a first straight side wall and a second angled side wall; where an angled rectangular portion emerges from the upper half of said angled wall, in which a trapezoidal projection emerges from the lower portion of said base, to fit with the coatings or liners of the inside of the mill; a multi-laminated spring portion which is made up of a plurality of convex curved sheets and a bent straight portion that is located under the angled rectangular portion of said base; and a hollowed-out rubber body, located in the cavity formed by the base and the convex curved sheets.

The invention relates to an agitator ball mill, with a grinding container, the inner side of which is made of a ceramic material, a rotor arranged inside the grinding container with a grinding gap formed between the surface of rotor and the inner side of the grinding container, a plurality of cams, fitted to the inner side of the grinding container and extend radially inwards. Wherein the ratio of the height of each cam and the inner diameter of the grinding container is 0.05, and wherein the ratio of the height of each cam and the grinding gap width is 0.35.

The invention relates to an agitator ball mill, with a grinding container, the inner side of which is made of a ceramic material, a rotor arranged inside the grinding container with a grinding gap formed between the surface of rotor and the inner side of the grinding container, a plurality of cams, fitted to the inner side of the grinding container and extend radially inwards. Wherein the ratio of the height of each cam and the inner diameter of the grinding container is 0.05, and wherein the ratio of the height of each cam and the grinding gap width is 0.35.

A liner element for lining a vertical grinding mill agitator including one or more primary mounting portions configured to releasably mount the liner to a shaft of the agitator; and one or more secondary mounting portions configured to releasably mount one or more wear members to the liner. A liner segment including the liner element and at least one wear member is also disclosed.

A stirring mill, including a horizontally arranged milling vessel and a stirring shaft which is arranged therein so that it can be rotationally driven are provided. The stirring shaft has a first stirring shaft section adjacent to an inlet for material to be ground, which has a smaller diameter D24, and a second stirring shaft section adjacent to an outlet for material to be ground, which has a larger diameter D25 and in which a separating device is formed. Bypass channels leading into the separating device are formed in the first stirring shaft section.

A stirring mill, including a horizontally arranged milling vessel and a stirring shaft which is arranged therein so that it can be rotationally driven are provided. The stirring shaft has a first stirring shaft section adjacent to an inlet for material to be ground, which has a smaller diameter D24, and a second stirring shaft section adjacent to an outlet for material to be ground, which has a larger diameter D25 and in which a separating device is formed. Bypass channels leading into the separating device are formed in the first stirring shaft section.

A vertical ball mill for grinding a solid input material to form a slurry, and includes a grinding tank which defines a mixing chamber, rotatable main auger assembly having mixing blade in a lower portion of the mixing chamber and a materials flow guide. The flow conduit is provided within the grinding tank interior, and includes one or more conduit segments configured to direct input material downwardly in the grinding tank towards the lower mixing chamber and auger mixing blade. An impeller is provided within the flow conduit, with a blade configuration selected to effect the downward flow of input material through the conduit segments and outwardly therefrom adjacent to the mixing blade as the auger assembly is rotated.