Disclosed herein is a rock mill lifter having in one example: a radially outward surface with a radially inward recess having a radially inward surface which is substantially parallel to; a calculated radially outward lift surface of the lifter at a minimum allowed lifter height. The rock mill lifter in one example may further include: a circumferential following surface having; a radially inward recess configured to wear to be; substantially parallel to the radially inward surface of the radially inward recess.

The invention relates to a shell plate, to a method for making a shell plate and to a grinding mill for ore grinding. The shell plate is mountable to a shell of a grinding mill for grinding ore and includes a shell plate body having a first portion including a fixing surface for fixing the shell plate body to the shell, and a second portion having a wear surface facing toward an interior of the grinding mill. The first portion and the second portion form a continuous shell plate body, and the second portion includes polyurethane such that the wear surface is made of polyurethane.

A sonic reactor for transferring kinetic energy to a process fluid medium has a resonant element horizontally oriented and mounted to the two resonance units using two or more nodal support rings located at the nodal positions of the resonant element. The nodal support rings are adjustable in position relative to the resonant element and the resonance units to permit positioning of the rings directly at the nodal positions during operation, where, for example, adjustment may be required due to changes in the total mass attached to one or both free ends of the resonant unit. The sonic reactor has a grinding or mixing chamber mounted at one or both of the free ends of the resonant element.

A sonic reactor for transferring kinetic energy to a process fluid medium has a resonant element horizontally oriented and mounted to the two resonance units using two or more nodal support rings located at the nodal positions of the resonant element. The nodal support rings are adjustable in position relative to the resonant element and the resonance units to permit positioning of the rings directly at the nodal positions during operation, where, for example, adjustment may be required due to changes in the total mass attached to one or both free ends of the resonant unit. The sonic reactor has a grinding or mixing chamber mounted at one or both of the free ends of the resonant element.

An apparatus (10) for micronizing an inorganic salt, having a receiving vessel (14) for receiving the salt (46) to be micronized in an interior of the receiving vessel (14); a grinding unit (22) for comminuting the salt (46) to be micronized located in the receiving vessel (14) and for forming micronized salt particles (54); an ascending pipe (24), which is connected fluidically to the receiving vessel (14) and serves to transport the micronized salt particles (54), wherein one end of the ascending pipe (24) has an outlet orifice (38) through which the micronized salt particles (54) can flow out of the apparatus (10); a fan (26) for generating an air stream (40); and a housing (12) with an air outlet (44) and an air duct (42) connecting the fan (26) to the air outlet (44), wherein the air duct (42) is separated by at least one wall from the interior of the receiving vessel (14), such that the air stream (40) generated by the fan (26) does not flow through the interior of the receiving vessel (14), and wherein the air outlet (44) at least partly surrounds the ascending pipe (24) in a region of the outlet orifice (38).

Milling methods that use grinding media particles formed of a ceramic material having an interlamellar spacing of less than 1250 nm.

An agitator ball mill that includes agitating discs (18) on an agitating shaft drivable in a spinning direction (38), which are provided with entraining profiles (35). These entraining profiles (35) are formed by a trailing wall of a respective channel of a plurality of channels (36). In relation to the spinning direction (38) the trailing wall (39) of an inner channel section (49) runs radially straight relative to the central longitudinal axis (15) and has a length f, and has an outer bent-off channel section (41), which is bent off counter to the spinning direction (38). The outer channel sections (41) are closed radially to the outside by a peripheral portion (42) of the agitating disc (18) having a radial width e.

A lifter bar, method for making a lifter bar, a method for assembling a lifter bar and a grinding mill for ore grinding is provided. The lifter bar includes a lifter bar body having an outer surface conforming to the outer surface of the lifter bar and a fixing element for connecting the lifter bar to the shell of the grinding mill. The lifter bar body further includes a first portion and a second portion forming a continuous lifter bar body. The fixing element is embedded in the first portion such that it forms part of the fixing surface of the lifter bar. The second portion is made of polyurethane and forms 35-85% of the volume of the lifter bar.

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.

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.