A device, which serves to separate particles of a bulk material, which is deliverable at an input location and is removable processed in different or at least approximately unitary particle sizes at an output location, includes at least one separating element, which has a metal separating plate with through-openings provided therein, which separating element can be provided with ultrasonic energy and for this purpose is connected to an ultrasonic transducer and which is held by a holding device. The holding device is a mounting shaft, which is held at one end or at both ends fixedly or movably, in particular rotatably and/or axially displaceable, and which at one end or at both ends is connected to an ultrasonic transducer, by means of which ultrasonic energy is couplable via the mounting shaft into the separating element, which is designed to be dimensionally stable.

A device, which serves to separate particles of a bulk material, which is deliverable at an input location and is removable processed in different or at least approximately unitary particle sizes at an output location, includes at least one separating element, which has a metal separating plate with through-openings provided therein, which separating element can be provided with ultrasonic energy and for this purpose is connected to an ultrasonic transducer and which is held by a holding device. The holding device is a mounting shaft, which is held at one end or at both ends fixedly or movably, in particular rotatably and/or axially displaceable, and which at one end or at both ends is connected to an ultrasonic transducer, by means of which ultrasonic energy is couplable via the mounting shaft into the separating element, which is designed to be dimensionally stable.

A metering system for applying a bead of a multi-component composite material to a component. The metering system comprises a mixing head including a mixing chamber. The metering system includes one supply line for each component of a multi-component composite material, leading from a source of each component to the mixing chamber. The mixing chamber is configured to mix the components of the multi-component composite material in the mixing chamber and has an outlet opening through which the mixed multi-component composite material exits the mixing head. The metering system includes a metering pump to convey a discharge of the multi-component composite material through the outlet opening. The metering system includes a control unit to output, to the metering pump, a control signal comprising control information andvadjust a metering output of the multi-component composite material through the outlet opening of the mixing head based on the control signal.

An apparatus for aerating bodies of water, comprising a floating platform (19), a motor (15) supported by the floating platform (19), a transmission (16) which is coupled to the motor (15) and whose output shaft is in the form of a hollow shaft (17), a fan for supplying air through an air supply line (18) connected thereto, wherein the air supply line (18) is connected to one end (E1) of the hollow shaft (17), a hollow stirring shaft (1) coupled to the other end (E2) of the hollow shaft (17), an stirrer (K) affixed to the free end of the approximately vertical stirring shaft (1), wherein the stirrer (K) is designated as a hollow body and has a central opening (3) through which air supplied by the stirring shaft (1) can pass, and a multiplicity of air outlet openings (14).

A stirring member (90) for an industrial stirrer, in particular for a stirring rod arrangement, for connecting to a stirring mechanism combinable with a container for receiving liquids, wherein the container comprises a filling opening closable with a lid for filling the container in an upper bottom wall, wherein the stirring member is connectable to a rod-shaped stirring member carrier of the stirring rod arrangement, wherein the stirring member comprises a bearing end (91) and a stirring member end (94) connected to the bearing end (91) via a link (92) and having a flow tube (93), wherein the flow tube comprises a tube wall, wherein the flow tube comprises an annularly formed accumulating surface (95) at its flow inlet cross section, wherein the accumulating surface comprises at least one circular ring sector (96) which is inclined with respect to an inflow plane of the flow inlet cross section.

A method is useful for triboelectrically charging chemically conditioned bulk salt mixtures by mechanically moving the bulk salt mixture in a container by at least one vertical mixer.

This invention is directed toward a mixing vessel and mixer where the design of the mixer and mixing vessel allow the mixer to reach all the cracks and crevices of the mixing vessel. The mixer also has two opposing openings with mixing vanes that facilitate turbulence and blending through a strong centrifugal flow. The mixer has unbroken or minimally broken surfaces for grinding/shearing lumps into a smooth, lump-free paste.

An apparatus for accommodation and dispensing of miscible materials has an accommodation vessel having a lower region in the form of a truncated cone, with a lower discharge opening in the direction of gravity, and ha a mixing mechanism shaft disposed centrally in a mixing space, which shaft has at least one mixing mechanism that revolves in the accommodation vessel. The discharge opening is provided with a displacer apparatus that projects into the interior of the lower region of the accommodation vessel. The lower end of the mixing screw or mixing spiral of the mixing mechanism projects into the approximately V-shaped channel between the lower vessel wall and the displacer apparatus.

A stirring staff arrangement (29) for being connected to a stirring machine that can be combined with a container (20) for receiving liquids, wherein the container, in an upper bottom wall (26), has a filling opening being closable with the help of a lid (28) for filling the container, wherein the stirring staff arrangement has a bar-shaped stirrer element carrier (30) embodied as a hollow shaft for receiving a stirring machine shaft, and stirrer elements (32) coupled to the stirrer element carrier so as to be pivotable, in such a manner that the stirrer elements have been pivoted, in a mounting configuration, with a free stirrer element end, against an axis of rotation of the stirrer element carrier, wherein a spring means is arranged between the stirrer elements and the stirrer element carrier, in such a manner that the stirrer elements, in an operating configuration, are charged with centrifugal force as a consequence of a rotation of the stirrer element carrier and take a pivoted position that depends on the rotational speed of the stirrer element carrier, a stirring angle being realized with respect to the axis of rotation, wherein the free stirrer element ends are arranged at a stirring distance r from the axis of rotation and the spring force, which increases as the stirring angle grows, opposes the centrifugal force.

The invention provides a method for producing prion protein having an aggregated conformation by contacting native conformation prion protein with aggregated conformation prion protein in a liquid preparation and subjecting this to at least one cycle or to a number of cycles of application of shear-force for fragmenting aggregates of prion protein, wherein the shear-force applied is precisely controlled. In addition to this process for amplification of aggregated state prion protein from native conformation prion protein, the invention relates to the aggregated state prion protein obtained by the amplification process, which aggregated state prion protein has one conformation, which is e.g. identical within one batch and reproducible between batches, e.g. as detectable by proteinase resistance in a Western blot.