DE334966C - Process for separating magnetic material in several magnetic fields that process the material one after the other - Google Patents

Description

Method for separating magnetic goods in several the goods one after the other processing magnetic fields. The invention relates to a method for cutting magnetic Good in several magnetic fields that work on the good one after the other. In such a Magnetic fields are the raw material flow in two or more superimposed or one behind the other Partial flows divorced.

According to the invention, one or more of these substreams or all partial streams, completely. Or partially, after they have been removed from the discharge body have fallen off, so deflected to the side that the deflected next to the not deflected partial currents or side by side from the following magnetic fields to be treated further. The magnetic and the non-magnetic goods thus become side by side processed in very wide strips on the same or another drum. According to the procedure, it is sufficient if, after the preliminary decision, for some ores only. a magnetic field for the further processing of the magnetic and non-magnetic material is used. With this method of operation, you have a raw material with only one magnetic Variety, so the magnetic fields of the pre-separation and post-separation of the same increase or of decreasing strength, because both the magnetic and the ummagnetic Good to be divorced in the second field. The benefits are great performance of the Machine and the achievement of pure concentrates and exits.

It is useful to remove the partial flows still adhering to the discharge device also to make them fall off and next to those already fallen off and distracted To supply partial flows of the discharge device again, whereupon all partial flows in further partial flows can be separated.

If one separates from the raw material flow in the first magnetic field Partial flows side by side in such a way that the entire width of all partial flows is equal to or approximately equal to the width of the raw material flow, the discharge device and the magnetic fields are used everywhere in their full width.

The drawing shows some exemplary embodiments of separators, with which the procedure can be carried out; namely in Fig. z with a drum separator two magnetic fields arranged one behind the other in a side view, the same in FIG. 2 Drum separator in front view against the separated partial flows, in Fig. 3 one Belt separator with two magnetic fields arranged one above the other in a side view, in Fig. q. the same belt separator in front view against the divided partial flows, 5 shows a drum separator with two magnetic fields arranged one above the other in side view, in Figure 6 the same drum separator in front view against the Partial flow deflected to the right, in FIG. 7 the same drum separator in a front view against the partial flow deflected to the left and the same drum separator in FIG. 8 in front view against the two cross-diverted partial flows together.

The drum separator shown in Figs. Z and 2 forms with -his Magnet 2 two magnetic fields 3 and 4. The raw material flow I is transferred to the upper field 3 fed, which is in a known manner in two superimposed substreams II and III separate. The magnetic partial current adheres to the drum I and becomes so easily fed to the field 4, but without this field 4 the partial flow II further separates. The weakly magnetic good III is according to the invention by the handlebar 6 guided to the side that it is on the feed device 5 the Magnetic field 4 flows in, but is next to Gutsstrom II on the magnetic drum I camps. Field 4 then separates stream III into substreams IV and V.

The tape separator 7 (Fig. 3, 4) contains the magnets 8 and io, which form the fields g and m. The field g on the feed device 12 is the raw material flow I fed. The field separates the current I into the partial currents lying one behind the other II and III, which are passed next to one another through the intermediate links 14 will. The adjacent streams II and III are on the feeder 13 supplied to the field ri, the substreams IV and V and from the stream II from the Stream III separates the partial streams VI and VII.

Both in the separator according to FIGS. 1 and 2 and in the separator according to FIGS. 3 and 4, the discharge device is not used. Particularly disadvantageous is that the magnetic fields are only partially charged with good. The full Utilization of both the discharge device and the magnetic fields is in the 5 to 8 illustrated magnetic separator achieved in that the partial flows not only distracted by the handlebars, but also narrowed so that they together roughly correspond to the width of the raw material flow. In the discharge drum 15 the magnet 16 forms the magnetic fields 17 and 18. The upper field 17 is on the The raw material flow I is fed to the channel ig. Field 17 divides this stream into two equally wide, superimposed partial flows II and III, which through the handlebars 2o, 21, 22 are deflected so that they are in the adjacent funnel 23 'and 24 fall. The triclter openings are so narrow that every partial flow that on the channel 25 is noticeable, is about half as wide as the raw material flow. The narrow ones Partial streams II and III are fed side by side to the field 18 that consists of the stream II separates streams IV and V and stream III separates streams IV and VII. the Widths of the partial flows are adapted to the composition of the ores.

Claims (3)

PATENT CLAIMS: i. Method of cutting magnetic material into several magnetic fields that process the material one after the other, in which the raw material flow through the first field into two or more partial flows lying one above the other or one behind the other is divorced, characterized in that one or more of the substreams or all partial flows, in whole or in part, after they have been removed from the discharge body have fallen off, are deflected to the side in such a way that the deflected next to the non-deflected partial currents or side by side, from the following magnetic fields can be further processed. 2. The method according to claim i, characterized in that the partial flows still adhering to the discharge device also caused to fall and in addition to the partial currents that have already dropped and deflected, the following magnetic fields are fed, whereupon all substreams can be separated into further substreams. 3. The method according to - claims i and a, characterized in that the from the raw material flow in the first magnetic field separated partial flows in such a way next to each other are directed that the entire width of all partial streams is equal or approximately equal the width of the raw material flow, so that the discharge device and the magnetic fields can be used everywhere in their full breadth. -