NO117792B - - Google Patents

Description

Magnetic separator.

The present invention relates to a magnetic separator for use in the preparation of magnetic materials. Magnetic separators are known in various designs, e.g. such as roller separators, belt separators and the like. The present invention relates to the electromagnetic structure of such magnetic separators to the extent that these are equipped with a magnetic circuit of ferromagnetic material, e.g. magnet sheet, as well as a magnetizing winding through which magnetizing current flows and which

stands of insulated conductors. The magnetic circuit can be designed as an open or closed circuit, as in the latter case there are one or more air gaps in the closed magnetic circuit for goods

review. The magnetic circuits are geometrically mostly U-shaped, E-shaped or roller-shaped.

In principle, with magnetic separators, it is necessary to arrange the elements so that a great separation capability is ensured. With open magnetic circuits, this ability depends on the field strength and on the magnetic field geometry, and with closed magnetic circuits it depends on the field strength in the air gap or air gaps. A disadvantage of the known magnetic separator is that increasing the field strength by magnetic saturation of the ferromagnetic material in the magnetic circuit is subject to technical limits. A further disadvantage consists in the fact that the poles of ferromagnetic material mostly only cover a small part of the effective surface. The reason for this is that often the largest part of the total volume is necessary for placing a sufficiently large magnetizing winding. The result is poor separation ability. An increase in the size of the poles with a corresponding reduction of the winding space results in a worse thermal effect for the same génnorn current. An increase in throughput will be limited by technical and economic limits. In the case of known magnetic separators, a given size, that is to say a predetermined total volume, as well as opposing constructive tendencies and interpretive tendencies limit the separation capability by compromise.

The present invention is based on a magnetic separator, possibly of the specified type, where the separation capability can be increased without increasing the overall volume.

The invention thus consists in a magnetic separator for the separation of magnetic materials, with a magnetic circuit of ferromagnetic material and a magnetization winding which is re-energized by a magnetization space consisting of insulated conductors, where the peculiarity is that the magnetization winding, for increasing the cross-section in the magnetic circuit, partly. is made up of insulated ferromagnetic conductors. Furthermore, it is possible to design the magnetic circuit so that it at least partially consists of insulated ferromagnetic conductors which are also re-energized by magnetizing current. Thereby. the magnetizing winding, or rather the flux produced by the magnetizing winding, becomes larger. It is also possible to combine these two measures.

The magnetic separator according to the invention can be designed in different ways. In the case of open magnetic separators, according to the invention, an enlargement of the poles can also be achieved in a simple way, in that the ferromagnetic conductors in the magnetization winding are assigned to a pole in the magnetic circuit in a reinforcing manner, however in such a way that no magnetic bridge is formed between two magnetic opposite poles, and possibly completely or partially covered by pole parts (pole plates or pole sheath). In this case, but also in the embodiment described above, where the magnetic circuit at least partially consists of insulated ferromagnetic conductors through which magnetizing current flows, there is a possibility that the magnetic circuit at least in certain areas, e.g. poles, yokes or pole plates, in their overall cross-section, are made up of insulated, ferromagnetic conductors that are fed by magnetizing current.

In the case of a specially designed magnetic separator according to the invention, which has a particularly high separation capability, the distinctive feature of the design of the magnetic circuit, respectively the magnetization winding in the specified manner, is that the magnetic circuit in a manner known per se (cf. German patent document 1,228,213) as an open magnetic circuit and is closed further by means of at least one further yoke element forming one or more air gaps for goods passage. Hereby, it is also possible to make the further yoke element or the further yoke elements wholly or partly of insulated ferromagnetic conductors and allow magnetizing current to flow through them. A variant consists in two open-ended magnetic circuits in a manner known per se (cf.

the aforementioned patent document) are connected to each other, possibly under the intermediate connection of yoke elements or rollers, where one or more air gaps are formed between these for the passage of goods.

The advantages of the invention consist in the fact that without increasing the overall volume, a considerable increase in the separation capability is achieved. This will be described in more detail below with reference to the attached drawing which shows an exemplary embodiment, while at the same time it is pointed out that the ferromagnetic conductors for the magnetization winding, respectively the magnetic circuit, can be designed in different ways. Fig. 1 shows the principle structure of a magnetic separator according to the invention, in the form of a separator roller. Fig. 2 shows the basic structure of a magnetic separator according to the invention, with an E-shaped magnetic circuit. Fig. 3 shows two embodiments of the separator according to fig. 1.. Fig. 5 we see an embodiment of the magnetic separator according to fig. 2. 3 Fig. 5a graphically shows the increased effect achieved by means of the invention. Fig. 6 and 7 show two embodiments of a magnetic separator according to the invention, with a U-shaped magnetic circuit. Fig. 8 qg 9 show a schematic floor plan of a separator device with magnetic separators according to the invention. Fig. 10 and 11 schematically show two embodiments of magnetic separators according to the invention, with additional yoke elements. Fig. 12 shows unfolded parts of a magnetization winding with ferromagnetic conductors, designed in a special way.

The magnetic separators shown in the drawing serve as additional preparation. magnetic materials and basically consists of a magnetic circuit 1 of ferromagnetic material and a magnetizing winding 2 which is re-energized by magnetizing current.

In the embodiment shown in fig. 1 and 2, the magnetizing winding 2 is partly made up of insulated ferro-magnetic conductors" 2a and otherwise consists of non-ferromagnetic conductors 2b. The magnetic circuit 1 and the magnetizing winding 2 are in the embodiment shown in Fig. 1 in the form of a separator roller and in the embodiment shown in Fig. 2 in the form of an E-shaped magnetic system In details, the magnetic circuit E consists of poles 3

which in the embodiment shown is reinforcingly assigned to the ferro-magnetic part 2a in the magnetization winding 2, pole parts 3a which completely or partially cover the ferromagnetic part 2a in the magnetization winding 2, as well as a yoke A.

Fig. 3 °g <*>+ shows embodiments of the power separator according to the invention, where the magnetic circuit 1 and the magnetizing winding 2, as shown in fig. 1, is in the form of a separator roller.

In the embodiments which are shown in fig. 3 °g is the magnetic circuit 1

at least partly made up of insulated, ferromagnetic conductors 1a which are also flowed through by magnetizing current and which thereby increase the effect of the magnetizing winding 2. In addition, in these embodiments, the magnetizing winding 2 is partly made up of insulated ferromagnetic conductors 2a so that the magnetic circuit 1 is made larger in cross-section. In the embodiments i.v shown in fig. 3°g ^ of the magnetic separator according to the invention is also a further feature of the invention brought to fruition. In the smallest area shown in the full cross-section, the magnetic circuit 1 is constructed of insulated, ferromagnetic conductors 1a through which magnetizing current flows. In fig. 3, the yoke *f as part of the magnetic circuit 1 in its overall cross-section is formed by insulated, ferromagnetic conductors 1a, while in fig. h the poles 3 °g the yoke h is constructed in the manner described.

In the embodiment shown in fig. 5, the middle pole 3 in the magnetic circuit 1 is partially extended by insulated, ferromagnetic conductors 1a while at the same time; a part of the magnetization winding 2 is extended by insulated ferromagnetic conductors 2a. Otherwise, up-;'; the building of this embodiment. the already described embodiments..V,

In fig. 5a, the course of the flux is plotted for the different parts of the object shown in section in fig. 5. It appears that in the area from D to C, with equal structure of the parts 2a and 2b in the magnetization winding 2, the flux will rise linearly, while in the area from C to B it remains constant and in the area from B to A again rises linearly. This last linear rise in the area from B to A can only be achieved by the fact that insulated ferromagnetic conductors 1a are arranged in the middle pole 3 of the magnetic circuit 1, which are also passed through by magnetizing current.

In the embodiments shown in fig. 6 and 7, U-shaped magnetic circuits 1 are arranged in the embodiment shown in

fig. 6 a part of the yoke k is extended by ferromagnetic conductors 1a. At the same time, the magnetization winding 2 which is laid around the yoke h consists of an insulated, ferromagnetic conductor 2a and a portion of insulated non-ferromagnetic conductors 2b. Fig. 7 shows an embodiment where the yoke h consists entirely of ferromagnetic material, and around this yoke lies, in the same way as in fig. '6, the magnetization winding 2, which consists of a part of insulated ferromagnetic conductors 2a and a part of insulated non-ferromagnetic conductors 2b. Furthermore, the device in fig. 7 in the area of the poles 3, insulated ferromagnetic conductors 1a so that the magnetization winding 2, or the effect thereof, becomes greater.

Otherwise, pole parts 3a are connected to poles 3»

In fig. 8 and 9 show ground plans of separate wire devices using magnetic separators according to the invention. Fig. 8 shows a device consisting of two parallel running magnetic separators in the form of cylindrical separator rollers which are stored in a common holder 5 aj iron. In the embodiment which is VBt in fig. 9, the magnetic separator is designed in the form of a cylindrical separator roller in connection with a magnetic holder 6. Between the two magnetic separators in fig. 8, respectively between the magnet separators and the magnetic holder 6 in fig. 9 there is one. air gap 7.

Fig. 10 and 11 show preferred embodiments of magnetic separators according to the invention, whereby a particularly high separation capability is achieved. In fig. 10 shows an embodiment where the magnetic circuit 1 is laid out as an open magnetic circuit which is closed by means of a further yoke element 8 forming two air gaps 7 for the passage of goods. A conveyor belt 9- is arranged between the air gaps 7. The further yoke element 8 can also consist wholly or partly of insulated ferromagnetic conductors 8a through which magnetizing current flows. Fig. 11 shows an embodiment where two U-shaped, open magnetic circuits 1 are connected to each other, as air gaps 7 are formed between the two U-shaped magnetic circuits 1 for the passage of goods and where instead of the conveyor belt 9 in fig. 10, rollers 10 of ferromagnetic material are arranged.

The insulated ferromagnetic conductors 2a, respectively 1a in the magnetization winding 2, respectively the magnetic circuit 1 can advantageously consist of windings of ferromagnetic tape 11 with an insulating coating or intermediate layer 12. For example, the coating or intermediate layer 12 can consist of conductive non-ferromagnetic foil 12a as a carrier with an insulating layer 12b e.g. oxide layer. With such a structure, it is appropriate to connect the conductive, non-ferromagnetic foil 12a in parallel with the ferro-magnetic strip 11, whereby the possibility of current loading becomes greater. The section shown in connection with fig. 2 shows this.

In fig. 12 shows an embodiment of insulated ferromagnetic conductors 2a, respectively 1a in the magnetization winding 2, respectively the magnetic circuit 1, respectively the roller 10, where ferromagnetic tin plates 13 are used which have inclined slots 1<*>f, while the insulating coatings or spacers 12 has radial slots 15 so that a composition of the individual ferro-magnetic tinplates 13 is possible, as can be seen from fig. 12. After compression of the individual ferromagnetic tin plates 13, these form the ferromagnetic conductors 2a, respectively 1a in such a way that each of the ferromagnetic plates 13 forms a winding.

Claims (9)

1. Magnetic separator for the preparation of magnetic materials, with a magnetic circuit of ferromagnetic material and a magnetizing winding which is re-energized by magnetizing current and which consists of insulated conductors^ characterized in that the magnetizing winding (2) for increasing the cross-section in the magnetic circuit (1) is partly made up of insulated ferromagnetic conductors (2a). 2. Magnetic separator as stated in claim 1, characterized in that the magnetic circuit (1) is at least partially made up of insulated ferromagnetic conductors (1a) which are also carried through by magnetizing current. 3. Magnetic separator as specified in claim 1 or 2, characterized in that the ferromagnetic conductor (2a) in the magnetization winding (2) is reinforcingly assigned to a pole (3) in the magnetic circuit (1) and possibly completely or partially covered by pole parts (3a). h. Magnetic separator as stated in claims 1-3, characterized in that the magnetic circuit (1) is at least partially built up in the full cross-section of insulated, ferromagnetic conductors (1a) which are re-energized by magnetizing current. 5. Magnetic separator as stated in claim 1-<*>f, where the magnetic circuit (1) is designed as an open magnetic circuit and is closed by means of at least one further yoke element (8) forming one or more air gaps (7) for goods passage , characterized in that the further yoke element (8) is also fully or partially made up of insulated, ferromagnetic conductors (8a) and the magnetizing current flows through it (fig. 10). 6. Magnetic separator as stated in claims 1-5", where two open-ended magnetic circuits (1) are connected to each other, possibly with intermediate connection of yoke elements (8) or rollers (10), and form one or more air gaps (7) between them for goods inspection, characterized in that the rollers (10) are also fully or partially made up of insulated, ferromagnetic conductors (10a) and are fed through by magnetizing current (fig. 11). 7. Magnetic separator as stated in claims 1-6, characterized in that the isolated ferromagnetic conductors (2a, respectively 1a) in the magnetization winding (2), respectively the magnetic circuit (1) consists of windings of ferromagnetic tape (11) with insulating coating or spacer (12) (fig. 2). 8. Magnetic separator as stated in claim 7, characterized in that the insulating coating or intermediate layer (12) consists of a conductive, non-ferromagnetic foil (12a) which supports an insulating layer (12b), e.g. oxide layer, as the foil (12a) can be connected in parallel with the ferromagnetic band (11) (fig. 2). 9. Magnetic separator as specified in claims 1-6, characterized in that the isolated ferromagnetic conductors (2a, respectively 1a) in the magnetization winding (2), respectively the magnetic circuit (1) consists of ferromagnetic tin discs (13), especially ring-shaped discs, with an insulating coating or spacer (12) (fig. 12).