DE1608262C - - Google Patents

Description

The subject of the main patent is a magnetic separator for processing magnetic substances, in particular for the separation of strongly magnetic parts, with arbitrary, for example roller, U, E-shaped or similarly designed open magnetic circuit and at least one excitation winding, consisting of one or more coils. The subject of the main patent is that only part of this excitation winding consists, as usual, of insulated, non-ferromagnetic conductors, while the remaining part consists of insulated, executed ferromagnetic conductors and is arranged in the winding space of the magnetic separator that Although he reinforces the iron cross-section of at least part of the magnetic circuit, such as poles, Magnetic core or magnetic yoke, but no magnetic bridge between two magnetic opposing poles forms and together with the non-magnetic part of the excitation winding, the excitation current flows through it is. In this way, a considerable improvement in the magnetic properties is achieved of magnetic separators of the type dealt with in the main patent and thus ultimately, with the specified Size, an improvement in the separation force. The teaching of the main patent is the general idea based on conducting excitation currents through ferromagnetic conductors, thereby reducing the magnetic To improve the properties of a magnetic separator.

A disadvantage of this magnetic separator is that the magnetic circuit is made of ferromagnetic material no magnetic potential is generated and a certain number of. Magnetic poles that only form by assigning appropriate excitation windings to magnetically active elements.

The invention is based on the object of creating a magnetic separator in which the magnetic circuit generates a magnetic potential which is the magnetic potential generated by the excitation winding mainly superimposed reinforcing in the ferromagnetic pole faces, so that the generation of a stronger magnetic field with a large gradient, without increasing the electrical power consumed the excitation winding or increasing the volume of the device is possible.

According to the invention, this object is achieved in that, in addition to the excitation winding, the magnetic core, the magnet yokes and / or poles and pole plates are designed as insulated, ferromagnetic conductors and are connected to an excitation voltage.

According to the invention, as in the main patent, excitation currents are passed through ferromagnetic conductors, however, parts of the excitation winding are not made up of ferromagnetic conductors, but rather conversely, parts of the magnetic circuit designed as ferromagnetic conductors and of at least one Part of the excitation current also flows through it. However, there is also the option, on the one hand, of a To build part of the excitation winding from insulated ferromagnetic conductors and thereby the magnetic circuit to enlarge cross-section, on the other hand part of the magnetic circuit as isolated ferromagnetic Train conductors and also flow through at least part of the excitation current leave. A preferred embodiment of the invention is characterized in that the magnetic circuit at least in certain areas (e.g. poles, yokes or pole plates) in its entire cross-section made of insulated, ferromagnetic conductors through which the excitation current flows.

It is also necessary to solve the aforementioned problem the invention provides that the open magnetic circuit by at least one additional yoke piece is closed with the formation of one or more air gaps. This proposal of the invention is characterized by a particularly high separation force.

Another variant is characterized in that two open magnetic circuits, optionally under ίο Interposition of pole pieces or rollers, are switched against each other and between them one or more air gaps for the passage of goods form. In these embodiments there is still the possibility of using the additional yoke piece or the additional yoke, pole pieces and rollers also wholly or partially made of insulated, ferromagnetic Build up conductors and connect them to an excitation voltage.

The advantages achieved by the invention are ao above all to be seen in the fact that in an inventive Magnetic separator without increasing the total volume, the separation power is quite considerable is enlarged. By combining the teaching of the main patent and the measures according to the invention the separation force can be increased while maintaining a predetermined total volume enlarge.

Details and exemplary embodiments of the invention are based on the drawings described, at the same time it is shown that the insulated ferromagnetic conductors in various Way can be built. It shows

F i g. 1 in a view - partially cut open - The basic structure of a magnetic separator according to the invention in the form of a stationary one Cutting roller with rotating drum,

FIG. 2 shows another embodiment of the object according to FIG. 1,

F i g. 3 shows a vertical half section through an E-shaped magnetic separator according to the invention Magnetic circuit,

F i g. 3 a is a graph to explain the effect achieved by the invention,

4 shows an embodiment of a magnetic separator according to the invention with a U-shaped magnetic circuit,

F i g. 5 shows another embodiment of the object according to FIG. 4,.

F i g. 6 and 7 are schematic representations of magnetic separators according to the invention, with FIG such a magnetic separator with two U-shaped magnetic circuits and in FIG. 7 a magnetic separator with U-shaped magnetic circuit and an additional yoke piece is shown,

F i g. 8 and 9 schematic representations of further types of magnetic separators according to the invention, wherein in Fig. 8 such a magnetic separator with a U-shaped magnetic circuit and a roller and in Fig. 9 shows a magnetic separator with two U-shaped magnetic circuits and two rollers,

10 and 11 embodiments of rollers and pole pieces according to the invention for forming the working gap in magnetic separators according to FIG. 8 '_; and 9, wherein in FIG. 10 such a rotating roller and in FIG. 11 a stationary roller with an um-; is shown running drum

F i g. 12 and 13 exploded views of parts of two specially designed windings with ■

ferromagnetic !! Ladders, wherein in FIG. 12 parts of the roller according to FIG. 10 and dog in FIG. 13 parts of the pole piece according to FIG. 11 are shown,

F i g. 14 and 15 partial sections of a magnetic circuit with ferromagnetic conductors, indicating the preferred Field direction,

F i g. 16 exploded view of parts of a specially designed magnetic circuit with ferromagnetic Ladders,

FIGS. 17 and 18 show two other embodiments of the object according to FIG. 14 and 15.

In the embodiments shown in the drawings are for the same or similar Construction parts largely identical. Reference symbols have been used.

The F i g. 1 and 2 show embodiments of magnetic separators according to the invention in which the magnetic circuit and the excitation winding are designed in the form of a stationary separating roller. A thin-walled steel tube 1, which is provided with eccentrically arranged bearing journals 2, la with a transverse bore, serves as the supporting structure for the magnet systems. A thin-walled insulating tube 3 and insulating washers 9.9 a separate the supporting structure and the induced parts of the magnetic circuit from the ferromagnetic conductors. In the embodiment of a magnetic separator according to the invention shown in FIG. 1, a feature of the invention is realized, according to which the magnetic circuit is at least partially constructed in its entire cross section from insulated, ferromagnetic conductors through which the excitation current flows. The entire cross section of the magnetic core 5 is made up of insulated, ferromagnetic conductors. Windings 6 made of the same material, together with the disks 4 made of sheet steel, form the poles of the cylindrical magnetic circuit. The ferromagnetic conductors 5 and 6 have a current flowing through them which is smaller than the current which flows through the excitation windings 7, 8. This results in a more favorable distribution of the magnetic potential on the roll surface. According to the teaching of the main patent, the excitation winding assigned to each pole pair consists of a part 7 made of ferromagnetic conductors, which reinforces the pole 4, 6, and a part 8 made of non-ferromagnetic conductors.

The embodiment according to FIG. 2 differs from that according to FIG. 1 in that the magnetic circuit is composed entirely of insulated, ferromagnetic conductors which form the entire cross section of the magnetic core 5 and the poles 6 a .

With the help of the flange pieces 10, 10 a, the individual components are pressed together. The power supply lines run through longitudinal bores, not shown in FIGS. 1 and 2, of the bearing journals la. Rotatably mounted end walls 11 carry a drum 12 and are driven with the aid of a V-belt pulley 15. The drum is used to convey the flow of material.

In the case of the FIG. 3 illustrated embodiment of an E-shaped magnetic separator is the Center pole 20, 23 of the magnetic circuit partially constructed from insulated, ferromagnetic conductors 23, while At the same time, part of the excitation winding 24, 25 is made up of insulated, ferromagnetic conductors 24 is. The remaining part of the magnetic circuit: magnetic yoke 21, outer poles 22, 22a and center pole part 20 are made of dynamo cast steel. Thin insulating layers 16, 17 separate the induced. Parts of the magnetic circuit from the ferromagnetic conductors.

In FIG. 3 a is over the cross section of the object according to FIG. 3 the course of the magneti-S see scalar potential plotted. For orientation, the most important pole edges of the lifting magnet are included in the diagram as pixels A, B, C, D, E. The excitation winding 24, 25 builds up a trapezoidal potential distribution, which from the outer pole edge D

ίο increases linearly towards the center pole edge C. This induced potential remains constant over the entire center pole surface (dashed curve CBA). The ferromagnetic winding 23 builds up an additional trapezoidal scalar potential, rising between points B and A. The amplification of the magnetic scalar potential generated by the winding 23 can be seen in the diagram as a hatched area. Since the magnitude of the field strength is proportional to the magnetic scalar potential, the diagram shows the

ao achieved increase in separation force.

In the magnetic separators according to the invention shown in FIGS. 4 and 5, U-shaped magnetic circuits are present. The magnetic circuit of this magnetic separator M, in turn, consists of one part

as dynamo steel with pole legs 26, 26 a, yoke pieces 27, 27 a and pole plates 28, 28 a. In the embodiment of FIG. 4, part of the yoke is off ferromagnetic conductors 29 built. At the same time there is the excitation winding placed around the yoke 27, 29 30, 31 partly made of insulated, ferromagnetic conductors 30 and partly of insulated, non-ferromagnetic conductors Ladders 31. FIG. 5 shows an embodiment in which the yoke 27a is continuously from There is ferromagnetic material around which, as in the example according to FIG. 4 also, the excitation winding 30, 31 sets. In addition, the object according to FIG. 5 in the area of the pole 26 α isolated, ferromagnetic Head 29 a, whereby the flow through the field winding 30, 31 is increased.

The F i g. 6 to 9 show preferred embodiments of magnetic separators according to the invention, which are characterized by a particularly high separation force. In FIG. 6, an embodiment is shown in which two U-shaped open magnetic circuits M are mutually connected, in which arise between the two magnetic circuits M air gaps L 1, Ll for the Gutdurchgang. The separated material is brought into the effective area of the magnetic field with the help of any conveyor link. In FIG. 7 shows an embodiment in which the open magnetic circuit M is closed by an additional yoke piece 33 with the formation of two air gaps LX, Ll . Any conveyor 32 is provided in the air gaps. The magnetic separators F i g. 6 and 7 are equipped with pole pieces P, the special features of which will be explained in the following. The embodiments according to FIG. 8 and 9 again form a group with an inherently similar construction. Here, induced rollers W 1 made of ferromagnetic material are used in a known manner instead of the conveying means 32 from FIG. 6 and 7 are used. The adaptation of the pole faces of the magnetic circuits Ai to the roll profile takes place with the help of pole shoes 34, 34 a, 35, 35 a.

In a particular embodiment of the invention, rollers Wl and pole pieces P are used, the inventive features of which will be explained in the following.

As is known, a strong magnetic field must be created in the air gap L in order to achieve a good separation effect. This is the task of the magnet systems M. A further strengthening of the magnetic field in the air gap is achieved according to the invention by the fact that the air gap L between the rollers W 2 and the pole pieces P, at least partly according to the principle described above, consists of insulated, ferromagnetic conductors through which the excitation current flows are constructed.

In FIGS. 10 to 13 particularly advantageous embodiments of these parts according to the invention are shown. The roller W 2 shown in FIG. 10 contains a ferromagnetic winding covering the entire width of the fixed pole piece 34 and is designed as a rotating roller. It has a core 36 made of square steel. slipped-on insulating tube 37. Thin sheets 38 made of ferromagnetic material are alternately pushed onto the insulating tube 37 in a rotationally fixed manner with thin disks 39 made of insulating material. With the help of pressure pieces 40, 41 and ring nuts 42 a, these parts are pressed together. As can be seen from the exploded view according to FIG. 12, inclined slots made of ferromagnetic material and radial slots are worked into the insulating washers 39, which allow the composition shown. After pressing together, the parts 38, 39 form insulated, ferromagnetic conductors, each sheet 38 forming a turn. The power is supplied via pressure washers 40 which are made resistant to breakdown against the ring nuts 42 a with the aid of the insulating washers 41. The pressure disks 40 are supplied with electricity via slip rings 43. A thin-walled insulating tube 44 separates this winding according to the invention from the protective jacket 45.

One from the left half of Fig. The embodiment shown in FIG. 10 differs from that according to FIG. 10 in that the roller is arranged fixedly in terms of rotation in the magnetic separator. At both ends of the roller Wl end walls 46 are rotatably arranged on the shaft 36 a and carry a drum 45 a made of magnetic or non-magnetic material.

The in Fig. 11 of the Poistücks P according to the invention also contains insulated ferromagnetic conductors through which the excitation current flows. A tab 47 made of magnetically conductive material with an insulating tube 48 serves as a carrier. On the tube 48 sheets 50 made of ferromagnetic material are arranged alternately with thin insulating washers 49 between the pressure pieces 51. As can be seen from the exploded view according to FIG. 13, the parts 50, 49 differ from the parts 38, 39 only by their external shape. After assembly, the parts 49, 50 form insulated, ferromagnetic conductors. The power is supplied via pressure washers 52, which were made puncture-proof against the pressure pieces 51 with the aid of the insulating washers 53. Insulating foils 54, 55 separate the ferromagnetic conductors 50 from the pole 56 and from the cover 57. The honeycomb H '2 and the pole piece P are connected in such a way that they each have the polarity of the pole to which they are assigned.

With reference to FIGS. 14 to 18 are now still some embodiments of insulated, ferromagnetic conductors of the magnetic circuit or the excitation winding are shown. In every figure with off taking the F i g. 14 that field direction is indicated which has a minimum of magnetic losses guaranteed / In Fig. 14 a rectangular winding made of ferromagnetic material is shown. As

s can be seen from the partial exploded view, each turn is made up of four angled ferromagnetic Sheets 50 a assembled. With the help of thin plates 49 a made of insulating material, the individual Windings separated from each other.

ίο Fig. 15 shows a partial cross section through a Another embodiment of a winding made of ferromagnetic conductors. The wire 58 with rectangular Cross-section is provided with a thin insulating layer 59. This insulating layer can be made of, for example There are lacquer, iron phosphate or wrapping material. The embodiment according to FIG. 16 differs from that shown in FIG. 15 only in that instead of wire a ferromagnetic one Volume 58 a was used.

ao The embodiments according to FIG. 17 and 18 again form a group with inherently similar ones Construction way. In both windings, a ferromagnetic band 58 a together with one Foil 60 made of non-ferromagnetic conductor material

as wound up. An insulation layer 62 or intermediate layer 61 separates the individual turns. With such a structure, it is expedient to connect the conductive, non-ferromagnetic foils 60 in parallel with the ferromagnetic tape 58a.

whereby the current carrying capacity is increased.

Claims (7)

Patent claims: 1. Magnetic separator for processing magnetic materials, especially for the separation of Strongly magnetic parts with any configuration, such as roller, U, E or similar open magnetic circuit and at least one excitation winding, consisting of one or more Ren coils, where excitation currents are passed through ferromagnetic conductors, according to patent 1 262922, characterized in that in addition to the excitation winding and the magnetic core (1), the magnet yokes (21; 27, 27 a) and / or the Poles (4: 20, 22, 22a; 26, 26a; 28, 28a: 34, - 56) are designed as insulated ferromagnetic conductors (5; 6, 6a; 23: 29, 29a; 38; 50) and are connected to an excitation voltage. 2. Magnetic separator according to claim 1, characterized in that the magnetic circuit at least is built up in some areas in its entire cross-section from insulated, ferromagnetic conductors (5, 6a, 38, 50) through which the excitation current flows. 3. Magnetic separator according to claims 1 and 2, characterized in that the open magnetic circuit (M) ge at least by an additional yoke piece (33) with the formation of one or more air gaps (Ll, Ll) is closed. 4. Magnetic separator according to claims 1 to 3, characterized in that two open Magnetic circuits (M), if necessary with the interposition of pole pieces (P). Yoke pieces (35. 35a: M. 34a) or rollers (Wl, Wl) are switched against one another and between them one or more.: Air gaps (Ll, L2) for the product through. -w. form. 5. Magnetic separator according to claims 1 to 4, characterized in that the additional pole piece (P) or the roller (W 2) are constructed entirely or partially from insulated, ferromagnetic conductors (38, 50) and are connected to an excitation voltage. 6. Magnetic separator according to claims 1 to 5, characterized in that the isolated, ferromagnetic conductor of the magnetic circuit made of ring-like ferromagnetic sheet metal disks (38; 50) and insulating disks (39; 49) are formed, the electrically conductive connection of the Sheet metal washers through slots and corresponding Corresponding bending of one end of the slot is made when the disk pack is pressed together is. 7. Magnetic separator according to claims 1 to 6, characterized in that the isolated, ferromagnetic conductor of the magnetic circuit or the excitation winding made of angled juxtaposed Sheet metal strips (50 a) are made of ferromagnetic material, which by insulating strips (49a) are separated from each other, with an overlap point remaining uninsulated the electrically conductive connection between the sheet metal angles is established. For this purpose 2 sheets of drawings 009 636/122