DE897681C - Permanent magnetic collecting and adhesive device, in particular magnetic separator - Google Patents

Description

Permanent magnetic collecting and adhesive device, in particular magnetic separator the The invention relates to a permanent magnetic collecting and sticking device, especially a magnetic separator. Such catching and adhesive devices are known in numerous embodiments and for various uses.

In the case of a permanently magnetic drum separator, it has been suggested that a small number of rod-shaped permanent magnets with a part of the inside of the drum To connect sector-shaped overlapping, ferromagnetic plate, with the Trummelmantel consisted of ferromagnetic rods isolated from one another. Here it is around a system of magnetic rods arranged on a common yoke body, which are a series of ferromagnetic, separated from one another by magnetic air gaps Excite guiding rods.

The invention aims to improve such a system in Direction towards the utilization of the existing magnetic forces, especially for the depth effect, In order to achieve the higher visibility of a flow of goods with economically bearable dimensions to influence magnetically, to pull out the iron parts and to hold them.

According to the invention, the back yoke body should consist of a plate, on which one or more magnetic rods run parallel to the return plate Pole ends are arranged at a distance from one another and parallel to one another, the @ Covering the pole ends, leaving an air gap, through against each other non-magnetic Rods isolated conductive rods form a pole plate, which runs parallel to the return plate and is coextensive with this.

The parallel arrangement of pole and return plates with appropriate Formation of the magnet rod ends in connection with the equality of area of the two In contrast to the well-known permanent magnetic catchment and adhesive devices, Platten offers a number of notable advantages.

The parallelism of the plates and pole ends with the resulting, always the same air gaps enables a uniform design of the between the force fields running through the poles. The equality of area of the plates results in it in addition, the shortest path of the force lines between the plates at their ends and thus a greater concentration of the flow of the lines of force.

Every deviation from the equality of area extends the path of the lines of force at the plate ends and weakens the force field. One over the surface of the return plate Extensive area of the pole plate would on its parts projecting beyond the former no practically effective magnetization obtained, unless you have the Magnet bars uneconomically dimensioned. The greatest magnetization of the pole plate lies in the area of the force field between the return plate and the pole plate. Any parts of the pole plate that protrude beyond this are turned away from the flow of force lines therefore no longer covered by the mass of the lines of force and consequently remain for the practice magnetically ineffective.

The decisive factor for the degree of efficiency is that at the ends of the plates the shortest path of the lines of force is taken care of, which is the most important prerequisite Parallelism and equality of area of the return path and pole plate are. Opposite to a relatively flat mounted magnetic, which is not sufficient for many purposes Force field that often does not fully affect the iron parts in higher material flows able to pull out and possibly the iron parts from the lower area of the Pulls out the stream of material, the invention has a previously unattained depth effect on.

In addition, there is a greater impact force and resistance to demagnetization due to the constant cross-section of the air gap between pole ends and pole plate. A plate can be placed between the pole plate and the magnetic bars with the same success arrange made of antimagnetic material.

Further advantages and details are given below using the in Embodiments shown in the drawing are described. It shows Fig. 1 a Magnet system for the new catching and adhesive device with two unequally polarized Magnetic bars in cross section, FIG. 2 shows a longitudinal section of FIG. 1 with several one behind the other arranged same systems, Fig. 3 a magnet system with three alternately unlike polarized magnetic bars in cross section, Fig. 4 one with five alternating unevenly polarized magnetic bars in cross section, FIG. 5 shows a magnet system with two homopolar magnetic bars and a guide tongue in cross section, FIG. 6 a magnet system with three magnet bars of the same polarity and two guide tongues in cross section, 7 shows a magnet system with a single magnet rod in cross section.

According to FIG. 1, two are on a ferromagnetic iron conductor plate 5 Bar magnets 6 of any cross-section, which are preferably made of hardenable Al-Ni or Al-Ni-Co magnetic steels or similar magnetic steel alloys exist, mutually opposite Pole direction attached and fixed vertically. You can now use several systems of Fig. 1 in any number one behind the other or these systems on one common ferromagnetic iron guide plate, which serves as a magnetic return path, attach, as shown in the longitudinal section of FIG. You can do that Form catching device in any desired length, with the one behind the other Magnets are arranged with the same pole direction.

On the two unlike poles of the An anti-magnetic plate 3 rests on both magnet rods and is attached. on this anti-magnetic plate 3 in turn is a plate arranged in the longitudinal direction the catching and sticking device alternately made of ferromagnetic iron guide rods 1 and antimagnetic insulating spacers 2 assembled and through Welding, soldering, casting, screwing, riveting or otherwise into one unitary plate is connected.

Between the poles protruding freely from the back iron plate 5 the magnet rods 6 and the iron conductor rods 1 and antimagnetic spacers 2 composite plate is created by the anti-magnetic plate 3 an anti-magnetic Zone. In addition, stich on the upper plate 1, 2 put together through the antimagnetic spacers 2 antimagnetic zones in the magnetic Kneils how air gaps act. You can also use the antimagnetic plate 3 and the antimagnetic Leave out intermediate pieces 2 and replace them with air gaps. From strength and For reasons of fastening, however, the arrangement shown in FIG. 11 is in most cases Cases more advantageous.

The magnetic fields of the freely towering poles of the magnetic bars 6 penetrate through the antimagnetic plate 3 into the ferromagnetic guide rods I of the assembled plate I and 2, the lines of force being in the iron guide rods I collect the assembled plate 1, 2 and push it outwards in a bundled form, while the remaining lines of force on the ferromagnetic guide rods I are bent and move left and right by skipping over the anti-magnetic Intermediate pieces 2 from the N pole of one magnet to the S pole of the other magnet try to short-circuit. This course of the lines of force, shown in dashed lines in FIG is indicated, makes the entire collecting surface of the collecting device magnetic. The anti-magnetic zone 3 made of antimagnetic material or in Shape of an air gap is necessary to avoid premature demagnetization to prevent the tearing off and removal of the captured or stretched iron parts.

The collecting device described can still be on the side and on the front and back are provided with anti-magnetic head plates 4 and 7, respectively, to protect the magnet systems inside, the collecting device, from contamination.

The side plates 4 can also consist of ferromagnetic iron, so that the external magnetic lines of force over the side walls 4 from N to S can short-circuit. Likewise, the front and rear head plate 7 can be made of ferromagnetic Iron exist, but the ferromagnetic guide rods 1 must not be with these two head plates 7 come into contact, otherwise at the joint with the end of the plate 1,2 the external magnetic field would disappear.

The embodiment shown in FIG. 3 is similar to that of FIG. however, there are three magnetic bars 6 next to one another on the ferromagnetic iron back yoke plate 5, with alternating pole direction, arranged. Otherwise the structure the same as the first embodiment. Several of these can also be used here Any number of systems can be put together one after the other to form a unit.

Of course, more than three magnetic bars 6 can alternate with Pole direction combined into a system next to each other and such systems in turn can be arranged one after the other in any number. 4 shows, for example a collecting device with five juxtaposed magnetic bars 6 with alternating Polar direction.

Another possible embodiment of the invention is shown in FIG Shape differs from the previous ones in that two magnetic bars 6 with attached to the same pole direction on the ferromagnetic iron back yoke plate 5 are.

The magnetic lines of force of the poles S, S of the same name on the magnetic bars 6 on the iron back yoke plate 5 are by one between the two magnetic rods 6 located and with the iron back yoke plate 5 firmly connected ferromagnetic Iron guide tongue 8 upwards in the direction of the free pole ends N, N or magnetic bars 6 derived, so that an S'-pole is created here. Otherwise the structure is the same as in the embodiments described so far.

In the embodiment according to FIG. 5, an even better and more uniform one is obtained Distribution of the force line fields achieved on the surface of the collecting device. Of course, any number of such systems can be used one after the other to be ordered.

Any number of magnetic bars 6 with the same pole direction can also be used arrange them side by side with a corresponding number of guide tongues 8. Fig. 6 shows, for example a magnetic catching system with three adjacent magnetic bars of the same polarity 6 and two ferromagnetic guide tongues arranged between the magnetic bars 6 8, which are firmly connected to the ferromagnetic iron back yoke plate 5.

Finally, Fig. 7 shows a magnetic collection system with only one Magnetic bar 6. The rest of the structure is the same as that previously described.

In the case of the catching and adhesive devices described above, the ferromagnetic return plate 5 and the assembled cover plate I, 2 have any shape, so that the entire collection and adhesive device receives a corresponding design.

Claims (3)

PATENT CLAIMS 1. Permanent magnetic catching and adhesive device, in particular magnetic separators, with arranged on a common yoke body Magnetic bars, which are a series of ferromagnetic, through magnetic air gaps excite separate conductive rods, characterized in that the return body consists of a plate, on Ider one or more magnetic bars with the return plate parallel pole ends arranged at a distance from one another and parallel to one another are, the pole ends covering, leaving an air gap, against each other Conductive rods isolated by non-magnetic rods form a pole plate that is parallel runs to the return plate and is the same area with this. 2. Apparatus according to claim 1, characterized in that between the pole plate and the magnetic bars, a plate made of antimagnetic material is arranged is. 3. Apparatus according to claim 1 or 2, characterized in that the magnets of the same name attached to the return plate and that next to or between The magnets are arranged with ferromagnetic guide tongues. Attached publications: German patent specifications No. 700 855, 710 OII, 722 182; U.S. Patent Nos. 2,269,345, 2,275,839.