DE1741268U - ADJUSTABLE PERMANENT MAGNET AND A POLARIZED ELECTROMAGNETIC RELAY EQUIPPED WITH IT. - Google Patents

Description

Adjustable permanent magnet and adjustable permanent magnet equipped with it and dam relay.

With certain electromagnetic devices, such as polarized relays, electromagnetic pickups / o. Like. It is sometimes necessary to use one or more permanent magnets whose magnetic strength can be regulated within relatively narrow limits. In some cases it is necessary, for example when there is a subdivided magnetic circuit, that two permanent magnets have to be adjusted to exactly the same strength. Such operating conditions exist, for example, in electromagnetic relays as they are in British patents 315 496 (DRP 607 203), 559 047 and 619 546 are described. If some of the modern magnet alloys with high coercive force are used, it is thereby possible to use very small magnets, which is highly desirable because of the reduction in weight and space requirement; however, it has been found that if such magnets have the same dimensions and the same strengths as these, by means of the strengths of the two apparently identical magnets, are different by up to 20 percent.

The innovation makes the Adjustment of the strength of such magnets is achieved so that they are in practically identical Way can be made.

It has now been found that when you try the strength of a To regulate magnets, for example, that adjustable soft pole pieces in Row are arranged in the magnetic circuit, the achievable change in the strength of the Magnet is insufficient. If still external and adjustable shunt components are provided, the design is generally clumsy or bulky effective and impractical, and the outside field is regularly disturbed, causing Variable shunts or Storfeider arise. Has been through the innovation avoided these disadvantages.

According to the innovation, a permanent magnet consists of a section of a Magnet alloy with high coercive force, another part with low coercive force, which one tight is arranged at the permanent magnet detachment, and from an adjustable magnetic shunt, which is set up so that it absorbs part of the flux, which comes from the permanent magnet part, so that that flux outside the magnet itself or in the magnetic circuit of any device, in which the magnet is used is ineffective. With a practically usable one Embodiment are the permanent magnet part and the part with low coercive force arranged butting in end contact contact, and the magnetic shunt is designed as an insert, which from one part after the other through a common contact surface between them. Because the soft iron component can be subjected to machine processing and removed / taped /, the Insert have a section that goes into the offset hole in the soft iron component can be screwed in, as well as a stamp part, which in a hole in the magnetized Section protrudes.

The innovation should now be more detailed based on it for example reproducing drawing are explained, and although shows Fig. 1 in a spatial representation a particularly advantageous stick embodiment of the magnet, in which the Insert, which serves as a magnetic shunt, is shown removed; 2 shows a front view of a relay which is provided with two such magnets, FIG. 3 shows a three-dimensional representation of a somewhat modified embodiment of a magnet, while FIG. 4 shows a vertical center section along the section line IV-IV in FIG.

In the embodiment shown in Fig. 1 of the innovation a soft iron component with a lower coercive force than the one running in the longitudinal direction Approach of the permanent magnet section B provided with a high coercive force, which consists of one of the most recently used magnet alloys.

Since the soft iron component A is subjected to machine processing two screw holes C are drilled into it for fastening purposes. Furthermore, the soft iron component A has an inner, stepped / tapped / hole D provided which in the central axis in parts A and B or to one side offset to this if more space is required for the attachment can. The magnet section B also has a bore E, which essentially is to be addressed as an extension of the hole D and in the production in can be introduced in the manner described below. The magnetic shunt is designed as an insert F whose punch part sits with a snug fit in the bore E. He has a short Koprtcil G with screw thread, so that the insert F in the hole D can be screwed in, for which purpose the head G with a screwdriver slot H is provided.

It can be seen that the use is fine-tuned and such set can be that it protrudes into the bore E to the extent desired. If it is therefore not desired to short-circuit a large part of the magnetic flux or to run in the tributary to the permanent magnet section B, the Insert F just screwed into the hole D, so that only a small one Part of its front end penetrates into the hole E. On the other hand, the use F can be screwed a fairly large piece into the hole D so that it can be Piston or stamp part a considerable magnetic flux from the permanent magnet section D here is able to absorb. The insert can be introduced with a precise fit, in such a way that it remains in the regulated position to be readjusted from time to time to be able to. However, once it has been adjusted, it is advisable to to be determined in some way, for example by making a plumb bob or a other fusible material is made to run in.

The external or useful magnetic flux from section B can, as easily can be seen from its maximum value by a controllable value by adjusting of the insert F can be reduced.

A simple method for producing such a magnet is that by means of powder metallurgy or sintering production, in which a cast or press mold is used, which has an inner cavity of the shape of the magnet part B and the adjoining part of the workpiece A, and an outer cavity of the shape of the right section of part A in Fig. 1. A cylindrical C> or slightly tapered core with the dimensions of the holes D, E sits within the mold such that it extends along the central axis through the inner cavity and into and through the outer cavity. Some powder of the magnet alloy, in such an amount that part B can be produced, is poured into the inner cavity of the mold, while soft iron powder for part A is poured into the outer cavity, around the remaining part of the space to be filled in within the form. The composite component is then exposed to high pressure in the usual way and the whole is sintered and finally magnetized to produce a permanent magnet. The hole is drilled out and the insert F is produced for the purpose of pre-rolling the magnet. Such a magnet is obviously of compact design and can be manufactured with small dimensions, while the adjustment does not disturb the field distribution of the external useful field to any significant extent, but only causes the required change in strength.

A relay is shown in FIG. 2 as an application example for the innovation shown, which is exactly the same as that shown in FIGS. 1 to 4 of the British Patent 619,546 is shown. The only difference is that the two full magnets 9 according to the aforementioned patent by a pair Magnets improved according to the innovation replace the same reference numerals as in the earlier patent one in Fig. 2 has been used, so that the two Pole pieces 1, 2 between the magnet legs 4 of the oscillating armature 13, the lugs 5, the contact holding rails 6, the spacer rails 8 and the signal coil 21 can be seen are. Parts A, B of one the magnets 9 are clearly together with the insert F and the holes B, E. Two screws K, which pass through the hole C to hold the magnet in its working position. As can be seen, good access to the screwdriver slot H is for control purposes available so that one or both magnets can be adjusted so that the the magnetic fluxes emanating from them are of the same magnitude.

The one in FIGS. 3 and 4 shown magnet corresponds in its structure that shown in Fig. 1, and again corresponding parts A, B are provided. In this case, however, instead of being an insert, the magnetic shunt is in a Bore E seated, designed to be a soft iron block L that is slidable in a Channel or a groove M is guided, which or which is formed in the head part of the magnet with the soft iron block being fitted into the channel M. The adjustment will made in that the block L in the channel M performs a sliding movement and is established in the regulated position. For this purpose there is a clamping screw N provided, which is to be screwed into part A below the channel M.

The screw N extends downward through a slot P im Block L, with the purpose of achieving a more pleasing appearance or more compact structure her head R is seated in a wider upper part S of the slot P. the Screw W is loosened for the purpose of adjustment and tightened after adjustment has been carried out, to clamp the block L in the regulated position.

Protection claims.

Claims (6)

Protection claims 1. Adjustable permanent magnet, characterized in that that a permanent magnet part with high coercive force, an adjacent part with low Coercive force and an adjustable magnetic shunt are set up in such a way that that this part of the magnetic flux from the permanent magnet part in such a way absorbs the fact that the magnetic flux outside the magnet itself is ineffective. 2. Permanent magnet according to claim 1, characterized in that the Magnet part with high coercive force and the part with low coercive force butt against each other are provided in end contact contact and that the adjustable magnetic shunt is designed as an insert, which is through a common contact surface between the two parts moved through. 3. Permanent magnet according to claim 1 or 2, characterized in that the magnetic tributary flux by means of a screw connection with a remote one Bore / tapped bore / can be adjusted in the magnetic part with a low coercive force. 4. Permanent magnet according to claim 3, characterized in that the magnetic shunt protrudes into a hole in the part with high coercive force. 5. Polarized electromagnetic relay with a split magnetic circuit for the polarizing magnetic flux and a pair of permanent magnets according to claim 1 to 4 for generating the polarization magnetic flux, characterized in that, that the magnets are to be adjusted so that they have the same magnetic strength. 6. Adjustable permanent magnet, in particular according to claim 1 to 5, as shown and described.