DE29618217U1 - Holding magnet - Google Patents

Description

18 October 1996 Ne/

Applicant: Brugger GmbH, 78739 Hardt
"Designation: Holding magnet

The invention relates to a holding magnet consisting of
a ferromagnetic return pot, which has a cylindrical
Ring wall with a flat front surface and a flat pot bottom with a central hole, as well as a permanent magnetic ring,
which is at least approximately concentric and recessed in the
The return pot is arranged and secured therein by means of cast or injected plastic.
The invention also relates to a holding magnet of the
same type and basically the same design, but with a stamped and deep-drawn return pot
is used.

Holding magnets of the generic type are known per se
In a known holding magnet of this type, which has already
for some time in large quantities in electrical
Emergency stop switches are used as holding magnets,

the yoke pot and the magnetic ring are dimensionally coordinated in such a way that there is only an annular gap between the annular wall of the yoke pot and the peripheral surface of the magnetic ring, which is filled with plastic. The axial height of the magnetic ring and the axial depth of the yoke pot also match exactly, so that the outer front surface of the magnetic ring lies flush with the plane of the flat front surface of the yoke pot and forms a common adhesive surface with it.

With the magnetic materials used in these known holding magnets, the holding force specified for safety reasons, e.g. in electrical emergency stop switches, which should be between 35N and 7ON, cannot be achieved with the required reliability. The rejection rate for conventional holding magnets is high.

Instead of the previous magnet rings, neodymium iron drill magnets (NeFeB) are now available, which can be magnetized more strongly, thus generating a significantly higher magnetic flux and thus also providing a significantly higher holding force. The holding force of the new magnet rings can be on average up to 50% higher than the holding force of the previous magnet rings, whereby the

Magnetic rings made from the new magnetic material have significantly smaller cross-sections and thus also significantly smaller dimensions in both the axial and radial directions.

In order to be able to use the same design principle for the new, smaller magnetic rings, it would be necessary to use much smaller return pots into which these new magnetic rings fit, forming an annular gap with the required radial width. However, this would have the disadvantage that these new, smaller holding magnets would no longer fit in the emergency stop switches or other devices in which they have been used and are to continue to be installed in the conventional way; design changes would have to be made to the devices.

In addition, a magnetically stronger magnet ring with a wall thickness of the pot base that is designed for a magnetically weaker magnet ring will also cause increased stray fields to occur in undesirable places, namely on the base side, especially in the area of the hole edge, which will reduce the adhesive force on the actual opposite adhesive surface of the return pot.

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is weakened. In addition, with a material thickness of a conventional pot base, a magnetic saturation can be reached that does not allow a further increase in the adhesive force.

The invention is based on the object of creating a holding magnet of the type mentioned at the beginning, in which a magnetic ring which is smaller in size but significantly stronger magnetically is inserted into a return pot provided with predetermined external dimensions matched to a less powerful magnetic ring in such a way that, with unchanged installation dimensions of the return pot, the maximum holding force of the magnetically stronger magnetic ring is available on the front side forming the holding surface.

This object is achieved in a holding magnet according to the preamble of claim 1 in that when using a magnetic ring whose axial height is smaller than the axial depth of the return pot, a thickening of the pot base is provided which does not completely compensate for the axial dimensional difference, which extends to the ring wall and on which the magnetic ring with

its flat inner face (2 6) rests without a gap.

In a holding magnet which, according to the preamble of claim 3, has a punched and deep-drawn return pot, the object is achieved according to the invention in that, when using a magnetic ring whose axial height is smaller than the axial depth of the return pot, an annular and ferromagnetic spacer disk is arranged between the magnetic ring and the pot base, which does not completely compensate for the axial dimensional difference and which rests against the magnetic ring and the pot base without a gap.

The solutions according to the invention, which are based on the same solution principle, not only make it possible to create a magnetically greatly improved holding magnet in a simple manner, which can also easily replace the previous holding magnets of inferior quality in terms of installation technology, but essentially the same tools and production methods can also be used for its production.

A very important advantage, however, is that the thickening of the pot bottom or the
An inserted spacer disk creates an enlarged ferromagnetic material cross-section in the bottom area of the return pot, which prevents magnetic saturation in the bottom area of the return body and thus also prevents the formation of undesirable stray fields, so that a maximum adhesive force is available on the adhesive surface.

Advantageous embodiments of the invention are the subject
of subclaims 2 and 4 to 17.

The drawing below shows an example of implementation
the invention is explained in more detail. It shows:

Fig. 1 shows a holding magnet in section along the line I-I of Fig. 3;

Fig. 2 the same holding magnet in section after
Section line* II-II from Fig. 3;

Fig. 3 is a view III of Fig. 1;

Fig. 4 a magnetic ring in section;

Fig. 5 shows the magnetic ring of Fig. 4 in plan view;

Fig. 6 shows a return pot in section;

Fig. 7 shows the return pot of Fig. 6 in plan view;

Fig. 8 a spacer disc in section;

Fig. 9 shows the spacer disk of Fig. 8 in plan view;

Fig. 10 a side view of the holding magnet in natural size; -

Fig. 11 is a plan view XI of Fig. 10.

Fig. 12 shows a cross-section of a holding magnet with a different magnetic return pot.

The holding magnet shown in Figures 1 to 10 consists of a punched and deep-drawn, ferromagnetic yoke pot 1, which has a cylindrical ring wall 2 with a flat front surface 3 and a flat pot base 4 with a central cylindrical bore 5. The holding magnet also consists of a permanent magnetic magnet ring 20 which is arranged and fixed concentrically and countersunk in the yoke pot 1.

It can be seen in particular from Fig. 1 and 2 that the outer diameter D20 of the magnet ring 20 is significantly smaller than the inner diameter dl of the ring wall 2 of the magnetic return pot 1 and that the axial height h of the magnet

gnetrings 20 is substantially smaller than the axial depth t of the return pot 1.

Between the magnetic ring 20 and the pot base 4, an annular and ferromagnetic spacer disk 10 is inserted without a gap, which does not completely compensate for the axial dimension difference t-h; i.e., the spacer disk 10 rests without a gap on the pot base 4 and the magnetic ring 20 rests with its lower flat face on the top of the spacer disk without a gap.

The spacer disk 10 has on its circumference an annular collar 12 which projects towards the open front side of the return pot 1, the peripheral surface 15 of which is at least approximately cylindrical and the diameter D10 of which is adapted to the inner diameter dl of the annular wall 2 in such a way that no gap is created between the spacer disk 10 and the annular wall 2 and the magnetic flux finds a largely resistance-free transition. " -

This spacer not only compensates for the axial dimension difference t-h to a large extent, but also achieves a functionally important increase in the ferromagnetic material cross-section in the area of the pot base, which leads to a significant improvement.

The gap-free spacer disc more than doubles the cross-section of the magnetically conductive material in the area of the pot base, to such an extent that even with a significantly stronger magnetic ring 20, no magnetic saturation can occur. This avoids undesirable stray fields in the area of the pot base 4 and the maximum adhesive force remains available on the actual adhesive surface.

The magnetic ring 20 is surrounded on its outer, frontal ring surface 24 and on the circumference by a plastic bed 31 introduced using the injection molding process.

This plastic bed fills both the cavity existing on the circumference between the ring wall 2 and the magnetic ring 10 and the gap remaining between the end face 24 of the magnetic ring 20 and the plane of the end face 3 of the return pot.

The spacer disk 10 designed in this way is provided with several pinch noses 6 produced on the inside of the ring wall 2 by axial impact, which rest on the edge 16 of the ring collar 12 under a certain axial pressure.

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zen, secured without play in the return pot 1. Instead, a simple press fit could also be sufficient.

Due to the annular collar 12 projecting axially towards the end face 3, the distance to the end face is shortened so that the impact depth required to produce the pinch noses is smaller.

As can be seen from Fig. 3, a total of four pinch lugs 6, each offset by 90° to one another, are provided for fixing the spacer disk 10. Between these pinch lugs 6, there are further pinch lugs 7, also produced by impact or the like, on the inside of the ring wall 2, which are, however, arranged at a certain axial distance from the edge 16 of the ring collar 12 of the spacer disk 10 and which protrude into the plastic bed 31 in a claw-like manner in order to give it additional axial support.

The pinch lugs 6 sitting on the edge 16 of the ring collar 12 also protrude into the plastic bed 31 as radial, inward-facing projections, but with a smaller anchoring depth than the pinch lugs 7.

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The base diameter dl2 of the ring collar 12, which is conical on the top and rounded on the bottom, is matched to the outer diameter D20 of the magnetic ring 20 in such a way that the ring collar 12 can also serve as a centering receptacle for the magnetic ring 20, which is an advantage during production.

As can also be seen from Fig. 1 and 2, the bore inner surface 22 of the magnetic ring 20 and the bore inner surface 14 of the bore 11 of the spacer disk 10 are cast with an axially continuous, common plastic hub 35, which has a cylindrical central bore 36, the diameter d36 of which is slightly smaller than the diameter d.5 of the bore 5 of the pot base 4. This makes it possible to use the central bore 36 at the same time as a sliding bearing for a cylindrical guide pin guided therein, not shown in the drawing.

In order to give the plastic hub 35 a sufficiently break-resistant wall thickness, the bore diameters dl0 and d20 of the spacer disk 10 on the one hand and of the magnet ring 20 on the other hand are each larger than the diameter d5 of the bore 5 of the pot base 4.

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The hole 11 of the spacer disk 10 is provided with a bevel 13 on the side facing the pot base 4, which is also cast with plastic, which is connected in one piece to the plastic hub 35. This also gives the plastic hub 35 a positive axial connection with the spacer disk. 10 and the plastic bed 31, which is connected in one piece to the plastic hub 35 and cast together with it, provides additional axial security in the return pot 1.

The plastic bed 31 has a flat front surface 32 which lies flush in the plane 8 of the front surface 3 of the return pot 1, which defines an adhesion plane. The plastic bed 31 and the plastic hub 35 connected to it in one piece are expediently made of polyamide 6.6, which is ideally suited for this purpose because it has the required hardness and high impact strength as well as good sliding properties.

A holding magnet of the type according to the invention used in practice is shown in its natural size in Figs. 10 and 11. The external diameter Dl of the return pot 1 is 23 mm, its axial height H 6.2 mm and the diameter d36 of its hub bore is 8.5 mm.

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The wall thickness of the return pot 1 is 1 mm. If the magnetic ring 20 is 3 mm thick, the spacer disk 10 has a thickness of approximately 1.5 mm to 1.7 mm, so that the total thickness of the pot base 4 including the spacer disk 10 is approximately 2.5 mm to 2.7 mm and the plastic layer covering the ring surface 24 of the magnetic ring 20 has a thickness of 0.7 mm to 0.5 mm.

Such a holding magnet with a NeFeB magnet ring 20 provides the required holding force of over 35N on its holding surface with sufficient safety.

In the embodiment shown in Fig. 12, the holding magnet does not have a punched and deep-drawn return pot, but rather a return pot 2/1 made in one piece from the solid turned material, the pot base 4/1 of which is provided with a thickening 10/1, so that the thickness a of the entire pot base 4/1 including the thickening 10/1, as in the previously described embodiment, is approximately 2.5 mm to 2.7 mm.

Functionally, this one-piece manufacturing method of the return pot 2/1 represents an improvement over the previously described embodiment, because there are no transition resistances at the contacting surfaces. However, this manufacturing method of the return pot is more expensive than that of a stamped and deep-drawn

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drawn return pot with inserted spacer disk 10.

Furthermore, in this embodiment, the magnetic ring 20 is also cast on three sides in an analogous manner with a plastic bed 31, into which, as in the previously described embodiment, pinch lugs 7 protrude in a form-fitting manner for axial securing, which are arranged and produced in the same way as in the return pot 2 of Fig. 1 to 3.

The pot base 4/1 or its thickening 10/1 is also provided with an annular collar 12/1 that projects conically towards the open front side, the base circle diameter dl2 of which is matched to the outer diameter of the magnetic ring 20 in such a way that the latter can be centered in this annular collar 12/1.

In this embodiment, the return pot 1/1 is provided with a central bore 5/1, the inner diameter d.5/1 of which corresponds to the inner diameter dl of the magnetic ring 20. Here too, the inner surfaces 22 of the magnetic ring 20 and the inner surface 14/1 of the central bore 5/1 of the return pot 1/1 are cast with a plastic hub 35/1, which in this case is attached to the bottom.

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underside of the pot base 4/1 ends in a bevel 13, so that the additional axial securing of the plastic bed 31 is also present in this embodiment. The inner diameter d36 of the cylindrical central bore 36 is also retained in this plastic hub 35/1, so that this plastic hub can also be used excellently as a plain bearing for a cylindrical pin.

Claims (1)

17 October 1996 Ne/ Protection claims 1. Holding magnet, consisting of a ferromagnetic return pot (1/1) which has a cylindrical ring wall (2/1) with a flat front surface (3) and a flat pot base (4/1) with a central bore (5/1), as well as a permanent magnetic magnet ring (20) which is arranged at least approximately concentrically and countersunk in the return pot (1/1) and is fastened therein by means of cast or injected plastic, characterized in that that when using a magnetic ring (10) whose axial height (h) is smaller than the axial depth (t) of the return pot (1/1), a thickening (10) of the pot base (4/1) is provided which does not completely compensate for the axial dimension difference · (t - h), which extends to the ring wall (2/1) and on which the magnetic ring (20) rests with its flat inner end face (26) without a gap. 2. Holding magnet according to claim 1, characterized in that the return pot (1/1) has a pot base (4/1) whose thickness (a) corresponds to at least two thirds of the axial height (h) of the magnet ring (10), 3. Holding magnet, consisting of a punched and deep-drawn, ferromagnetic return pot (1), which has a cylindrical ring wall (2) with a flat front surface (3) and a flat pot base (4) with a central bore (5), as well as a permanent magnet ring (20) which is arranged at least approximately concentrically and countersunk in the return pot (1) and is secured therein by means of cast or injected plastic, characterized in that that when using a magnetic ring (10) whose axial height (h) is smaller than the axial depth (t) of the return pot (1), an annular and ferromagnetic spacer disk (10) is arranged between the magnetic ring (20) and the pot base (4), which does not completely compensate for the axial dimension difference (t - h), and which rests against the magnetic ring (20) and the pot base (4) without a gap. 4. Holding magnet according to claim 1 or 3, characterized in that the magnetic ring (20) is enclosed at least on the circumference and on its outer end face (24) with a plastic bed (31). 5. Holding magnet according to claim 3 or 4, characterized in that the spacer disk (10) is secured in the return pot (1) without play by a press fit and/or by pinch lugs (6) produced on the inside of the ring wall (2) by impact. 6. Holding magnet according to one of claims 1 or 3 to 5, characterized in that projections, in particular pinch noses (7) produced by impact or the like, are arranged on the inside of the ring wall (2, 2/1), which protrude radially into the plastic bed (31). 7. Holding magnet according to claim 4 or 5, characterized in that the spacer disc (10) is provided on its circumference has an annular collar (12) projecting towards the open front side of the return pot (1) on which the pinch lugs (6) sit. 8. Holding magnet according to claim 1, characterized in that the thickening (10/1) has an annular collar (12/1) projecting towards the open end face of the return pot (1/1). 9. Holding magnet according to claim 7 or 8, characterized in that the base diameter (dl2) of the ring collar (12, 12/1) corresponds at least approximately to the outer diameter (d20) of the magnetic ring (20). 10. Holding magnet according to one of claims 3 to 7, characterized in that the bore inner surfaces (22, 14) of the magnet ring (20) and the spacer disk (10) are cast with an axially continuous, common plastic hub (35) which has a cylindrical central bore (36). 11. Holding magnet according to one of claims 1, 2 or 8, characterized in that the bore inner surface (22) of the magnet ring (20) and the bore surface (14/1) of the pot base (4/1) are cast with an axially continuous, common plastic hub (35/1) which has a cylindrical central bore (36/1). 12. Holding magnet according to claim 10, characterized in that the bore diameters (dl0 and d20) of the spacer disk (10) and of the magnet ring (20) are each larger than the diameter (d5) of the bore (5) of the pot base (4). 13. Holding magnet according to claim 10 or 11, characterized in that the plastic hub (35, 35/1) is integrally connected to the plastic bed (31) comprising the front ring surface (24) and the circumference (25) of the magnet ring (20). 14. Holding magnet according to one of claims 3, 7, 9, 10, 12 or 13, characterized in that the bore (11| the spacer disk (10) has a bevel (13) on the side facing the pot base (4), which is also cast with plastic connecting to the plastic hub (35). 15. Holding magnet according to one of claims 1, 2, 8, 11 or 13, characterized in that the bore (5/1) of the pot base (4/1) has a chamfer (13) on its outside, which is also cast with plastic connecting to the plastic hub (35/1). 16. Holding magnet according to claim 4, characterized in that the plastic bed (31) has a flat front surface (8) which lies flush in the plane of the front surface (3) of the return pot (1) defining a holding surface. 17. Holding magnet according to one of claims 4, 10, 11, 14 or 15, characterized in that the plastic bed (31) and the plastic hub (35, 35/1) connected in one piece thereto consist of polyamide 6.6.