DE2539757A1 - Rotating magnetic key for vehicle cylinder lock - has split screened magnets for preventing interaction generating directed magnetic fields - Google Patents

Abstract

The magnets inserted into the key each consist of two part magnets. Between each magnet is placed a screening layer (3) made of ferromagnetic material. This screens the field of individual magnets from each other and prevents a displacement of the magnetic fields by interaction of the magnets. The component magnets can be made from an isotropic material. In this case the screening layer is used as conducting layer for magnetic force lines. Magnetic fields of each magnet emerge at right angles to the magnet surface and are directed to the magnets of the associated lock tumblers. The magnetic system is accurately matched to the given key circuit, and no angular shift of magnetic field occurs due to interaction of the magnets.

Description

Reversible key for cylinder lock with magnetic tumblers Patent description The invention relates generally to locking devices with magnetic Guard locks and especially on such locks according to my patents no. 1 280 085 and Io. 1,553,365. In the patent application relating to laid-open specification 1,678 003 of December 23, 1970, has already become a reversible key for such locks described. However, the arrangement mentioned there showed in practical use various disadvantages. The first disadvantage is that the magnetization is on both Sides of the key magnet must be carried out at the same time.

This has to do with the necessary use of isotropic magnetic materials the consequence that inevitably with the magnetization a shift BEZW. distortion the predetermined pole position of the magnets takes place, so that the magnets obtained do not fit into the defined pole system. Because of the confusion of the pole shifts there are corrections on the top and bottom of the magnets of the key magnet, which would lead to the correct pole position, not possible. In the Offenlegungsschrift No. 1 678 003, a split key magnet is also shown in FIG. 5, but since the material in between of the key body is not ferromagnetic, the fields of the magnets 9 are not shielded from each other, so that always a resulting field acts. in addition, the small thickness of the partial key magnets causes a very strong stray field emerging from the side, so that the effective field of this arrangement is small. The key structure does not allow a greater thickness of the magnets, and In addition, the key channel in the lock would be too wide. This is another disadvantage requires that only an isotropic magnet material is used as the material for this magnet can be. This creates strong stray fields from the magnets, which create the effective fields reduce the size of the magnets considerably.

To avoid these disadvantages are in the present invention Used magnets, which consist of an upper and a lower part magnet, and which are attached to both sides of a thin plate made of ferromagnetic material.

Such an arrangement allows the use of anisotropic magnetic materials. In addition, the intermediate layer made of ferromagnetic material, which as Separating layer or shielding works, any influences from the upper to the lower Magnets resp. reversed canceled. With the new arrangement it is possible to Manufacture double magnets that fit exactly into a given key scheme fit and no angular displacement of the magnetic fields due to mutual interference of upper and lower magnet.

In the following description, the invention is referenced explained in more detail on the figures in the accompanying drawing. In the drawing are FIG. 1 shows an illustration of the nine key magnets; Figure 2 is a plan view of one Reversible key; FIG. 3 shows the magnetic field lines of a key magnet when using an isotropic magnetic material; Figure 4 shows the same representation the magnetic field lines when using an anisotropic magnetic material; figure 5 the magnetic field lines in a cut magnet for the upper part magnet when using an isotropic material, FIG. 6 shows the same representation when using an anisotropic material; Figure 7 shows the representation of a reversible key Use of a plate made of anisotropic magnetic material3 Figure 8 shows the same representation on average.

The definition and advantages of a reversible key have already been made in application no. P 16 78 003.3 given respectively. described. These are for a key as he does today, especially with vehicle locks is widely used, which can not only be introduced into the lock in one position can, but regardless of the location, the lock opens or closes in any case. With reference to the key according to the invention, this means that the pole arrangement of the Key according to Figure 2 with the magnets 5, 6 and 7 when the key is turned around the axis A - A 'around 1800 must show the same polarity as in the figure 2 is shown.

In practice, of course, the magnets are rotated by rotating the pole fields 5, 6 and 7 around their axis numerous variations possible, with a reversible key However, the polarity of the opposite side of the magnet must always be such that when it rotates of the key around 1800 on this the pin pattern shown on the first page again appears.

The use of a reversible key is particularly important for magnetic locks important with magnetically operated rotary tumblers. A key to a plate or pin cylinders, if only because of the profile grooves that are usually present, you can't go wrong introduce into a castle. The key for a magnetic lock has such a profile but not available, and it is possible to use the simple key (i.e. no reversible key) to be introduced into the keyway in any position. The lock doesn't open and too high a torque is involuntarily applied by the user, the will damage the key.

Even if you have to fix the correct key position in the key channel on the key different high cams N, N '(Figure 2) attaches in corresponding Engaging the scenes of the key channel can not be prevented by an unintentionally applied torque of the not fully inserted key to the weak webs S, S '(Figure 2) the key can break off, as is the practice has shown.

An object of the present invention is the division of the Key magnet in two part magnets and that Insertion of an intermediate layer made of ferromagnetic material. In Figure 1, 1 and 2 are the partial magnets with the niwischenschiexit 3. Winch complete key with three key magnets 5, 6 and 7 shows the figure 2. In order for this to be a reversible key, the magnets the opposite side must be polarized in accordance with the previous explanation.

Figures 3 and 4 show the disadvantages BEZW. the advance notice of use of isotropic benz. anisotropic magnets materials for the key part magnets. In the case of the isotropic material (Figure 3), the resulting field practically corresponds that of a bar magnet with a strong stray field; the intermediate layer 3 'acts here only as a shield. The main line of force flow remains within the magnets 1 ' and 2 '.

The anisotropic material to which FIG. 4 applies has a preferential direction the magnetization, which is denoted by X in FIG. This is how the river flows between the poles of a magnet essentially within the ferromagnetic Intermediate layer 3 ", and the resulting magnets 1- t and 2" have similar to Horseshoe magnets create a small stray field.

In addition, the emerging lines of force are directly on the magnet of the Guard locking directed in the lock, with which the corresponding key magnet cooperates. Figures 5 and 6 illustrate this again using a cut key magnet, in which only the field profile of the upper part of the magnet is shown.

While to this day for the key magnets almost exclusively fixed ones Magnetic materials, mostly isotropic are used, it is now possible to use plastic ones Use materials with a preferred direction (anisotropic). You bring one once easier processing during production, on the other hand they result in larger pole moments. With these materials, it is possible according to the invention, the entire key part magnets 5 ', 6' and 7 'made from one piece of anisotropic material.

Such an arrangement is shown in FIGS.

In the key body 4 'are the partial magnets 5', 6 ', 7' and the Ferromagnetic plate 3 "embedded. The magnetization with corresponding polarity can be placed in the key, but with the enclosed ferromagnetic conductive layer 3 ". To the plate 8 with the partial magnets 5 ', 6' and 7 'in the key according to FIGS. 7 and 8 naturally also includes a counterplate 9, which has also impressed three partial magnets and whose polarity is that of a reversible key is equivalent to. The magnetization of this plate can also be carried out before you put it into the key body take place.

The finished key then contains a ferromagnetic intermediate layer, which bristles from two thinner sub-layers (not shown).

Claims (6)

Claims 1. A reversible key for cylinder locks with magnetically operated Tumblers, particularly suitable for use as a motor vehicle key, characterized by the fact that the magnets inserted in the key consist of two partial magnets exist, between which there is a shielding layer made of ferromagnetic material is located, because the fields of the individual magnets are shielded from each other and a shift of the magnetic poles due to the mutual influence of the 'Reilmagnete' is prevented. 2. A reversible key according to claim 1, wherein the partial magnets from an anisotropic material, the shielding layer in this case as a conductive layer is used for the magnetic lines of force and so a magnetic field of the individual magnets is obtained whose force lines emerge perpendicular to the surface of the partial magnet and are aimed directly at the magnet of the associated guard locking. 3. A reversible key according to claims 1. and / or 2. in which the partial magnets in each key hole with a shielding respectively Conductive layer are connected, so that the Deil magnets are completely magnetized in the Keys can be used and there are two shielding elements between the partial magnets respectively Leitschichben are. 4. in reversible key according to claims 1. and / or 2. in which the partial magnets on each side of the key are combined to form a 2 lath and this plate is made of an anisotropic permanent magnet material. 5. A reversible key according to claim 4, wherein the magnetic disks on each side of the key made of a plastic builder magnet material R with ma Netic preferred direction exist. 6. A reversible key according to claim 5, whose Teilma £ netplatten with one shielding bozw. Conductive layer are provided and prior to installation in the key can be magnetized. Blank page