DE3538841A1 - Safety contact device operated by a magnetic field - Google Patents

Abstract

In the case of a safety contact device having a contact device which is operated by a magnetic field and having a first permanent-magnet system which is allocated to said contact device for operation, an additional second permanent-magnet system is provided which masks the polarity of the first permanent-magnet system on the unprotected side of the safety contact device or simulates an opposing polarity and/or is allocated to a second contact device which is operated by a magnetic field of opposing polarity.

Description

The present invention relates to a magnetic field actuated safety contact device according to Preamble of claim 1.

In alarm systems, monitoring devices and the like systems are often operated by magnetic fields Contact devices used to determine the state of a establish monitored facility, e.g. B. whether a Window or door is open or closed. These safety contact devices contain in generally a so-called reed relay or protection Tube contact device, the two in a glass tube vacuum-sealed contact blades or paddles contains by an external magnetic field from one Hibernate can be switched to a working state. The contact device is, for. B. as part of a monitoring window installed and at the associated Window sash is on one for unauthorized persons, ie from a permanent magnet outside the inaccessible point system ("actuating magnet system") arranged, the Magnetic field the contact device when closed Windows in their excited state (working state), in  that the contact is open holds. Will the window opened and the exciting permanent magnet system there by removed from the contact device, so switches the contact device because of the now missing or too weakening magnetic field in the de-excited state (Idle state), the contact closes and the associated system an alarm, a display or generated any control function.

The well-known magnetic contact operated safety contact furnishing is relatively easy, however outsmart. One can namely of the unprotected, outer side the polarity of the contact device in the excited state holding magnetic field easy to determine with a so-called polar indicator and then outside near the contact device other permanent magnet system (external magnet system) ent appropriate polarity and strength, which the Contact device keeps excited, even if the window opened and the actuation magnet system is removed from the contact device.

The present invention is accordingly the Task based on a magnetic field operated safe to specify the safety contact device Function from outside practically not rendered ineffective can be.

This object is characterized by in claim 1 nete safety contact device solved. Continuing dungen and advantageous embodiments of the Invention appropriate safety contact devices are the subject of subclaims.  

With the magnetic field operated safety contacts direction according to the invention is the polarity of the Actuation magnetic field, which the contact device normally keeps them excited, from the outside not recognizable and / or it is not possible that the Contact device holding magnet when excited field through from the unprotected side to the External magnetic field.

The following are exemplary embodiments of the invention explained in more detail with reference to the drawings.

Show it:

Fig. 1 is a schematic plan view of a known magnetic field-operated safety contact device, to which reference is made to explain the problem underlying the invention;

Fig. 2 is a schematic side view of a first embodiment of a magnetic field-operated safety contact device of the invention;

Fig. 3 is a schematic plan view of a second embodiment of the invention;

Fig. 4 is a side view of a strip-shaped magneti overbased permanent magnet body as it can find in the embodiment of Fig. 3 using,

FIGS. 5 and 6 are plan views corresponding to FIG. 1 of further embodiments of the invention, the additional, serving for deception Magnetsyste me included.

Fig. 1 shows a simplified part of a secured by an alarm window. In the window frame 10 , a magnetic field-operated contact device 12 (z. B. a so-called reed relay or a protective tube contact) is installed, the z. B. contains two contact blades or paddles in a protective gas-filled, melted glass tube. For the following it is assumed that the contact device forms a normally closed contact, ie that the contact is closed by suitable mechanical and / or magnetic biasing of the paddles in the absence of an external excitation magnetic field sufficient of strength and suitable polarity. The contact device 12 is connected in series with its connections to a voltage source 14 and a display, alarm or control device, for example shown as a lamp 16 . In the window sash 18 , a permanent magnet system 20 in the form of a bar magnet is arranged in the contact device 12 so that when the window is properly closed, the magnetic field generated by the “actuation” permanent magnet system 20 holds the contact device in the excited state, in which the contact opens and therefore the circuit between the voltage source 14 and the indicator lamp 16 is interrupted. If the actuating permanent magnet system 20 is removed from the contact device 12 when the window sash 18 is opened, the contact and thus the circuit is closed.

In the known magnetic field actuated th safety contact device described above, the polarity of the magnetic field generated by the permanent magnet system 20 from the unprotected, outer side of the window can easily be determined by means of a so-called polar indicator 22 . If you then attach an "external" permanent magnet 24 with suitable polarity to the outside of the window frame 10 , the contact device 12 remains in the excited state, even when the window sash 18 is opened and the actual actuating permanent magnet network system 20 is removed. The safety function is therefore out of operation.

Such decommissioning of the safety function is not possible with the safety contact devices according to the invention. In the illustrated in Fig 2 embodiment of the invention (in Fig. 2 not shown) in the window frame two magnetic field actuated contact devices 12 a, 12 b arranged above each other and that contact devices are two Permanentmag netsysteme 20 a, 20 b in the window casement (does not Darge) associated , which consist of bar magnets and are arranged next to each other with opposite polarity. If the contact devices are polarized contact devices, the contact devices 12 a and 12 b are of course also installed with a corresponding, opposite polarity.

In the device according to FIG. 2, the polarity of the magnetic field is firstly not be determined unambiguously by the unprotected side and secondly, the Annähe is tion of a foreign magnet corresponding to the bar magnet 24 (Fig. 1) is always to respond (closing) of one of the contact devices 12 a or 12 b .

Fig. 3 shows another way to prevent the safety contact device from being taken out of operation from the outer, unprotected side. (The unprotected side is generally that side of the contact device which is opposed to the associated permanent magnet system used for actuation).

In Fig. 3, the magnetic field-actuated Kontaktvorrich device 12 is assigned a plate-shaped permanent magnet body 30 which is magnetized in strips , as the top view of the permanent magnet body 30 in Fig. 4 shows. The position of the permanent magnet body 30 is adjusted so that the magnetic field distribution resulting at the location of the contact device 12 keeps the device in the excited state. It is obvious that in the device according to FIG. 3 it is neither possible to determine the polarity of the magnetic field holding the contact device in the excited state nor to replace this magnetic field with an external external magnetic field.

In the embodiment according to FIG. 5 corresponds to the known device according to FIG. 1 with the exception that a "deception" magnet system 40 is arranged on that side of the contact device 12 which is opposite to that of the actual actuating permanent magnet system 20 . The illusion magnet system is thus located on the outer, unprotected side of the contact device 12 and consists of a Stabmagne th, which is polarized opposite to the bar magnet that forms the actuation permanent magnet system 20 . The ratios are chosen such. B. by the pole spacing of the illusion system 40 larger and / or the pole thickness smaller and / or the distance between the illusion system and the contact device 12 chosen larger that the actuating permanent magnet system 20 is still able to the contact device in the excited state hold. On the outer, unprotected side (in Fig. 5 below), however, the influence of the tau permanent magnet system closer to this side predominates, so that polarity is determined by means of a polar indicator, which is opposite to that of the actuating magnetic field. If an external magnet 24 is now attached to the outside with a polarity that corresponds to that of the deception system 40 , the contact device is brought to close, since the external magnetic field is directed counter to the actuating magnetic field and therefore weakens the device at the location of the contact device.

Fig. 6 shows an embodiment of the invention, which is based on a similar principle as the embodiment according to FIG. 5. Again, on the actuating magnet system 20 side of the contact device 12, a deceptive magnet system is provided, which the polarity of the Actuation permanent magnet system 20 veiled on the unprotected side of the safety contact device. In Fig. 6 several simple Magnetsyste me 40 a , 40 b , ... 40 e are provided for deception, which can have the shape of rods or short cylinders and are arranged with their poles with such, possibly different orientations, (as is, for example, indicated in Fig. 6 by the polemarkings N or S) that the orientation of the actuating magnetic field for an unauthorized person can not be determined. Again, it is impossible to determine the polarity of the actuating magnet system 20 with a polar indicator from the unprotected side. The deception magnet systems can be simple and cheap oxide magnets.

If a free-standing object, like a plastic, too is to protect, the deception magnet systems around the Contact device and the actuation magnet system be arranged around.  

The actuation magnet system 20 here and in the other embodiments can advantageously consist of a high-quality magnetic material, such as a rare earth alloy, for example samarium cobalt or neodymium iron.

In safety systems that work with quiescent current, can of course contact devices with Ar contact or in the case of more complex systems devices with changeover contact can be used.

In summary, the present one Invention at least one additional permanent magnet system with at least two poles, the Polarity of the actual actuation magnetic field on the unprotected side veiled or an opposite simulated polarity and / or a second Contact device is assigned by a oppositely polarized magnetic field like the first can be actuated.

Claims (10)

1. Safety contact device for an alarm system and the like with a magnetic field actuated contact device ( 12 ) and at least one pair of opposite poles containing first permanent magnet system ( 20 ) for generating a first magnetic field that keeps the contact device in an excited state when the first permanent magnet system is located in the vicinity of the contact device, characterized in that at least one second magnet system ( 30 , 40 ) with at least two poles is arranged in the vicinity of the first magnet system, which distorts the first magnetic field in the vicinity of the contact device. 2. Safety contact device for an alarm system and the like with a contact device ( 12 a) and a first permanent magnet system ( 20 a) containing at least one pair of opposite poles for generating a first magnetic field that keeps the first contact device ( 12 a) in a working state when the first permanent magnet system is in the vicinity of the first contact device, characterized by a second contact device ( 12 b) , which is arranged in the vicinity of the first contact device ( 12 a) , and a second magnet system for generating a second magnetic field, which is the second contact device holds in a working state when the second permanent magnet system is in the vicinity of the second contact device, the magnet systems ( 20 a , 20 b ) are arranged side by side with opposite polarity ( Fig. 2). 3. Safety contact device according to claim 1, characterized in that the second magnet system ( 40 ) on the side facing away from the first magnet system ( 20 ) of the contact device ( 12 ). 4. Safety contact device according to claim 3, characterized in that the two magnet systems ( 20 , 40 ) contain bar magnet systems which are arranged parallel to one another with opposite polarity. 5. Safety contact device according to claim 1, characterized in that the two magnet systems are formed by a multipole, in particular strip-shaped magnetized permanent magnet body ( 30 ). 6. Safety contact device according to claim 1, characterized in that on the first permanent magnet system ( 20 ) facing away from the Kontaktvor direction ( 12 ) a plurality of illusion magnet systems ( 40 a to 40 e ) are arranged ( Fig. 6). 7. Safety contact device according to claim 1, characterized in that the contact device and the first magnet system of several illusion magnets systems is surrounded. 8. Safety contact device according to claim 6 or 7, characterized in that the illusion magnet systems have different orientations. 9. Safety contact device according to claim 6, 7 or 8, characterized in that the deception mag Network systems are simple oxide magnets. 10. Safety contact device according to one of the An Proverbs 1 to 8, characterized in that the first Magnet system made of a rare earth alloy, such as Samarium cobalt or neodymium iron.