DE9004623U1 - Locking cylinders with electromagnetic locking, especially profile cylinders intended for mortise locks - Google Patents

Abstract

Profile locking cylinders in mortise dead locks are provided with a cylinder housing (1) and a cylinder core (2) mounted rotationally adjustably therein and able to be secured against unauthorised turning by key-actuable tumbler elements and by an additional blocking element (5) actuable by means of an electromagnet (11) installed in the cylinder housing (1) and being subjected to the action of a restoring spring (6). To be able to further simplify this locking cylinder structurally and readily actuate it in the event of any failure of the power supply to its electromagnet by means of its conventional fitting key or to be able to unblock its cylinder core, the blocking element (5) is to be brought into its blocking position securing the cylinder core (2) against rotation by current flow through the electromagnet (11) and is to be held in this position, whereas when current is not flowing through the electromagnet (11) the blocking element is to be brought into the release position by the restoring spring (9) of said electromagnet (11). <IMAGE>

Description

DR.-ING. DIPL-PHYS. N. STÜRII& PATENT ATTORNEYS

DIPL-ING. P. EICHLER

BKS 3mbH, Heid-T.r. 71, 5620 Velbert 1

Lock cylinder with electric magnetic locking system particularly for mortise locks of a certain profile&mdash;

swan

The invention relates to a locking cylinder with electromagnetic locking, in particular a profile cylinder intended for mortise locks, which is provided with a cylinder housing and a cylinder core mounted therein so that it can be rotated, which is to be secured against unauthorized rotation by means of key-operated locking elements and by an additional locking element which can be actuated by means of an electromagnet built into the cylinder housing and which is actuated by a return spring.

Locking cylinders of the above type are known from DE-OS 38 00 823. In these, the armature of the electromagnet, which is housed in a central bore in the cylinder housing web part, forms the locking element, which, when no current is flowing through the electromagnet, protrudes into a radial locking bore arranged in the cylinder core and is held there by means of the return springs acting on the armature.

the electromagnet through which current flows is moved against the effect of the return spring into its retracted release position in the cylinder housing bore. In order to only have to hold the locking element electromagnetically for a short time in this release position, which corresponds to the key insertion position, in order to save electricity, a control element is arranged in the cylinder core which can be moved by the key against the effect of a return spring. When the key is inserted, the locking element, which has been moved into the release position by briefly energizing the electromagnet, is locked and allows it to return to its locking position after the key is removed. This additional control element requires a corresponding mechanical effort. In addition, these known locking cylinders have the disadvantage that the cylinder core cannot be unlocked if the electrical power supply or the control of the electromagnet fails.

The invention is therefore based on the object of creating a locking cylinder of the type mentioned at the beginning, which does not have the aforementioned defects, but rather is of even simpler construction while retaining the advantages resulting from the additional electromagnetic locking option of its cylinder core and, in the event of a power failure of its electromagnet, can be easily operated or its cylinder core unlocked using its conventional matching key. This object is achieved according to the invention in that the locking element can be brought into its locking position, which secures the cylinder core against twisting, by current flowing through the electromagnet and can be held there, whereas when no current is flowing through the electromagnet, it can be brought into the release position by the return spring.

Such a locking cylinder can be used with particular advantage wherever the power supply of door locks equipped with it with electronic programming and remote monitoring capability requires a fixed power line connection via the door leaf anyway. Since only a comparatively small amount of power is required to maintain the locking position of the locking element, which secures the cylinder core against twisting, the electrical energy required is not affected.

consumption does not play a significant role in such a power supply of the door lock and its electronics.

According to a further feature of the invention, the locking element advantageously consists of a locking pin, together with its comparatively weak return spring, which is housed in a radial bore of the cylinder core and can be moved to a limited extent. The locking pin is supported with its outer end on the armature of the electromagnet, which is housed in a bore of the cylinder housing web part and is under the action of another, but stronger return spring, in such a way that the locking pin reaches the cylindrical separating surface located between the cylinder core and the cylinder housing when no current is flowing through the electromagnet, but projects into the bore of the cylinder housing web part which accommodates its armature and the return spring acting on the latter when current is flowing through the electromagnet. This ensures that the electromagnet armature itself does not directly take over the anti-rotation locking of the cylinder core and is therefore not exposed to any corresponding wear and shear stress.

In principle, however, it is also possible for the locking element to be formed by the armature of the electromagnet, which is housed in a bore in the cylinder housing part together with the return spring acting on it and which, when the electromagnet is energized, projects into a locking bore running radially in the cylinder core, but is pressed back into its receiving bore in the cylinder housing web part by the return spring when the electromagnet is not energized.

Furthermore, the invention provides that a voltage-current converter is built into the power supply circuit associated with the electromagnet, which can be controlled by an adjustable timer, and by means of which the electromagnet can be operated both briefly with a stronger starting current and for a long time with a weaker operating current. In this way, the requirements of the electromagnet are taken into account, which requires a much stronger current to attract its armature because of the larger air gap that has to be overcome in the process than is necessary to simply hold the armature in its attracted position, in which' _: el'a .Zu: stätkät 'SjCrom not only increased

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energy consumption but also excessive heating of the electromagnet and its surroundings. |

Finally, the invention also provides for an indicator device to monitor the electromagnet with regard to its weak operating current supply, which is switched off when the current flowing through the electromagnet is either strong or interrupted. In this way, the functional reliability of the locking cylinder can be easily checked and when the current flowing through the electromagnet is interrupted,

Please note that a corresponding error has been resolved. Pastures. -■

The drawing shows an advantageous embodiment of the new locking cylinder, in a vertical cross-section running through the electromagnet and the locking element actuated by it, where |v

Fig.l the locking position and &

Fig.2 shows the release position of the locking element, §

while in « Fig.3 a corresponding block diagram is shown.

The profile locking cylinder shown only in cross section

circular cylindrical part 1', which has a cylinder core 2 that carries a locking bit that is used to operate the door lock or can be coupled to it. In the cylinder core 2 and in the web part 1'' of the cylinder housing 1, locking holes with locking elements that can be moved in them are provided in the conventional way, which can be moved by inserting the appropriate key into the key channel 3 of the cylinder core 2 so that they reach the cylindrical separating surface between the cylinder core 2 and the cylinder housing 1 with their paired end faces. As a result, the cylinder core 2 could in principle be turned using the key, provided that the latter or also remote control also cancels the additional electromagnetic locking of the cylinder core 2.

For this additional electromagnetic locking of the cylinder core 2, a locking pin 5 together with the comparatively weak return spring 6 engaging it is accommodated in a radial bore 4 in the latter in a limitedly movable manner. This locking pin 5 rests with its outer end 5' on the widened head 7' of the electromagnet armature 8, which is accommodated together with the other, but stronger return spring 9 engaging it in the radial bore 10 located in the web part 1'' of the housing 1. In the enlarged section 10' of this housing bore 10 is

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�iacgr; through the sleeve 13 covered coil winding 14 with j the power connection cable 15. A soft iron end plug 16 is inserted into the lower end of the sleeve f 12. This is provided with a funnel-shaped recess 16' into which the lower, correspondingly funnel-shaped, tapered end 8' of the electromagnet armature 8 can protrude.

* When current flows through the electromagnet 11 or its L,pu-

winding 14, the electromagnet armature is moved against the action of the return spring 9 acting on it in the position shown in Fig.l.

i; set, retracted position in the housing bore 10

so that the locking pin 5, under the action of the spring 6, projects with its outer end 5' into the housing bore 10 and thereby locks the cylinder core 2 against unauthorized rotation. &iacgr; To maintain this locking position, only a relatively weak operating current is necessary. If, however, the power supply to the coil 14 is interrupted using the appropriate key inserted into the channel 3 or by a power failure caused by remote control or a malfunction, the electromagnet armature 8 is pushed outwards by the spring 9 acting on it, whereby it pushes the locking pin 5 completely back into the core bore 4 against the effect of the weak spring 6, so that the two adjacent, oppositely spherical or cylindrical end faces 5' and 7' of the locking pin 5 or the electromagnet armature 8 reach the release position shown in Fig. 2, in which they tangled the cylindrical separating surface 17 between the core 2 and the lock housing 1. The cylinder core 2 can thus be locked using the appropriate key, which has also brought the mechanical locking elements into the release position.

rotates and thus the lock equipped with this locking cylinder can be operated accordingly.

The circuit of the electromagnet 11 must be designed in such a way that the locking cylinder is released for the duration of the locking process and then the electromagnet armature 8 must be attracted again in order to lock the locking cylinder. Furthermore, the circuit must ensure that the electromagnet 11 is energized again with a current that is initially comparatively strong after a failure of its supply voltage due to a fault and after this fault has been eliminated. Finally, it is also important for the functional reliability of this locking cylinder that the operating current flowing through the electromagnet 11 can be monitored, since if the power is interrupted, the electromagnet armature 8 is not attracted and the locking cylinder could simply be closed with a mechanical key. Therefore, an error message is issued if the power is interrupted. To ensure that the locking cylinder can be used in a variety of ways, the circuit should be designed so that a short input pulse of, for example, around 50 ms releases the locking cylinder and locks it again after an adjustable time. Since the locking cylinder and the circuit can have several meters of connecting cables, it is also recommended to ensure that no interference pulses caused by external radiation lead to the unwanted triggering of the electromagnet 11.

The practical structure of such a circuit is shown in the block diagram shown in Fig.3. This circuit is operated with a constant voltage U ,'^, which is applied to the voltage-current converter 20. This provides the power stage 21 connected upstream of the electromagnet 11 with a comparatively strong inrush current for attracting the electromagnet armature 8 and a comparatively weak current for holding the armature 8 in the blocking or operating position shown in Fig.1. In the input stage 22 /earth, the interference pulses are filtered out of the signal S arriving here. The control signal is converted in such a way that the downstream timer element 23 can be reliably controlled.

The timer controls the power stage 21 and the voltage-current converter^'äCT." _: In the case of authorized closing

In the first step, the current flow through the magnet 11 is switched off. In this circuit state, it is ensured that the magnet monitoring device 24 does not report the lack of current in the downstream display device 25 as a magnet defect. After a certain period of time set in the timer 23, the electromagnet 11 is attracted by a comparatively strong holding current, which only flows through the magnet for a short time. The magnet 11 is then operated with a comparatively weak current in the attracting position of the electromagnet armature 8. In this circuit state, the monitoring device 24 is effective, which therefore monitors the operating current flowing through the electromagnet 11. If this fails, an error signal is output on the display device 25.

The timer 23 also ensures that after the failure and re-connection of the supply voltage, the electromagnet armature 8 is first attracted again by a strong inrush current and then held in the attracting position with a weaker holding current.

Claims (6)

&bull; · DR.-ING. DIPL-PHYS. H. STÜRIES PATENT LAWYERS DIPL-ING. P. EICHLER Claims: 1. Locking cylinder with electromagnetic locking, in particular profile cylinders intended for mortise locks, with a cylinder housing and a cylinder core mounted therein in a rotatable manner, which is to be secured against unauthorized rotation by key-operated locking elements and by an additional locking element actuated by means of an electromagnet built into the cylinder housing and acting under the action of a return spring, characterized in that the locking element (5) can be brought into its locking position securing the cylinder core (2) against rotation by current flowing through the electromagnet (11) and can be held there, but can be brought into the release position by its return spring (9) when no current is flowing through the electromagnet (11). 2. Locking cylinder according to claim 1, characterized in that the blocking element consists of a locking pin (5) which is housed in a radially extending bore (4) of the cylinder core (2) together with its comparatively weak return spring (6) and is movable to a limited extent, which is supported with its outer end (5") on the armature (8) of the electromagnet (11) which is housed in a bore (10) of the cylinder housing web part (1'') and is under the action of another, but stronger return spring (9) in such a way that the locking pin (5) reaches the cylindrical separating surface (17) located between the cylinder core (2) and the cylinder housing (1) when no current is flowing through the electromagnet (11), but projects into the armature (B) and the bore (10) of the cylinder housing web part (1'') which receives the return spring (9) acting on the latter. &bull; *■ « 3. Locking cylinder according to claim 2, characterized in that the adjoining end faces (5 ',!') of the locking pin (5) and of the electromagnet armature (8) are oppositely spherical or cylindrical. 4. Locking cylinder according to claim 1, characterized in that the blocking element is formed by the armature of the electromagnet, which is housed in a bore in the cylinder housing web part together with the return spring acting on it, and which, when the electromagnet is energized, projects into a blocking bore running radially in the cylinder core, but, when the electromagnet is not energized, is pushed into its receiving bore by the <L; ? return spring. O ia ZyIi ^dergehäusestegteij. zurv, -jk^adrücken is. 5. Locking cylinder according to one of claims 1 to 4, characterized in that a voltage-current converter (20) which can be controlled by an adjustable timer (23) is built into the power supply circuit assigned to the electromagnet (11), by means of which the electromagnet (11) can be operated both briefly with a stronger inrush current and for a long time with a weaker operating current. 6. Locking cylinder according to claim 5, characterized in that a monitoring device (24) reports via a display device (25) when the electromagnet (11) no current flows through outside the release time determined by the timer (23).