AT394604B - LOCKING CYLINDER WITH BUILT-IN ELECTROMECHANICAL LOCK - Google Patents

Description

AT 394 604 B

The invention relates to a lock cylinder with a built-in electromechanical lock, which comprises an electromagnet with magnetic coil and iron core that can be controlled by an electronic comparison circuit, in a bore in the cylinder housing, the bore being extended into a cylinder core, having a tumbler with a crane and housing pin, and in particular is located in a series of mechanical tumblers, which can be displaced from a locked position into a release position by means of a key in a bore in the cylinder housing, which are continued in the cylinder core rotatably mounted in the housing.

Lock systems are known which operate on the basis of a cylinder lock with a flat key. As usual, the key bit moves a number of spring-loaded core and housing pins in the locking cylinder. If division is not tight - i.e. the contact surfaces of the core pins with the housing pins lie in the cylinder surface of the core - then the core can be rotated in the housing and the conversation is opened. In addition to this, it is known to superimpose an electronic blocking criterion on this system. A known exemplary embodiment provides, for example, a code transmitter in the key box, which is inductively supplied with energy in the vicinity of the lock and emits its code. Alternatively, magnetic or mechanical code elements on the key are also known, which can be scanned electrically or optically. A receiver is provided in the rosette of the cylinder, which receives the incoming code and then compares it with a stored lock code. If the code matches, an additional lock is unlocked in the lock cylinder or in the mortise lock. Such a system therefore presupposes that both the mechanical key secret transmitted via the toothing of the flat key and the electronic key secret realized by the code are known in the lock and thus there is a lock. The particular advantage of such a lock system lies in the simple possibility of reprogramming, for example if a key is lost or the access authorization is changed.

As mentioned above, the electronic circuit additionally requires a lock which is switched on or off in accordance with the result of the electrical target / actual comparison.

For this purpose, an electromagnet is known from EP-A3 281 507, the magnet armature of which engages in a half-shell of the coupling. If an additionally coded key is inserted on the outside, the coupling is unlocked electromechanically, provided that in addition to the mechanical lock secret, the additional coding is also correct. From the inside, a key with a mechanical lock secret is sufficient for the locking process.

US Pat. No. 4,798,068 shows a balance beam or a rocker with two pins, one of which engages in a bore in the core and the other in the key channel. A spring causes the latter pin to be pressed into the key channel. The rocker is switched by an active key, whereby the signal of a key-side signal generator in the lock is evaluated and, if the code matches, a switching magnet is activated electrically.

From EP-A 303 849 an electromagnetic lock lock is known which comprises a solenoid which inserts one or more pins into a blind bore of the cylinder core or displaces these or other locking elements and locks and unlocks the cylinder core. Regardless of this, a flat key is provided, which brings core and housing pins to division in a known manner. The design requirements are low energy consumption and minimal size. Furthermore, the electromechanical lock should lock the cylinder core in the de-energized state and release it in the excited state. It is ideal if the interlock interacting with the electronic circuit and controlled by it can be installed directly in standard components with the least possible effort and if a combination of an electronic criterion is superimposed on a mechanical key secret.

According to the invention this is achieved in that the bore for the solenoid of the electromagnet opens into the key channel, and a housing pin in the bore is displaceable directly or via an extension or an intermediate piece from the iron core when the solenoid is excited and in the bore on the side facing away from the iron core At the end of the housing pin, a core pin which is displaceable by the housing pin from a locked position into the key channel is mounted.

The magnetic coil with its iron core replaces the spring of a common tumbler in the locking cylinder, which pushes the housing pin and the core pin into the key channel of the cylinder core until the core pin is in contact with the key notch. If the appropriate key is inserted, it moves the usual core and housing pins against spring force into the dividing surface or forms the stop of the last-mentioned pair of pins, so that division occurs. The locking cylinder can be locked. If the code is read from mechanical or electronic brands of the key bit or the back of the key, then it is only fully recognized when the key is fully inserted into the key channel. Therefore, when the code matches, the core pin and housing pin are pushed directly against the stop of the key bit teeth of the key already in the key channel as a result of the coil excitation. With the right key, the stop position reached is immediately the division position in which the contact surface between the core pin and the housing pin lies exactly in the outer surface of the cylinder core. Due to the variation of the key toothing, the end stop of the core pin and thus its length matched to the key represent a further safety criterion.

However, if, for example, the electronic code of the key does not match the lock code, the solenoid remains unexcited and the core and housing pair remain in a position that cannot be reached by the key.

AT 394 604 B

Position in which the core pin lies exactly in the cylindrical surface of the core and prevents rotation of the core. There is a situation that would arise with a classic cylinder if a tumbler spring was removed. The pair of pins falls into the bore and remains in a position in which the core pin blocks the rotation of the cylinder core. In the construction according to the invention, the state with or without a spring is achieved by an activated or non-activated magnet coil.

When the solenoid is activated with the correct key already in the key channel, the pair of pins snaps up into the key channel against the key bit. To keep the pair of pins in this position, even when the power supply to the solenoid z. B. is switched off for reasons of savings, it is expedient if a brake, in particular friction brake, is provided which engages the core or housing pin or the iron core, which after short-term excitation of the magnet coil when the key position in the key channel reaches the insertion position, at least the core pin in the holds advanced position in the core and when the con and optionally the housing pin and possibly the iron core can be reset by a serration of the key bit profile coming against the core pin. This keeps these pins in the extended position until they are moved from a prong to a locking division when the key is removed. Is provided in a particular embodiment that the magnet coil carries the friction brake for the housing pin or its extension or intermediate piece at its end facing the housing pin, which is designed as a sleeve or magnet coil with a friction-locking collar and which the housing and when the magnet coil is switched off holds the core pin in the extended position while compensating for its own weight. A braking effect can also be achieved by a permanent magnet against the iron core or a ball catch.

An embodiment is shown in the drawings. 1 shows a flat key for a locking cylinder, FIG. 2 shows a longitudinal section through half of a locking cylinder and a rosette, FIG. 3 shows a front view of the locking cylinder according to FIG. 2, FIG. 4 shows a detail from FIG. 2 with the magnet coil energized, 5 shows a detail from FIG. 2 on an enlarged scale and FIG. 6 shows a friction brake.

A flat key (1) (Fig. 1) has a key profile (2) and a toothing (3), the spring-loaded core pins (6) and housing pins when inserted into a key channel (4) of a locking cylinder (5) (Fig. 2) (7) so that their contact surfaces (8) come to rest in the cylindrical surface (9) of the cylinder core (10), so that the cylinder core (10) in the housing (11) of the locking cylinder (1) can be rotated. While in the usual mechanical locking cylinders, for example, five rows of the aforementioned pairs of core and housing pins acting as tumblers are provided, which are prestressed in bores (12) by springs (13) in the direction of the key channel (4), the one shown in FIG. 2 has Lock cylinder (5) via four tumbler rows with springs and a fifth hole in which a core pin (14) and a housing pin (15) are provided, which are not mechanically sprung but can be moved against the key channel by means of a magnetic coil (16). For this purpose, the housing pin (15) made of brass or another material that is indifferent to magnetic forces engages with an extension (17) into the interior of the magnet coil (16) that is designed as a solenoid. An iron core (18) lies in the unexcited state of the magnet coil (16) (FIGS. 2 and 5) largely outside the magnet coil and is pulled into the interior when voltage is applied to the connections (19) and thus when the latter is excited. The iron core thus lifts the housing pin (15) and the core pin (14) and pushes them in the direction of the key channel (4) (Fig. 4).

If the key (1) is now inserted into the key channel (4), the four mechanically sprung pin pairs (6, 7) of the first four tumblers are split against the forces of the mechanical springs (13), while the pin pair (14, 15) achieve division against electromagnetic forces. The lock cylinder can then be operated.

The effect on the pins (14, 15) is similar to the effect of the spring (13), however the electromagnetic spring effect can be switched on or off by energizing or de-energizing the solenoid. When the magnetic coil is switched off, the pins (14, 15) fall down (FIG. 2), the core pin (14) lying in the transition area between the core (10) and the housing (11) and blocking the actuation of the locking cylinder (5), even if the first four tumbler pairs are split.

The above-described effect of the electromechanical locking of the cylinder core (10) is used for an additional locking criterion in the key (1). In addition to the toothing (3), the key (1) has further coding, in the example a small code transmitter (20) in the key box, the signals of which are received by a receiver (21) in a lock rosette (22) and with a Target code to be compared. If the code matches - that is, if the key (1) has been identified as authorized to block - the solenoid (16) is energized via a line (23). The key then locks the cylinder like a classic mechanical locking cylinder. If a code match cannot be found in the receiver (21), the solenoid remains unexcited and the pins (14, 15) in the locked position outside the key channel. The key (1) brings the first four tumblers to division, but the fifth tumbler (pins (14, 15)) remain passively in the locked position. You are not reached by the key. The locking cylinder remains locked

In order to save electrical energy in the event of a code match and thus excitation of the magnetic coil (16), the excitation can be switched off again immediately after the electromagnetic field has built up, if a friction brake acts on the housing pin (15) or its extension (17), causing it to fall back the hoisted -3-

Claims (5)

AT 394 604 B benen housing pin (15) prevents excitation in particular only when the key (1) is fully inserted into the key channel, so that the core pin (14) soaring up magnetically and the housing pin with the correct key directly in the Division area come to rest. It can therefore be blocked. When the key is withdrawn, the end-sided prong (24) of the key toothing pushes the pair of pins back into a neutral position which does not correspond to the division position. According to FIG. 6, a sleeve (25) can be provided as the friction brake, which is fixed in place on the magnetic coil (16) and has an annular collar (26) which rests on the extension (17). The dashed arrow shows where the cuff can be installed in a fixed position. In Fig. 5 permanent magnets (27, 28) are also shown, which hold the raised iron core (18) after pulse activation and switching off the excitation in the upper position against the dead weight and the weight of the housing pin (15) and the core pin (14). Only when the key (1) is removed does the prong (24) (see dashed line in the key channel (4) in Fig. 2) press the core and housing pin down from the dividing surface and thus the iron core out of the range of action of the magnets (27, 28 ). The iron core (18) and the non-magnetic pins (17, 15, 14) thus fall into the position according to FIG. 5 and wait for the next excitation of the magnetic coil via the connections (19). The above explanations assume the usual installation position of a locking cylinder (1), as can be clearly seen in FIG. 3. PATENT CLAIMS 1. Lock cylinder with built-in electromechanical lock, which comprises an electromagnet with magnetic coil and iron core that can be controlled by an electronic comparison circuit, in a bore in the cylinder housing, the bore being extended into a cylinder core, having a tumbler with a core and housing pin, and in particular in is a series of mechanical tumblers, which can be moved from a locked position into a release position in a bore of the cylinder housing, which are continued in the cylinder core rotatably mounted in the housing, from a key channel in the cylinder core, characterized in that the bore for the Magnetic coil (16) of the electromagnet opens into the key channel (4), and a housing pin (15) in the bore directly or via an extension (17) or an intermediate piece from the iron core (18) is displaceable when the magnetic coil (16) is excited and in the Bohru On the end of the housing pin (15) facing away from the iron core (18), a core pin (14) which can be displaced from the locking pin (15) into the key channel (4) is mounted from the housing pin (15). 2. Lock cylinder according to claim 1, characterized in that a on the core (14) or housing pin (15) or the iron core (18) engaging brake, in particular friction brake is provided, which after short-term excitation of the magnet coil (16) when the Insert position by the key (1) in the key channel (4) holds at least the core pin (14) in the advanced position in the core (10) and that the core (14) and optionally the housing pin (15) and possibly the iron core (18) can be reset by a prong (24) of the key bit profile that comes into contact with the core pin (15). 3. Lock cylinder according to claim 2, characterized in that the magnetic coil (16) carries the friction brake for the housing pin (15) or its extension (17) or intermediate piece on its end facing the housing pin (15), which acts as a sleeve (25 ) the magnetic coil (16) is formed with a friction-locking collar (26) and which holds the housing (15) and the core pin (14) in the extended position while compensating for its own weight when the magnetic coil (16) is switched off. 4. Lock cylinder according to claim 2, characterized in that the magnet coil (16) preferably in the housing pin (15) facing half as a brake at least one permanent magnet (27, 28) for holding the iron core (18) in the magnet coil (16 ) is assigned to the attracted position 5. Lock cylinder according to claim 2, characterized in that it comprises a spring-loaded ball as a friction brake, which rests on one of the pins (14, 15) or the iron core (18). For this purpose 1 sheet of drawing