DE19855207C1 - Contactless switch for activating identification system in access control system, has coil in which voltage is induced by changing magnetic flux when code medium approaches/leaves switch to activate transmitter - Google Patents

Abstract

A permanent magnet (1) with an associated coil (2) near the transmitter (6) is magnetized so its field lines pass out of the switch. Non ferromagnetic code media each contain a transponder with an antenna and a ferromagnetic part. A voltage induced in the coil by changing magnetic flux when the code medium approaches or leaves the switch activates the transmitter, which is deactivated either when code information is no longer required or the code medium leaves the transmitter's field.

Description

The invention relates to a contactless switch for activation of a contactless identification system as it is in the preamble of Claim 1 is described.

Non-contact identification systems with code carriers on transponder Basis are known and in practice z. B. in various network-operated access control systems implemented. In these cases, the transmitter is always activated. He therefore decides permanently via an electromagnetic field, which transmits one to the transponder Transmitter approximate code carrier supplies operating energy and through the feedback of Transponder is modulated and thereby code information from the transponder em begins. The permanent electricity consumption caused by the permanently activated transmitter 100 mA can be tolerated in a mains-operated system. However, this power consumption becomes problematic when the system is battery operated is what particularly with self-sufficient operated electronic locks and electronic Security fittings is the case. In such cases, the battery would only be unacceptable short service life. This also applies to a limited extent to systems that do are mains operated, but are supplied with battery for a longer period in the event of a mains failure must be: B. in intrusion alarm systems that are subject to VdS regulations. There the battery would then have to be dimensioned inappropriately large.

A possible solution is presented in DE 44 35 894 A1. A is described Method for securing a motor vehicle and a security system for through conduct of the procedure. The security system has an electronic locking system consisting of a transponder, 2 induction coils, a control unit and an electronic immobilizer and a mechanical locking system. The transponder that is supplied with energy via an induction coil if required, sends one Identification code, which is inductive to the induction coil and from there to the control unit is transmitted. The control unit decodes this identification code, checks it  the access authorization and unlocks the mechanical if the result is positive Locking system or the electronic immobilizer. The two induction coils are only switched on when required. Switching on the one induction coil is done by a door handle switch that automatically when the door handle is operated is also operated. The other induction coil is activated by pressing the ignition switch switched on. The induction coils are therefore normally at rest and are "woken up" only when required by a special operation. Since only during the short-term activation phase when there is a need for electricity, this solution is for battery operation well suited. The disadvantage of this solution, however, is that the activation only can be triggered by a previous special operation. Would be beneficial it is when the mere approach of the transponder triggers the activation would.

Two possible solutions to problems are in the battery-operated electronic security Security fittings from HEWI (Heinrich Wilke GmbH in 34454 Arolsen) was realized. There the transmitter is only when needed activated. In the version with "active identifiers", activation takes place with the help the code carrier used in the system. These not only have a transponder, but also via a battery-operated "wake-up transmitter", which when approached of the code carrier to the lock activated the lock transmitter, so that the informa tion exchange between transponder and lock transmitter can take place. This solution is energy saving and therefore suitable for battery operation. The disadvantage, however, is that the code carriers require a relatively large design and are therefore quite bulky. They also lose their alarm function as soon as the voltage of the code carrier Battery becomes too low.

With the HEWI version with "passive identifiers" the transmitter of the fitting is also used Energy-saving activated only when required and is therefore suitable for battery operation. The In this version, activation takes place by turning the outer rotary knob of the Fitting. This knob is used to unlock and open or at the same time Locking the lock needed. This solution has the advantage that the code carrier compact design and can be encapsulated watertight, since it only has one transponder  with antenna contains. The disadvantage of this solution, however, is the cumbersome nature Operation: the lock or its transmitter must first be turned by turning the rotary knob be activated before code carriers and lock transmitters exchange information can start.

The object of the invention is a contact-free switch to create the mere approach of the code carrier to the fixed transmitter This is automatically activated without any additional activity and still a hand code, robust and waterproof encapsulable code carrier without its own power supply enables.

The object is advantageously achieved by the in the characterizing part of the patent claims 1 listed measures.

A further advantageous embodiment of the invention exists according to claim 2 in that the induced voltage, which triggers the signal to activate the transmitter is amplified.

The measures described in claim 3, the permanent magnet in The simplest possible design. However, this requires an operation precise approach of the code carrier to the magnet.

The measures described in claim 4 ensure that the approximation of the code carrier on the magnet must be carried out less precisely.

The measures described in claim 5 ensures that at Approach of the code carrier to the magnet also a certain lateral offset without Loss of function can be tolerated.  

The measures described in claim 6 ensure that the requirements the precision of the approximation can be further reduced - but bought by a larger and more complicated design of the magnet.

Some embodiments of the invention are described below with reference to the Described drawings. Show it:

Fig. 1: Execution of the permanent magnet as a bar magnet with a surrounding coil

Fig. 2: Code carrier in key form with transponder and ferromagnetic tongue

Fig. 3: switches and transmitters as a circuit diagram

Fig. 4: Execution of the permanent magnet as a U-magnet with coil

Fig. 5: Execution of the permanent magnet as an E-magnet with a coil

Fig. 6: Execution of the permanent magnet as a pot magnet with a coil.

In Fig. 1, the permanent magnet is shown as a bar magnet 1 a with a surrounding coil 2 a. The magnet is fixed in the vicinity of the transmitter 6 . The design shown as a bar magnet is particularly simple and space-saving. Since the magnetic field lines run on both sides of the bar magnet 1 a, only those field lines can be effective which are on the side to which the code carrier 4 is approximated. This has the disadvantage that the ferromagnetic part 3 must be brought very close to the bar magnet 1 a and that the approach of the ferromagnetic part 3 only induces the desired voltage in the coil 2 a when the axis of the part 3 is largely parallel to the axis the bar magnet 1 a is approximated.

In FIG. 2, a code carrier 4 is shown in the form of keys with attached ferromagnetic part 3. The head of the code carrier 4 consists of non-ferromagnetic material - preferably plastic and encapsulates a transponder 7 with an antenna in an encapsulated, watertight manner, in the chip of which the code information of the code carrier 4 is stored. Fixed to the head of the code carrier 4 is the ferromagnetic table part 3 , which extends in the form of a key tongue. Since the code carrier 4 does not need its own battery, it can be designed in a handy, compact, robust and key-like shape, so that it can be carried by the user without problems on the key ring.

In Fig. 3 switches and transmitters 6 are shown in the circuit diagram. If a code carrier approximately 4 to the permanent magnet 1 and its associated coil 2 causes associated with the code carrier 4 ferromagnetic member 3 a United enlargement of the magnetic flux through the coil 2, which is induced by the flux change in the coil 2 a small voltage. If the code carrier 4 is removed from the magnet 1 , the magnetic flux through the coil 2 is reduced and a small voltage is induced in the coil 2 in the opposite direction. The desired voltage (approach or distance) is amplified by an operational amplifier 5 to such an extent that it is sufficient to activate the transmitter 6 . The activated transmitter 6 builds up an electromagnetic field, which supplies the transponder 7 with operating energy and is modulated by the reaction of the transponder 7 and thereby receives code information from the transponder, which are compared in the evaluation electronics with the code information stored there as valid. The transmitter 6 is deactivated as soon as the code information of the transponder 7 is no longer required. The deactivation of the transmitter 6 occurs at the latest when the code carrier 4 leaves the field of the transmitter 6 .

In Fig. 4 the permanent magnet is shown as a two-leg U-magnet 1 b with assigned coil 2 b. In this design, the magnetic field lines are guided through the two legs of the magnet in the direction from which the code carrier 4 is approached. Compared to the design as a bar magnet 1 a, a greater effect is achieved here, so that the desired voltage is induced even at a greater distance. But even with this design, care must be taken that the ferromagnetic table part 3 is approximated as axially parallel as possible to the connecting line of the two magnetic legs.

In Fig. 5 the permanent magnet is shown as a three-leg E-magnet 1 c with an associated coil 2 b. Also with this design, care must be taken that the ferromagnetic table part 3 is approximated as axially parallel as possible to the connecting line of the magnetic legs. Compared to the design as a U-magnet 1 b, however, a greater lateral offset when approaching the part 3 is permitted with the same effect, so that less precision is required when handling the code carrier 4 .

In Fig. 6 the permanent magnet is shown as a pot magnet 1 d with an associated coil 2 b. This design is more complicated and voluminous than the others. However, it has the advantage that the ferromagnetic part 3 can be approximated in any direction of rotation with the same effect and that even greater lateral misalignment can be tolerated when approaching. This design therefore enables the most convenient handling of the code carrier 4 .

Claims (6)

1. Contact-free switch for activating a battery-operated or battery-operated, network-operated, contactless identification system, which is preferably used in access control systems and which has a fixed transmitter with antenna, evaluation electronics and mobile code carriers with transponder and antenna, the transmitter being activated in an electromagnetic state Field builds up, which supplies the transponder of a code carrier approximated to the transmitter with operating energy and is modulated by reaction of the transponder and thereby receives code information from the transponder, which is compared in the evaluation electronics with the code information stored there as valid, characterized in that a permanent magnet 1 with an associated coil 2 is arranged in the vicinity of a transmitter 6 that the permanent magnet 1 is magnetized so that the magnetic field lines penetrate to the outside n that code carrier 4 consist of a non-ferromagnetic material and each carry a transponder 7 with antenna, that each code carrier 4 additionally carries a ferromagnetic part 3 , that when a code carrier 4 approaches with its ferromagnetic part 3 to the permanent magnet 1 or in the subsequent Removal of the changed magnetic flux caused by the ferromagnetic part 3 through the coil 2 induces a voltage which provides a signal for activating the transmitter 6 that the transmitter 6 is modulated in the activated state by reaction of the transponder 7 and thereby receives code information and that the transmitter 6 is either deactivated when the code information is no longer required or at the latest when the code carrier 4 leaves the field of the transmitter 6 . 2. Arrangement according to claim 1, characterized in that on coil 2, an operational amplifier 5 is coupled, which amplifies the voltage induced in the coil 2. 3. Arrangement according to claim 1 or 2, characterized in that the permanent magnet is designed as a bar magnet 1 a with the associated coil 2 a. 4. Arrangement according to claim 1 or 2, characterized in that the permanent magnet is designed as a U-magnet 1 b with the associated coil 2 b. 5. Arrangement according to claim 1 or 2, characterized in that the permanent magnet is designed as an e-magnet 1 c with the associated coil 2 b. 6. Arrangement according to claim 1 or 2, characterized in that the permanent magnet is designed as a pot magnet 1 d with the associated coil 2 b.