EP0410024B1 - Electronic locking system - Google Patents

Description

The invention relates to an electronic locking system with means for forming diverse hierarchies of locking authorization, the locking system having a lock with a mechanical locking device in particular and an electronic control device in particular and further consisting of an electronic key that cooperates with the control device in detail Control device and electronic key are each designed to carry out the same sequence of programmable or selectable operations that form an access code on the basis of operands which can be input when a locking operation is initiated by coupling the key to the assigned lock. The key and lock are designed to have at least one assignment area for storing an access code. One assignment area of the key has the function of a conventional key and another assignment area another conventional key or optionally a central locking function in a hierarchy level. Further assignment areas of a key can correspond to further conventional keys on a key ring or further hierarchy levels.

Various types of electronic locking systems are known. They should increase security and allow greater flexibility than conventional locking systems. In a known locking system, partial solutions provided can be read on the generic term of claim 1 (DE-A-3 514 660). In the known locking system, also insofar as it relates to the generic term of claim 1, An electronic key lock system is proposed, in which each key can be assigned a freely selectable and, if necessary, also easily changed selection from the locks of the system. The known system also works with a basic code that serves to differentiate the individual systems. The known system works partly in the manner of a rotation code. In all its variants, it enables diverse and changeable hierarchies.

The invention has for its object to develop a particularly simple and universally applicable electronic locking system according to the generic term so that it corresponds to high security requirements, especially with regard to reprogramming.

According to the invention, the solution to the described problem consists in an electronic locking system according to claim 1. Here, a lock or key carrier for a security code, for example a card, the lock or the key can be additionally assigned to a programming device by means of appropriate precautions, the security code of the wearer is part of the basis for changing the access code of the locking system. The locking operation itself is carried out by coupling the key to the associated lock, for example by placing the key on the lock at a designated point. An access code is understood here as a work code that embodies the authorization to lock. The precautions according to the invention ensure that despite a high degree of flexibility in the assignment of keys to locks and despite being easy to program, it is ensured that unauthorized reprogramming is not possible, even if a relevant service device is available.

The access code is stored in at least one assignment area per key and in one assignment area per lock. The access code cannot be changed without special carriers for a security code assigned to the lock or key. For this purpose, the security code is to be inserted, for example, into a programming device designed as a service device on a card and the same security code is also stored at the lock.

An assignment area of the key fulfills the function of a conventional key and another assignment area can correspond to another conventional key or alternatively fulfill a central locking function in a hierarchy level. Further assignment areas of a key can correspond to further conventional keys, for example on a key ring or further hierarchy levels.

With the electronic locking system according to the invention, all hierarchies of locking systems can be realized. This avoids synchronization between the lock and key, for example in the form of a rotation code, which achieves significantly higher functional reliability and higher system security. So there are no synchronization commands that could be tapped. The locking system according to the invention cannot be fully recognized on the basis of transmitted and listenable information and can therefore not be cracked with the known means. With a high qualitative coding capability and with a possible configuration with a quantitatively large coding possibility, the security is further increased. If random numbers are selected for the operands that can be entered, the security is further increased. It also ensures that strangers cannot reprogram the locking system and could gain access in this way.

The electronic locking system is particularly convenient because the locks can be easily reprogrammed by the authorized person without the need for a bus system. A conventional keychain can be replaced by a single key with multiple assignment areas. Several conventional keyrings can also be replaced by a key with several assignment areas. The key does not apply because only the memory area in the key is expanded. In addition, you avoid a battery in the key.

The assignment areas can be easily programmed and also deleted using a programming device designed as a service device. Such an access code can be stored in a non-volatile, electrically programmable memory, according to today's technical development in an EEPROM. In terms of hardware, the locks can be equipped with plug-in modules, each of which carries a security code and can hold an access code. In the basic version, they can initially be provided with an access code. The security code is advantageously only readable, according to the current state of development, for example in ROM masks. Such a security code is advantageously arranged on a carrier which, in addition to an access code, can also contain an identifier for an assignment area.

The hierarchical organizations can be prepared by the manufacturer by assigning corresponding or different security codes under the same assignment areas and by correspondingly providing locks with the assigned security code. This can be done on carriers that are inserted or attached to the lock in a modular manner. It is advantageous if the lock supports for carriers with security code, access code and characteristic of the assignment area.

According to a further development, a device for delivering an identifier for the assignment area is provided at the lock, which, when coupled with the key, leads to the search for the corresponding assignment area. This avoids a repeated search in the lock, which would have to be triggered by the key until the assignment area is found in the lock, which matches the corresponding assignment area of the key.

For electromagnetic coupling between the lock and the key, and also between the programming device and the key or the programming device and the lock, a flat coil can be attached in a region designated on the door, which is used for energy transmission and data exchange to the key. The data transmission can advantageously take place in "frequency shift key", FSK, or in frequency modulation, FM, and can be operated in handshake mode. This eliminates the need for a battery in the key, since in the meantime alternating acknowledgment charging can electromagnetically transmit energy to a memory in the key, which ensures that the computer is supplied in the key.

It is also possible to provide means for programming the programmable operations of the access code which are connected to a central bus. Such a design is advantageous for hotel operations and saves the operators from having to walk to the locks. In all organizational systems, a connection to a bus system is possible, which connects the locks to a computer for central control.

It is convenient if means in the castle to detect the coupling are available with a key, which initiate the operating state of the lock and which put the lock into an energy-saving idle state without coupling. For this, the damping, which is created by coupling coils, can be measured. The automatic detection by the lock, whether a key or a programming device is in place, ensures an energy-saving idle state.

The means for recognizing the coupling can advantageously work with pulses, in particular needle pulses, the damping of which serves as a criterion for a present coupling.

Securing keys, which are handed over to children, can be achieved according to a further development in that the key is attached to a tether that is to be attached to a child's wrist if the access code is designed in such a way that when the tether is opened for the key is destroyed. On the other hand, an intended opening point can be secured against impairment of the code by a supplementary device, to which contact can be made by the tether, so as not to destroy the access code when the tether is authorized to be opened. Such a key can be called a self-deleting key.

It facilitates a clear organization when the carrier for the security code, such as cards, with an identifier, z. B. number, a relevant access area are provided.

In order to achieve a reliable locking function in practice, also taking into account faults, it is advantageous to code more than one allocation area for the lock and the assigned key in order to match the Increase redundancy. For this purpose, more than one locking device with control device can also be assigned to a locking device. The redundancy can be increased even further by both measures. If a first assignment area does not respond due to transmission errors, the closing process is ensured by the second transmission area. If you use two identical locks that work with a common locking device, the functional reliability is understandably further increased. The redundancy of the lock components and the separate coupling coils is then used.

• In FIG 1 ist das Zusammenspiel der Komponenten des Schließsystems aus Schloß, Schlüssel und Servicegerät, einem Programmiergerät und Steckkarten mit Sicherungscode, veranschaulicht.
• In FIG 2 ist das Blockschaltbild eines Ausführungsbeispiels für den Schlüssel wiedergegeben.
• In FIG 3 ist das Blockschaltbild eines Ausführungsbeispiels für das Schloß dargestellt.
• In FIG 4 ist ein Ausführungsbeispiel für die Signalfolge bei der Kopplung eines Schlüssels mit einem Schloß wiedergegeben.
• In FIG 5 ist ein Ausführungsbeispiel für einen Organisationsplan des Schließsystems für ein Einfamilienhaus dargestellt.
• In FIG 6 ist ein Ausführungsbeispiel für einen Organisationsplan des Schließsystems für ein Miethaus veranschaulicht.
• In FIG 7 ist ein Ausführungsbeispiel für einen Organisationsplan des Schließsystems für ein Hotel dargestellt.
• In FIG 8 ist ein Ausführungsbeispiel für ein Funktions-Struktogramm des Schlüssels wiedergegeben.
• In FIG 9 ist ein Ausführungsbeispiel für ein Funktions-Struktogramm des Schlosses dargestellt.

The invention will now be explained in more detail with reference to exemplary embodiments shown roughly schematically in the drawing:

• In Figure 1, the interaction of the components of the locking system from lock, key and service device, a programming device and plug-in cards with security code is illustrated.
• 2 shows the block diagram of an exemplary embodiment for the key.
• 3 shows the block diagram of an exemplary embodiment for the lock.
• 4 shows an exemplary embodiment of the signal sequence when coupling a key to a lock.
• 5 shows an exemplary embodiment of an organizational plan of the locking system for a single-family house.
• 6 shows an exemplary embodiment of an organizational plan of the locking system for a rental house.
• 7 shows an exemplary embodiment of an organizational plan of the locking system for a hotel.
• FIG. 8 shows an exemplary embodiment of a functional structure diagram of the key.
• FIG. 9 shows an exemplary embodiment of a functional structure diagram of the lock.

According to FIG. 1, the control device of the lock carries out operations on the basis of an access code if the assigned key is coupled at the intended location. The core part of an access code is stored in a field. According to one exemplary embodiment, an access code can consist in each case of a core part 1 or 1 ', etc. and consist of operands which are formed by a random generator in the control device of the lock. The core part can be a memory field in which computing algorithms are stored.

On the basis of the damping of a test signal, the control device of the lock is brought into the activated state, the energy store of the key is charged by the control device of the lock by inductive coupling via the coupling coils and a sequence of programmable or selectable operations on the basis of determined or specified operands and on the basis of the core part 1 of the access code in the assignment area 4 of the lock on the one hand and of the access code in the assignment area 5 of the key.

The energy store of the key can be charged at intervals between the arithmetic operations. The computational algorithms in the core part, for the operations and for the sequence of operations, can be stored in a non-volatile, electrically programmable memory, as of today in an EEPROM. A number of arithmetic operations can be varied in the result by selecting specific operands. When the arithmetic operation is initiated by a random generator, these operands can each be new in the control device of the lock with the assignment area 4 formed and communicated to the assignment area 5 of the key. The arithmetic operations, the arithmetic algorithms, in the assignment area 4 in the control device of the lock and in the assignment area 5 in the control device of the key then run with these selected operands as the access code. The result determined for the key is fed to the lock via the communication line 6 and compared with the result for the lock. If there is a match, the lock or its locking device is actuated and opened by means of its energy store. This can be understood to mean that the door can then be opened by hand or that a bolt is automatically withdrawn. An access code can also be formed by making a selection from several computing algorithms using operands. These operands can again be generated in a random generator.

Corresponding to the access code 1, an identifier, a word or a number is also stored in the assignment area 5 of the key as the area number with the reference symbol 2. The corresponding area number 2 is also stored in the assignment area 4 of the lock. When the key is coupled to the lock, the area number 2 of the assignment area 4 is fed via the control line 7 to the field with the area numbers and there to the corresponding area number. This avoids running through all access codes in the key. Otherwise, if another access code is stored in the key in the first place during the search, the operation with the computing algorithm will deliver a different result than for the assignment area 4 of the lock. If the assigned access code is finally found in the key, the results match and the lock is opened.

It is therefore advantageous if a device at the lock for issuing an identifier for the assigned core part of the access code is provided in such a way that, when coupled with the key, it immediately leads to the search for the corresponding core part, so that the search over all fields with core parts is avoided. This can significantly shorten the closing process.

When the lock is open, on the other hand, coupling with the key can lead to the operations being carried out again, whereupon the lock is transferred in its second state, the locking state.

A security code 3 is also stored in the assignment area 4 of the control device of the lock. The security code can be stored in a read-out memory, a ROM. It ensures that a recoding of the lock is only possible with a programming device 8 designed as a service device if the security code 3, with its ROM mask, the programming device corresponds with the security code 3, or the ROM mask, of the lock. The programming device can be inserted for programming, carrier 9 for information, for example when inserted as plug-in cards. The programming device 8 has a generator 10 for operations, for example computing algorithms. An area number 2 and a security code 3 are stored on the carrier 9, and a field is provided for the core part 1 of an access code. In the exemplary embodiment, the core part is a computing algorithm or a majority of computing algorithms.

With the carrier 9 inserted, the programming device 8 can reprogram the assignment area 4 in the control device of the lock with its core part 1 of the access code or else the access code. For this purpose, a calculation algorithm can be generated by the generator 10 of the programming device 8, which is based on the Carrier 9 of the core part 1 of the access code is stored and transferred to the assignment area 4 of the lock as core part 1 of the access code. The security code 3 of the carrier cannot be changed. Via a control line 7, the programming device 8 with the inserted carrier 9 in the assignment area 4 of the lock can find the assigned area number 2 and via the communication line 6 a comparison can be made with regard to the security code 3 between the carrier 9 and the assignment area 4 of the lock. If the security code matches, the core part of the access code 1 can be reprogrammed in the assignment area 4 of the lock via a working line 11. Understandably, the lines 6, 7 and 11 can be understood as paths of a communication route. This can in particular be designed as an inductive transition path.

Correspondingly, the corresponding area number 2 can be found in the assignment area 5 of the key by the programming device 8 when the carrier 9 is inserted via a control line 7 and the core part of the access code 1 can be reprogrammed via a work line 11. The area number can be indicated by a pointer 12. The pointer can point to the associated field for the core part of the access code 1 by specifying the area number.

Corresponding security codes between the assignment area 4 of the lock and the corresponding carrier 9 for the programming device must be ensured by the lock manufacturer. The security code, stored for example as a ROM mask, should be appropriately high-coded to eliminate the risk of manipulation. The assignment area 5 of the key can contain a variety of assignment areas, each of which can hold the area number 2 and a corresponding core part 1 of an access code.

These individual assignment areas can be freely programmed and deleted. They can be filed in an arbitrary order.

The lock can have several assignment areas 4, in the exemplary embodiment 4 and 4 ', in the manner of modules. The assignment areas can be plugged in or permanently installed in the lock by the manufacturer. Several hierarchy levels can be ensured by several assignment areas 4 and 4 'of the lock.

For reasons of comfort, the carrier 9 can be displayed in a field 12 for visual indication of the area number 2.

It may be necessary to re-program the lock and key if a key has been lost or if attempts have been made to tamper with the lock. For security reasons, recoding can also take place from time to time.

As protection against manipulation of the locks, it can be provided that, after a predetermined number of unsuccessful attempts to operate the lock, it is locked against further actuation attempts for a certain time, for example for 15 minutes. On the inside of the door, you can also provide a display that indicates tampering.

The programming device is designed as a universal device that can be manufactured in large quantities. The security code, which is produced as a ROM mask, can be generated by the manufacturer using random generators and can be stored on the carrier 9 for the first time. Using this carrier, the number of modules required for the lock can then be assigned to an assignment area be programmed and made available by hardware.

The computation algorithm for the access code can be accommodated in two parts, an immutable part stored in a ROM and a variable part which is stored in a non-volatile, electrically programmable memory, for example an EEPROM. Here, the amount of all arithmetic operations can be stored in the ROM, whereas the amount of the specific operands available for selection or the specific operations can be stored in the EEPROM.

A key can be organized according to FIG. 2, which shows a block diagram of the key according to one exemplary embodiment. Signals are read into the key and transmitted from the key via a coupling coil 13. In addition to this information transfer, energy is transmitted via the coupling coil 13 into the energy store 14 of the key. An electronic switch 15 in the line to the energy store 14 is open during transmission. The reading into the main memory 16 takes place via an amplifier 18 controlled by the main memory 16, which is followed by a demodulator 17. The working memory 16 also accommodates the assignment area 4 or a variety of assignment areas 4, 4 'etc., each consisting of area number 2, for example B3 and B7, between which a deleted area is arranged in the example. The working memory 16 further takes the respectively assigned core part 1, 1 ', 1' '. . . an access code.

The reading out of the working memory 16 takes place via a modulator 19 which is followed by an amplifier 20 which is controlled from the working memory 16. A trigger threshold 21 fulfills the "power on reset" function. The Elements Demodulator, modulator and power-on-reset can be contained in a microcomputer or created by software.

A slide switch 22 can expand its functional area on the key and, depending on the position, can implement a figuratively speaking further set of keys of conventional keys.

A lock can be organized according to FIG 3, which shows a block diagram of the lock according to one embodiment. Via a coupling coil 13, signals are read into the lock or more precisely into the working memory of the control device of the lock and sent out from the lock. The reading into the main memory takes place via an amplifier 18, which is controlled by a processor 16 with main memory and which is followed by a demodulator 17. The signal is fed from the connecting line between amplifier 18 and demodulator 17 to an attenuation measuring element 23. The attenuation measuring element 23 determines when an attenuation of the pulses of the pulse stage 24 emitted via the coupling coil 13 occurs, corresponding to an applied key. The read-out from the main memory takes place via a modulator 19, which is followed by an amplifier 20, which is controlled by a processor 16 with main memory. A pulse stage 24 is connected to the input of the amplifier 20. When the damping measuring element 23 has determined a corresponding damping, the operating state of the lock is initiated and the previously energy-saving idle state is left. The processor 16 with the working memory of the lock is expanded by carriers for allocation areas 4 and 4 ', each of which contains a security code 3 or 3', the core part 1 or 1 'of an access code and a characteristic z. B. have an area number 2 or 2 '. In order to be able to infect such carriers at the castle, this has a plug-in rail 25 or a plug-in base with support receptacles 26. The plug-in rail 25 is designed to be electrically conductive and is connected to the processor 16. The operating program is stored in the permanent memory of the processor 16, for example in a ROM 27. Unchangeable parts of the computing algorithms can also be stored in the ROM 27.

4 shows the signal sequence transmitted and received by the lock for the coupling of a key to a lock. The lock transmits needle pulses 28, which are generated by the pulse stage 24 according to FIG. 3, via the coupling coil 13 at regular time intervals. Time is plotted on the abscissa and the envelope of the signals is illustrated on the ordinate. When the needle impulses experience damping typical for the application of a key, the control device of the lock is brought into the activated state and a charging phase 29 follows, which initially charges the energy store of the key. This is followed by a lock telegram 31 starting with a start bit 30. The lock telegram is composed of a term for "lock" and operands for the access code. After a signal pause 32, the lock control unit switches to reception and the code 33 "key" is received. After a signal pause 32, the area number of the lock is transmitted in a transmission signal 34. This is followed by an intermediate charging phase 35, during which and the subsequent signal pause 32 there is time to perform the arithmetic operations according to the access code. The signal 36 for the calculation result of the key is received at intervals 37 for bit groups with intermediate intermediate charging phases 35. If the result of the algorithm matches the key and lock access code, the lock controller sends an unlock pulse 38 to its unlocking device. Meanwhile the final word 42 can be sent to the key. After a work break 39, needle pulses 28 are again transmitted.

In the exemplary embodiment according to FIG. 5 for an organizational plan of the locking system for a single-family house, the assignment areas of the keys for V = father, M = mother, K = child, K1 = small child and R = room attendant are illustrated. An order number for an access code is entered in each of the compartments in the drawing columns. The access code one, two, three and four for the corresponding four locks is stored in the assignment area 5 of the key at "V". "00" illustrates free or deleted areas for storing an access code. The key "M" has the access codes one to four only in a different order to illustrate that the order of the spatial storage is irrelevant. The key "M" with the assignment area 5 thus also gives access to the four locks mentioned. The access codes one, two and four are stored on the key "K" in its assignment area 5. So there is no storage of access code three, for example for a first garage. Only the access code one and special software are stored in a memory location 40 on the key “K1” in its assignment area 5. This software ensures that the key for toddlers is destroyed if the key strap is opened without authorization. The key "R" is again a normal key, in the assignment area 5 of which only the access code one is stored.

The access code one is stored, for example, in the lock of the garden door, the front gate and a second entrance door. Access code two is in the lock of the basement, access code three is in the lock of a first garage and in the lock of a study and the access code four in the lock of a second garage.

The locking system described has the function of a level authorization system. So there is no main key hierarchy. Each lock is equipped with a single assignment area. The security code can be the same for all locks. You then work with a lock type. It is advisable to work with several lock types, i.e. with similar locks and a specific security code for each lock type:

The exemplary embodiment described above can then be understood in such a way that the numbers one to four in the columns illustrate assignment areas, each with its own security code for each identical number. You then work with four types of locks, with lock type one being used for the garden door, front gate and entrance, lock type two for the basement, lock type three for the first garage and for the study and lock type four for the second garage. The user, for example the father, then receives four plug-in cards in order to be able to reprogram the four lock types, so that at least one access code can be assigned to each assignment area one to four. The plug-in cards can advantageously be provided with an identifier, an area number 2, each with a number one to four. Each memory location for an access code corresponds to a conventional key, so that a column, V or M or K or K1 or R corresponds to a set of keys with keys that can be made up and made out. The keys that can be made out refer to the free memory locations.

6 for an organizational plan of the locking system for a rental house, the columns again correspond to individual keys in the locking system. Each of the tenants 1.1, 1.2 and the following and each of the tenants 2.1, 2.2 and the following receives a key of the locking system.

At least assignment areas 5 and 5 'are provided on the keys. Each assignment area 5, 5 'of the key corresponds to an assignment area 4, 4' of the lock, each with its own security code for the assignment area 4 and its own security code for the assignment area 4 '. The numbers in the compartments of the columns, the numbers one to two can be understood as the order numbers of the fields for the numbers of the assignment areas. Each of the tenants provides an assignment area with at least one access code. With a correspondingly high coding possibility, the assignment areas are provided with matching order numbers, i.e. area numbers, with different access codes. The caretaker A has a key with the assignment areas one to three and the caretaker B with the assignment areas one, two and four. Using the assignment area one, the caretakers can lock their own apartments or offices. The caretakers have access to the tenants' apartments via the assignment areas three and four if the lock is provided with the corresponding assignment area.

A cleaning company has a key with assignment area two. The locks can have the order number "area two" for gate, garden and underground garage in the assignment area 4. The apartments 1.1, 1.2 and following can have assignment areas one and three and the apartments 2.1, 2.2 and following locks with the assignment areas one and four.

In the exemplary embodiment, there is a plug-in card distribution matrix for the rental house 41, so that all tenants and caretakers receive a card with the security code for "area one". The caretaker A also receives the security code for the assignment areas two and three and the caretaker B in addition to the "area one" the security code for the "area four".

The exemplary embodiment according to FIG. 6 shows a simple master key hierarchy with up to two assignment areas in the locks. In terms of hardware, the locks each have two security codes thanks to a plug-in system or secure software. For tenants, the locks for the apartment door are coded in "area one" and in "area two" for the gate, garden and underground car park. For example, due to the individual codes with an access code to the apartments, the caretakers have no access via assignment area one. You also cannot transcode. However, the caretaker A can, in addition to his assignment area one, recode locks with the "areas two and three" for his own apartment or for his office and the caretaker B locks with the "area four".

Each tenant in the exemplary embodiment according to FIG. 6 can have one or more keys. The unused areas in the key can be used to form another authorization subsystem. So it is conceivable to set up the organization of a flat authorization system according to the example for a family home according to FIG. 5 for each apartment. The order of the "areas" or the assignment areas in the keys can be arbitrary in practice, as can be seen from the exemplary embodiment according to FIG. 5 for the single-family house. If the locks have several assignment areas, a correspondingly multiple hierarchical authorization organization can be set up, as described by the hierarchy of rankings Master key systems of conventional locking systems is known.

In the exemplary embodiment for an organizational plan of the locking system according to FIG. 7 for a hotel, the assignment areas for guests 1.1, 1.2,. . . as well as 2.1, 2.2,. . . illustrated in columns. For example, guests 1.2 and 2.1 receive keys with assignment ranges one to three. Guests 1.1 and 2.2 have keys with programmed allocation ranges one to four. The assignment area one refers to the room door or the door of the apartment, the assignment area two to the hotel entrance, the assignment area three to the garage and the assignment area four to the sauna.

Area four can be organized as an area for various access options, so that the guest can be given permission to access certain rooms, such as the sauna, if desired. This assignment area can be programmed if the key is given to the guest.

Management, staff A and B and administration, for example, receive keys, as illustrated. Group A personnel are assigned to assignment areas one, two and five, group B personnel are assigned to assignment areas one, two and six, the director is assigned to assignment areas one to six and administration is assigned to one and three. The locks are provided with modules for the following assignment areas: rooms 1.1 and following with assignment areas one and five, rooms 2.1, 2.2 and the following with assignment areas one and six. The lock on the front door of the hotel is assigned to assignment area two, that of the garage with assignment area three and that of the sauna with assignment area four.

The reproduced distribution matrix 41 can be provided as an example. The security code on a carrier, for example a plug-in card, is then given the following scope: the directorate for assignment areas one to four, the administration for assignment areas one, five and six and the staff of both groups A and B for assignment area one. The assignment areas are shown abbreviated in the drawing with "B".

The second assignment area on the room keys, the assignment area five or the reproduced assignment area six enable a main group master key hierarchy. Keys with the corresponding assignment area five or six therefore allow access to the doors with the corresponding locks regardless of the respective programming state of the assignment area one.

The keys of the guests, whose hospitality has ended, can, for example, be placed on a key board, which is designed as a programming device or service device. The assignment areas with the access codes can thus be deleted centrally and reprogrammed when they are allocated or in stock, that is to say they can be provided with a corresponding access code.

FIGS. 8 and 9 illustrate a functional structure diagram of the key and the lock.

Claims (10)

1. Electronic closure system, which has means for forming diverse closure authority hierarchies,

   - in which the closure system has a lock ("locks") having an interlocking device which is, in particular, mechanical and a control system which is, in particular, electronic and furthermore comprises an electronic key ("keys") which interacts with the control system,

   - in which control system and electronic key are in each case designed to carry out the same sequence of programmable or selectable operations which form an access code (1) on the basis of operands which can be entered on initiating a closure actuation by coupling the key with the associated lock,

   - in which key and lock have at least one allocation area (4, 4' ...; 5, 5'...) for storing an access code,

   - in which one allocation area (5) of the key is given the function of a conventional key and another allocation area corresponds to another conventional key or optionally to a central locking function of a hierarchy level, and further allocation areas of a key correspond to further conventional keys on a key ring or further hierarchy levels, characterized in that, in addition to a programming device (8), a carrier (9), which is specific to each block or key, for a security code (3), for example a card, can be allocated to the lock ("locks") or the key ("keys") as a result of suitable precautionary measures, the security code (3) of the carrier (9) being part of the basis for changing the access code (1).
2. Electronic closure system according to Claim 1, characterized in that the lock ("locks") has carrier receptacles (26) for carriers with a security code (3), an access code (1) and a characteristic feature (2) of the allocation area (4, 4', ...).
3. Electronic closure system according to Claim 1, characterized in that a device for emitting an identification for the allocation area is provided on the lock ("locks"), which device, on coupling with the key ("keys"), leads to the location of the corresponding allocation area (4, 4', ...) in the key.
4. Electronic closure system according to Claim 1, characterized by devices which transmit the operating energy and data inductively to a working memory in the key ("keys").
5. Electronic closure system according to Claim 1, characterized in that devices (8) which are connected to a central bus are provided for the programmable operations for the purpose of programming them.
6. Electronic closure system according to Claim 1, characterized in that means are provided in the lock ("locks") for detecting the coupling with a key ("keys"), which means induce the operating state of the lock and which, without coupling, set the lock to an energy-saving quiescent state.
7. Electronic closure system according to Claim 6, characterized in that the means for detecting the coupling employ pulses, in particular needle pulses (28), whose attenuation serves as a criterion for the existence of a coupling.
8. Electronic closure system according to Claim 1, characterized in that the access code (1) is designed in such a way that it is destroyed if a retaining strip for the key ("keys") is opened, but, on the other hand, an opening point which is provided can be secured against impairment of the code by an additional device to which contact can be made by the retaining strip.
9. Electronic closure system according to Claim 1, characterized in that the carriers for the security code (3), for example cards, are provided with an identification, for example an area number (2),of an allocation area (4, 4', ...; 5,5', ...).
10. Electronic closure system according to Claim 1, characterized in that more than one allocation area (4, 4', ...; 5, 5', ...) are correspondingly coded in the lock ("locks") and in the key ("keys") and/or more than one interlocking device with control system is assigned to a safety catch.

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