EP1363261A1 - Method for the operation of an alarm system, and alarm system for the implementation of said method - Google Patents

Abstract

On initial start up after detection of a line fault a number of detections are undertaken. These include the location of the fault, and the first and second addresses of the last detector reached. A comparison is made with previously-stored information concerning the desired or actual data of the alarm lines. An Independent claim is included for the corresponding hazard alarm system.

Description

The invention is concerned with a method of operation a hazard detection system. The invention also relates to also a hazard alarm system, especially for implementation this procedure.

In order to target a hazard detection system quickly enough To be able to react to an impending danger, it is important that the system is quickly ready for operation even in the event of a fault is. It also requires that the location of a disturbance or an alarm can be displayed. To do this, the Alarm-triggering detectors can be precisely identified, and their Installation location. A hazard alarm system precisely identify all detectors operated on a zone can, is described in EP A 0 093 872. The one described there System has a ring-shaped detection line that is connected to a control center via two terminals. The on detectors operated by the detection line have a sensor, a transducer, a control unit and a switching element.

The switching element serves the connection between the control center and establish the next following detector or open separate.

When the system is started up, all switching elements are opened, whereby only the detector can be reached, that of the control center is closest. This detector is now given an address which he stores in a special memory area. After that the switching element in this detector is closed, whereby the next detector can be reached. After addressing of the second detector, the third is addressed until towards the last detector on the detection line.

After the detection line is fully started and all Detectors are provided with addresses, all detectors can be used in parallel are operated on the detection line and are nevertheless identifiable.

A major disadvantage of parallel operation, however, is that a Short-circuit the line of the entire detector line can. To compensate for this disadvantage, every detector should System described above on the input and output side Short circuit detector included. When a short circuit is detected should now the switches in the detectors, the short circuit on next are to be opened. This will cause the short circuit isolated and the supply voltage on all detectors in the zone can be maintained. Now all detectors can starting from the first terminal of the headquarters to Short circuit are supplied and queried. All other detectors can be supplied and queried via the second terminal at the headquarters become.

However, since the voltage and Current changes almost simultaneously across the entire detection line impact, it is associated with a high level of technical effort, if you want to make sure that only the switches, in the detectors closest to the short circuit are opened. This Effort increases because the short-circuit detectors and switches that both have to be extremely fast in each Detectors exist, which is the price of a single detector considerably more expensive.

Another method to solve the short circuit problem is in doing without parallel operation, and is in the DE 43 22 841 C2 described. For each polling cycle, first all switching element opened. After querying the first The detector's switching element is closed so that the next detector can be reached. If the polling cycle is from the first terminal is finished, a new cycle begins, starting from the second terminal. By constantly changing the Query direction between the query cycles is guaranteed that all detectors are queried even in the event of a line fault can.

However, the method described last has the disadvantages in itself that the query cycles through the always necessary Switching on the detectors and the associated waiting time a lot take longer than in parallel operation. In addition, everyone must Detectors have an energy storage from which the detector is supplied as long as it is not connected to the control center. The energy storage must have enough energy for the duration Provide at least one complete query cycle and be reloaded before each query. It is also with this Procedure for a detector not possible if there is no of queries caused by a malfunction in the control center, an emergency alarm to be submitted because there is no connection to the control center.

The invention is therefore based in particular on the object a method for operating a hazard detection system and a To create a hazard alarm system which, if a line fault occurs, like break or short circuit, quickly again are operational and all detector queries and the location of the Can specify errors without the disadvantages mentioned above exhibit.

The solution to this problem is the procedure of the beginning mentioned type in those described in claim 1 Process steps. Advantageous embodiments of the invention Processes are described in subclaims 2 to 5. The hazard alarm system according to the invention exists Solution in the features of the current claim 6.

The present subject matter has at least a ring-shaped detection line with at least two wires, which are connected to a control center via two similar terminals is, the detection line in different operating states is operated. The first time it is started the detection line is in a first operating state, the serves to start and in which the detectors receive their first addresses and be configured. The head office notes this all assigned first addresses and compare them with one previously saved profile. If the start-up ran without errors the zone changes to a second operating mode. In the second operating mode, the detectors become parallel to operated each other on the detection line and cyclically from the first Terminal queried off. Every detector is included in the query addressed to his previously assigned first address, on what the detector responds with its alarm or measurement data. by virtue of the addressing is also a query in any order conceivable. If now during operation in the second mode an error occurs, is in a third mode branched. In the third operating mode, all detectors become new started and the fault location isolated. After that, in a fourth operating mode changed, in which all detectors to the point of failure from the first terminal, the detectors behind the fault location supplied and queried from the second terminal and the error is displayed.

All detectors of the hazard alarm system according to the invention are equipped with sensors to detect dangers such as fire, Gas, burglary or other dangers, an evaluation and control circuit, a memory and at least one switching element to connect the next following detector to the control center.

The terminals of the alarm system according to the invention have via devices for monitoring the applied voltage and to detect short circuits between the different ones Cores of the detection line.

In the first operating mode, all detectors are initially dead; a voltage-free detector always has an open one Switching element and the first address zero. Then on the first Terminal applied the supply voltage of the detection line. To the application of the supply voltage is initially only that Terminal next detector powered and a time t1 waited until the first detector has initialized and all Energy storage, which are necessary for regular measuring operation, are loaded. After the time t1 is over, the first one Detector addressed with the first address zero, its type read out and with a new first that corresponds to its location Provide address. Type and the first address of the detector stored in the control center for further use. Subsequently the switching element of the first detector is closed, whereby the second detector is supplied with voltage. In turn after the time t1, the second detector can be activated with the first address zero. With the second and each further detector is operated in the same way as with the first Detector until the last detector in the zone with its new first address. If the switching element in the last terminal is closed, the second terminal recognizes the voltage now present that the ring is closed and all connected detectors via the saved first Addresses can be addressed. Then all the detectors found with a zone profile previously saved in the control center compared and each assigned to a detector from the notification line profile. Each detector then receives a profile that matches the profile second address that is in a non-volatile memory is written. If the start-up is error-free now switched to the second operating mode. However, if already in the first operating mode line faults are recognized by the first terminal from only started up to the location of the error and then do the same from the second terminal, until the fault location is isolated, the switching elements closed to the detectors that are adjacent to the errors stay or be opened again. After that, in the fourth operating mode branches.

In the second operating mode, all detectors are on the detection line supplied from the first terminal and queried cyclically; each detector with its, in the first operating mode assigned first address, addressed and a corresponding Command in the form of a digital data word, for example a Query command, transmitted. The corresponding detector then sends its alarm data, which are further processed in the control center become. If during operation in the second mode a line fault occurs, the system switches to the third operating mode, in which the error is isolated and the accessibility all detectors are restored.

In the third operating mode, the basic procedure is that first disconnect the supply voltage of the detection line becomes. This opens the switching elements in all detectors and the first addresses fall back to zero. After a wait t2 becomes the first detector from the first terminal Power supplied and then after the waiting time t1 over the first Address addressed zero. The type and the second address of the first detector are read out and with the data contained in the first operating mode were compared. Subsequently the second address will again correspond to the location of the detector set and the switching element closed. With every other Detector will proceed in the same way until the location of the fault or at an error that only occurred for a short time, the second terminal is achieved. In the event of a line break, the location of the Error recognized that the next detector is not within answers a given time. After the interruption was found the switching element that was closed last has been opened again and the starting process is started by the second Terminal continued to the other side of the error. The detectors are restarted here as well as from first terminal, the switching element of the detector, the the location of the fault is not closed, because from the known data it is clear that no further detector is available.

In this way, it is possible for n detectors on a detection line to be ready for operation again in the time nxt ₁ + t ₂ . This corresponds approximately to the time required for a query cycle according to the method described in DE 43 22 841 C2.

However, there is a problem with a short circuit as an error. If the switching element that is closest to the short circuit is closed, the voltage across the entire detector line that has been started up to that point collapses, the switching elements in the detectors open and the first addresses are set to zero. The location of the fault is therefore partially known and the closing of the last switch before the short circuit can now be avoided, but all detectors that have been started up to this point must be started again. In the worst case, if the short circuit is just before the second terminal, this can lead to a total time for restarting the alarm line of more than 2 (nxt ₁ + t ₂ ), which leads to an unacceptable amount of time.

Therefore, according to the invention in the third mode before restart between the interrupt and Short circuit differentiated.

The voltage monitoring device in the second terminal recognized by the fact that after the interruption occurred there is no more voltage on the second terminal. After this an interruption is recognized, is described after the above Procedure restarted the detection line, which means only one short-term interruption the detection line even error-free restarted and returned to the second operating mode can be. If the interruption still exists, from both terminals only started up to the point of failure and switched to the fourth operating mode.

In the event of a short circuit, which is detected by one of the short-circuit detection devices of the two terminals, there is initially a wait for the duration of the time t2 and only a little after the voltage has been applied from the first terminal to the first detector and also from the second terminal the next detector to the second terminal. As already described above, after a waiting time t1, the detectors closest to the terminals with the first address zero are addressed, detector type and second addresses are read out, compared with the data stored in the control center, the first addresses corresponding to the location of the detectors are set and the switching elements are closed , As soon as the short circuit is reached from a terminal, the location of the short circuit is known from the address of the detector reached immediately beforehand from the respective terminal and the comparison with the target and actual data from the control center. The supply voltage from both terminals is switched off again and, after a further waiting time t2, a second restart is started from both terminals, which ends immediately before the short circuit. This reduces the maximum time required to find the short circuit by at least half. The total time until all detectors can be addressed again and changed to the fourth operating mode results in a time of nxt ₁ + 2t ₂ , which is only slightly longer than the time required for an interruption. The time nxt ₁ + 2t _{2 is} calculated as follows: with n detectors and a short circuit after the m th detector, viewed from the first terminal and a waiting time t2 before each restart: For 1. Start of repair 2. Start of repair total m <n / 2 t ₂ + t ₁ m t ₂ + t ₁ (nm) = 2t ₂ + t ₁ n m> n / 2 t ₂ + t ₁ (nm) t ₂ + t ₁ m 2t ₂ + t ₁ n

A further reduction in the repair time can be achieved when the supply voltages in the two terminals from each other are independent. Then the short circuit only works the terminal closest to the short circuit. Since the The location of the short circuit is known as soon as the short circuit of one of the two terminals can be reached from the other Terminal off until the short circuit continues. The switching element in the detector, which is immediately in front the short circuit remains closed. In the meantime, is from the terminal closest to the short circuit has started with the second repair start, also ends just before the short circuit.

After the line errors have been found and all detectors over the first or second terminal can be reached again in the fourth operating mode branches. In the fourth mode all previously found errors are displayed by type and location and supplies all detectors from the first or second terminal and asked regularly about their alarm data.

With the method described above, it is possible to do all To take advantage of parallel operation and also with one Short circuit in a short time again all detectors reliably to be able to operate and thus to ensure the alarm readiness.

Fig. 1

zeigt eine erfindungsgemäße Gefahrenmeldeanlage,

Fig. 2

zeigt ein Zustandsdiagramm mit den möglichen Betriebszuständen, die die erfindungsgemäße Gefahrenmeldeanlage einnehmen kann.

Fig. 3

zeigt eine erfindungsgemäße Gefahrenmeldeanlage mit einem Unterbruch, und

Fig. 4

zeigt eine erfindungsgemäße Gefahrenmeldeanlage mit einem Leitungskurzschluß.

The invention will now be explained in more detail with reference to the drawings.

Fig. 1

shows an alarm system according to the invention,

Fig. 2

shows a state diagram with the possible operating states that the hazard alarm system according to the invention can assume.

Fig. 3

shows an alarm system according to the invention with an interruption, and

Fig. 4

shows a hazard detection system according to the invention with a line short circuit.

1 shows a hazard alarm system 1 according to the invention, which are described below as a fire alarm system becomes. Of course, it can also be done by an intruder alarm system or mixed system for fire, burglary and other dangers are formed. The fire alarm system 1 exists from a control center 2 and a reporting line 9 with at least two Wires 7 and a variety of hazard detectors 8. The control panel contains a memory for a target table 3 and an actual table 4 and at least one pair of terminals consisting of two Similar terminals A and B 5/6. Terminal A 5 is with connected to one end of the reporting line and Terminal B 6 with the other end. Terminals A and B 5/6 are used for supply and communication with the detectors 8 and Devices for monitoring the voltage, not shown on the detection line 9 and for the detection of short circuits between the wires 7. The wires 7 provide the connection between terminals 5/6 and detectors 8, which are used as smoke, temperature, Gas, multi-criteria or intrusion detectors trained are. The detectors 8 contain a first memory 10 for one first address corresponding to the location of the detector, a second non-volatile memory 13 for a second the installation plan appropriate address and a switching element with which at least one of the wires 7 can be interrupted.

FIG. 2 shows a diagram showing four different operating states or operating modes are shown by the hazard alarm system can take. From the first state "start", can in the states "normal" and "AB operation" are changed from second state "normal" and fourth state "AB operation" can in the third state "repair" and from "repair" after "AB operation" and "normal".

In the "start" operating state, all the switching elements 11 in the detectors 8 are initially open, the first address is zero, the second address is indefinite and the supply voltage is zero. Then the supply at Terminal A 5 is switched on and the first detector closest to Terminal A 5 is supplied with voltage. After a waiting time of approx. 2 s, its energy stores are filled and the detector 8 can be addressed zero via the first address.
The detector type is then read out and the first memory 10 is assigned, for example, the address one in accordance with the location of the detector 8. The first address and the detector type are stored in the actual table of the control center and the switching element 11 is closed.
Again after 1.5 s, the next detector 8 can be addressed with the address zero. The same procedure is followed with each other detector 8 as with the first detector 8, the first addresses being assigned in ascending order. When the switching element 11 in the last detector 8 on the detection line 9 is closed, the terminal B 6 recognizes from the voltage now present that the detection line 9 is completely switched on. In a subsequent comparison of the target and actual tables, the second addresses are generated and the detectors 8 are written into the second memories 13.

After an error-free start-up of zone 9, the "Normal" status changed. However, if there are line faults, the reporting line 9 will be from Terminal A 5 and Terminal B 6 started only up to the error, whereby from Terminal B from the first addresses with the largest possible Allocate address starting counting down and the Switching elements 11 of the detectors 8, which are adjacent to the fault are not closed. Then the state is "AB operation" changed.

In the "normal" state, all detectors 8 are switched off from terminal A 5 supplied and queried their alarm data. The query takes place cyclically, with each detector 8 from Terminal A 5 with its first address is asked for its alarm data. The query can, however, in principle also be carried out in any order become. If a line fault occurs during parallel operation occurs, the system branches to the "Repair" state.

In the repair state, a distinction is first made as to which type of line faults. An interruption is due to the lack of Supply voltage detected at terminal B 6. A short circuit is reported by the short-circuit monitoring device.

The treatment of an interruption is explained on the basis of FIG. 3. If an interruption is detected, the Power supply to zone 9 at the terminals is interrupted. As soon as the line 9 is de-energized, everyone is gone first addresses zero and the switching element 11 opened. To the Isolation of the interruption is first from Terminal A 5 voltage placed on the first detector 8 and its second address read out by the detector 8 addressed with the address zero and the corresponding command is sent. The read one Address is with the existing data in the debit and the actual table 3/4 compared, then the associated one first address written in the first memory and that Switching element 11 closed. With the following detectors 8 will do the same. When the interruption 30 is reached, this becomes due to the lack of response from the following detector 8 recognized and the last closed switching element 11 again open. The same procedure is then followed from Terminal B 6 as previously described for Terminal A 5, the switching element 11 of the detector 8 which is located in front of the terminal B 6 Interruption is no longer closed because of the place of the interruption already from the comparison of those in the headquarters 2 stored data emerges.

The treatment of a short circuit is explained using FIG. 4. A short circuit 40 on the detection line 9 is immediate after its occurrence by the short-circuit detection means in terminals A and B 5/6 and the power supply immediately interrupted. This means that after one Waiting time of 10 s all switching element 11 in the detectors 8 opened, and the first addresses dropped back to zero. After that is supplied from terminal A 5 from the first detector 8. Right away Terminal B 6 then turns it into the Terminal next, detector 8 supplied. Both detectors 8 are each after a waiting time of 1.5 s from the corresponding Terminal 5/6 addressed with the first address zero, and the second Read addresses. These are with the data from the target table and the actual data previously obtained in the "Start" state compared. Then the first addresses are the location of the Assign detector 8 accordingly. The detector 8 at Terminal A 5 receives first address one and the detector at Terminal B 6 receives the first address six. You can also see how easy is the largest possible first for the detector at Terminal B 6 Assign address. Then the switching elements 11 of the detectors 8 closed, being between the closing of the switching element 11 is waited long enough until an existing one Short 40 was discovered. After closing the switching element 11 in detector 8 with the first address six Short circuit 40 detected and the detection line de-energized. Because now again all switching elements 11 are open and all first Addresses are zero, with the start of zone 9 again as previously described from both terminals A and B 5/6 started from. But now the switching elements remain Detectors 8, which are adjacent to the short circuit 40, are closed. The location of the short circuit 40 is determined by those previously carried out Comparing the addresses of the most recently reached detectors 8, with the target and actual data stored in the control center, known.

When all detectors 8 can be reached again, the fourth Operating state "AB operation" changed. In the AB mode, all detectors 8 are either from Terminal A 5 or from Terminal B 6 supplied and queried. In addition, the place and the type of the previously recognized error in a not shown Control center display shown.

Due to the slightly delayed start from both sides the reporting line and the comparison with those in the headquarters stored data, a short circuit can be localized much earlier and be isolated as with a simple change of querying terminals after the first short circuit is reached. In addition, without the comparison with the data of the headquarters a third start is necessary. Because you know through that Reaching the short circuit from Terminal B 6 only the distance to Terminal B 6. You get the distance to Terminal A 5 only by reaching the short circuit 40 again this becomes effective again and a third start is required makes. Accordingly, the invention brings a great time advantage when a detection line is made available again after a Short circuit 40 and thus represents an enormous gain in safety represents.

The invention is a method of operation a hazard detection system with one operated at two terminals Annular detection line. In the event of a short circuit on the detection line it succeeds with a slightly delayed start and re-address the detector from both terminals and the Comparison of a fixed address with that previously stored in a control center Data, all detectors in the zone quickly again to have available.

Claims (6)

Method for operating a hazard alarm system, with a control center which has at least two terminals for at least one ring-shaped alarm line, with a large number, after a start-up phase, operated in parallel on one alarm line and which can be addressed via a first address and which supplies from both sides of the ring line and can be queried, whereby in the event of a line or other fault, the detection line is restarted, and after restarting normal operation or a two-terminal operation, in which the detectors are supplied and queried from one terminal to the fault location is switched over, characterized in that when starting for the first time after the detection of a line fault, the location of the line fault, when the line fault is reached, at the first and second address of the last detector reached and a comparison with target or actual values previously stored in the control center. Detection line data t will. Method according to Claim 1, characterized in that the line fault is isolated by the switches of the detectors located in front of the line fault not being closed and the detectors being supplied and interrogated from the first or second terminal until the line fault. Method according to claim 1, characterized in that, in the event of a line short-circuit as an error, the restart is carried out immediately after detection of the short-circuit from both terminals. A method according to claim 3, characterized in that at the first start after the detection of the short circuit, the location of the short circuit, when the short circuit becomes effective, at the first address of the detector last reached and the comparison with previously stored target data or the actual data the detection line is recognized. A method according to claim 4, characterized in that the short circuit is isolated on the second start by the switches of the detectors located before the short circuit are not closed and the detectors are supplied and queried until the short circuit from the first or second terminal. Hazard detection system, in particular to carry out the Method according to one of the above claims, which Hazard detection system according to at least one of claims 1 to 5 is designed.

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