EP1703481A1 - Method for determining the configuration of an alarm system and alarm system - Google Patents

Abstract

The method involves sequentially activating detectors (M1 - M10) that are uncoupled by isolator switches (S), and sequentially registering the detectors with a central office (Z). The registration of one of the detectors is only accepted during the simultaneous registration of more than one detector. Communication addresses are differenced during registration of the detectors with the addresses based on an arbitration method. An independent claim is also included for a danger alarm system.

Description

The present invention relates to a method for determining the configuration of a central unit and to these via a reporting line connected devices having alarm system, in which each device has an isolator switch, a unique identification number and a communication address and the decoupled via the isolator switch devices sequentially to be started.

Devices are to be understood in this context in particular danger detector, but it may also be actors, such as visual or audible alarm, relays, alarm displays, transmission devices for the transmission of alarms and the like. At any rate, when the following description refers to detectors, it should not be construed as limiting.

Such methods, which are known under the name chain synchronization or daisy-chain, have long been used to determine the detector arrangement on a pure stub or a pure loop. In the EP-A-0 093 872 Such a method is described in which when commissioning the system, all detectors are separated by a change in voltage of the signaling line and then staggered by the switch so staggered again to the reporting line that every detector after a certain time delay, a subsequent detector in addition to the line voltage turns on , The detectors contain address memories, which are assigned to the communication addresses of the individual detectors in the specified sequence from the control panel.

In the in the EP-A-0 093 872 described method, the treatment of branching can be problematic, since after the closure of the front of a branch isolator switch suddenly two or more than two detectors start simultaneously at multiple branches, especially if they do not yet have a unique communication address. It must be assumed that when communicating detectors between different signal lines, duplicate communication addresses are also possible for pre-addressed detectors.

In the EP-A-0 485 878 a method for determining the configuration of detectors of a hazard detection system is described, in which the center must perform a variety of steps until the assignment of the communication address to the detectors, which takes a relatively long time. Determining the position of a newly installed detector by restarting the entire network is time-consuming and certainly not efficient, especially for larger networks. Apart from that, this method does not work with symmetrical branches.

In the EP-A-0 880 117 A method for the automatic localization of detectors is described, in which the detectors are equipped with means for communication with neighboring Meidern. To locate a detector, all detectors open their disconnectors and the detector to be located sends a corresponding message, which is only received by its neighbors. Subsequently, the disconnectors are closed and it is determined which detectors are these neighbors, allowing a clear determination of the position of the detector to be located. This method is relatively fast, but requires the equipment of the detectors with the said communication means.

The invention is now a method for determining the configuration of a hazard detection system will be given, which allows for branched topologies determination of the line network arrangement and faster and easier than the known method works.

This object is achieved according to the invention that log on at startup, the devices at the headquarters sequentially and with simultaneous registration of more than one device only the registration of one of these devices is accepted.

A first preferred embodiment is characterized in that the devices register with their communication address at the central office, and that with simultaneous registration of devices with different communication addresses, the communication addresses distinguished by an arbitration process and the two different communication addresses are registered sequentially.

A second preferred embodiment of the method according to the invention is characterized in that the devices register with their communication address at the central office, and that the simultaneous detection of devices with the same communication addresses, the collision of these same communication addresses is detected and resolved.

A third preferred embodiment of the method according to the invention is characterized in that the devices register with their identification number at the central office, and that a sequential application is made secure by means of an arbitration method via the identification number and the devices are assigned a unique communication address via the identification number.

A first alternative solution to the problem is characterized in that the communication addresses of all devices polled when starting from the center and thereby newly added communication addresses are detected, and that with multiple occupancy of communication addresses the collision of these same communication addresses is detected and resolved.

A second alternative solution of the task is characterized in that the identification numbers of the newly started devices are queried when starting from the center and each device found a unique communication address is assigned.

The invention further relates to a hazard alarm system with a program-controlled center to which a device is connected several devices in parallel, each of which contains at least one sensor, an isolator switch, an evaluation with at least one memory and a manufacturer assigned, individual and unchangeable serial number , The inventive hazard detection system is characterized in that the center comprises means for carrying out said method steps.

A preferred embodiment of the inventive hazard detection system is characterized in that the said devices are formed by hazard alarms and / or actuators, such as visual or audible alarm, and / or relays and / or alarm displays and / or transmission devices for the transmission of alarms.

• Fig. 1 eine schematische Darstellung einer Gefahrenmeldeanlage; und
• Fig. 2 ein Flussdiagramm zur Erläuterung der Bestimmung der Leitungsnetzanordnung.

In the following the invention will be explained in more detail with reference to an embodiment and the drawings; it shows:

• Fig. 1 is a schematic representation of a hazard detection system; and
• Fig. 2 is a flowchart for explaining the determination of the line network arrangement.

The danger warning system shown in Fig. 1 consists of a central Z, an outgoing from this annular reporting line ML connected to these detectors M ₁ , M ₂ and M ₅ to M ₁₀ and a branching off from the reporting line ML stub SL with connected to these detectors M ₃ and M ₄ . The detector M ₁ has the communication address 1, the detector M ₂ the communication address 2, and so on. Each of the detectors M _n contains at least one sensor for a hazard parameter, such as smoke, temperature or a fire gas, an evaluation (both not shown) and an isolator switch S.

In the case of the hazard alarm system illustrated, it is assumed that each detector M _n has a communication address and a unique identification number. The latter was assigned to the relevant detector in the factory; it is unchangeable and occurs exactly once.

As already mentioned in the introduction to the introduction, detector M should not only be understood as a danger detector, but more generally as an addressable device used in a message line. In addition to a danger detector, this can also be an actuator, such as an optical or acoustic alarm, a relay, an alarm display, a transmission device for the transmission of alarms and the like.

In order to determine the arrangement of the detectors M _n on the network formed by the reporting line ML and the stub line SL, the detectors M _n which can be decoupled via the isolator switches S are started sequentially from the center Z, with the detectors optionally being assigned a unique communication address , In addition, information from the detectors M _n , if any, such as detector type, an identification number, such as a serial number or an existing communication address for the complete determination of the detector arrangement can be read on the network in the center Z. Whenever a detector M _{n has closed} an isolator switch S and has logged on, the next detector closes its isolator switch in response to a command from the central station Z. After each closure of an isolator switch S, the control center Z waits until no more detectors M _n log in and then also knows how many detectors are connected directly behind the one who has last closed its isolator switch S. If only one detector has reported after the last closure of an isolator switch S, then there is no branching, two detectors have reported themselves, it is a simple branch, and so on.

1. 1. Die Melder melden ihre Kommunikationsadresse an die Zentrale Z, welche bei gleichzeitigem Eingang von zwei oder mehr Kommunikationsadressen über ein Arbitrationsverfahren die gleichzeitige Anmeldung von mehreren Meldern mit unterschiedlicher Kommunikationsadresse verhindert. Beim Arbitrationsverfahren werden die Adressen bitweise verglichen und es wird beispielsweise derjenige Melder bevorzugt, der ein Bit gesetzt hat. Dieser Melder erhält dann ein Kommando von der Zentrale Z und schliesst seinen Isolator-Schalter. Anschliessend wird die Kommunikationsadresse des bei der Arbitration unterlegenen Melders in die Zentrale Z eingelesen, der Melder erhält ein Kommando von der Zentrale Z und schliesst seinen Isolator-Schalter S. Dann meldet sich der nächste Melder, und so weiter.
2. 2. Die Melder melden ihre Kommunikationsadresse an die Zentrale Z, welche den gleichzeitigen Eingang von zwei gleichen Kommunikationsadressen als Kollision erkennt und auflöst. Die Auflösung erfolgt dadurch, dass die Zentrale Z allen an der Kollision beteiligten Meldern eine ungültige Kommunikationsadresse zuweist, worauf sich die Melder mit einer ungültigen Kommunikationsadresse nach der Variante 3 erneut anmelden (Fig. 2).
3. 3. Die Melder melden sich mit ihrer Identifikationsnummer bei der Zentrale Z an. Durch ein Arbitrationsverfahren der beschriebenen Art wird eine sequentielle Anmeldung sichergestellt und den Meldern werden über die Identifikationsnummern eindeutige Kommunikationsadressen zugewiesen.
4. 4. Von der Zentrale Z werden die Kommunikationsadressen aller Melder abgefragt, wodurch neu hinzu gekommene Melder erkannt werden. Eine Mehrfachbelegung von Kommunikationsadressen wird als Kollision erkannt und die Kollision wird auf die schon beschriebene Weise aufgelöst.
5. 5. Von der Zentrale Z werden die Identifikationsnummern der neu aufgestarteten Melder abgefragt (es können praktisch nicht alle möglichen Identifikationsnummern abgefragt werden, weil der Zeitaufwand für eine Vielzahl der vielstelligen Identifikationsnummern zu gross wäre), wofür sich ein auf einem binären Suchbaum basierendes Verfahren anbietet. Anschliessend wird jedem gefundenen Melder eine eindeutige Kommunikationsadresse zugeteilt.

The handling of branches is problematic, especially if the detectors at a branch do not already have a unique communication address. In addition, it must be assumed that by exchanging detectors between different lines even with pre-addressed detectors, duplicate communication addresses are possible, which must be prevented under all circumstances. In order to master such a situation, the system must be able to recognize that there is a branch, that is, several detectors have started up. The following methods are suggested for this:

1. 1. The detectors report their communication address to the center Z, which prevents the simultaneous registration of multiple detectors with different communication address with the simultaneous receipt of two or more communication addresses via an arbitration process. In the case of the arbitration method, the addresses are compared bit-by-bit and, for example, the detector which has set a bit is preferred. This detector then receives a command from the central Z and closes its isolator switch. Subsequently, the communication address of the inferior in the arbitration detector is read into the center Z, the detector receives a command from the control center Z and closes its isolator switch S. Then the next detector reports, and so on.
2. 2. The detectors report their communication address to the central station Z, which detects the simultaneous receipt of two identical communication addresses as a collision and dissolves. The dissolution takes place in that the center Z assigns an invalid communication address to all detectors involved in the collision, whereupon the detectors log on again with an invalid communication address according to variant 3 (FIG. 2).
3. 3. The detectors register with their identification number at the Z headquarters. By an arbitration method of the type described a sequential logon is ensured and the detectors are assigned unique communication addresses via the identification numbers.
4. 4. From the central Z the communication addresses of all detectors are queried, whereby newly added detectors are detected. A multiple assignment of communication addresses is detected as a collision and the collision is resolved in the manner already described.
5. 5. From the Z headquarters, the identification numbers of the newly started detectors are queried (it can not be practically queried all possible identification numbers, because the time required for a variety of multi-digit identification numbers would be too large), for which a based on a binary search tree method offers. Subsequently, each detector found is assigned a unique communication address.

Using any of the described methods, all detectors that are directly attached to branch outlets are known and can proceed sequentially with the start of each branch, so that finally the topology of the entire network can be recorded.

When the fire alarm system shown in Fig. 1 is started, the isolator switch S all detectors M _{n are} opened. Then, for example, reports the detector M ₁ at the headquarters Z with its communication address 1, the control center sends to the detector M ₁ a command to close its isolator switch S and waits for the registration of the next detector M ₂ , whose application proceeds analogously. After the registration of the detector M ₂ , the two detectors M ₃ and M ₅ report their communication addresses 3 and 5, respectively, to the control center Z. The control center registers that there must be a branch and also registers that it involves the simultaneous registration of two detectors with different communication address acts and applies the Arbitration method described in point 1, in which, for example, the detector M _{3 is} preferred.

After the registration of the detector M ₃ , the detector M ₄ logs in at the headquarters Z, after this the detector M ₅ and so on. After the registration of the detector M ₁₀ , no detector will report, the control center Z now knows the configuration of the network of the fire alarm system. If, for example, because of a reporting exchange during maintenance / revision work the detector M ₈ would have the communication address 3, the central Z would recognize when logging in that the communication address 3 is already assigned to the detector M ₃ and would redirect the detector M ₈ to a free communication address.

As has already been mentioned, multiple branches can also be recognized with the described method, wherein, of course, a branch of a branch may itself again contain a branch.

Claims (10)

Method for determining the configuration of a security alarm system having a central unit (Z) and devices (M _n ) connected to it via a signaling line (ML), in which each device (M _n ) has an isolator switch, (S) a unique identification number and a Having communication address and via the isolator switch (S) decoupled devices (M _n ) are started sequentially, characterized in that log on at startup, the devices (M _n ) at the headquarters (Z) sequentially and with simultaneous registration of more than a device (M _n ) only the registration of one of these devices (M _n ) is accepted. Method according to Claim 1, characterized in that the devices (M _n ) log onto the central station (Z) with their communication address, and that with simultaneous registration of devices (M _n ) with different communication addresses, the communication addresses are distinguished on the basis of an arbitration method and the two different communication addresses are registered sequentially. A method according to claim 1, characterized in that the devices (M _n ) register with their communication address at the control center (Z), and that with simultaneous registration of devices (M _n ) with the same communication addresses, the collision of these same communication addresses is detected and resolved , A method according to claim 1, characterized in that the devices (M _n ) register with their identification number at the control center (Z), and that based on an arbitration process on the identification numbers sequential application made sure and the devices (M _n ) on the identification number a unique communication address is assigned. Method for determining the configuration of a security alarm system having a central unit (Z) and devices (M _n ) connected to it via a signaling line (ML), in which each device (M _n ) has an isolator switch (S), a unique identification number and a Having communication address and via the isolator switch (S) decoupled devices (M _n ) are started sequentially, characterized in that when starting from the control center (Z) the communication addresses of all devices (M _n ) queried and thereby newly added communication addresses detected and in the case of multiple assignment of communication addresses, the collision of these same communication addresses is detected and resolved. Method for determining the configuration of a security alarm system having a central control unit (Z) and devices (M _n ) connected to them via a signaling line (ML) in which each device (M _n ) has an isolator switch (S), a unique identification number and a communication address, and the devices (M _n ) which can be decoupled via the isolator switches (S) are started sequentially, characterized in that, when starting up the device Central (Z) the identification numbers of the newly started devices (M _n ) are queried and each device found (M _n ) is assigned a unique communication address. Method according to Claim 3 or 5, characterized in that the collision is canceled by an invalid communication address being assigned to all devices (M _n ) involved in the collision, the devices (M _n ) subsequently logging in, the sequential log-on being initiated by a Arbitration method on the identification number is ensured, and that the devices (M _n ) is assigned a unique communication address via the identification number. Method according to one of claims 2, 4 or 7, characterized in that the Arbitrationsverfahren by a bitwise comparison of the communication addresses or the identification numbers takes place, the device (M _n ) is preferred, which has set a bit. Security alarm system according to one of Claims 1 to 8, having a program-controlled central unit (Z) to which a plurality of devices (M _n ) are connected in parallel via a signaling line (ML), each of which has at least one sensor, an isolator switch (S), contains an evaluation with at least one memory and a manufacturer assigned, individual and unchangeable serial number, characterized in that the center (Z) comprises means for performing said method steps. Danger avoidance system according to claim 9, characterized in that said devices (M _n ) are formed by hazard alarms and / or actuators, such as visual or audible alarms, and / or relays and / or alarm displays and / or transmission devices for the transmission of alarms.

Images