WO2014044818A1 - Fire alarm system and fire alarm network comprising a plurality of fire alarm systems - Google Patents

Abstract

While fire detectors are used in private homes as stand-alone solutions so that they surveil exclusively a section e.g. of a house and only output an alarm if a fire is detected in this section, interconnected fire detectors are used in larger building complexes. The invention relates to a fire alarm system (1) comprising a plurality of fire detectors (2), the system comprising a fire alarm center (5). The fire alarm center (5) is connected to the fire detectors (2) via a first network (4) so that fire detection data B, B' can be transferred from the fire detectors (2) to the fire alarm center (5), the fire detectors (2) and/or the fire alarm center (5) being designed to output a fire alarm. A surveillance center (9) for surveilling an installation state and/or maintenance state of the fire detectors (2) and/or of the fire alarm center (5) is connected to the fire alarm center via a second network (8).

Description

 description

title

 Fire alarm system and fire detection network with a plurality of

Fire alarm systems

PRIOR ART The invention relates to a fire alarm system with a plurality of

Fire detectors and a fire alarm panel, the fire alarm panel is connected via a first network with fire detectors so that fire detector data can be transmitted from the fire alarms to the fire panel, the fire alarm and / or the fire alarm panel is designed to issue a fire alarm. The invention also relates to a fire network with a plurality of such fire alarm systems.

While in homes, fire detectors are often used as stand-alone solutions so that they isolate a subarea, e.g. monitor a house and only issue an alarm if a fire is detected in this subarea, it is common in larger building complexes to use networked fire detectors. The networking allows the fire detectors to exchange information with a fire alarm central unit so that an overview of the dangerous situation in the building complex can be formed.

For example, document DE 10 2008 042 391 A1, which is believed to be the closest prior art, discloses a fire safety device having an evaluation module and an input module, wherein the input module is coupled to a plurality of fire sensors, e.g.

Temperature sensors, smoke or smoke density detectors, CO or C02 sensors, as automated fire detectors, etc. is connected. The Fire safety device can trigger different countermeasures when detecting a fire.

Disclosure of the invention

In the context of the invention, a fire alarm system with the features of claim 1 and a fire detection network with the features of claim 13 is proposed. Preferred or advantageous embodiments of the invention will become apparent from the dependent claims, the following description and the accompanying drawings.

In the context of the invention, a fire alarm system is proposed, which is suitable and / or designed for a surveillance area. The fire alarm system is used for automatic detection of fires in the surveillance area. The surveillance area may be formed as a contiguous or non-contiguous area in a complex. For example, the fire alarm system in a building complex, in a warehouse, etc. arranged. The fire alarm system may also serve to accommodate larger public areas, such as To monitor stations, airports, etc. as a surveillance area.

The fire alarm system comprises a plurality of fire detectors. The fire detectors are preferably designed as automated fire detectors. In particular, the fire detectors are designed to detect a fire automatically. For example, the fire detectors to at least one sensor

Detection of a fire, such as an optical scattered light sensor, a temperature sensor, a smoke sensor or a smoke density sensor, etc.

The fire alarm system also includes exactly one or at least one fire alarm panel, the fire alarm panel is connected via a first network with the fire alarms. The fire alarm system is designed in such a way that fire detector data can be transmitted via the first network from the fire detectors to the fire alarm control panel. Optionally, the fire panels are interconnected via another network, in particular a LAN. The fire detectors and / or the fire alarm panel are designed to issue a fire alarm. The output of the fire alarm can be done for example via a signal-related siren or optical warning device. It is also possible that the output of the fire alarm is forwarded to rescue workers via an interface.

In the context of the invention it is proposed that the fire alarm panel is connected via a second network with a monitor center, the monitor center is suitable and / or designed for monitoring an installation and / or maintenance condition of the fire alarm and / or the fire panel.

The monitor center can be designed as an automated monitor center, which performs the monitoring automated. Alternatively, the monitor center is designed as a person-based monitor center, with monitoring personnel is present, which monitors the installation and / or maintenance status of the fire alarm and / or the fire panel. In the latter embodiment, the monitor center has human-machine interfaces, such as e.g.

Computer workstations enabling monitoring to be carried out by surveillance personnel.

It is an advantage of the invention that the fire alarm system is divided into two areas viewed from the architecture. A first area, which includes the fire detectors and the fire alarm control panel, is used to output the fire alarm. In particular, this first region is designed to have real-time capability, the real-time being defined by the fact that a reaction to a fire detected by one of the fire detectors takes place within less than 10 seconds. The fire alarm system comprises a second area which is suitable and / or designed for monitoring the installation and / or maintenance state of the first area. This second area does not have to meet the hard real-time requirement of the first area. Thus, it is conceivable, for example, that a reaction to a detected, critical installation and / or maintenance state of the fire alarm and / or the fire panel at least in individual cases later than 15 minutes after detection, in particular later than 30 minutes after detection and in particular later than 60 minutes after detection. Accordingly, it is preferable that the first network be real-time capable of issuing the fire alarm without delay, whereas the demands on the second network may be lower. By dividing the functions fire monitoring on the one hand and installation and / or maintenance monitoring on the other hand, the complexity of the fire alarm system can be reduced by real-time non-critical functions are separated from the real-time critical functions. By such an architecture, on the one hand, the monitoring by the fire alarm system with regard to fires can be improved and, on the other hand, the monitoring with regard to an installation and / or maintenance state can be simplified.

In a preferred embodiment of the invention it is provided that the second network is designed as an Internet connection at least in a connection section between the fire alarm control panel and the monitor center. Internet connections suffer in public networks now and again at connection failures, but this is tolerable in the monitoring of an installation and / or maintenance condition of the fire alarm and / or the fire panel. In this way, the fire alarm system is comparatively easy to install and operate.

In an alternative embodiment of the invention, the second network has a private IP network in a connection section between the fire panel and the monitor center. Such private IP networks - also called security networks - use ADSL, SDSL, GPRS, EDGE, UMTS, HSDPA +/- technology. In the private IP networks, the network partners are not accessible from the public Internet and thus protected against dangerous attacks from the global network. An example of such a private IP network is the Applicant's BOSINET-NGN. In a preferred structural embodiment of the invention, it is provided that the monitor center is arranged decentrally and in particular more than 10 km, preferably more than 50 km and in particular more than 100 km away from the fire panel is located. This configuration is made possible only by the function separation fire supervision / installation and / or maintenance monitoring, since it is easy, installation and

To transport maintenance information even over long distances. On the other hand, it is preferable that the first network connecting the fire detectors and the fire panel is formed as a security network. In particular, the first network is designed as a digital fieldbus system. For example, the first network is called a LSN

(Local Security Network) realized. The LSN bus is designed as a 2-wire system which transmits information encoded via pulse width modulation. Such 2-wire lines in the first network have a very high security standard because they are available in different network topologies and different network monitoring mechanisms are known to detect creeping changes or disturbances.

In a preferred embodiment it is provided that the fire detector data include environmental sensor data, component state data and / or operating state data:

Under environmental sensor data are especially or exclusively measured data of the sensors in the fire detectors to understand. For example, a scattered light intensity is emitted by a scattered light sensor in a fire detector, a temperature signal, etc., by a temperature sensor in a fire alarm.

In particular, the environmental sensor data represents smoke densities, temperature values or gas densities.

By component state data is meant, in particular or exclusively, resting values of the sensors in the fire detectors, electrical voltages, currents and resistances of interface modules or batteries in the fire detectors and / or the supply lines as well as the evaluation of faulty data telegrams for evaluating the quality of the transmission lines in the first network.

Under operating state data, in particular or exclusively, the logical states of the system components, in particular the fire detectors are detected. Changes in these logical states result, for example, from alarms, controls, configuration changes or when components are classified as faulty or faulty due to changes in the physical properties. It is further preferably provided that the fire alarm system is formed that fire detector data or processed fire detector data - hereinafter also collectively referred to as fire detector data - are transmitted via the fire panel to the monitor center. The

Fire alarm panel forms in this embodiment, a network node over which the above data are transmitted to the monitor center. For example, the fire alarm data or processed fire alarm data is stored in a suitable data format and prepared for data transmission over the second network to the monitor center.

The processed fire alarm data may be summaries of the fire alarm data.

In a preferred embodiment of the invention, it is provided that the monitor center is designed to detect slow, in particular only slow, changes in the fire detector data in order to monitor the installation and / or maintenance status. In particular, the monitor center is designed to detect drift changes in the fire detector data. Slow changes in the fire detector data are understood to mean changes which extend over a period of at least 15 minutes, preferably over a period of at least one hour and in particular over a period of several days.

In an alternative or additional embodiment of the invention, the monitor center is designed to detect rapid changes in the sensor data in order to monitor the installation and maintenance status. By detecting quick changes, transient changes can also be detected. In particular, changes with a frequency between 1 hertz and 0.1 hertz are recorded. In particular, in the detection of rapid changes, it is preferable that the monitor device is adapted to determine a periodic repetition of a pattern in the sensor data as a processing result. Thus it is possible, for example, even short-term, regular fluctuations in a longer cycle, e.g. to recognize in a 24-hour cycle.

In an alternative or supplement to the invention, it is provided that the fire detector data are applied as a data pattern and with Standard patterns are compared to detect significant deviations. Such a data pattern can be realized, for example, by plotting a 24-hour cycle of the fire detector data or partial data thereof. The standard patterns are recorded in normal operation. In this way, for example, continuous trends, such as increasing resistances, which give indications of the degradation or aging of a line or component, or a drift of resting values, which suggest increasing pollution, are possible. Technically speaking, it is preferable that the monitor center is designed

Signal changes with a frequency of change less than 0.001 Hertz, preferably less than 0.0003 Hertz and in particular less than 0.00001 Hertz to detect. To minimize the amount of data, it is preferred that the fire detector data be at a sampling frequency of less than 0.002 Hertz, preferably less than 0.0006 Hertz, and more preferably less than 0.00002

Hertz because these sampling frequencies are sufficient to detect the slow changes.

In a possible application of the invention it is provided that the monitor center is designed to detect contamination of the fire detector. In such pollution, for example, the resting values of light sensors, e.g. in a scattered light sensor, constantly reduced. Reducing the levels of rest over several days or weeks can be an indication of increasing pollution, and thus of the need for replacement or cleaning. This way you can

Maintenance status of the fire detectors are determined.

In another application, the monitor center monitors the change in voltage of a battery in a fire detector. Such batteries are often used as emergency power supply in fire detectors. Due to the constantly decreasing due to the self-discharge battery voltage can be concluded that a maintenance condition of the fire alarm.

Similarly, a maintenance condition of other components or modules of the fire detectors or the fire panel may be closed when certain values change over long periods of time. The advantage of the invention is to be seen in particular in that, by extrapolating the slow changes, it is also possible to conclude an exchange or maintenance of the components in the future, and that such an exchange or maintenance in good time, in

Maintenance intervals can already be carried out prophylactically. For example, it is no longer necessary to wait for a single fire alarm to indicate contamination and / or low battery voltage by outputting an optical signal. Rather, it is possible, before the fire detector itself detects this maintenance condition and outputs as an optical or other signal to identify in advance the pending maintenance case and to make the maintenance or replacement in good time before the signal is issued in the surveillance area. As a result, all fire detectors or fire alarm control panels of the fire alarm system can be serviced at longer intervals without having to use maintenance personnel for each individual maintenance case.

In another application, for example, signal changes within one day or within 24 hours are detected and compared with reference data sets to detect periodic irregularities. So it is conceivable, for example, that in a temperature sensor due to direct sunlight regularly at a given time by the sun, a temperature increase is detected, which can occur in extreme cases, even in the vicinity of a triggering temperature for an alarm. In this case, it can be determined via the monitor center that the associated fire detector is unfavorably positioned and should be moved during the next maintenance interval. Likewise, unfavorable installation positions can be detected in smoke detectors when e.g. smoke occurs at certain times of the day in the surveillance area due to trucks or due to planned burns. Next

Signal changes within 24 hours may also detect weekly changes (caused, for example, by effects of weekday and weekend change), monthly or yearly changes (e.g., seasonal effects). By this type of detection is thus an installation state of the fire alarm and / or the

Fire alarm panel monitored. Another object of the invention relates to a fire detector network, wherein the fire detector network comprises a plurality of fire alarm systems, as described above or according to one of the preceding claims. The fire detection network is characterized in that the fire alarm systems use a common monitor center. In particular, it is provided that the fire alarm systems are arranged distributed locally, in particular from each other have a distance of at least 1 km, preferably of at least 10 km. In particular, the fire detection network comprises at least five such fire alarm systems. The architecture proposed by the invention thus makes it possible for the functions requiring real time, namely fire detection and alarm triggering, to be centrally regulated in the area of the fire alarm system. The function of the maintenance and installation condition monitoring, however, is decentralized and can be taken over by a monitor center for several fire alarm systems. This architecture can thus be saved components of the fire detection network.

Further features, advantages and effects of the invention will become apparent from the following description of a preferred embodiment of the invention. Showing:

Figure 1 is a schematic block diagram of a fire alarm system as an embodiment of the invention;

Figure 2 is a graph for explaining the detection of maintenance conditions by the fire alarm system in Figure 1;

Figure 3 is a graph for explaining the detection of installation conditions by the fire alarm system in Figure 1;

1 shows a schematic block diagram of a fire alarm system 1 as an embodiment of the invention. The fire alarm system 1 comprises a plurality of in particular automatic

Fire detectors 2, which for monitoring a surveillance area 3 are arranged. For example, the fire alarm system 1 comprises more than 100 or 500 fire detectors 2. The fire detectors 2 each have a fire sensor system, eg a temperature sensor, a scattered light sensor, a flue gas sensor, a fire gas sensor or other specific sensors. Optionally, the fire detectors 2 each have a self-sufficient energy source, in particular a

Have battery, so that they are powered at least in emergency mode with energy.

The fire detector 2 are connected via a first network 4 with a fire panel 5 signal technology. The first network 4 is for example as a

Network formed, which transmits information via pulse width modulated signals. In particular, the first network 4 is designed as an applicant's LSN network. The connection between the fire panel 5 and the fire detectors 2, for example via a 2-wire cable.

Fire alarm data B or processed fire alarm data B 'are combined by the fire detectors 2 in the fire control panel 5. The fire alarm panel 5 and / or the fire detector 2 are designed to issue a fire alarm. For this purpose they are connected to an alarm module 6, the alarm module 6 in turn connected to signaling devices, such as e.g. sirens,

Speaker systems, optical signals, etc. is connected to output the fire alarm.

The components mentioned so far, in particular the fire detector 2, the first network 4, the fire panel 5 and the fire module 6 form a first area I which must work in real time to immediately detect a fire detected by the fire detector 2 via the fire module 6 in a fire alarm to change. In particular, the fire detectors 2, the fire alarm control panel 5 and the fire module 6 are arranged within or in the immediate vicinity of the surveillance area 3.

The fire panel 5 has an output interface 7, which is designed to output the fire detector data B or processed fire alarm data B '. The output interface 7 is signal-connected via a second network 8 to a monitor center 9. The second network 8 may be a public Internet or a private IP network act. In particular, a larger distance, such as greater than 10 km, is bridged by the second network 8.

In the monitor center 9, the fire alarm data B and the processed fire alarm data B '- hereinafter referred to only as fire detector data B.

- evaluated. The evaluation extends in particular to periods in which the fire detectors 2 and / or the fire alarm panel 5 and / or the fire detection module 6 in a normal state / monitoring state, if necessary repair condition, but not in an alarm condition. In particular, fire alarm 2, network 4, fire panel 5 and

Fire detector module 6 in a monitoring state.

In the monitor center 9, the fire data B are evaluated in order to realize a monitoring of an installation and / or maintenance status of the fire detector 2 and / or the fire panel 5 in this way. The

Evaluation can be done for example via statistical methods. In particular, during the evaluation, only slow changes in the fire detector data B are monitored, in particular changes that take place over a period of more than 10 minutes. Such slow changes indicate a change in the installation and / or

Maintenance condition of the components, ie in particular the fire detector 2, the fire alarm panel 5 or the first network 4, back and are not justified in particular by an alarm message or an alarm. The fire detector data B can be divided into three groups:

Environmental sensor data includes data collected by the fire detecting sensors in the fire detectors 2. These are, in particular, measured values of temperature sensors, flue gas sensors, fire gas sensors, smoke gas density sensors or scattered light sensors.

Component state data includes signals for self-monitoring of the components, in particular the fire detector 2. These include, for example, signal voltages at components, in particular at batteries in the fire detectors 2. Operating state data includes logical states of the components, in particular the fire detector 2, in particular with regard to the state monitoring / alarm case / maintenance. Since the evaluation by the monitor center 9 is not time-critical, the second network 8 and the monitor center 9 form a second area II, which must have lower real-time requirements. So it is quite tolerable in the area II that signals are sampled only very slowly, for example, with a sampling frequency less than 0.0001 Hertz, or that delays in the signal transmission of greater than 15 minutes occur.

FIG. 2 shows a possible application of the fire alarm system 1 in the form of a diagram, wherein a time t in months is plotted on the X axis and a signal level I, for example in volts, is plotted on the Y axis.

In the diagram, two limit values G1 and G2 and an interpolated signal curve 10 of fire data B are entered. As can be seen from the diagram, the signal level decreases steadily, but very slowly over the 12 months shown. Such a waveform 10 may represent, for example, a battery voltage at one of the fire detectors 2, which slowly decreases due to the self-discharge of the battery over the period of a year. Alternatively, the waveform 10 may also include a quiescent signal, e.g. represent an optical sensor in the fire detector 2, which steadily decreases due to pollution. In both applications mentioned may indeed be an internal monitoring in the

Fire detector 2 or in the fire panel 5 are realized. Usually, an alarm is then output when falling below the lower limit value G2 and called, for example, a maintenance personnel who cleans the fire detector 2 or exchanges the battery. By monitoring this fire date B in the monitor center 9, however, it is possible to trigger early a "pre-alarm" at a signal level G2 ', the maintenance staff is advised that a maintenance in the near future, for example in the next three months will be necessary , In this case it is possible, for example for a future maintenance interval of three months, to collect all maintenance status messages from all fire detectors 2 and to carry out the corresponding maintenance work in one day. This leads to a significant saving in personnel costs and also to an increase in the availability of the fire alarm system 1.

FIG. 3 shows a second application example for the fire alarm system 1, in which case a 24-hour day is shown on the X-axis. The two dashed lines D1 and D2 indicate a reference signal range over the 24-hour day as recorded in a normal state of the corresponding fire detector 2. For example, the signal curve 12 shown may be the signal level of a temperature sensor or the signal level of a smoke sensor of the fire detector 2. Between 12 o'clock and 15 o'clock, the signal curve 12 exceeds the limiting line D1, so that a fault is detected by the evaluation. Such a fault can - as far as fire alarm 2 and alarm panel 5 are in normal condition - be caused by an unfavorable positioning of the monitored component. For example, it is possible that a temperature sensor is very strongly heated by solar radiation and therefore leaves the tolerance range. In this case, the fault can be evaluated as a failure of an installation state, the maintenance personnel monitored in the next use the relevant fire detector 2 at the specified time to detect in this way early installation errors can.

Another application may rely on the monitoring of error messages of the first network 4 to determine a maintenance status of the first network 4. In this case, for example, the number of error codes is monitored as operating state data in the fire panel 5. With a slow increase in the frequency of the error codes can be concluded on a slowly developing conduction damage or an error at the interfaces of the components and thus to a maintenance condition.

Claims

 claims

1 . Fire alarm system (1) with a plurality of fire detectors (2), with a fire alarm panel (5), wherein the fire alarm panel (5) via a first network (4) with the fire detectors (2) is connected, so that fire detector data (B, B ' ) from the fire detectors (2) to the

 Fire alarm panel (5) can be transmitted, wherein the fire detector (2) and / or the fire panel (5) are designed to issue a fire alarm or is characterized by a monitor center (9) for monitoring an installation and / or maintenance status of the fire alarm (2) and / or the fire panel (5), wherein the monitor center (9) via a second network (8) with the fire panel (5) is connected.

2. Fire alarm system (1) according to claim 1, characterized in that the second network (8) in a connecting portion between the

 Fire alarm panel (2) and the monitor center (9) as one

 Internet connection is formed.

3. Fire alarm system (1) according to claim 1, characterized in that the second network (8) in a connecting portion between the

 Fire panel and the monitor center is designed as a private IP network.

4. Fire alarm system (1) according to any one of the preceding claims, characterized in that the monitor center (9) is arranged decentrally and in particular more than 10 km, preferably more than 50 km and in particular more than 100 km away from the fire panel is arranged.

Fire alarm system (1) according to one of the preceding claims, characterized in that the first network (4) is designed as a safety network.

Fire alarm system (1) according to one of the preceding claims, characterized in that the fire detector data (B, B ')

 Environmental sensor data, component state data, and / or

 Operating state data include.

Fire alarm system (1) according to any one of the preceding claims, characterized in that the fire alarm system (1) is formed that fire detector data (B) or processed fire detector data (Β ') via the fire alarm panel (5) to the monitor center (9) are transmitted.

Fire alarm system (1) according to one of the preceding claims, characterized in that the monitor center (9) is designed to detect slow changes in the fire detector data (B, B '), wherein the fire detector data (B, B') over a period of at least 15 min, preferably over a period of at least a 1 h and

 especially over several days change.

Fire alarm system (1) according to claim 8, characterized in that the monitor center (9) is designed to signal changes with a

 Change frequency less than 0.001 Hz, preferably less than 0.0003 and in particular less than 0.00001 Hz to detect.

0. Fire alarm system (1) according to any one of the preceding claims, characterized in that the monitor center (9) is adapted to compare the temporal signal waveforms of the fire detector data (Β, Β ') with Referenzsignalverläufen.

1 . Fire alarm system (1) according to one of the preceding claims, characterized in that the monitor center (9) is formed, a Contamination of the fire detector (2) to detect as a maintenance condition.

12. Fire alarm system (1) according to one of the preceding claims, characterized in that the monitor center (9) is formed, a

 Incorrect installation of the fire detector (2) to detect as installation condition.

13. fire detection network with a plurality of fire alarm systems (1) according to one of

 preceding claims, characterized in that the

 Fire alarm systems (1) use a common monitor center (9).