EP0345798A1 - Fire alarm system - Google Patents

Abstract

To increase the reliability with respect to false alarms of fire alarm systems, an acoustic sensor (10) is used which outputs electrical signals in dependence on pressure changes in the environment to be monitored and the output signal of which, after amplification, is combined with the output signal, also amplified, of a fire sensor (12). In this arrangement, the sensitivity of the fire detectors (BM) used in the fire alarm system is changed in dependence on the output signal of the acoustic sensor (10), that is to say on the existence of noise sources in the space to be monitored. According to different developments of the fire alarm system according to the invention, the signals can be combined within a fire detector or the signals can be evaluated in a central evaluating unit. <IMAGE>

Description

The invention relates to a fire alarm system according to the preamble of claim 1. Such fire alarm systems are generally known. For example, CH-A-629'905 describes a gas and fire detection system in which fire detectors are connected to a signaling center via lines, the fire detectors having threshold values for the fire phenomena to be detected, and when exceeded, an alarm signal is forwarded to a signaling center.

In the above-mentioned CH-A-629'905 it was proposed that the disadvantage of the previously known fire alarm systems, that the low response thresholds set for security reasons cause an alarm to be triggered even if a fire phenomenon occurs temporarily, which may not be due to a damage fire is to be remedied by the fact that a warning signal occurring in the fire detector when a first threshold value is exceeded is initially not self-sustaining and is brought into latching and forwarding by the signaling center after a predetermined time delay and that an alarm signal occurring after exceeding a second threshold value is immediately latched and is forwarded. This should make it possible to differentiate reliably between briefly occurring, insignificant faults and a real alarm situation. However, this required the intervention of personnel.

In order to be able to reliably detect different types of fire (e.g. low-smoke liquid fires, smoldering fires), e.g. proposed in GB-A-2'043'977 to combine fire sensors which respond to different fire phenomena with one another in an OR circuit. However, this increases the frequency of false alarms considerably.

In order to reduce the susceptibility to false alarms, the fire sensors in such known combined fire detectors were connected by an AND circuit (e.g. CH-A-506'147), which, however, significantly reduced the sensitivity, since an alarm signal is only triggered if both fire conditions occur in sufficient strength. In order to eliminate this disadvantage, it was proposed in CH-A-572'252 to design the evaluation circuit in such a way that, when one sensor is influenced by a fire, the response threshold of the other sensor in the sense of an increase in sensitivity changed. A similar arrangement has been proposed in EP-A-0'076'338.

One way of reducing the false alarm susceptibility of fire detection systems would, of course, be to generally reduce the sensitivity of the fire detectors they contain. However, this is forbidden for the simple reason that there is a danger that the fire detectors would not report a real alarm situation or would report it too late.

The object of the present invention is to provide a fire alarm system which avoids the disadvantages of the known fire alarm systems and which reduces the susceptibility to false alarms of known fire alarm systems, in particular without impairing the security of the detection of real alarm situations.

This object is achieved in a fire alarm system of the type mentioned by the characterizing features of claim 1. Preferred embodiments of the invention and refinements are defined in the dependent claims.

Most disturbance variables that can occur as sources of false alarms are based on human activity, such as tobacco smoking, welding (smoke and sparks), painting (developing solvent vapors), working with steam (moisture), cooking and operating machinery and vehicles (exhaust gases, smoke). Surprisingly, it has now been found that a significant reduction in the false alarm rate is achieved without an increase in the risk that a real alarm situation is not recognized if the sensitivity of the fire detectors is reduced as a function of the presence of people or machines. The presence of people and / or machines can be detected by means of passive infrared detectors or - preferably - by means of acoustic sensors.

The switching elements for linking the output signals of the fire sensors can either be arranged in a fire detector or they can be provided in a signal center. Separate switching devices can also be provided for partial areas, for example larger halls or halls.

The fire alarm system according to the invention has the significant advantage that, in the presence of people, the sensitivity of the fire detectors can be reduced without reducing security, since people can not only be the cause of false alarms, but can also reliably differentiate between disturbance variables and real alarm situations. Since the false alarm rate strongly depends on the response behavior of the fire detectors, a significant reduction in the false alarm rate can be achieved by changing the response behavior.

In the absence of people or the absence of machine noise, the system is automatically switched to a high sensitivity. This will hardly increase the false alarm rate since the main sources of false alarms are not available.

The fire alarm system according to the invention has the further advantage that even static sources of interference as the cause of false alarms can be switched off. By adapting the acoustic sensors to the special sources of interference that may occur in the room to be monitored, it is also possible to reduce the false alarm rate. The output signal of the acoustic sensor can be filtered by frequency analysis and a more reliable decision can be made.

According to a preferred embodiment of the invention, the fire sensor consists of an ionization chamber and the acoustic sensor consists of a microphone.

According to a further embodiment of the invention, the acoustic sensor is structurally connected to the fire detector, wherein it is preferably arranged in the housing of the fire detector, in its base or on one of these parts.

According to a further embodiment of the invention, the acoustic sensor is arranged spatially separate from the fire detector, an acoustic sensor being provided for controlling the sensitivity of one or more fire detectors. Conversely, the fire detection system can also be designed in such a way that several acoustic sensors are provided for controlling the sensitivity of a fire detector, it also being possible for several acoustic sensors to control a group of fire detectors.

According to further embodiments of the invention, the switching elements for changing the sensitivity of the fire detector are designed such that either the output signal of the fire detector is influenced or that the response threshold of the threshold value detector is changed. The switching elements for changing the sensitivity of the fire detectors can preferably be designed such that, after a fire detector has responded, all fire detectors of the same group are switched to full sensitivity.

Exemplary embodiments of the invention are explained in more detail below with reference to the drawing. The figure shows a block diagram of the circuit of a fire alarm system according to the invention.

The fire alarm system consists of an ionization fire detector BM, an acoustic sensor 10 and a signaling center SZ connected to the fire detector BM via lines. In this example, the fire sensor works according to the ionization principle, and a microphone is used as the acoustic sensor 10. The sensor of the Ionisatios smoke detector BM consists of a measuring chamber KM, in which the air is made electrically conductive (ionized) by a radiation source. The measuring chamber KM is connected in series with a reference chamber KR and both chambers form a voltage divider which is connected to the operating voltage UB via the matching resistor 9. The reference chamber KR is closed, while the measuring chamber KM is accessible to the room air to be monitored. The connection point VP of the voltage divider is connected to an impedance converter 1, the output signal of which is fed to the threshold value detector 2. The threshold detector 2 in turn is functionally connected to a flip-flop 3, which may generate an alarm signal.

If fire aerosols (combustion products) penetrate the measuring chamber KM, the chamber flow is reduced. The internal resistance of the measuring chamber KM increases, which causes a shift in the voltage at the connection point VP. If this voltage shift exceeds a predetermined threshold value, the flip-flop 3 is activated via a first impedance converter 1 and the threshold value detector 2, whereby an alarm is triggered.

An acoustic is used to control the sensitivity of the fire detector BM Sensor 10, the output signal of which is amplified by a second impedance converter 11 and fed to the threshold value detector 2. The threshold value detector 2 is designed in such a way that it raises the response threshold for triggering an alarm when the output signal of the second impedance converter 11 connected to the acoustic sensor 11 exceeds a certain value, that is to say the occurrence of a disturbance variable, for example the presence of a person or the switching on of a person Machine or the like.

An electrical function control and a check of the response sensitivity of the fire detector BM is possible via the measuring point MP3. With a special measuring device, the voltage between the measuring points MP1 and MP3 can be measured via the matching resistor 9. By changing the resistance value of the matching resistor 9, a change in the voltage at the connection point of the chambers KM, KR can be achieved, as a result of which the electrical sensitivity of the fire detector BM is changed. This makes it possible to adapt the response sensitivity of the BM fire detectors to special environmental conditions such as the presence of people, vehicle traffic, etc.

An embodiment of a fire detection system according to the invention has been described above, in which the signals from the fire sensor KM and the acoustic sensor 10 are linked in switching elements which are arranged in the fire detector BM. The acoustic sensor 10 can be integrated in the fire detector BM, or it can be spatially separated from the fire detector (s).

Not shown in the figure is a further design option for the fire alarm system according to the invention, in which the output signals of the fire detectors BM and the acoustic sensors 10 are linked in the signal center.

Modifications of the above-described circuits for fire alarm systems are possible within the scope of the invention according to the claims and are familiar to the person skilled in the art.

Reference numerals

• 1 First impedance converter
• 2 threshold detector
• 3 toggle switch
• 9 decoupling resistor
• 10 Acoustic sensor
• 11 Second impedance converter
• BM fire detector
• KM fire sensor = measuring chamber
• KR reference chamber
• MP1 measuring point
• MP2 measuring point
• UB operating voltage
• VP connection point

Claims (10)

1. Fire alarm system, which consists of at least one fire detector (BM), a signaling center (SZ) and lines that connect the fire detectors (BM) to the signaling center (SZ), with the fire detector (BM) depending on the fire phenomena that occur an electrical signal emitting fire sensor (12) is provided and furthermore an electrical evaluation circuit comprising a threshold value detector (2) is provided, which emits an alarm signal when a predetermined threshold value of the fire sensor output signal is exceeded, characterized in that at least one electrical signal depends on pressure changes in the environment Signals-emitting acoustic sensor (10) is provided, the output signal after amplification in an impedance converter (11) is fed to the evaluation circuit and that switching elements (2) are provided in the evaluation circuit, which the sensitivity of the fire detector (BM) depending on the output signal of the acoustis Chen sensor (10) change. 2. Fire alarm system according to claim 1, characterized in that the acoustic sensor (10) is structurally connected to the fire detector (BM). 3. Fire alarm system according to claim 1, characterized in that the acoustic sensor (10) is arranged spatially separate from the fire detector and that an acoustic sensor (10) with several fire detectors (BM) is functionally connected. 4. Fire alarm system according to claim 1, characterized in that the acoustic sensor (10) is spatially separate from the fire detector (BM) and that several acoustic sensors (10) are functionally connected to at least one fire detector (BM) and control its sensitivity. 5. Fire alarm system according to one of the claims 1 to 4, characterized in that the switching elements (2), which change the sensitivity of the fire detector (BM), are arranged in the signal center (SZ). 6. Fire alarm system according to one of the claims 1 to 5, characterized in that the switching elements (2) for changing the sensitivity of the fire detector (BM) are designed so that the output signal of the fire sensor (12) is influenced. 7. Fire alarm system according to one of the claims 1 to 5, characterized in that the switching elements (2) for changing the sensitivity of the fire detector (BM) are designed so that the response threshold of the threshold detector (2) is changed. 8. Fire alarm system according to one of claims 1 to 7, characterized in that the fire sensor is an optical smoke sensor, preferably a scattered light smoke sensor. 9. Fire alarm system according to one of the claims 1 to 7, characterized in that the fire sensor is an ionization smoke sensor (12). 10. Fire alarm system according to one of the claims 1 to 7, characterized in that the fire sensor is a heat detector.

Images