EP1389331A1

EP1389331A1 - Self-aspirating fire detection system

Info

Publication number: EP1389331A1
Application number: EP02737792A
Authority: EP
Inventors: Michael Spohn; Hauke Dittmer; Kurt Lenkeit
Original assignee: Minimax GmbH and Co KG; Preussag AG Minimax
Current assignee: Minimax GmbH and Co KG
Priority date: 2001-05-23
Filing date: 2002-04-15
Publication date: 2004-02-18
Anticipated expiration: 2022-04-15
Also published as: WO2002095705B1; WO2002095705A1; CN1462418A; DE50202632D1; EP1389331B1; ES2239232T3; ATE292316T1; DE10124280A1

Abstract

The invention relates to a self-aspirating fire detection system and to a method for operating the same, by means of an aspirating device (1, 3, 10) for controllable aspiration of ambient air from a supervised area. Said fire detection system includes a high-sensitive optical scattered light measuring system (2, 16), with a high-energy light source (4) and one or several receiver elements (6, 8), for detecting an optical radiation, scattered on smoke particles, located in the measuring area, in one or several angles of dispersion. The receiver elements (6, 8) of the scattered light measuring system (2, 16) are connected to a microcontroller system (13) and/or a central fire alarm system (15) for data analysis and storage. According to the invention, one or several gas detectors (9) and/or a gas detector array (9) are also arranged in the fire detection system, said detectors detecting at least one fire gas type, and connected to the central or local microcontroller system (13) and/or to the central fire alarm system (15) for signal evaluation.

Description

Self-priming fire alarm system

The invention relates to a self-priming fire alarm device for monitoring technical systems, buildings and storage areas for the occurrence of fires according to the preamble of claim 1.

Self-priming fire alarm systems are to be understood as fire alarm systems that have one or more suction pipes, the suction openings of which take air samples from the area of the system or room to be monitored and feed the fire detection detectors to measure different fire parameters.

Fans or fans are often used as suction means for generating a continuous air flow from the monitoring area, but piston or diaphragm pumps are also used in various ways.

Self-priming systems are used to advantage if only a low thermal develops during a smoldering fire and smoke particles only very slowly reach the detection area of the fire detectors, which are often located at greater distances.

This is particularly the case in larger rooms and storage areas. In air-conditioned and forced-ventilation rooms where some changing air currents and strong dilution effects, self-priming systems of higher sensitivity can be used very advantageously for early detection.

In conventional systems without self-priming, an alarm message would be triggered at a very late point in time and the subsequent fire-fighting measures would be delayed. which can result in considerably higher damage to property and personal injury than would be the case if the alarm was triggered earlier.

In air-conditioned and forced-ventilation systems where thermal convection can hardly develop during the development phase of a fire due to changing air flow conditions, early detection is hardly possible with systems without suction.

Another advantage of self-priming systems is that the suction openings can be located within certain areas of the system at risk, such as the housing of an electrical control cabinet or an EDP system, so that the air samples are more specific directly from the hazardous area

Plant objects can be removed and recorded together.

Emerging fires in plant areas can be detected early and suitable countermeasures taken.

Depending on value concentration, fire risk and overall

Fire protection concept come with a particular economic importance

Early fire detection, usually only highly sensitive detectors for self-priming systems

Commitment.

Optical scattered light measuring systems as highly sensitive detectors have proven to be well suited, smoke particles products of thermal decomposition,

To detect soot or floating particles) even in the smallest amounts.

Such known systems are available in numerous variants and mostly use an LED or a laser diode as a scattered light source. The light beams emitted by the light source pass through a measuring section through a sample volume and are scattered on existing smoke particles. The inhomogeneously distributed scattered light is then one or more

Receiving elements (photoelectric detectors) in a measurable electrical

Signals converted.

The intensity of the scattering angle of the scattered light is u. a. depends on the

Size and shape, as well as the optical properties of the im

Sample volume of existing smoke particles.

From the analysis of the signals of the arranged in different scattering angles

Receiving elements can draw conclusions about the number and in the

Air sample volume pull existing particles.

Recent developments for the detection of even the smallest quantities of smoke aerosols in an aspirated sample volume are increasingly relying on highly sensitive and more precise laser-based measuring systems.

High-energy laser radiation has the advantage of striking

Smoke particles to deliver higher and thus more detectable scattered light intensities.

Due to the spectral narrow band of the laser, the uniqueness is more resultant

Measured values given in relation to the underlying scattered light theory.

This often involves considerable design effort for optimal coupling of the

Laser measuring system operated with the air sample chamber and the gas supply.

A disadvantage of highly sensitive systems is the risk of false alarms due to the unexpected occurrence of irrelevant fire parameters

(e.g. cigarette smoke) or the effects of disturbance or deceptive variables such as fine dust or

Water vapor on the detectors.

In principle, it is often difficult for the detector systems to distinguish certain disturbance variables or non-relevant particles for fire detection in the measurement volume from smoke particles to be detected.

Therefore, there are numerous in fire protection technology Efforts have been made to distinguish fire parameters from disturbance or deceptive variables in order to rule out false alarms as far as possible.

Optical stray light measuring systems can be used without additional measures particularly advantageously where there is only a small amount of interference or

Deceptive variables can be expected.

These are in particular air-conditioning and clean room areas, IT systems,

Production facilities of semiconductor and biotechnology as well

Telephone and communication facilities.

From what has been said it becomes clear that the demand for ever more sensitive

Detector systems for the early detection of fires contradict the growing influence of disturbance and deception variables.

DE19605637 C1 describes a method for air flow monitoring and a

Device for detecting fires according to the principle of

Air sample suction described.

Representative partial quantities are taken from the ambient air or cooling air of a hazardous area to be monitored via two intake pipe systems and fed to a detector for recognizing a fire parameter.

An important prerequisite for the early detection of fires is the detection of undesirable faults in the intake system, for example due to blockages in the intake openings or breaks in the intake pipe system.

The continuous supply of a defined volume of air plays a role

Detector chamber plays an important role.

To solve this problem, the use of an air flow sensor is proposed for each of the two intake lines, the output signals of which are compared and used to monitor the air flow. As a further measure for the reliable detection of a fire parameter, the possible arrangement of a second detector in a second detector chamber of the fire detector is proposed.

However, no further details on their type or use are given.

Most of the developments of self-priming fire alarm systems that have become known have set themselves the goal of achieving reliable early detection of fires as early as the development phase.

For this, numerous improvements in the intake systems or in the sensitivity (response threshold) of the (optical) used

Detectors proposed.

In order to achieve an improvement in the sensitivity of detector systems and to keep the influence of disturbance or deceptive variables small, various proposals have been made.

So is known from DE4231088 A1 fire alarm system, one after the

Scattered light principle includes smoke detector, the stray light receiver can be positioned at different scattering angles.

In order to obtain a more precise picture of the particles in the sample volume, it is proposed that the optical scattered light measuring system be additionally equipped with a

Equip polarization filters and determine the degree of polarization of the scattered light.

A definite type of smoke can then be concluded from the clear correlation between the degree of polarization and the scattering angle.

Experimental tests with test fires revealed different patterns of

Types of smoke with threshold values are stored in databases, which are then linked to the

Results of the scattered light and polarization measurement can be compared.

The comparison of both smoke patterns should then provide information on the type of fire result.

Even with this known fire prevention device, no information can be found on the reliable differentiation between disturbance and deception variables that are always present and the smoke particles that appear as a fire parameter.

The object of the present invention is therefore derived from the known disadvantages of the prior art to provide a fire alarm device which detects the occurrence of fire at an early stage and is nevertheless able to deal with the occurrence of disturbance or deceptive variables and for the development of the fire and the course of the fire relevant

Differentiate fire parameters safely.

Furthermore, the fire alarm device according to the invention should be able to generate various alarm levels in accordance with the fire development, which permits the use of graduated flexible fire-fighting measures.

The aim is to minimize the frequency of false alarms while increasing the

Sensitivity of the system can be achieved.

This object is achieved by the characterizing features of the first claim.

Further advantageous refinements of the invention are specified in the subclaims.

According to the invention, a highly sensitive optical is proposed

Scattered light measuring system by additional arrangement of one or more

To add gas sensors or a gas sensor array, and the measured variables of the individual detectors to a logical

Link alarm level generation.

Both the optical stray light measuring system and the gas sensors connected to a microcontroller system and / or a fire alarm system.

The invention also relates to a method for operating this fire detection device, which is characterized by the formation of a sum signal from the measured variables detected in different scattering angles of the optical scattered light measuring system and the measured variables detected by the additionally arranged gas sensors and / or the gas sensor array.

In a particularly advantageous embodiment of the invention, the receiving elements of the scattered light measuring system are arranged in the forward and backward scattering directions and their signal processing is designed in such a way that parameters, such as particle color, size and concentration, are characteristic of the particles in a defined sample volume by the simultaneous detection of the forward and backscatter angle ranges of detected signals can be determined.

The simultaneous detection and processing of the light beams scattered at different angles is particularly important with the measuring system receiver-microcontroller system.

Only through the simultaneous recording and processing of the received

Scattered light signals from the different scattered light angles allow a precise description of the particle distribution in the sample volume at a certain point in time, since the sample volume is not a static variable, but rather its parameters depend on the

Constantly change the flow rate of the suction device.

In a further advantageous embodiment of the invention, fire detectors of various types, such as temperature detectors or ionization smoke detectors, can also be used in the self-priming device according to the invention Fire alarm device arranged and connected to the microcontroller system and / or the fire alarm control center. In addition to the preferred arrangement of these detectors and also the gas sensors directly in the intake flow of the intake device, their arrangement in a bypass to the intake pipe is also possible.

According to the invention, the measurement quantities determined by the latter fire detectors in the sample volume are also included in the signal processing of the fire detection device and are weighted accordingly using evaluation algorithms stored in a database.

The inventive arrangement of a highly sensitive optical

Scattered light measuring system for the detection of smoke particles from a fire in combination with

Gas sensors and / or a gas sensor array in a fire alarm device for

Detection of fire gases and / or fire load-specific gases has numerous advantages over the known prior art.

Increased in an advanced fire phase with increasing temperature

Emissions from full combustion products, such as CO2 and H2O, as well

Soot particles and smoke aerosols on The smoke particles of different sizes and

Distribution can be detected very precisely with the highly sensitive scattered light measuring system.

In contrast, gas sensors not only enable additional early detection

Detection of a fire development parameter but also the checking and weighting of the measurement results of the

Scattered light system through the measured variables of the gas sensors or the

Gas sensor arrays.

As is generally known, the additionally arranged gas sensors are particularly well suited, Reliably detect fire gases arising at the start of a fire, such as CO H2, CH4, as well as longer-chain saturated and unsaturated hydrocarbons and sulfur compounds. By linking and logically processing the respective fire parameters, a safe alarm is possible earlier than with the previously known self-priming systems. However, an alarm is only given and in different presettable stages when the signal evaluation of the optical scattered light measuring system reaches or exceeds certain threshold values and at the same time the gas sensor (s) detect fire gases.

A broadband gas analysis of the aspirated air samples is possible by using several sensors that detect different types of gas or a sensor array.

A further improvement in gas detection is possible by knowing the type of fire or smoldering gas to be expected from the surveillance area.

The most common cause of fires in cable ducts or other cavities and gaps between devices and systems are the electrical cables, connections and connections that run through them.

The mostly narrowly limited overheating can lead to smoldering fires, in which material-specific, gaseous products (pyrolysis gases) such as HCL are released in different concentrations.

The gas sensors to be provided for use in the fire alarm device can then be selected from a large number of different measuring cells (gas sensors) depending on the gases to be detected and allow the detection of very low gas concentrations in the ppb-

Area.

As with smoke particle detection using the optical scattered light measuring system, appropriate fire patterns are determined in the gas sensor system (test fires) and stored electronically. The databases obtained in this way are implemented, for example, in the memory area of the microcontroller system and are available from the currently determined one

Measured variables are available as comparison data.

The comparison and the weighting of the measured variables determined by the different fire detectors of the fire detection device according to the invention therefore enables early and reliable fire detection.

False alarms due to disturbance or deceptive variables can largely be excluded.

Will the data of the fire detection device or several such

Facilities by a central monitor unit, preferably one

Fire alarm center processed, it is through cyclical queries of the individual

Fire detectors also make it possible to characterize the course of the fire more precisely in terms of time and to carry out a fire course analysis.

This can then be used very useful for initiating countermeasures and graded according to the degree of risk

Warning times serve.

It is also within the scope of the invention to operate the fire alarm device described without self-priming.

So it is quite possible to arrange the fire alarm device according to the invention in a ventilation shaft or the like in which an air flow flows at a certain speed.

Sampling can then take place e.g. B. through appropriately dimensioned openings in the housing of the fire detection device.

Further details of the invention will now be made with reference to drawings and one

Embodiment will be explained.

Show it :

Fig. 1, the fire detection device according to the invention with an intake pipe, Fig. 2 is a flow chart for signal processing of the scattered light measuring system and additionally arranged detectors, Fig. 3 is a block diagram of the individual system components of the fire alarm device

1 shows the fire alarm device 2 according to the invention, which is connected via the intake pipe 1 to the area of the plant or room which is to be monitored for a possible fire.

In a further embodiment, a plurality of suction pipes with a plurality of suction openings can also be arranged, or the suction pipes can be designed as flexible hoses, the openings of which suck air even from system areas which are difficult to access.

The air samples are sucked in continuously by means of a suction fan 3 with an adjustable constant flow rate and the measuring chamber

(Sample volume) of the fire alarm device 2 supplied.

Taking into account the permissible maximum transport times, this can

Intake pipe network can be designed for lengths of up to 200 m, for example.

With the air flow sensor 10, the flow rate of the intake

Air measured and compared with the setpoint.

A fault message is triggered in the event of impermissible deviations.

Light source 4, receiver elements 6, 8 and focusing optics 5, 7 are each separated from the sample volume of the aspirated flue gas by plexiglass shields (not shown).

The so-called bypass technique can also be used for areas of application with higher air speeds, such as exhaust air and air conditioning ducts. Air samples are constantly taken from the channel to be monitored via a pipe system and passed through the measuring chamber of the scattered light measuring system, where the gas sensors 9 can also be arranged. In the standard measuring setup shown in Fig. 1, this is highly sensitive

Smoke particle measuring system 16 (FIG. 2) arranged at right angles to the air flow and shielded by the plexiglass panes mentioned.

It consists of a high-energy sheep-light source, preferably a laser diode 4 with collimation optics to generate scattered light intensities

Smoke particles in the collision focus, plus an opposite one

Beam trap that absorbs the laser beam, as well as a collection and

Focusing optics 5.7, which the scattered light of the assigned

Solid angle segments on the respective receiving elements 6,8 (optical

Map detectors).

For the precise analysis, the detection volume is to be kept as small as possible and is essentially determined by the intersection volume of the focal points of the

Lens systems with the diameter of the laser beam in its collimation

Focus.

The receiving elements 6, 8 and the collecting and focusing optics 5, 7 are arranged in such a way that the scattered light beams are detected from the solid angle segments of the forward direction and the backward direction.

The forward and backward scattered light then generates in the receiver elements an electrical signal proportional to the received scattered light intensity which is processed and stored in the connected microcontroller system 13 and / or a fire alarm control panel 15.

The measured values obtained according to this measuring principle are in relation to

Smoke particle concentration, but also particle properties such as shape, color and

Size.

In an advantageous embodiment of the fire detection system, the high-energy light source (for example laser diode) is controlled with a pulsed driver circuit, which increases the service life of the light source many times over. The modulated light pulses can only be triggered by the control electronics 13 if a new scattered light measurement is to take place.

According to the invention, one or more gas sensors 9 or one of several

Existing gas sensor array arranged in the intake flow or a bypass and connected to the microcontroller system 13 and / or the fire control center 15 via signal lines.

Different gas detectors or a gas sensor array can be used and different ones, which characterize an early fire development phase

Detect fire gases.

These are, in particular, the gases that are produced at an early stage, such as CO, H2, CH4, and longer-chain saturated and unsaturated hydrocarbons and

Sulfur compounds, but also fire-specific gases (e.g. HCL), such as those used in thermal

Decomposition of PVC can be reliably detected by using special gas sensors.

The logical processing and linking of the scattered light signals with the

The intelligent sensor according to the invention allows measurement variables of the gas sensor system

Fire detection.

According to the invention, it is also possible for signal processing of the scattered light and other detector signals and, depending on the analysis criteria used, to use one or more microprocessors as decentralized computing units.

2 shows the individual process steps for signal processing of the fire detection device.

According to the Mie scattered light theory to be applied to the scattered light measuring system, the direction and intensity of the light scattered on a particle depend on its shape, color, and size as well as the light wavelength.

Are light wavelength, optical power and the scattering angle through appropriate arrangement of the receiving elements known and if the measured scattered light intensity is logically linked, conclusions can be drawn about the properties and distribution (concentration) of the

Draw smoke particles in the sample volume.

Even more precise statements can be obtained by measuring the scattered light intensity of more than two scattering angles 17, 18, 19.

According to the invention, the simultaneous measurement and evaluation of the in

Light portion 17 scattered in the forward direction with that scattered in the backward direction

Light portion 18 a statement that can be used for fire determination.

In the specified version, practical values have been found for the

Scattering angle segments for the respective measuring channel in the forward direction about 20 ° +/-

4 ° and in the reverse direction 160 ° +/- 4 °.

Further scattered light detectors (receiving elements) are preferably arranged in the angular range between 5 ° and 45 ° affected by strong changes in the intensity.

Then one or more intensity indicators can be determined from vector sums of the angle-dependent scattered light intensities and one or more particle property indicators from the logarithmic ones

Determine ratios of the angle-dependent scattered light intensities.

After the values of individual scattered light intensities have been recorded from the different solid angles 17, 18, 19, they are used in the next process step

20 normalized to a property vector (classification e.g. according to size, color and refractive index). Comparative data of permitted determined smoke properties are stored in the smoke aerosol database 21.

The property vector obtained from 20 and the comparison data stored in FIG. 21 are then linked 22 to form the smoke identity number.

The smoke scattered light intensity of the highly sensitive measuring circuit 23 is then in

Method step 27 is evaluated with the measured variables determined by the gas sensor 24. In addition, the measurement variables of an optional smoke sensor (ionization smoke elder or optical smoke detector) 25 and / or an optional temperature detector 26 can also be included in the evaluation. The evaluation of the individual measured variables and the mutual dependency takes place with the aid of algorithms and comparative analyzes, which use data from test fires in a database 28.

The further method then provides for the comparison of the sum signal obtained from method step 27 with pre-parameterized threshold values and, with corresponding comparison results, leads to activation and display of assigned alarm stages 29.

In addition, the optional individual display or individual control 30 from

Alarm levels of individual parameters can be provided in comparison with the assigned individual threshold value.

For example, a CO alarm can be triggered when a

Maximum concentration irrespective of other measured variables.

An optional individual display or can also be used for the scatter light measuring system 16

Individual control of alarm levels can be provided.

Fig. 3 shows the block diagram of the system components of the invention

Fire detection means.

The two highly sensitive measuring circuits 32 and 33 each process those of

Receiving elements 6.8 delivered scatter signals.

The laser diode as the light source is driven in pulse form by a laser driver circuit 34, the pulses being supplied by the microcontroller system 13.

The diode laser is advantageously only operated at the time of measurement, which leads to a multiplication of the laser life.

The gas sensor system 35 and the optional temperature detector 37 are also via one A / D converter connected to the microcontroller system 13. Of particular importance are the sample-and-hold circuit 36, which enables the scattered light measured values to be detected simultaneously by the trigger pulses of the microcontroller system.

As a result, according to the invention, more precise information about the concentration and properties of the smoke aerosols contained in the sample volume can be achieved, and in particular statistical statements about the occurrence behavior of certain particle property indicators enable good selection for further processing.

The microcontroller system 13 performs the analysis algorithms and evaluates gas and stray light measuring circuits, stores data and events, controls event-related displays and peripheral units, carries out communication with connectable peripherals 38 and compensates for environmental aerosol background drift of the sensitive stray light circles.

LIST OF REFERENCE NUMBERS

1 suction device with suction pipe

2 fire alarm devices

3 intake fans

4 high-energy narrow-band light source (e.g. laser diode)

5 collecting and focusing optics for the first stray light measuring circuit

6 receiving element (detector) for the first scattering angle

7 Collecting and focusing optics for the second stray light measuring circuit

8 receiving element (detector) for the second scattering angle

9 gas sensor or sensor array

10 air flow sensor

11 temperature detectors or heat sensors

12 ionization smoke detectors or optical smoke detectors

13 microcontroller system (for measurement control, data analysis and storage)

14 display and control modules (relays, LCD, LEDs)

15 fire alarm control center (building management system, control center PC)

Explanation of the reference numerals for the signal processing flow diagram of the fire detection device

16 Highly sensitive smoke particle scattered light measuring system 7 Scattered light intensity from scattering angle α1

18 scattered light intensity from scattering angle α2

19 Scattered light intensity from scatter angle on

20 Standardization of the values for the property vector

21 Smoke particle database (comparison data of permitted smoke properties determined) 2 Processing of the property vector by 21 and temporal occurrence behavior to smoke intensity key figure 23 Smoke scattered light intensity of the highly sensitive measuring circuit 16

24 gas sensor (fire gas sensor) or sensor array (e.g. CO sensor)

25 Optional smoke detector (ionization smoke detector, optical smoke detector)

26 Optional temperature detector (temperature sensor)

27 Evaluation of the intensities of scattered light and gas sensors for the sum signal by means of 29 and temporal correlation, optionally the measured variables of the temperature detector (26) and the smoke detector (25) are also included.

28 evaluation algorithms from database of test fires

29 Comparison of the sum signal with pre-parameterized threshold values, activation and display of assigned alarm levels

30 Optional individual display or control of alarm levels of individual parameters from the comparison with the individual threshold value

31 Optional individual display or control of alarm levels of the highly sensitive scattered light measuring system for early warning

Explanation of reference symbols for the block diagram Fig. 3 system components

32 Highly sensitive measuring circuit, forward scattering angle range

33 Highly sensitive measuring circuit, reverse scattering angle range

34 Laser driver circuit, operated by μP pulse only at the measuring time

35 Measuring circuit for gas sensors 6 Sample and hold circuits 7 Optional temperature and / or smoke sensor measuring circuit 8 Peripheral configuration and control units

(Configuration and monitoring PC, fire alarm and extinguishing control centers)

Claims

claims

ή. Self-priming fire alarm system for monitoring fire and / or explosion-prone systems and buildings, comprising a suction system (1, 3, 10) for controllable suction of ambient air from the surveillance area, a highly sensitive optical scattered light measuring system (2,16) with a high-energy light source (4) and one or more receiving elements (6, 8) for the detection of optical radiation scattered in one or more scattering angles on the smoke particles located in the measuring range, the receiving elements (6, 8) of the scattered light measuring system (2) having a microcontroller system (13) and / or a fire alarm center (15) for data analysis and storage, characterized in that in addition one or more gas sensors (9) and / or a gas sensor array (9) are arranged which detect at least one type of fire gas and also signal technology with the central or decentralized Microcontroller system (13) and / or the fire signaling center (15) are connected for signal evaluation.

2. Brandmeldeeinrichtüng according to claim 1, characterized in that the gas sensor (s) (9) in the air flow of the intake pipe (1) or in one

Bypass are arranged and as an electrochemical gas sensor, semiconductor gas sensor, ion mobility spectrometer or heat tone sensor for the detection of

Fire gases such as CO, H2, CH4, as well as long-chain saturated and unsaturated

Hydrocarbon and sulfur compounds or fire load specific gases like

HCL are formed, wherein they have different measuring ranges for different and / or the same gas types.

3. Brandmeldeeinrichtüng according to claim 1, characterized in that the optical scattered light measuring system (2) has at least two receiving elements (6,8), which are arranged to the measuring volume of the sample stream from the suction pipe (1) such that the optical radiation scattered on the smoke particles can be detected simultaneously in a forward scattering angle range and a backward scattering angle range and the measured values obtained in parallel can be processed in the microcontroller system (13) or a fire alarm control panel (15) to form a measurement variable characterizing the aerosols in the measurement volume.

4. Fire alarm device according to claim 3, characterized in that further fire detectors (11, 12) operating according to different measurement principles are arranged, such as ionization smoke detectors (12) or optical smoke detectors (preferably different wavelengths, sensitivity ranges or measurement principles than the sensitive scattered light system) (12) and / or temperature detectors (11), which are also connected in terms of signal technology to the microcontroller system (13) and / or the fire alarm center (15) for evaluating the measurement signals determined in the sample volume.

5. A method of operating a fire alarm device according to one of claims 1 to 4, characterized in that the scattered light signals generated by the individual on the scattered light receivers (17, 18, 19) of the scattered light measuring system (16) are transmitted to the microcontroller system (13) and a simultaneous joint processing of the measured values supplied by one or more additional gas sensors (9) or a sensor array and likewise transmitted to the microcontroller (13) takes place to form a sum signal (27), and then a comparison of the sum signal generated in this way with pre-parameterized stored threshold values (29) and the results of the comparison form the basis for the decision to trigger alarm signals and / or alarm levels.

6. The method according to claim 5, characterized in that also generated by the additionally arranged fire detectors (11, 12), such as the ionization smoke detector (12) and / or the temperature detector (11)

Measured variables are included in the evaluation of the sum signal (27)

7. The method according to claim 6, characterized in that for the evaluation of the different additionally arranged

Fire detectors (14, 24, 25, 26) are supplied by comparing evaluation operators stored in a database (28).

8. The method according to any one of claims 5 to 7, characterized in that the selection of the alarm levels to be controlled by the or the measured variables of the individual fire detectors (11, 12, 24, 25, 26), the sum signal of the scattered light measuring system (13) and the total signal ( 27) and can be set depending on the local conditions of the surveillance area or the specific application.

9. The method according to claim 8, characterized in that the evaluation of the measured variables of the individual detectors links to a fire course analysis and their results, e.g. at (15.38).