DE2519267A1 - FIRE ALARM - Google Patents

Description

PATENT LAWYERS

Dr.-lng. Wolff
H. Bartels

Dipl.-Chem. Dr. Brandes Dr.-lng. hero
Dipl.-Phys. Wolff

2513267

D- 7 Stuttgart 1, Lange Strasse 51

Tel. (0711) 29 6310 and 29 72 95

Telex 07 22312 (patwod)

Telegram address:

tlx 07 22312 Wolff Stuttgart

PA Dr. Brandes: Headquarters Munich postal check account Stgt. 7211-700 Deutsche Bank AG, Stuttgart. 14/28630

Registration number. 124 657 - _{Office time:}

- - 9-11.30 a.m., 1.30 p.m.-4 p.m.

except saturdays

24.4.1975 / 3322 imn

Nohmi Bosai Kogyo Co. Ltd., Noi. 7-3, Kudan Minami 4-chome Chiyoda-ku, Tokyo (Japan)

Fire alarm

Addition to patent ... (patent application P 24 52 839.0)

Information and orders over the phone are only binding after 609810/0557 written confirmation

The invention relates to a fire alarm with at least two sensors which react to various fire phenomena and a common sensor Evaluation circuit for evaluating changes in the properties of the sensors and for generating an alarm, which occurs when the one sensor due to a fire phenomenon, the response wave of the other sensor for the alarm signaling in the sense of an increase in sensitivity changes, according to patent ... (patent application P 24 52 839.0).

Such fire alarms take advantage of the fact that in one Fire practically always several fire phenomena occur at the same time, e.g. smoke, flame radiation, combustion gases or temperature increase. Such fire detectors are therefore able to differentiate a real fire from disturbance variables better than before, v / which happen to have an effect similar to one of the fire phenomena.

On the other hand, the automatic sensitivity increase of a sensor when influencing another sensor achieved by a fire phenomenon that such a fire detector responds to almost all types of fire, even if one of the evaluated Fire phenomena appears only very weakly and the threshold value provided for a single fire phenomenon does not exceed. This ensures improved security of the alarm signaling.

In one embodiment of the main patent, the evaluation circuit set up so that it only emits an alarm signal if the sum of the output signals of both sensors is a exceeds the specified value, but the alarm threshold is selected to be higher than each possible individual signal of the individual Sensor. It has been found to be disadvantageous that such a fire alarm only responds if the second one also responds Fire phenomenon exceeds a certain, albeit lower, threshold. It is therefore possible that with certain extraordinary Types of fire, e.g. in the case of completely smokeless liquid fires, no alarm signal is given.

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- * - 25 1326? • J.

The invention is based on the object of a fire alarm to improve according to the main patent to the effect that the disadvantages described are avoided, including such Fire types in which one of the evaluated fire phenomena is only extremely weak, with certainty an alarm signal is given.

This object is achieved in that the evaluation circuit is set up to trigger an alarm signal when the product the sensor output signals exceed a specified value.

In the following the invention is illustrated with reference to in the drawing Embodiments explained in detail. Show it:

Fig. 1 shows the circuit diagram of a first embodiment ;

Fig. 2 is a diagram for explaining the mode of operation of this embodiment;

3 shows the circuit of a second embodiment.

The fire alarm according to FIG. 1 has a smoke sensor A, which works according to the scattered light principle, as well as a temperature sensor B for the rate of temperature rise, a multiplication circuit C, which is the product of the output signals from sensors A and B, and a circuit S.

In the smoke sensor A there is a light source L, which is connected in parallel with a Zener diode ZDl via a resistor Rl between connections a and b, which in turn are connected to the two poles of a voltage source E in a signal center Re, and an amplifier AmI for amplifying the output signal a selenium photocell Ce is provided, which picks up the light scattered on smoke particles from the light source L. A controllable resistor VR _{A is} connected to the amplifier output, from which the output voltage VA is taken and the multiplier

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cation circuit C is supplied directly.

A thermistor TH1 with a small thermal time constant is provided in the temperature sensor B and, for this purpose, a further thermistor TH2 with a large thermal time constant is provided in series between connections a and b. A transistor T, the base of which is connected to the connection point of the two thermistors, is also connected to the connections a and b via a resistor R2. In parallel with this resistor R2 are a Zener diode ZD2 and a controllable resistor VR _ßS in series from which the output voltage VB is taken and the multiplication circuit C is also fed.

A thermistor TH1 with a small thermal time constant is provided in the temperature sensor B and, for this purpose, a further thermistor TH2 with a large thermal time constant is provided in series between the connections a and b. A transistor T ₉ whose base is connected to the junction point of both thermistors is also connected to terminals a and b via a resistor R2. A Zener diode ZD2 and an adjustable resistor VRg _{9 are connected in parallel to this resistor R2} from which the output voltage VB is taken and also fed to the multiplication circuit C.

Both output voltages VA and VB are fed to an analog multiplier Am2 of the multiplication circuit C. On one at the output of the multiplier / connected resistor R3 there is thus a product of the two sensor output voltages

VA and VB corresponding output voltage VC, which the-

Circuit S is supplied. When this output voltage VC exceeds a specified value, the circuit is actuated, and a signal relay N in the signal center responds.

In the diagram shown in Fig. 2, the mode of operation of this fire detector with evaluation of the product of the sensor signals compared to a fire detector with evaluation of the

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Sum of the output signals explained. The two coordinate axes are assigned to the output voltages VA and VB of both sensors. The abscissa is therefore the smoke density, and the ordinate the rate of temperature rise is given.

The hatched area 1 between the ordinate and the straight line oa through the origin ο represents an area which normally does not correspond to a real fire, but, for example, the effect of heating devices, etc. The area 2, also shown hatched between the The abscissa and the straight line ob also correspond to a range in which normally no fire occurs, but for example Cigarette smoke. The area 3 between the straight lines oa and oc corresponds to a fire with greater heat development than Smoke formation, e.g. with open flames. The area 4 between the Straight ob and od corresponds to a fire with heavy smoke formation, e.g. a smoldering fire.

The area 5 between the straight lines oc and od corresponds to the most frequently occurring types of fire in which both phenomena are relatively well represented.

The mode of operation of a fire detector with evaluation of the sum of the sensor output signals is shown by the straight line P, which connects the points Ll on the two axes. In contrast, the hyperbola Q through the points Pl and P2, at which the Straight line P intersects the lines oa and whether, the working characteristics of a fire alarm according to the invention with evaluation of the product of the sensor output signals. When comparing the characteristics P and Q, it can be seen that both fire detectors for extreme types of fire have the same sensitivity in accordance with points P1 and P2, while the fire detector according to the invention with product evaluation according to the characteristic Q for the middle area of the most frequently occurring types of fire in areas 3 and * l, but especially in area 5, a significantly improved sensitivity owns.

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In the circuit shown in FIG. 3 of a further exemplary embodiment the invention is instead of a smoke sensor A, a gas sensor G with a semiconductor ox in the form of a pearl as a detection element with embedded heating coils h, which also serve as electrodes. One of the heating coils h is connected to a voltage source E in a signal center Re via connections a and b. The gas sensor G is with this voltage source E via the connection a, a resistor Rl, the connection c and a signal relay N connected. The resistance Rl is Connected via a pair of diodes Dl and D2 to the base of a transistor Tl, the emitter of which via a voltage divider VR. at the Connection c is located. The tap of the voltage divider VR. is connected to the input of a multiplier Am.

When the gas sensor G comes into contact with ferbr burn gases, its resistance decreases, whereby the voltage drop Va across the resistor Rl increases. The diodes Di and D2 are chosen so that the output voltage VA at the voltage divider VR _& normally, so when there is no fire} is Mull.

Circuit S contains a transistor »T3 _S. which is connected via a resistor R5 and a resistor R6 bridged by a capacitor C between the terminals a und.e and whose emitter is additionally connected to the terminal a via a resistor RH. Furthermore, a transistor = T ^ _9, which is controlled by the voltage drop across the resistor R7, is connected via the resistor R6 between the terminals a and c = A resistor R3 at the output of the multiplier Am is arranged between the base of the transistor T3 and the terminal c.

When the output voltage Vc across the resistor R3 is a predetermined Exceeds the value, the transistor T3 becomes conductive, and a current flows between the base due to the voltage drop across the resistor R6 and emitter of transistor T4 through transistor T3, whereby the transistor TU becomes conductive. Due to the voltage drop in the Resistor R7, the transistor T5 is also conductive, and the

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Transistors Tt and T5 remain in their state and operate the signal relay N in the signal center Re.

The mode of operation of this exemplary embodiment is the same as that in FIG. shown example, apart from the fact that Instead of a smoke sensor, a gas sensor is used, which allows the concentration of combustion gases to be detected. This fire alarm does not respond to paint mist, for example, as is to be expected from the fire alarm according to FIG is.

It can be seen that the fire alarm according to the invention has a simple structure and normal fire types are considerably faster and without Time delay. A faulty alarm generated due to other causes than a real fire, e.g. heat development in the gaps, cigarette smoke or paint fumes on the other hand hardly ever take place.

It should be noted that instead of the fire sensor described, also other types of sensors can be used, e.g. ionization chambers, flame detectors, etc. phenomena occurring in a fire or other combustion products react.

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Claims (6)

Claims Fire detector with at least two sensors that react to different fire phenomena and a common evaluation circuit for evaluating changes in the properties of the sensors and for generating alarm signals, which, if one of them is influenced, Sensor due to a fire phenomenon, the response threshold of the other sensor for the alarm signaling in the sense of a Increased sensitivity changes, according to patent ... (patent application P 24 52 839.0), characterized in that the Evaluation circuit (C, S) is set up to trigger an alarm signal when the product of the output signals (V., Vg) the sensor (A, B; G; B) exceeds a specified value. 2. Fire detector according to claim 1, characterized in that the evaluation circuit has an analog multiplier (Am; Am2), to whose inputs the sensors (A, B; G, B) are connected and the output of which is connected to a switching device (S) which is able to trigger an alarm signal when the input signal exceeds a predetermined threshold. 3. Fire alarm according to claim 1 or 2, characterized in that that one of the sensors is designed as a smoke sensor (A) and a light source (L) and a photoelectric converter (Ce) contains. U. fire alarm according to one of claims 1 to 3, characterized that one of the sensors acts as a temperature sensor (B) that responds to the rate of temperature rise is formed and two thermistors (THl, TH2) with different having thermal insulation. 5. Fire detector according to one of claims 1 to 4, characterized in that that one of the sensors is used as a 6098 10/0557 ORIGINAL! SUSPECTED, - * - 25192b ¹ / Λ. Semiconductor gas sensors sensitive to combustion products (G) is trained. 6. Fire detector according to one of claims 1 to 5, characterized in that that one of the sensors has an ionization chamber. 03810/0557