DE2115759B2 - FIRE DETECTION SYSTEM - Google Patents

Description

The invention relates to a signaling system with a plurality of parallel via a pair of lines to one Central unit connected detectors, each one when the detector responds via the line pair the central unit, which generates vibrations characteristic of the respective detector Electromechanical AC voltage oscillator included, and provided with one in the central unit Display device which supplies a display corresponding to the respective generated frequency.

From the German patent 890470 a reporting system is known in which several reporting points are connected in series in a loop that leads to a central unit. One of the reporting offices contains a generator that generates several characteristic frequencies, while in the remaining detectors a corresponding filter is provided in each case, which the assigned characteristic frequency for modulation filtered out with a measured value. The different characteristic frequencies finally reach the central unit, where they are separated again with the help of additional filters for individual evaluation. With this well-known Arrangement there is the problem of the mutual influence of the damping curves in the filters provided for the individual detectors. To avoid these difficulties, the individual Detectors equipped with bypass circuits for the characteristic frequencies not assigned to them, while their own characteristic frequency is filtered out of the ring line, with the help of a push button switch is modulated and then fed back to the ring line.

Weherhin is from the German patent specification 919 173 a system for the transmission of signals that works according to the so-called frequency step process known in which each of the possible current states of each signal channel by a changeover switch represented by a frequency characteristic of the current state in question. The alternating currents of several signal channels present at the same time are mutually exclusive modulated, and the resulting modulation products become those alternating currents

ίο different frequency filtered out whose each by its frequency one of the possible combinations of simultaneous times in the different Signal channels existing current states clearly represents.

From the German patent 578019 is still a synchronous control circuit known, which with tongue resonators on the transmitter and receiver side works, with the help of which a synchronism of the revolutions of a control switch with

a reception desk is established. The circulating one The control switch is mechanically coupled to a roller that is similar to the roller on a music box is provided with small pegs, which the differently tuned tongues of the donor resonance

mark the gate. The sensed vibrations of different frequencies of the individual reeds are transmitted via a line to a reed frequency meter, from each of which the corresponding Tongue is stimulated to vibrate and via a

Lever arrangement a receiver roller constructed according to the donor roller to the next pin can continue to rotate. In this way the rotations of both rollers are kept in synchronism, see above that the switches coupled to them also rotate synchronously.

From the German Auslegeschrift 1026 668 a fire alarm system is known, which the individual Fire alarms each have an oscillator in the form of a relaxation circuit that works with a relay contain, which has a thermistor, the resistance of which is determined by its temperature Oscillation frequency of the relaxation circuit is determined. In this way, on the central unit by observing the oscillation frequency with the help of a measuring instrument, the temperature of those Determine the location at which the relevant fire alarm has responded. With the help of temperature it can then be determined whether it is really a fire or something else caused Temperature increase acts. Since the oscillation frequency of the relaxation circuit increases with If the temperature rises, we cannot speak of a frequency that is characteristic of the individual fire alarms will.

Usually in fire alarm systems there is a number of fire or smoke alarms in parallel between a pair of conductors connected, which is connected to a single central processing unit, which is a power supply unit and contains an alarm device. When one of the detectors responds, it becomes a closed one Circuit for the power supply unit and the alarm device via the relevant fire alarm is formed and the alarm device generates an alarm signal. Here, however, the alarm signal is generated if at least one of the fire alarms has triggered, but it cannot be determined which fire alarm it has been. These systems can only indicate that there is one somewhere in the surveillance area

Fire broke out, but not where. It has therefore the ^Breuer detectors individually via respective lines to the central unit connected, however, characterized srgibt a large installation costs with cable harnesses and high costs.

The object of the invention is to improve the well-known fire alarm systems with several connected in parallel to a single connecting line Fire alarms and a possibility to determine the fire alarm that has been addressed Has. The individual fire alarms should be as simple as possible, so that effort and costs are kept low.

This task is performed in parallel in a signaling system with a plurality of over a pair of lines detectors connected to a central unit, each one via the line pair when the detector responds to the central unit, generating swirling waves characteristic of the respective detector electromechanical alternating voltage oscillator, and with one in the central unit provided display device, which corresponds to a frequency generated in each case Provides display, achieved in that, according to the invention, the excitation device in a fire alarm system each oscillator with one connected between the line pair and when the Fire alarm in the line state controlled silicon rectifier Each fire alarm is coupled so that its line current causes the oscillator to oscillate stimulates.

The controlled silicon rectifier, which is controlled by sc ^! The line pair leading to the central unit is bridged and thus triggers an alarm. It is also used to switch on the oscillator, the characteristic frequency of which then also reaches the central unit via the line pair and indicates where the fire broke out.

In a further embodiment of the invention, each fire alarm can be connected to the Be connected to a pair of lines that contains an acoustic transducer, which is under control Sound waves generated by the oscillator vibrations. This makes it even easier for s>; h to be the exact one Determine the location of the fire outbreak.

The ^f He indung the views of embodiments is explained in more detail below with reference. It shows

F i g. 1 is a block diagram of the fire alarm system according to the invention,

F i g. 2 shows a circuit diagram of an embodiment of the fire alarm used according to the invention,

F i g. 3 another embodiment of a fire alarm,

4 shows the circuit of a central unit designed according to the invention,

F i g. 5 shows the circuit diagram of an opposite FIG. 3 modified fire alarms,

F i g. 6 shows the circuit diagram of part of a further embodiment of a fire alarm according to the invention,

F i g. 7 shows a modification of part of the FIG. 2 fire me'ders shown,

F i g. 8 is a circuit diagram of a modification of the one shown in FIG. 5 shown fire alarm and

F i g. 9 shows a modification of the FIG. 6 shown circuit.

Fig. 1 shows an embodiment of a fire alarm system with a number of fire or smoke detectors 3-1, 3-2, 3-3 ... 3- / i, the parallel between two conductors 1 and 2 are switched and are connected to a central unit 4. Every reporter 3 contains a working contact, not shown, which is closed when the detector heats or feel smoke. The central unit 4 contains a power supply part and an alarm device, which in

ίο series are connected between conductors 1 and 2. When the normally open contact of the fire alarm is closed, the alarm circuit receives power and gives an η alarm.

In addition, in the circuit described here, each detector contains an alternating current generator, which generates an alternating current signal of a certain characteristic frequency and via the Conductors 1 and 2 to the central unit; i lets get if the detector has responded or the switch has

ao closed ^: st. The central unit 4 also contains a number of band filters with the characteristic frequencies of the fire alarms corresponding transmission ranges and with corresponding indications, such as lamps, which light up when they

as corresponding signals after passing through the relevant Filters are fed. So if any of the fire alarms feel smoke or heat, then it does it sends an alternating current signal of its characteristic frequency to the central unit, and this si-

gnal passes through one of the filters there, which has the corresponding pass band, and excites the Indicator lamp to indicate the relevant fire alarm.

In Fig. 2 is an embodiment of the invention

with a bimetal fire alarm 3 and with three resistors 23, 24 and 25, which are in series between a Pair of conductors 1 and 2 are connected, which in turn are connected to the central unit 4 and those of the Power supply part is supplied with a certain voltage. A normally open contact is located parallel to the resistor 24 22, which is connected to the ferrous metal heat sensor 21 so that it closes when the sensor 21 feels a certain degree of warmth. As a result, the resistor 24 is short-circuited via the contact 22, and a current flows through the conductors 1 and 2 which is sufficient to activate the alarm device in the central unit 4 to be put into action.

The connection point of the resistors 24 and 2Γ is via a capacitor S3 with one end

So '1er primary winding of a transformer 52 is connected, the other end to the ^Bas: s of a transistor is placed 51st One end of the secondary winding of the transformer 52 is connected to the second conductor 2 via a capacitor 54 and also to the first conductor 1 via a resistor 56. The other end of the secondary winding is connected to ground via the collector-emitter path of the transistor 51. In the present case, the second conductor 2 is also grounded.

The transistor 51, the transformer 52, the capacitors 53 and 54 and the resistors 55 and 56 are framed by a dashed box 5, which represents a blocking oscillator whose Vibration frequency through the values of these components

ments is determined. If the heat sensor II senses heat and closes the contact 22, then the bias voltage of the transistor 51 changes, so that the oscillator? with its characteristic frequency

begins to vibrate. The AC signal of this frequency passes through capacitor 54 and the Resistance 56 to receiver 4 and is determined in the manner described later.

In Fig. 3 shows another embodiment of a fire alarm 3, which has ionization chambers works, which are surrounded by a dashed box 6, while the oscillator part is framed by a dashed box 7. The ionization smoke detector 6 contains a closed Ionization chamber 61 with a pair of electrodes 611 and 612 and a radioactive source 613, which are sealed off from the ambient air, as well as an open ionization chamber 62 with a similar pair of electrodes 621 and 622 and a radioactive source 623 exposed to ambient air are open so that smoke can penetrate, and finally the smoke sensor contains a field effect transistor 63. The two ionization chambers are connected in series between conductors 1 and 2, and its connection point is connected to the control electrode of the field effect transistor 63. the The collector-emitter path of the field effect transistor 63 is also connected in series with a load resistor 64 between the conductors 1 and 2. The emitter of the field effect transistor 63 is via a Zener diode 65 connected to the control electrode of a controlled silicon rectifier 66, the main current path of which via a potentiometer 67 between conductors 1 and 2.

When smoke enters the open ionization chamber 62, the impedance of the open one changes Ionization chamber 62, and thus the control electrode potential of the field effect transistor changes 63. This increases its emitter-collector current and accordingly also its emitter potential. If the emitter potential rises above the Zener voltage of the Zener diode 65, the silicon rectifier is activated 66 controlled via its Steutrel electrode. The conductors 1 and 2 are thus over the silicon rectifier 66 connected so that the alarm device is switched on in the central unit 4.

The oscillator part 7 contains a tuning fork oscillator with a diode 71, a tuning fork 72, Capacitors 73 and 74, resistors 75, 76 and 77 and with a transistor 78. One leg of the Tuning fork 72 has a piezoelectric element attached to it and a diode 71 connected to the contact arm of the potentiometer 67, the other leg of the tuning fork 72 is over another piezoelectric element attached to it to the base of transistor 78 tied together. The tuning fork itself is directly connected to the second conductor 2, and the base of the Transistor 78 is connected to the conductor via the parallel connection of a capacitor 73 with a resistor 75 2. The base is also via resistor 76 to the collector of the same transistor 78 and with connected to the anode of the diode 71. The emitter of transistor 78 is connected to the parallel circuit of the Capacitor 74 with resistor 77 on conductor 2. The characteristic frequency of this oscillator is determined by the mechanical properties of tuning fork 72 and the electrical properties of the others Components determined.

When the ionization smoke sensor detects 6 smoke and the controlled silicon rectifier 66 is switched on wd, then the bias of the oscillator circuit changes at the sliding contact of the potentiometer 67, and the oscillator will begin to oscillate when its bias conditions are met. The generated alternating current signal of the characteristic frequency in each case is generated with the aid of a resonance circuit from a capacitor 25 and the primary winding of a transformer 26 and amplified The central unit 4 is supplied via the secondary winding of the transformer 26. To block

ίο DC components are capacitors 27 and 28 inserted.

F i g. 4 shows an embodiment of the central unit 4 of FIG. 1, partly in a block diagram is indicated in the dashed box 4.

The central unit 4 contains an alarm device 8, which an electromagnetic relay 81 with a Normally open contact, a power supply unit 82 and an indicator lamp 85 with a parallel-connected Tone generator 84 contains which in series between

ao the relay contact and the power supply unit are switched. One connection of the relay 81 is connected to the first conductor, the other connection is connected to a voltage source 45 via a low-level filter 10 made up of the capacitors 11 and J 1 and a choke coil 13. The central unit 4 also contains a high-pass filter 9 made up of the capacitors 91 and 92 and a choke coil 93, the input of which is connected to the conductors 1 and 2 and the output of which is connected via an amplifier 14 to a frequency discriminator 40. The frequency discriminator 40 consists of a number of discriminator channels corresponding to the fire alarms 3-1, 3-2, 3-3 ... 3-7! the plant. To simplify the illustration, only three channels are shown in the drawing. It is also assumed that the first three channels correspond to the fire alarms 3-1. 3-2, 3-3, whose oscillators _{generate the frequencies Z 1} , / ₂ and / ₃ that are characteristic of them. Each of the frequency discriminator channels consists of a band filter 41. an amplifier 42, a rectifier 43 and an indicator 44. The pass frequencies of the filters 41-1, 41-2, 41-3 of the first, second and third channels are corresponding to the frequencies / ,, / ₂ or / ,.

For example, if the smoke alarm 3-1 a If a fire is detected, then the DC voltage component of the generator of the concerned passes through The fire alarm signal generated the low-pass filter 10 and actuated the alarm device 8, and at the same time

the alternating current component of the frequency / passes through the high-pass filter 9 in the amplifier 14 amplified and reaches the frequency discriminator 40. The output signal of the amplifier passes through here 14 only the band filter 41-1 with the frequency /,

and is amplified by amplifier 42-1, rectified by rectifier 43-1 and fed to indicator 44-1, which lights up in the case of a lamp. Since the other band filters 41-2 and 41-3 are not permeable _{to the frequency Z 1, the signal}

processed only in the first channel, from which it follows that the fire alarm 3-1 has detected the fire.

If any of the fire alarms in this system have detected a fire, this will be indicated by the alarm device 8 displayed, and the relevant

Fire alarm is signaled by the indicator 44 of the frequency discriminator 40. This also applies if several fire alarms respond at the same time.
The fire alarm oscillators can be operated in different

be designed in different ways, as shown on the basis of the examples in FIG. 5 and 6 will now be explained. According to FIG. 5 is an AC power source 30 which receives a signal of a characteristic frequency generated, connected to the primary winding of a transformer 31, the secondary winding in Row with the main current path of the controlled silicon rectifier 66 of the ionization smoke sensor 6 according to FIG. 3 is switched. If the smoke sensor has responded and the controlled silicon rectifier 66 is switched to its conductive state, then a conductor loop is created, which the Alarm device 8 contains, closed, and at the same time a signal from the AC power source 30 is over the transformer 31 is coupled into the conductor loop and superimposed on the direct current component and forwarded via conductors 1 and 2. Both the AC component and the DC component are in accordance with the mode of operation of FIG. 4 further processed.

In the circuit according to FIG. 6 there is an alternating current source 30 continuously in operation and just like the alternating current source 30 in FIG. 5 through the transformer 31 coupled into a closed circuit, which consists of the secondary winding of the Transformer 31, the primary winding of the transformer 32 and a pair of oppositely polarized diodes 33 and 34. The secondary winding of transformer 33 is connected to conductors 2 and 1 via DC blocking capacitors 35 and 36, respectively tied together. The center tap of the secondary winding of the transformer 31 is connected to the second conductor via a normally open contact 37, and the center tap of the primary winding of the transformer 32 is directly connected to the first conductor 1 tied together. The normally open contact 37 corresponds to the contact 22 in FIG. 2 or the silicon controlled rectifier 66 in FIG. 3, which closes a circuit with the alarm device when the fire alarm appeals to. If the fire alarm does not respond, then it is

the contact is open and a current induced in the secondary winding of the transformer 31 cannot in the primary winding of the transformer 32 flow because the diodes 33 and 34 have a high impedance to have. However, if the switch is closed, then

ίο the direct current component flows through the two Diodes and reduces their resistance. Hence that flows in the secondary winding of the transformer 31 induced alternating current signal in the primary winding of transformer 32 and passed over its secondary winding to the conductors 1 and 2. The signal is then in a corresponding manner in the Central unit 4 treated further.

Advantageously, each of the smoke alarms is provided with its own tone generator, which is a

ao acoustic signal generated when the fire alarm has responded. The F i g. 7, 8 and 9 illustrate modifications the in the F i g. 2. 5 and 6 illustrated circuits, which are provided with a loudspeaker are. In Figure 7 the transformer has 52

as a tertiary winding 57 to which a loudspeaker 58 is connected. In Fig. 8 is in series with the main current path of the silicon controlled rectifier 66, a transformer 59 is connected, the secondary winding of which actuates a loudspeaker 58. In

F i g. 9, the loudspeaker 58 is actuated by a tertiary winding 57 of the transformer 32.

In the case of the fire alarm system described above, the location of the fire outbreak and the extent of the fire was quickly detected on the central unit

and the countermeasures can be taken immediately and in a targeted manner.

1 sheet of drawings

Claims (2)

Patent claims: 1. Fire alarm system with a plurality of detectors connected in parallel to a central unit via a pair of lines, each of which contains an electromechanical alternating voltage oscillator which reaches the central unit via the line pair when the detector responds and generates vibrations characteristic for the respective detector, and with a display device provided in the central unit , which provides a display corresponding to the respective generated frequency, characterized in that in a fire alarm system the excitation device of each oscillator (72) is connected between the line pair (1,2) and when the fire alarm (3-1, 2> - 2 ...) in the line state controlled silicon rectifier (66) of each fire alarm is coupled that its line current excites the oscillator (72) to oscillate. 2. Fire alarm system according to claim 1, characterized in that each fire alarm is connected via an output circuit to the line pair (1,2), which has an acoustic Contains transducer (58) which, under the control of the oscillator vibrations, generates sound waves generated.