DE2115759A1 - Fire alarm system - Google Patents

Description

Zl Ib

8451 ~ 71 / Sch / Ba

182-4

Japanese patent application

No. SHO 45-26842

dated March 31, 1970

Mttan Company, Limited Shibuya-ku, Tokyo (Japan)

Fire alarm system

The invention relates to a fire alarm system with a plurality of heat or smoke-sensing fire alarms that have an electrical Generate signal, and with a central unit emitting an alarm signal when this signal is received. In particular the fire alarm system should be an improved option; to determine the location of the fire outbreak.

In known fire alarm systems, a number of fire! or! smoke alarms connected in parallel between a pair of conductors, j which is connected to a single central unit containing a power supply unit and an alarm device. If someone the detectors responds, a closed circuit for the power supply unit and the alarm device is over the relevant Fire alarms are 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 responded, but it is not possible to determine which fire alarm it was. ; These systems can only indicate that a fire has broken out somewhere in the surveillance area, but not where. Man has therefore had to use other aids such as a patrol in the known fire alarm systems to the Stelf Ie of the outbreak of fire to be determined. However, this is very troublesome, especially if there are a large number of fire alarms or the fire alarms are widely distributed in a large building. In order to save this effort, the fire alarms in some known fire alarm systems are individually

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connected with the central unit _s geekseh results in a great installation effort with cable harnesses and high costs.

The object of the invention is to improve the known Fire alarm systems with several in parallel to a single one Connection line connected fire alarms and one Possibility to identify the fire alarm that has been addressed Has.

This object is achieved according to the invention in that each fire alarm an AC signal generator having a AC signal with a for the relevant,! Fire alarm characteristic predetermined! frequency generated, and that the Central unit an equence discriminator to determine this Contains the frequency and display of the associated fire alarm.

The invention is described below with reference to the representations of exemplary embodiments. mower explained. Ss shows:

1 shows a block diagram of the fire alarm system according to the invention;

2 shows a circuit diagram of an embodiment of the invention used fire alarm |

3 shows a further embodiment of a fire alarm;

Fig. 4 shows a circuit formed according to the invention Central content j

FIG. 5 shows the circuit diagram of a circuit diagram modified from FIG. 3 Fire alarm;

6 shows the circuit diagram of part of a further embodiment a fire alarm according to the invention;

FIG. 7 shows a removal area of part of that shown in FIG

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B ORIGINAL

3? Ig. 8 is a circuit diagram of a modification of the Pig. 5 shown Fire alarm; and

Fig. 9 shows a modification of the Pig. 6 shown circuit.

Pig. 1 shows a general embodiment of a celebration alarm system with an ATigahl -ron fire or smoke alarms 3-1 »3-2, 3-3 ... 3-n, which are connected in parallel between two conductors 1 and 2 and with a central unit 4- are connected. Each hero 3 contains a working contact, not shown, which is closed when the hero feels warm or a breath. The central unit 4 contains a power supply unit and an alan device which are connected in series between conductors 1 and 2. When the working contact of the fire alarm is closed, the alarm circuit receives power and gives an alarm, as is the case with the known systems, too.

In addition, in the circuit described here, each contains Helder uses an alternating current generator that generates an alternating current signal of a certain characteristic frequency lets conductors 1 and 2 reach the central unit when the hero has responded or the switch is closed. the Central unit 4 also contains a number of band filters with the characteristic frequencies of the fire alarms corresponding Pass frequencies and with appropriate indicators, such as lamps, which light up when the appropriate ones Signals are fed after passing through the relevant filter. If one of the fire alarms feels breath or heat, then it sends an AC signal of its characteristic frequency to the central unit, and this signal passes through; There one of the filters, which has the corresponding pass band, and energizes the indicator lamp to display the relevant Fire alarm.

In Fig. 2 is an embodiment of the invention with a bimetal fire alarm 3 and old three resistors 23, 24 and 25, which are connected in hehe between a pair of conductors 1 and 2,

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which in turn are connected to the central unit 4 "and to which a certain voltage is supplied from the power supply unit. A normally open contact is located parallel to the resistor 24 22, which is connected to the bimetal heat sensor 21, so that it closes when the sensor 21 senses a certain degree of heat. As a result, the resistor 24 is short-circuited via the contact 22, and through the conductors 1 and 2 a current flows which is sufficient to set the alarm device in the central unit 4 in operation to put.

The connection point of the resistors 24 and 25 is connected via a capacitor 53 to one end of the primary winding of a transformer 52, the other end of which is connected to the base of a transistor 51. One end of the secondary winding of the transformer 52 is connected to the second _{conductor via a capacitor 54:} 2 and also via a resistor 56 to the first conductor 1. 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 indicated by a dashed line Box 5 framed, which represents a blocking oscillator whose oscillation frequency is determined by the values of these components is. If the heat sensor 21 senses heat and closes the contact 22, then the bias voltage of the transistor 51 changes, so that the oscillator 5 begins to oscillate at its characteristic frequency. The AC signal of that frequency passes through the capacitor 54 and the resistor 56 to the receiver 4 and is detected in the manner described later.

In Fig. 3, another embodiment of a fire alarm 3 is shown, which works with ionization chambers, which by: a dashed box 6 are surrounded, while the oscillator-j torteil is framed by a dashed box 7. Of the

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Ionization smoke alarm 6 contains a closed ionization chamber 61 with a pair of electrodes 611 and 612 and a radioactive source 613, which are closed off from the ambient air, and an open ionization chamber 62 with a similar pair of electrodes 621 and 622 and a radioactive source 623, which are open to the ambient air The two ionization chambers are connected in series between conductors 1 and 2, and their connection point is connected to the control electrode of the field effect transistor 63. The collector-emitter path of the field effect transistor 63 is in series with a load resistor 64 also between the conductors 1 and 2. The emitter of the field effect transistor 63 is connected via a Zener diode 65 to the control electrode of a controlled silicon rectifier 66, whose _; Main current path is via a potentiometer 67 between conductors 1 and 2.

When smoke enters the open ionization chamber 62, the impedance of the open ionization chamber 62 changes, and this changes the control electrode potential of the field effect transistor 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, then the silicon rectifier 66 is controlled via its control electrode. The conductors 1 and 2 are thus over the silicon rectifier 66 connected to one another, so that the alarm device in the central unit 4 is switched on.

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 is connected to a piezoelectric element, which is attached to it, and a diode 71 connected to the contact arm of the potentiometer 67, the other leg the tuning fork 72 is via a further piezoelectric egg

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ment attached to it is the base of the transistor 78 connected. The tuning fork itself is directly connected to the second conductor 2 and the base of the transistor is via the parallel connection of a capacitor 73 with a resistor 75 on the conductor 2. Me base is also on the Resistor 76 connected to the collector of the same transistor 78 and to the anode of diode 71. The emitter of transistor 78 is connected via the parallel connection of capacitor 74 with resistor 77 on conductor 2 «The characteristic prequens this oscillator is determined by the mechanical properties of tuning fork 72 and the electrical properties of the others Components determined,

When the ionization roughness sensor detects 6 puffs and the controlled one Silisiumgleichriohter 66 is turned on, then changes the bias of the oscillator circuit at the sliding contact of the potentiometer 67 "and the oscillator begins to oscillate, w © im its Yorspasssmgsbedingungen are met. That generated Weehsal current signal of the characteristic prequent in each case is made from a capacitor with the help of a resonance circuit 25 and the primary Wisklimg of a transformer 26 reinforced and via the secondary power of the transformer 26 of the central unit 4 supplied. To block direct current components capacitors 27 and 28 are inserted.

Pig. 4 shows an embodiment of the central unit 4 of FIG 1, some of which are shown in block form in the dashed box 4 is indicated. Me central unit 4 contains an alarm device 8, welQhes an electromagnetic Heiais 81 with an i Normally open contact, a Stroaversorgungseinhelt 82 and an indicator lamp 85 with a parallel-connected gate generator 84 which, in addition to the Selaiskoiitakt and the power supply are switched. Sin connection of relay 81 is with des © s © t @ a Jjeitgs TsrfeiHideSg the other connection is üfe®r © ia fi © fpsifilter 10 ans the Eondeiisatoren 11 and 12 12nd

15 with one Source of Education 45

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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-n of the system. 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, the oscillators of which generate the frequencies f-, f- and f-, which are characteristic for 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 f ,, f ₂ or f ₅

If, for example, the breath detector 3-1 detects a fire, then the direct voltage component of the signal generated by the generator of the fire alarm in question passes through the low-pass filter 10 and the alarm device 8 is activated, and at the same time the alternating current component of the frequency f passes through the high-pass filter 9 and is amplified in the amplifier 14 and reaches the frequency discriminator 40. Here the output signal of the amplifier 14 only passes through the band filter 41-1 with the frequency f ₁ and is amplified by the amplifier 42-1, rectified by the rectifier 43-1 and fed to the indicator 44-1, which in the event a lamp lights up. Since the other band filters 41-2 and 41-3 are not permeable _{to the frequency f 1,!} the signal is 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 on this system start a fire has established, this is indicated by the alarm device 8, and the fire alarm in question is indicated by the indicator 44 of the

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Frequency discriminator 40 signals. This also applies if several fire alarms respond at the same time.

The oscillators of the fire alarms can be designed in various ways, as shown on the basis of the examples in FIGS. 5 and 6 will now be explained. According to Fig. 5, an alternating current source 30, which generates a signal of a characteristic frequency, connected to the primary winding of a transformer 31, the secondary winding in series with the main current path of the controlled silicon rectifier 66 of the ionization smoke sensor 6 according to FIG. 3 is connected. If the sensor is here has responded and the controlled silicon rectifier 66 is switched to its conductive state, then a Conductor loop, which contains the alarm device 8, is closed, and at the same time a signal is received from the alternating current source 30 coupled into the conductor loop via the transformer 31 and superimposed on the direct current component and via the conductor 1 and 2 forwarded. Both the alternating current component and the direct current components are processed further in accordance with the operating principle of FIG.

In the circuit according to FIG. 6, an alternating current source 30 is constantly in operation and, like the alternating current source 30 in FIG There is a pair of oppositely polarized diodes 33 and 34. The ^! The secondary winding of the transformer 33 is connected to the conductors 2 and 1, respectively, via DC blocking capacitors 35 and 36! 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. The normally open contact 37 corresponds to the contact 22 in FIG. 2 or the controlled silicon rectifier 66 in FIG. 3, which has a j

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Circuit with the alarm device closes when the fire detector appeals to. If the! Fire alarm does not respond, then the contact is made open and one in the secondary winding of the transformer

31 induced current cannot be in the primary winding of the transformer 32 flow because the diodes 33 and 34 have a high impedance. If the switch is closed, however, then flows the direct current component through the two diodes and reduces their resistance. Therefore it flows in the secondary winding of the transformer 31 induced alternating current signal in the primary winding of the transformer 32 and passes through its secondary winding to conductors 1 and 2. The signal is then processed further in the central unit 4 in a corresponding manner.

The goal is to provide each of the smoke alarms with its own sound generator, which generates a sound signal when the Has responded to the fire alarm. The Pig. 7, 8 and 9 illustrate variations of the method described in Pig. 2, 5 and 6 shown Circuits which are provided with a loudspeaker. In Pig. 7, the transformer 52 has a tertiary winding 57 to wel before a loudspeaker 58 is connected. In Pig. 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 Pig. 9 becomes the Loudspeaker 58 from a tertiary winding 57 of the transformer

32 actuated.

With the fire alarm system described above, the location of the fire outbreak and the extent of the fire can be quickly determined on the central unit, and countermeasures can be taken immediately and in a targeted manner.

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Claims (1)

-10- Patent early Fire alarm system with a plurality of heat or smoke-sensing fire alarms which generate an electrical signal and with a central unit which emits an alarm signal when this signal is received, characterized in that each, feiaenaelösr (5-1 .... 3-n) has an alternating current signal generator (7 ), which generates an alternating current signal with a predetermined frequency characteristic of the fire alarm in question, wtd that the central unit (4) has a frequency discriminator (41-44) for determining this frequency . Contains display of the associated fire alarm. Fire alarm system according to claim 1, characterized in that that the frequency discriminator filters a plurality of ban & pass filters (41-1. ».. 41-n) according to the fire alarms (3-1 ... 3-n), the permeability of which corresponds to that of the fire alarms @ sg @ iigtea correspond to frequencies. Fire alarms for detecting heat or Eauch and generating an electrical signal for use in the fire alarm system according to claim 1, characterized by an alternating current generator (7) for generating an alternating current signal with a predetermined characteristic frequency for the fire alarm, which is generated when the fire alarm Notices heat or stomach. 10S8U / 106 &