DE2419919A1 - Fire alarm system with smoke detectors - has parallel contacts in closed loop and series failure contacts operating when alarm fails - Google Patents

Abstract

The fire alarm system has smoke detector contacts coupled in parallel into the system loop line and failure contacts coupled in series into the loop between the detector contacts. The failure contacts operate when the alarm itself fails to operate and break the loop. The smoke detector consists of an optical coupler whose output drops when smoke is present and triggers a transistor that operates the relay whose contacts form the parallel detector contacts in the loop line. A second relay is operated if the warning light associated with the first relay fails to light. This second relay contacts are the failure contacts. The voltage in the loop line is monitored.

Description

Formwork arrangement for interconnecting several signaling devices, in particular smoke alarms The invention relates to a circuit arrangement for interconnecting several signaling devices to form a signaling loop, with each Signaling device an alarm contact that switches when the signaling device responds, as well as a fault alarm contact, which in the event of a fault in the alarm device switches, has.

For smoke alarms such as those used in automatic fire alarm systems it is known to interconnect several signaling devices to form a loop and to provide evaluation electronics that trigger the alarm or take hold of it initiate certain measures when the alarm contact of any signaling device addressed. In addition, is it is known to be a quiescent current to be sent through the message loop, the strength of which is below that for triggering the alarm leading strength, the absence of which is determined to be a wire break or to determine another fault in the message loop.

The known smoke alarms work with a system consisting of a light source and a photo sensor. If smoke occurs between the light source and the photo sensor the light transmission is changed as a result of the scattering and the photosensor changes its resistance value. This causes an alarm relay to respond, whose contact is usually designed as an opener. To avoid a failure of the light source, through which the reporting device becomes inoperable, to be brought to the display it is known to switch a relay in series with the light source. Will the light source circuit interrupted, the relay switches and activates a fault signaling contact.

In the well-known message loop, there are the alarm contacts and the fault message contacts all signaling devices connected in series. The alarm contacts are each bridged by a resistor. All contacts are designed as openers. If one of the fault signaling contacts opens with this circuit, the entire circuit is closed the message loop is interrupted and an alarm signal cannot be issued in an emergency more to be passed on.

The object of the invention is to provide a circuit arrangement of the initially mentioned to train mentioned type in such a way that the Functionality for alarm signals is retained to a greater extent even when individual fault signaling contacts are actuated. In addition, the number of resistors required should be reduced.

To solve this problem it is proposed according to the invention that the alarm contacts of the signaling device are connected in series in the loop, and that the alarm contacts are parallel to each other when the alarm contacts are closed and are designed as closer.

This ensures that when a fault alarm contact is triggered the functionality of those alarm contacts is fully preserved before switched fault message contact. If the smoke alarms are used, smoke exhaust flaps in a building automatically via appropriate release devices in the event of a fire open to let the smoke out, then the smoke vents will already be triggered when any of the reporting devices in the reporting loop is triggered Has. If one of the fault signaling contacts was switched over as a result of the failure of a light source, what of course leads to the output of a fault signal, so are with the Circuit arrangement according to the invention thereby by no means all reporting devices disabled, but only those behind the opened alarm contact lie.

The functionality of the entire reporting device is thus considerable made safer.

Another advantage is that only one resistance is required to limit the quiescent current in the entire reporting loop. This Resistance bridges all alarm contacts. In the known system, however, is a separate parallel resistor is used for each alarm contact.

In an advantageous embodiment of the invention, the reporting device a smoke detector that detects the presence of smoke by means of an array of light sources and photosensor determined, in series with the light source a fault message contact controlling alarm relay is, while the photo sensor activates the alarm contact Alarm relay controls.

The invention is described below with reference to the figures a preferred embodiment explained in more detail.

Fig. 1 shows the circuit diagram of a message loop with a connected Evaluation circuit, and FIG. 2 shows the basic circuit diagram of a fault reporting device.

Reference is first made to FIG. 2, in which a reporting device is shown in the form of a smoke alarm. The smoke detector has a light 40, which in series with an alarm relay 30, the load resistance of an npn transistor 41 forms. The transistor 41 is connected to the negative supply line via the emitter resistor 42 43 connected. Its base is on one of a zener diode 44 and a resistor 45 existing voltage divider between the negative supply line 43 and the positive supply line 46 is connected. The zener diode 44 delivers a constant reference potential for the transistor base and at the same time the supply voltage for a voltage divider composed of a resistor 47 and a photoresistor 48 exists. The photoresistor 48 is hit by the light from the lamp 40, and with different intensity depending on whether there is between the both parts smoke or not. The tap of the voltage divider from the Resistors 47 and 48 is connected to the base of a transistor 49, the Alarm relay 20 controls.

The circuit described above is considerably simplified in order to to clarify the working principle.

The alarm relay 20, which is de-energized in the idle state or only from one very little quiescent current flows through it, responds when between the lamp 40 and the phototransistor 48 smoke occurs. It then closes the one in the message loop 1 lying alarm contact.

The lamp 40 and the alarm relay 30 are when the reporting device is in operation, always carrying current. For example, if the transistor 41 falls or the light 40 off, then the alarm relay 30 is de-energized and opens the corresponding alarm contact in Fig. 1.

The alarm contacts are in the message loop 50 shown in FIG. 1 21, 22 and 23 as well as the alarm contacts 31, 32 and 33 of a total three alarm devices of the type shown in Fig. 2 are interconnected. A loop can of course have a much larger number of reporting devices contain.

The fault signaling contacts are connected to the positive supply line 51 one behind the other 33, 32 and 31 connected. Behind each alarm contact is between the line 51 and the return line 52 of the loop the respective alarm contact 21, 22 or 23 switched.

The last alarm contact 21 is limited by a resistor 53 of the loop quiescent current bridged.

The alarm contacts 21, 22 and 23 are designed as normally open contacts, i.e. they close when the associated alarm relay 20 is energized. The fault message contacts 31, 32 and 33 are also designed as closer, i.e. they open when the Fault message relay 30 is de-energized.

The idle state of the message loop 50 is shown in FIG. 1. In In this case, a current flows from line 51 via all fault signaling contacts 33 to 31, and the resistor 53 to the return line 52. To the return line is a relay 54 is turned on, which acts as a threshold switch and through which the resistor 53 limited quiescent current does not respond.

The relay has its second connection on the negative supply line 55.

If smoke is detected on one of the reporting devices, that speaks corresponding alarm relay 20 and the Alarm contact 21 or 22 or 23 closes. This bridges the resistor 53 and the current in the relay 54 reaches such a value that the relay responds.

As a result, the changeover contact 56 is turned to the left, so that over the diode 57 negative potential is applied to a trigger 58, the other Connection to line 52 and thus to positive potential.

The trigger 58 can for example consist of an ignition chain, through which a number of smoke flaps are blown open.

If one of the lights 40 is defective, the associated relay drops 30 and one of the alarm contacts 31 to 33 opens. This is the quiescent current the message loop is interrupted, i.e. the return line 52 takes negative potential at. This means that via the ignition chain 58 and a resistor 59, negative potential reaches the base of an npn transistor 60, which with its emitter when de-energized Relay 54 via relay contact 56 and a resistor 61 at negative potential and its collector is at positive potential via a resistor 62. The transistor 60, which in the normal state of the loop 50 via the line 52 and the resistor 59 is driven positively and is therefore conductive, is at an interruption of the message loop 50 brought into the locked state.

The collector of transistor 60 is connected to the base of another Transistor 63 connected. The emitters of both transistors 60 and 63 are connected together.

The working resistance of transistor 63 is a fault light 64. In addition, an alarm line 65 leads from the collector out of the device.

The transistor 63 is not the message loop 50 in the normal state conductive, i.e. the fault lamp 64 has gone out and the output 65 is on positive potential. If the transistor 60 is due to an interruption in the message loop 50 blocked, transistor 63 becomes conductive and the fault indicator lamp 64 lights up on. At the same time, the potential of the output 65 is different from the positive potential. This potential difference can trigger an optical or acoustic Fault indication can be used.

Since when the relay 54 is pulled, the emitters of the two transistors 60 and 63 are no longer on line 55 via changeover contact 56, are in this If both transistors are de-energized, the fault light 64 in the event of an alarm does not light up. This is to clearly separate the two functions alarm and Intentional interference.

Claims (2)

Expectations 1. Circuit arrangement for interconnecting several signaling devices to a signaling loop, with each signaling device having an alarm contact, which at Response of the signaling device switches, as well as a fault signaling contact, which at Occurrence of a fault in the reporting device switches, has, d a d u r c h g e k e n n n z e i c h n e t that the fault signaling contacts (31, 32, 33) of the signaling device (Fig. 2) in the loop (50) are connected in series, and that the alarm contacts (21, 22, 23) are parallel to each other when the alarm contacts are closed and are designed as closer. 2. Circuit arrangement according to claim 1, d a d u r c h g e k e n n z e i c h n e t that the reporting device is a smoke alarm that the presence detected smoke by means of an arrangement of light source (40) and photosensor (48), wherein in series with the light source (40) the fault signaling contact (31, 32, 33) controlling Fault reporting relay (30) is on while the photo sensor (48) sets the alarm contact (21, 22, 23) actuating alarm relay (20) controls. Blank page