DE1900771C3 - Circuit arrangement for an automatically closing fire door - Google Patents

Description

The invention relates to a circuit arrangement for automatically closing fire door with * ^r> a counteracting a locking device holding magnet, the excitation circuit can be switched off by means of a fire detector device.

An electromagnetic gate holder is already known (DE-GM 1971 396), which can be switched off by a central fire alarm system, among other things. In this case, all fire doors in the system are closed with automatic closing devices. To close individual fire doors, the only option is to pull the door in question off the electromagnetic gate holder by hand. Thus, even in the event of a local fire, all fire doors are closed simultaneously via the fire alarm system. This can be in different cases disadvantageous because the fire doors are slammed in the still intact ^r> "parts of the building and possibly impede the escape route. If, however, the central reporting system does not work, there is again the risk that the excitation circuits of the electromagnetic gate keeper will not be interrupted and that individual fire doors will not be closed at all.

The object of the present invention is therefore to design a circuit arrangement of the type mentioned at the beginning in such a way that the individual fire doors ^{can be controlled individually M)} without the circuit complexity being correspondingly multiplied compared to the central fire alarm system.

According to the invention this object is achieved in that a single fire detector is directly coupled to the ^BR> holding magnet of the fire door and is powered by a force acting as a transformer auxiliary winding of the holding magnet with low voltage.

This means that a fire detector can be used together with the holding magnet of the fire door with just a few components be switched on. The low voltage for the detector circuit is thus via an additional winding won the front holding magnet, which must be connected to the supply voltage anyway. Consequently is neither a low voltage line from a central power supply nor an additional one Transformer required for fire detector; nevertheless, the detector receives a low voltage, see above that there is no risk of high voltages when touched. In an advantageous embodiment provided that on the secondary side of the transformer by means of two rectifiers in a doubling circuit voltages stabilized at two storage tanks are built up. Usually Zener diodes are used, by means of which the stabilized voltages are applied to two capacitors being constructed. As a switching means between the fire detector and the holding magnet can be a means a two-stage transistor amplifier stage energized NC relay can be used, which in the event of an alarm or also triggers the holding magnet for the fire door to be monitored in the event of a power failure Usual test button are provided, by means of which the operating voltage on the fire detector can be changed can, so that the detector connection of each individual fire door can be checked by means of a test alarm can.

The circuit arrangement according to the invention is explained in more detail below with the aid of an exemplary embodiment described.

In the exemplary embodiment, the structural design of an ionization detector is neglected and the two chambers K 1 and K 2 are only shown schematically. Both chambers K 1 and K 2 are radioactively irradiated by a radioactive radiation source, which is also not shown in the exemplary embodiment. As a result of the radioactive irradiation, the two chambers have a very specific electrical conductivity. One of the two chambers, for example chamber K 2, is in contact with the outside air. If a sweat or fire breaks out, the resulting smoke gases reduce the electrical conductivity in chamber K 2. Since both chambers K 1 and L 2 are in series, this results in a potential shift at the common connection point 1 of the two chambers . This potential shift is detected, for example, by means of a field effect transistor Π. A very sensitive component must be connected to the connection point 1 of the two chambers, since only a current of the order of magnitude of ^10-10 amperes flows in the two chambers.

Since, as already mentioned, the alarm connections of fire alarms, for example for individual fire doors, are often difficult to accommodate in a loop, a separate power supply is provided according to the invention for the alarms. In the example! the power is supplied via a standard transformer, for example a bell transformer KT, which transforms the mains voltage from 220 V to the required lower voltage. At the same time, this transformer KT ensures sufficient isolation of the detector connection from the supply voltage network. On the secondary side of the Air transformer, there are two Zener diodes acting as rectifiers

Gr 1 and Gr 2, which in addition to rectification ensure a constant voltage across two capacitors C1 and C2 . As already mentioned, the connection point 1 between the two chambers K 1, K 2 is at the base of the field effect transistor Tl, which is followed by a further transistor T2 for amplification, in whose collector branch a quiescent current relay A is located

When the alarm connection is idle, the transistors T1 and thus also the transistor T2 are conductive and the relay A located in its collector branch is attracted. If fire gas enters chamber K 2, which is connected to the outside air, the field effect transistor Tl and, of course, transistor T2 are blocked, causing relay A to drop out and, for example, a contact a to trigger the closing magnet for the fire door.

A resistor A3 and a test button PT are connected in series parallel to the two chambers K 1 and K 2.

This test button can be used to monitor the function of the detector and the rest of the detector connection. Pressing the test button fTwird then by means of a resistor R 2 and the resistor R 3 existing voltage divider the voltage at the stationary with the ambient air communicating chamber K 2 reduced this way an increase in resistance to the chamber K 2 is simulated, thereby triggering a Probemeidung , which takes place according to an actual alarm case

The relay A located in the collector branch of the transistor 7 * 2 also monitors a power failure at the same time, since the transistors T and T2 , which are conductive in the idle state, are no longer supplied with the required supply voltage and thus the idle current relay is automatically no longer energized and drops out

1 sheet of drawings

Claims (4)

Patent claims: 1. Circuit arrangement for an automatically closing fire door with a locking device counteracting holding magnet whose excitation circuit can be switched off by means of a fire detector device, characterized in that a single fire detector (Ki, K 2) is coupled directly to the holding magnet of the fire door and via a transformer acting additional winding of the holding magnet is supplied with low voltage 2. Control device according to claim 1, characterized in that on the secondary side of the transformer (KT ) stabilized voltages are built up by means of two rectifiers n (GRi, GR 2) in a doubling circuit on two memories (CX, C2). 3. Control device according to claim 1 or 2, characterized in that Zener diodes are used as rectifiers, by means of which the stabilized voltages are built up on two capacitors (C 1, C2). 4. Control device according to one of claims 1 to 3, characterized in that as switching means 2> between the fire detector (KX + K 2) and the holding magnet a by means of a two-stage transistor amplifier stage (TX, T2) energized break relay (A) is used .