DE915791C - Signaling system with several detectors - Google Patents

Description

Signaling system with multiple alarms The invention relates to a Signaling system with several detectors, such as those used for the purpose of fire alarms, Police reporting, guard control and the like is used. The detectors are lying in such a system usually in one or more loops. For safety reasons it is required that this also applies to simultaneous or short successive actuation from two detectors the message arrives even more clearly at the control center. This condition has so far been met by having either two or more recording devices in, the control center, or a memory was provided in which the incoming messages were stored until the recorder for reception was free.

The invention proposes to simplify such systems that the different. Connections assigned to detectors through time-dependent switching means to scan at certain time intervals in order to display existing messages one after the other To the recipient. The connections assigned to the various detectors, for example the two connections of a loop "contain, according to a further invention, blocking relays, which disconnect the other connections while a message is coming in and only switch on after the first message has ended. The flow of the message he follows then, if at the same time the time-controlled contact., the z. B. from one Clock may be closed.

In contrast to known systems, in the present exemplary embodiment a -, Uelder used whose magnet in the unexcited; Status of the detector's sequence locks and only releases after excitation. When the detector is activated, its sequence prepared so that it expires when the release magnet is excited. Of the The release magnet, in turn, is dependent on the closure of the loop that passes through the time-controlled contact and a contact of the blocking relay of the other loop connection then takes place. when the receiver is ready to record is.

The time-dependent control of the loop connections is natural even with the usual closed-circuit current loops with blocking magnets instead of the one here Embodiment described release magnets possible.

In Figs. I and 2, an embodiment of the invention is shown. Lying in the loop L i. the detector contacts in i to M4 of the combined fire and watchdog alarms M i to 314. The battery B i is used to power this loop, and the line relays LR i and LR: 2 take the incoming messages. up and give it continues in a manner known per se to the indexing magnet of the type printer.

The loop L2 contains the windings of the release magnets Fi to F4, which are designed in contrast to previously known iNfel # countries. that they block the process of the detector in the unexcited state and only release it after excitation. When the detector is triggered, contact sets up to 94 are actuated, which cause this excitation. -The structure of a detector drive is shown in Fig.:2. On the axis i is the type disk 2, on the circumference of which the control spring of the contact spring set m slides. The locking disk 3, on which the torsion spring 4 engages, is firmly connected to the type disk. The front end of the torsion spring 4 is attached to the winding pulley 5 , which is rotatable on the axis i and has the keyhole for the key 6 . In the rest state, the disk 5 is pulled by the torsion spring A so that it rests with the nose 7 against the stop lever 8 , which is under the influence of the spring 9 . The arm io of a further lever rests on the disk 5 and is rigidly connected via the axis ii to the release lever 12 influenced by the spring 16. The rear extension 13 on the lever io actuates the changeover contacts g. The electromagnet F acts on the lever 14, which is pulled against the locking disk 3 by the spring 15. Both windings of the electromagnet F are shorted g in the idle state through the contacts, so that, as i is apparent from Fig., The loop g immediately above the contacts i runs to 94. In addition to the detectors designed according to Fig. 2, the loop L2 includes the relays A and B with the contacts ai and a,: 2 as well as bi andb2 and the battery B2, the battery B3 and the hydrogen resistance EWTV. The ferrous hydrogen resistance EWW, which is located in front of batteryB3, is used to limit the current in the event of an earth fault near the control center.

From a time-dependent contact, for example a KontaktZu, which is controlled by a central clock, a relay Q is excited at short time intervals, for example from 1/4 '/ to 2 ", and closes or opens its contacts qi and q 2, which through each a, resistance Wi and TJ-2 1 are bridged in idle state. d h 'in ab-Orefallenern relay Q, the contact is qi closed and the Kontaktq.:. 2 opened the necessary in the safety circuit quiescent current control is performed with a for the excitation of the relays insufficient weak current through the resistors Wi and W2-. The instrument J indicates this quiescent current. The two windings of the magnets F are connected against each other in such a way that their magnetic effects cancel each other out when current flows through the same direction They are therefore overly awake and calm even with 1 flip of the contacts g .

To send a message, use the key to turn the disc5 clockwise one turn. First, the spring4 is pulled up. Shortly before the end of the revolution, the nose 7 actuates the lever 21 so that it in turn. takes the lever 1: 2 with it. As a result, the locking disk 3 is released from the lever 1: 2. At the same time, the contacts g are switched so that the middle spring is connected to earth. Is contact q i just closed at this moment, as shown. so comes. a circuit is established via the left branch of loop L: 2: earth, contact - 2, li111,2 winding of F 2, q i, b 2, a i, relay A, battery B 2, B 3, earth.

Magnet: F2 attracts its armature 14 and thereby releases the locking disk 3 so that the detector expires. The process is regulated by an inhibitor which is not shown in FIG. 2. In the course of the revolution, the contact m 2 sends out the impulses set by the type disc, which the. Mark the detector. These are recorded in the control center by the LR relay and evaluated in a manner known per se.

The Aufztigscheibe 5 is held again by the lever 8 after completion of the rotation and removal of the key. The lever io falls into its rest position, spring set g is held back, locked, and lever 12 stops the disk 3 with the type disk: 2 after it has completed one turn.

In the control center the relay A, whose response time is longer than that of the magnet F, responds, interrupts with the contact ai dien, current in the loop L2 and opens with a: 2 also the. right loop branch. The release of another detector is therefore prevented until relay A returns to its rest position after detector 1112 has expired. The contact a3 completes a circuit for the delay relay V, further from the line relay LR i and LR2 is dependent, in such a way that it does not respond in a manner not shown during the course of message "and only after a certain delay of the message its contact, v opens, so that the relay A drops out again and restores the idle state.

If the switching of the contacts g takes place at a moment in which q i is open and q 2 is closed, then flows in: Current in the right loop part of L-- and, the right winding of: F2-. In this case relay B responds.

The messages are recorded either by the line relays LR i and LR 2 at the same time if the loop is undisturbed, or in the event of a ground fault or wire break by one of the two relays alone, so only one receiving device is necessary. If another detector is activated while a report is in progress, the security guard can open this detector unhindered with the key and also pull the key out again. When switching over the contact g , however, no circuit for the magnet F is established. The locking disk 3 with the type disk is stopped by the lever 14 shortly after leaving the rest position. In this position, the tip of the lever 12 rests on the nose of the locking disk 3, so that the contact g remains switched.

It is now assumed that the detector F 3 was actuated at the same time as the detector F 2. Then contacts 93 interrupt the current in, the right winding of F2. The right winding of F3 is switched on. However, a complete circuit for this winding will not be established as long as contact q2 is open. Since the relay A was already energized via the just closed contact ai, a circuit for the relay B cannot be established until the contact a: 2 has been closed after receiving the first message and then the contact q2 to energize relay B closes. Due to the periodic excitation of the relay Q it is achieved that only one message can run despite the preparatory triggering of several detectors. Even though all the conditions of the safety circuit are met, only one receiving device is required.

Claims (2)

PATENT CLAIM: i. Signaling system with several detectors, their messages consecutively recorded by the same recipient, are marked with ", that the connecting lines of the detectors by time-dependent switching means in certain Time intervals are sampled in order to present messages one after the other to the recipient to feed. 2. Signaling system according to claim i, characterized in that the various detectors associated connections contain blocking relays (A, B) , which separate the other connections during the arrival of a message and only switch on after the first message has ended, if at the same time a time-dependent z. As of a clock controlled contact (q i, q 2) is closed. 3. Detector for systems according to claim i, characterized in that when actuated its sequence is prepared in such a way that its triggering is only dependent on the excitation of a release magnet which is then actuated via the detector line: when the receiver is ready to receive is. 4. Detector for guard control systems according to claim 3, characterized in that the winding of the drive spring (4) is effected by rotation of the key (6) and, at the end of the winding movement, a first lock (12) for the spring sequence is lifted so that the spring sequence now depends on the armature (14) of the release magnet (F): is.