DE167133C - - Google Patents

Description

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IMPERIAL

PATENT OFFICE.

The purpose of the present invention is to keep electrical signaling systems with several signaling devices in a common line, in which the signaling occurs through a series of current circuits and interruptions in the line, operational in the event of a line break. It is already known to equip such systems to achieve the stated purpose with two receiving devices and, in the event of a line break, to transmit the messages via earth and depending on the side on which the working reporting device is to the break point, to one or the other receiving device. The present invention now allows, in the event of a line break, a secure transmission of the messages over earth using a single receiving apparatus. The invention consists in that, in the event of a line break, the messages from an apparatus on one side of the break point are transmitted via earth, but otherwise in the usual way to the receiving apparatus, whereas the signals given by a detector on the other side of the break point are transmitted on the occurrence of wire break together with a Hilfsbatter _ä also to ground on an IE in the detector loop switched on relay function, which in turn affects a particular circuit is connected to which of the reception apparatus at line break by hand.

The receiving apparatus can be of any shape, e.g. B. a Morse code. In the embodiment of the invention on which the following description is based, which is illustrated schematically by the accompanying drawing, it is assumed that it is a fire alarm system in which, as is usually the case, the signals in multiple forms, e.g. B. be reproduced by writing, on a number display apparatus and by audible characters. The relay R ₁ is to be regarded as the receiving apparatus, which acts on local circuits in which the apparatus (omitted in the drawing for the sake of simplicity) for the actual character reproduction are arranged.

If a line break occurs in the quiescent current, e.g. B. at the point α , a signal that is automatically given in such a case, z. B. by the falling armature of the relay R _{1 as} a result of the power interruption closes an alarm circuit, the three switches b _u b. ₂ and b _{3 brought} into the position indicated by full lines. As a result, the relay R ₂ and the auxiliary battery B _{2 are} switched on in the detector loop and the loop is also connected to earth _{via the switch ^ 1} and the relay R _s at E. Furthermore, through the switch b ₂ , the previously existing direct connection between the line d and the receiving set. R ₁ (dashed digit

treatment · interrupted by b ₂ ) , so that line d is now only connected to R ₁ via line g, drop flap η and line k . The reporting apparatus M, M ₂ . . . are set up so that if any of them is put into action, always automatically a ground connection E ₁ respectively. E _{2 is} produced. If a signal is now given on one side of the break, for example by the apparatus Ai ₁ , the signal currents take their way from the battery B ₁ via R ₁ , line k, flap n, line g, line d, detector M ₁ , the earth connection E ₁ and E, line f and switch b _± to the battery B ₁ .

If a message is sent from an apparatus on the opposite side of a, for example from M ₂ , this is transmitted by current flows which are transmitted from the battery B. ₂ via the relay R ₂ , switch b _s , the line e, the earth connections E ₂ and E and the line / run back to battery B ₂ . The armature c of the relay R ₂ follows the power circuits and interruptions in the detector M ₂ and alternately closes and opens the contact z. The contact s and the armature c are respectively through the lines h. i _x with a circuit in connection, which is formed by the resistor W ₁ , the lever b ₂ , the receiving apparatus R ₁ , the battery Β _Λ and the line I and on the other hand can also be closed via the contact χ and the line i ₂ . Since the contact χ is interrupted by the relay R ₃ , the mode of operation of which will be discussed later, at the first current flow coming about via the line / and relay R ₂ , the armature c of the relay R ₂ causes the current circuits and - Interruptions are transferred indirectly to the circuit just mentioned, thus putting the receiving apparatus R ₁ into action.

If, when the detector M ₁ or another detector is working on the same side of α, a detector is connected to earth on the other side of a , it must be prevented that a current through the earth connections E ₂ and E ₁ , the lines d , g and k, the receiving apparatus R ₁ , the batteries B ₁ and B ₂ and the line e of the anchor of .R _{1 is} held. This is avoided in that the batteries B ₁ and B ₂ , as is known per se, are connected in opposite directions, so that their effects in the circuit mentioned cancel each other out completely with the same magnitude of the electromotive forces.

The anchor of R ₁ could also be held in place if, while the detector M _{2 is working,} by placing a detector on the opposite side of α, a current from B ₁ via lines k, g and d, earth, line f and receiving apparatus R _{1 would} come about. However, this is prevented by the fact that, when the armature c of R _{2 is} first attracted, the contact m is interrupted by the dropping of the flap η and so the line g is disconnected from the receiving apparatus R _1. But that is not reversed, for example if the detector M ₁ operates by Anerdelegen a detector in line e of the armature attracted c and so the radiation emanating from M ₁ message by interrupting the connection of the line D with the receiving apparatus R ₁ is disturbed, at the start the message the previously short-circuited resistor W ₂ in the line / switched on, so that a current coming about via the winding of R ₂ is not strong enough to cause an attraction of the armature c.

The resistor W ₂ is switched on by the flap q when the armature r drops from A ₁ . The short-circuiting of the resistor W ₂ is secured in the idle state by the fact that the special circuit formed when the line break occurs and contains the receiving apparatus R ₁ and the resistor JP ₁ , on which the relay R ₂ works, as already mentioned, via the drop flap p is closed, so that the apparatus A ₁ is energized and keeps its anchor tightened. When a message arrives, this circuit is interrupted in that the relay R _s connected to line f picks up its armature 0 when it is first connected to earth, causing flap p to fall and interrupting contact χ.

If there is _{a message from Ai 2} , then, as already mentioned, when the armature of the relay R ₂ goes back after the first attraction, the resistor W _{2 is switched} into the circuit of the relay R _{2 by the de-energization of .R 1} . Since the upstream connection of the resistor according to the above has the purpose of making an attraction of the armature c impossible under certain conditions, special precautions must be taken to ensure that the correct operation of the relay R ₂ by the resistor W ₂ does not prevent the rest will. This has been achieved in the W ^T else that c by the start of a message at first without prescreening of resistance attracted anchor a lockout is triggered, preventing the full decline of the anchor during re-drop. The flap η released when the armature c is first attracted assumes the position indicated by dotted lines in the drawing after it has dropped. When it falls, the anchor will only be able to go back until the nose s connected to it hits the flap η. To attraction

of the armature from this position, however, a lower amperage is sufficient than is required for attraction from the original rest position, and the distance from the magnetic pole, which the armature assumes during retraction, is such that the resistance w ₂ in the winding when the resistor is switched on the current strength of R _{2 is} able to cause the armature to be attracted.

ίο If, in the event of a line break, an earth fault occurs at the same time on line d , the receiving apparatus would be de-energized with the construction of the relay R ₃ shown in the figure, and its armature could not be kept attracted at all. Likewise, a ground fault occurring in part e of the loop would cause the armature to be attracted by R ₂ and thus result in a separation of part d of the loop from the receiving apparatus. However, these consequences can be avoided if the relays R ₂ and R ₃ are set up as shown in FIG. 2 so that they BEZW the rune circuit for the receiving apparatus. Do not interrupt the connection of the line d with the receiving apparatus until its armature drops again after an attraction caused by a current flow over earth. For this purpose, for example, the armature 0 of R _{3 is provided} at one end with a pawl t which, under the pressure of a spring u, rests against a stop of the armature. The pawl v, by which the contact χ is kept closed, lets the pawl t pass when the armature is attracted. When the armature retreats, however, the pawl ν is pushed to the side by t and the contact χ is opened. The pawls f and v ' act in exactly the same way on relay R ₂ . The drop flap η is provided here with a bracket y , which, similar to that previously described for the embodiment shown in FIG. 1, prevents the armature c from retreating completely.

Since in the case of a ground fault on the line e as long as no message is, keeps the relay R ₂ its anchor, permanently tightened, it would in the illustrated in FIG. 1 arrangement of the contact ζ be permanently closed, i.e. thus at a message from the line the opening of the contact χ which then takes place will be ineffective and the receiving apparatus will remain energized via W ₁ , line h, contact z, line I ₁ and line I , so that the message would not be transmitted.

To prevent this, in the arrangement of the relay R ₂ according to FIG. 2 in the line h in front of the contact ζ a switch is also arranged, which is only closed when the armature c goes back after the first attraction. . The line h is led to a contact spring which is connected to the flap η and which closes the contact z ' when the flap η falls when the armature c is retreating. The device described here only needs to be present once in a system with several detector loops. It is only in this case that the switches b _lt b ₂ and b _{3 have to} be designed in such a way that they allow the safety equipment to be connected to any detector loop. The safety device can also be connected to several or all detector loops at the same time if there is a line break in them at the same time.

Claims (8)

Patent Claims: i. Circuit arrangement for securing the signaling in the event of a line break in electrical signaling systems, in which there are several signaling devices in a common line, which when triggered cause a series of current circuits and interruptions in the line, characterized in that the signaling devices on one side of the Break point (a) outgoing signals are transmitted via earth in the same way as in normal operation to the receiver, whereas the signals given by a detector on the other side of the break point are switched to an auxiliary battery (B ₂ ) in the detector loop in the event of a line break Relay (R ₂ ) act, which affects a special circuit containing the receiving apparatus (R ₁ ) , which is formed in the event of a line break. 2. Embodiment according to claim 1, characterized in that the main battery (B ₁ ) and the auxiliary battery (B ₂ ) connected in the event of a line break are connected in opposite directions for the purpose of preventing the mutual interference of signaling devices on opposite sides of the break point. 3. Embodiment according to claim 1, wherein the armature of the receiving apparatus is kept attracted in the idle state of the system, characterized in that no closed circuit for the receiving apparatus is formed by the special circuit referred to in claim 1 in the event of a line break, which by a special relay (R ₃ ) is interrupted when a message arrives. 4. Embodiment according to claim 1, characterized in that with a message from an apparatus on the relay (R ₂ ) associated side of the break point through the relay (R ₂ ) at the same time the connection of the receiving apparatus with the detectors on the other side of the break point is interrupted to the Purpose of preventing the message from being disturbed by one of the last-mentioned detectors. 5. Embodiment according to claim 1, characterized in that in order to prevent that when a detector is working, the relay (R ₂ ) comes into full effect by Anerdelegen a second detector assigned to it, in the circuit of the relay (R ₂ ) at the beginning a resistor ( ¹ W ₂ ) is switched automatically for each message. 6. Embodiment according to claim 1 and 5, characterized in that for the purpose of enabling the proper operation of the relay (R ₂ ) when the resistor (w ₂ ) is switched on, by the armature initially attracted when the resistors are switched off (n> ₂ ) a blocking is triggered, which prevents the full retraction of the armature, so that a weaker current than before is sufficient for repeated attraction of the armature. 7. Embodiment according to claim 1 and 4, characterized in that to prevent interference with earth faults, the relays (R ₂ and RJ are set up so that their armature attracted to a current flow through the windings via earth BEZW the special closed circuit for the receiving apparatus. only interrupt the connection of the receiving apparatus with the reporting apparatus on one side of the break point when it returns to the rest position after the current flow has ceased. 8. Embodiment according to claim 1 and 7, characterized in that in the affected by the relay (R ₂ ) special circuits for the receiving apparatus, a switch is arranged which is closed by the relay (R ₂ ) when its armature after the first +5 attraction decreases. 1 sheet of drawings.