DEP0040458DA - Circuit arrangement for automatically securing a telecommunications system - Google Patents

Description

The invention relates to a circuit arrangement for automatically securing a telecommunications system, in particular an automatic telephone system.

In such systems, it is common to connect the consumers divided into groups to a common supply current source and to protect them from short circuits by means of separate fuses in the various groups. The groups are divided into sub-groups in the same way, whereby the sub-groups can e.g. be subdivided into racks and these in turn into selectors with associated relays. Each subsequent distribution level uses more sensitive fuses than the previous one. The groups and subgroups are often secured by so-called coarse fuses, while fine fuses are used in the further distribution stages. The fine fuses can be provided with an alarm contact which is closed when the fuse blows, whereby an alarm device can be actuated and an alarm system can be switched on to indicate and localize the defect.

In known circuits, an alarm relay is used to indicate a blown coarse fuse, which receives current via the fuse in question and normally is actuated. As soon as the fuse or a fuse blows in a previous distribution stage, the relay drops out and an alarm is given.

The known fuse circuits are not particularly useful. It happens repeatedly in practice that a microfuse does not melt immediately in the event of an overload, which makes it possible that a "less sensitive" coarse fuse melts rather than a microfuse and thus a larger number of consumer groups is disturbed than would be necessary. Even a fuse can ultimately break through in the event of a long-term load.

In many cases, a short circuit that occurs is only of a particularly short duration, e.g. as a result of the fact that a falling wire creates a wrong contact for a moment while working in the central office. In these cases, a short circuit occurs, as a result of which one or more fuses can blow, but the short circuit is remedied again at a subsequent instant. If voltage were present again at this moment, telephone operation could resume normally.

The invention overcomes these disadvantages and it is characterized in that at least one of the fuses is bridged by a circuit which has a series connection of an alarm relay and a fuse.

This measure has the effect that, if the first-mentioned fuse breaks down, the consumers fed by the fuse still receive power via the series connection of the alarm relay and the second fuse, with the alarm relay being energized. If it is a short circuit of a short duration, there is a good chance that the second fuse will remain intact and telephone traffic will continue unhindered.

The invention is explained in more detail with reference to the drawing, in which the feed part of a telephone exchange is shown schematically.

The consumers fed from the common battery Ba are divided into a number of main groups, of which in the

Figure only groups A and B are shown. Each main group is in turn divided into a number of sub-groups (a, b), while each sub-group is similarly divided into racks, which in turn are divided into consumers per voter. With each subdivision, the supply circuit is divided into a number of branches that are protected by separate fuses.

The main groups A and B are fed via coarse fuses SA and SB of e.g. 15 A. The ends of the fuses that are not connected to one another are each connected in series with a fuse (S'A or S'B) and a resistor (RA or RB) with one end of a winding HA (sub) 1 of an alarm relay HA common to the main groups connected. The other end of the winding is connected via a coarse fuse SAB of e.g. 20 A to the common ends of the fuses SA and SB and to the negative terminal of the battery.

The resistance of the relay winding HA (sub) 1 in series with RA or RB is high compared to the resistance of the fuses SA and SB, so that only a small fraction of the feed currents of the main groups A and B flows through the winding HA (sub) 1. This fraction is further reduced by the fact that the winding HA (sub) 1 is bridged by a resistor RAB.

When the fuse SA melts, the main group A receives current via the bypass path formed by the fuse SAB, the parallel connection of the winding HA (sub) 1 and the resistor RAB, the resistor RA and the fuse S'A. At the first moment, the feed current essentially only flows through the resistor RAB, since the current flowing through the relay winding does not immediately reach the full value due to the self-induction. The resistance RB is large compared to the resistance of the parallel connection of the winding HA (sub) 1 and the resistor RAB, so that only a small part of the feed current of the main group A flows through the fuse SB. Fuse SB is therefore not additionally burdened to a noteworthy extent. The same result is achieved if the resistors RA and RB are equal to judges to be replaced.

The relay HA is now energized and closes a hold circuit for itself via its normally open contact H'A, second winding HA (sub) 2 and microfuse S1, while the alarm lamp L1 is also ignited to indicate in which group the error occurs. An acoustic alarm device is also activated via contacts (not shown).

If the melting of SA is the result of a short circuit of a short duration, the delayed melting of a microfuse or a heavy load of a long duration of the fuse, the fuse S'A does not have to blow after the fuse SA has blown, and the supply can Group A can go on unhindered and the telephone traffic is not disturbed.

In the event of a long-term short circuit, S'A will of course also melt and group A will be de-energized. However, before this takes place, the alarm relay has been actuated.

In the circuit shown, the error indication of a coarse fuse of the main groups is effected in pairs by a single alarm relay. Naturally, each of these relays can also serve more than two main groups.

A similar circuit is used to secure the subgroups. For example, subgroups a and b of main group A are assigned an alarm relay ha.

The supply circuits of the holding windings of the alarm relays of the main and subgroups contain fine fuses S (sub) 1 or S (sub) 2, e.g. 1 A. These fuses are connected to an alarm contact S '(sub) 1 or S' (sub) 2, which is closed when the fuse blows. If the fuse S (sub) 2 blows, as a result of the closing of the contact S '(sub) 2, a circuit is created from earth via normally open contact S' (sub) 2, resistor R2, winding HA2, the alarm relay of a main group, microfuse S ( sub) 1 closed to the negative pole of the battery. As a result, relay HA is energized and the alarm device is activated. To localize the fault, one or more alarm lamps L (sub) 2 (which can be arranged on different distribution panels) are switched on. The resistors R1 and R2 are chosen so that when the contact closes

S '(sub) 2 the lamp L1 does not light up.

In a similar way, a defect in the fuse S (sub) 1, in which the contact S '(sub) 1 is closed, is indicated by means of the alarm relay ha of the subgroup.

Claims (3)

1.Circuit arrangement for automatically securing a telecommunications system, in which the supply circuits contain fuses, in particular an automatic telephone system, characterized in that at least one of these fuses (e.g. SA or SB) is bridged by a circuit that has a series connection of an alarm relay (HA (sub ) 1) and a fuse (SAB). 2. Circuit arrangement according to claim 1, in which the supply circuit is divided ind by separate fuses secured circuit, characterized in that the non-interconnected ends of at least two of these fuses (eg SA, SB) each via a series circuit a fuse (S'A or S'B) and a resistor or a rectifier (RA or RB) are connected to one end of a winding (HA (sub) 1) of the alarm relay and the other end of the winding via a fuse (SAB) to the common ends the fuses (SA, SB) is connected. 3. Circuit arrangement according to claim 1, characterized in that the alarm relay, when energized, closes a holding circuit for itself via a second winding (HA2) arranged on the relay.