DE1039578B - Ambiguity checker for outputting a signal if several relays of a plurality of functionally related relays simultaneously assume a certain switching state - Google Patents

Description

Certain organs in telephone switching systems contain a large number of relays or equivalent Circuit elements from which, when the organ is working properly, never more than one is in working position. There can also be several such groups of in one organ Relays for which the specified condition applies, can also be present in a telephone switching system several such organs may be present. The proper working of such Group of relays can now be monitored in such a way that one can use a test device determines whether more than one relay is in the working position at the same time, i.e. is energized. Is that the case, in this way a display device is actuated or a signal for reporting this error is emitted. One Such a test device can be called an ambiguity checker.

Experience has shown that such an ambiguity checker must, so that it works sufficiently reliably, meet various requirements; so he should be insensitive to disturbances, they should monitored relays only need a single additional contact for the purpose of monitoring, there should be no special tolerance conditions for the circuit elements of the ambiguity checker must be provided, inter alia. m.

For example, an ambiguity checker can use relays to intermittently fault current received, built up. Such a circuit is shown in FIG. With this circuit certain tolerance conditions for the operating currents of the relay must be observed, which is a Disadvantage of the circuit is. This is explained in more detail on the basis of the following explanations.

In the circuit according to FIG. 1, the potential difference that occurs between two of the contacts which are controlled by the relay to be monitored is evaluated in order to make the display element respond. This circuit has, for example, five relays to be monitored. Each relay controls a test contact. These contacts are located between the corresponding ends and taps of two series circuits of four equal resistors R 11 ... i? 14 and R 21 ... R 24. The series connection of the resistors R 11 ... R 14 is fed with the voltage U from a DC voltage source. An indicator relay M is connected to the ends of the series connection of the resistors R 21 ... R 24. If only a single test contact is now closed, the relay M receives no current, since there is no voltage between its two connections. If, on the other hand, two test contacts are closed, e.g. contacts a1 and a2, ambiguity checker

to deliver a signal,

if several relays at the same time

a plurality of functional

relays that belong together

assume a certain switching state

Applicant:
Siemens & Halske Aktiengesellschaft,

Berlin and Munich,
Munich 2, Witteisbacherplatz 2

Dipl.-Ing. Ulrich Körber, Munich,
has been named as the inventor

one terminal of relay M is supplied with voltage U via contact a1 and the other terminal of relay M via resistors R 24, R23, R22 and via contact 2 a lower voltage, so that because of the voltage difference at its terminals the relay M is traversed by current and thus excited. The effective voltage difference in this operating case is less than a quarter of the total voltage U due to the division of the total voltage across the series connection of the resistors. B. in another case the contacts a1 and a5 are closed, the relay M receives the undiminished total voltage U. When five relays are monitored, the voltage at the indicator relay M fluctuates from about IU to U, i.e. more than four times . If more than two contacts are actuated by the monitored relays at the same time, the voltage at the indicator relay is mainly determined by the contacts that are furthest apart.

This circuit has several disadvantages. It flows through the resistors R 11 ... i? 14 also in the rest position of the circuit a current that has the same order of magnitude as the current during operation. In addition, the voltage applied to the display relay fluctuates considerably as a function of the various switching states, which is disadvantageous for the safety of the operation of this relay. The fluctuation is

809 63W107

the stronger the more relays are monitored. You can only use a limited circuit with this circuit Monitor number of relays.

For the solution of the problem, which is quite analogous in itself, in which it has to be checked whether more than two at the same time Relays of a group of several relays are in the working position, a circuit is already known (Bell Lab. Record, January 1952, Vol. XXX, No. 1, p. 11). With this circuit the monitoring made with the help of a contact pyramid, which is formed from contacts, which from the to monitoring relays can be controlled. If a larger number of relays is to be monitored, then Here, however, it is disadvantageous that many contacts are connected in series and interference due to the addition the contact transition resistances occur. In addition, each monitored relay must have several additional Have contacts.

The circuit according to the invention avoids the disadvantages of the circuits specified above. It is an ambiguity checker that emits a signal if several at the same time Relays of a plurality of functionally related relays assume a certain switching state, in which a test contact assigned to each of the relays is closed. It is characterized by that with a series circuit of preferably equal resistances, a changeover contact serving as a test contact for each resistor is connected in parallel in the same way so that the changeover contacts in the idle state of Relays short-circuit the resistors and, in the switching state, those tapped at the series circuit Feed voltages to a display organ via a directional conductor.

FIG. 2 shows an example of such a circuit arrangement which is suitable for monitoring five relays in this case. The series connection of the resistors Rl ... R5 is at one end via contact p to ground and at the other end to the voltage U. Each resistor is connected in parallel with a switching contact u serving as a test contact of one of the relays to be monitored. On the working sides of each changeover contact, two directional conductors, z. B. GIl, G 12, each connected with one pole in opposite polarity. The other similar poles of the directional conductor G each lead to a connection of a display element M, which here z. B. consists of a relay M.

The ambiguity checker is put into the test state with the help of the normally open contact p. When the monitored organ is working properly, only one changeover contact is ever actuated and switched. Therefore, then only a single pair of rectilinear ladder, z. B. GIl, G 12, upon actuation of the changeover contact u 1 to the series connection of the resistors Rl. .. R5 voltage U connected. However, the display element M, which requires a voltage difference at its connections, cannot respond via this one pair of directional conductors.

However, if two changeover contacts are actuated due to a fault in the monitored organ, a voltage difference occurs at the indicator relay M. This is because two of the resistors i? L ... i? 5 are no longer short-circuited; they then rather form a voltage divider on whose

Center tap half the operating voltage - U can be tapped. For example, the contacts u 3 and u 5 are actuated. The actuated changeover contact with the lower index, i.e. n3, has its center spring at the full voltage U, since it receives this via the series connection of the changeover contacts wl, n2 with an even lower index, which are not actuated and therefore short-circuit their resistors. This voltage is applied to the pair of directional conductors G 31, G 32 via its working side. The actuated changeover contact with the higher code number, that is uS, has its center spring on the center tap of the voltage divider formed from the two resistors R 3 and R 5, which are no longer short-circuited. The second is therefore about his working page

Directional conductor pair G 51, G 52 connected to the voltage -jU . The display relay M is activated accordingly in each case when two changeover contacts

are supplied to the voltage difference U - - = y.

Of the two pairs of directional conductors located at this voltage difference, in each case, where the higher voltage is also, a current path with directional conductors stressed in the forward direction leads through the indicator relay M, which is therefore excited, because of the different polarity of the individual directional conductors. The other directional conductors are loaded in the reverse direction and therefore do not affect the flow of current. The result is that when any two changeover contacts on the indicator relay M are operated, the same voltage difference is always

namely -y lies.

If more than two changeover contacts are actuated as a result of a corresponding error in the monitored organ, the effective voltage difference supplied to the display relay M is even greater, as will be explained below. In the extreme case, all changeover contacts are actuated; then not a single resistor in the series circuit is short-circuited. The highest voltage is then in the working side of the changeover contact ul, it is the voltage U. The lowest voltage is on the working side of the

Changeover switch u5, it is equal to - = - U. If it were not five, but η resistors present, would result as the lowest Spannung- U. The existing adjoined by located between working faces of the change-over voltages with magnitudes also be between two specified limits, have no effect on the indicator relay M , since the associated directional conductors are in the blocked state. The maximum voltage difference on the display relay is U - - U = U \ I ä; U. The loading

The voltage differences sought are therefore, regardless of the number of relays, in the range of

-y to almost U.

However, these differences indicated so far only occur if no noticeable breakdown of the indicated voltage occurs due to the load as a result of the resistance of the relay M. But if the resistance of the relay M noticeably influences the voltages, it is useful to consider the ratio of the currents flowing in the various operating cases. In the most common error case, namely when two changeover contacts are actuated, the current driven by the voltage U flows through the parts of the circuit indicated in FIG. 3. When the interior

5 6

resistance of the voltage source U is negligible fluctuations in the voltages and currents at Anklein, then this is the internal resistance of the indicator, as explained above.

^. "Ι"".. _T. For the two at the outermost contacts of the

Lais feeding source ^ R. For power _{adjustment chain lying directional ladder)} so in the circuit

For this operating case, the directional conductors Gl and GS will therefore also apply

,, _,. l ", _T. r, the following peculiarities: The director of the Eq

Make the status of the relay = -R. In the simple branch of the circuit can be omitted entirely

, _TT . .,. ,,. , _n . _n , " _T V den, since the tapping of a voltage on the way results here the flowing current to I = - ^. _{the resistances} ^ _{1 to} ^ ₅ formed voltage- If all changeover contacts of η resistors ίο part via the contact u 1 does not take place at all. Which are actuated, the directional conductor G 5 driven by the voltage U flows, when the contact n5 is actuated, current is passed through parts of the circuit, as shown in FIG. 4, so that they are indicated. If the number η is sufficiently large point of the directional conductor G 5 a short circuit occurs, one can use the resistor (n -I) -R . In the circuit according to FIG. 5, the flowing currents were neglected and the directional conductors G1 and G 5 are, however, also drawn for the 15

, ,, ",. _n . _n . ".., _T 2 u the principle of the structure of this circuit clearly

current flowing through the relay this time I = ^. _{who (can you grasp} _

The current through the relay M therefore fluctuates between the two extreme operating cases to a maximum of organs instead of relays and corresponding indicators, tubes in the previously described 33% can also be used. Thus, in this case too, the swan circuits will be turned over by ambiguity checkers to counteract the information supplied to the display element used. In Fig. 7, 8 and 9 examples of current are given by the advantageous properties of it. When the switch according to the invention is actuated, contacts are made within narrow limits at the star point of the directional conductor of the hold, the fluctuation also being independent of the number of the monitored relays. 25 tial displacements, which can be used to control the tube because of the opposite polarity of the pairs. 7 is an example of a directional guide, it does not matter which polarity is indicated for control on the cathode side. The series the supply voltage U is applied. You can therefore switch the changeover contacts u 1 ... un is also fed with AC voltage, provided that the connection is ground and the potential —U. If no changeover indicator is suitable. If DC contact is operated, the cathode circuit voltage is always with the same polarity, so the tube V can be interrupted. If only one switch is activated in the two outer switch contact, the cathode is connected to ground via its ten ul and un belonging pairs of directional conductors cathode resistance. The operating chip in each case omit one, namely the one in the blockages of the tube V should be dimensioned in such a way that it is stressed in the direction. 35 is blocked. If two or more contacts are actuated in FIG. 5, the potential at the star point drops, the principle according to the invention is shown. Here is _{at least au} f _- ^ _a b. _{where the tube} i _side nd werein display area M with its one connection directly to that pole of the voltage source U den.

connected to which the central spring of the one, ul, 40. In Fig. 8 a circuit for the grid-side operator two outside in the series connection influence of the display tube V is shown. Here flow switchover contacts u lies, and with its other ßen via the resistors and directional conductor of the network connection via directional conductor Eq. . . G 5 to the working unit NWA the much smaller grid currents, on the side of the changeover contacts ul ... u5. The direction - what a structure with cheaper switching elements as a conductor are arranged in the same way and so 45 allowed in the previous case. The twisted polarity here that when two or more Um- network NWA is actuated corresponds to the network NW 4 switching contacts and one of the directional conductors on passage in FIG. used in the opposite direction. If there is only a single changeover contact wiring of the contacts here between ground and is activated, the voltage + U is on the working side of this contact 50. If no changeover contact is moving due to the nature of the circuit, the grid of the tube receives ground potential U. The indicator relay M is therefore connected to both of the resistors W1 and W2. If there is only one pole at the same voltage and thus does not respond, the changeover contact is activated on the working side. If, on the other hand, two changeover contacts are actuated, the actuated contact also becomes ground potential, then on the working side of the changeover contact, which is closer to ground, there is no change in the operating state of the tube ground, as occurs in the switching. If, on the other hand, two or more contacts be-1 τ- · ο j · ο U _ΐν,,, .. are made, the potential at the device according to FIG. 2, the voltage ^, increases accordingly. About the associated steni _{point of the R} f _chüeit i _{r and thus} also that

A current flows in the forward direction, grid potential, so that the tube V, provided that its loading

which actuates the display relay M. The other directional 6 ° operating conditions were appropriately selected from the

Some of the conductors are only single-pole on the circuit blocked is switched to the conductive state,

or are claimed in the reverse direction, so that they In Fig. 9 is a further circuit example for the

have no noticeable influence. Grid-side control of the display tube with the help

For this operational case, draw the effective network NWA of an ambiguity checker

Parts of the circuit are shown again in Fig. 3. 65. The Wi-Fi used in the circuit

The voltages and currents for the indicator relay derstand W2 should have high resistance to the resistors

are therefore just as large here as they are in the previously treated network NWA . With this circuit should

last case. The same applies if more than two errors are indicated by the fact that despite the

or if all changeover contacts are actuated. Closing the test contact / 'the tube is not conductive

The same 70 is obtained in these operating cases, so that if work is carried out properly

the monitored circuit in the test circuit with each test a display potential occurs. This method has the additional advantage that the test circuit is also monitored at the same time. When the test contact p is closed, the grid of the tube receives the positive potential + U if only one changeover contact is actuated, whereby the tube is made conductive. If, on the other hand, two or more changeover contacts are actuated, there is ground potential or even lower potential at the star point. Since the resistor W2 has a high resistance, this potential is not significantly changed by it. In this case, the tube is not made conductive, which is indicated by the meter.

The ambiguity checkers specified here contain, among other things, a series connection of contacts through which a current flows in the given case. It is therefore advisable to monitor the contact resistance of the contacts. A circuit suitable for this is given in FIG. The there described with XlVZ network can be illustrated by that used in Fig. 1 XlVl network or by the method used in Fig. 5 XW2 network. The already existing display element M is also used as a test element. The changeover contacts pl and /> 2 are used to switch between the two applications of the organ M. In the position shown of these contacts, a continuous current flows from U via the series connection of the contacts to be tested 11 in the network XW 3, via contact pl, the organ M, e.g. B. a relay, and via the contact /> 2 to ground, the relay M is energized. In the event of an error and an associated power interruption, the relay M is no longer energized, which triggers a display. When using the network XW3 for the ambiguity check, the two changeover contacts pl and /> 2 are in the working position. Then the circuit according to FIG. 6 corresponds completely to the circuit according to FIG. 2 or FIG. 5 and thus operates like the ambiguity checker described there.

Claims (7)

Claims: 45 1. Ambiguity checker for outputting a signal when simultaneously several relays of a plurality of functionally related relays assume a certain switching state in which a test contact assigned to each of the relays is closed, characterized in that in a series connection of preferably between the two poles of a voltage source equal resistances (Rl.... RS) to each resistor (Rl. .. R5) a changeover contact (ul ... u5) serving as a test contact is connected in parallel in the same way in such a way that the changeover contacts (ti 1 ... u 5) are the resistors when the relay is idle (Rl... R 5) and, in the switching state, feed the voltages tapped at the series connection of the resistors to a display element (M) via a directional conductor (GIl ... G52). 2. Ambiguity tester according to claim 1, characterized in that two directional conductors XGIl, G12; ... G51, G52) are connected in opposite polarity with one pole each to the working sides of the switching contacts (u-1. .. 11 S) a display element (J /) is located with its two connections on the other similar poles of the directional conductor (GIl ... G 52) (Fig. 2). 3. ambiguity tester according to claim 1, characterized in that a display element (M) with its one connection to that pole of the voltage source (U) on which the center spring of the one (u 1 in Fig. 5) of the two lying on the outside of the series circuit Changeover contacts, and with its other connection to the star point of directional conductors (Eq... G 5), which are on the working sides of the changeover contacts («1 ... G5) are arranged in the same way and polarized in such a way that when two or more changeover contacts (u) are actuated, one of the directional conductors (G) is subjected to transmission. 4. ambiguity tester according to claim 2 or 3, characterized in that a relay (M) is used as a display element. 5. ambiguity tester according to claim 3, characterized in that a tube (V) is connected to the neutral point of the directional conductor, which is under such operating voltages that it is made conductive by the potential shift occurring at the neutral point. 6. Test device for an ambiguity tester according to one of the preceding claims, characterized in that in the idle state of the circuit via the series connection of the idle sides of the changeover contacts (ti), a test element is controlled which tests the transition resistances of the contacts. 7. Testing device according to claim 6, characterized in that the display element (M) of the ambiguity tester is used as the testing element. Considered publications:
Bell laboratory. Record, January 1952, p. 11. 1 sheet of drawings ■ 8ΰ9 6ΪΪ / 107 9.58