DE959199C - Test arrangement for testing permanently installed electrical components in telecommunications systems - Google Patents

Description

The invention relates to a test arrangement for testing permanently installed electrical components Components in telecommunications systems in which plug-in components are also provided and where not all connections are connected to the bases of these plug-in components.

Telecommunication systems are used to transmit messages with the most varied types of electrical components, for example relays, coils, capacitors, resistors, step switches, Rectifiers, etc., equipped.

It is known that some of these components, which require special maintenance, can be plugged in to execute. In this case, the component is on a plug-like base plate mounted and only the base equipped with the corresponding connections by soldered connections connected to the system. For manufacturing reasons, both the base and the base plates of these components are also made uniform, d. i.e., they are all with one Equipped with the same number of evenly arranged contact pins or socket connections. Here but in the interests of a uniform design, the maximum requirements for contact pins, invoices must be carried, many plug-in components have a certain number of unconnected Contact pins and their base unconnected connection

Conclusions. Such pluggable components can be checked by removing them from their socket and insertion into a corresponding measuring device.

S For the majority of the components used in telecommunications systems, there is a plug-in type Execution not in question; rather, they are permanently installed and when the system is manufactured hard-wired by soldered connections. the

ίο - review and maintenance of these permanently installed Components is carried out in such a way that the measuring connections required for the test have loose plug connections (Alligator clips and banana plugs) are brought up to the measuring devices.

This type of connection is, on the one hand, time-consuming and confusing and, on the other hand, also burdens the measurement result with a certain measurement uncertainty, caused by poor contacts.
The invention is based on the object

ao to create a test arrangement with which the inspection of permanently installed components required measuring connections in a metrologically safe and electrically conductive connection can be connected to the measuring devices.

According to the invention, this object is achieved in that switching points that a checking of the Enable built-in electrical components, with otherwise unconnected base connections pluggable components are firmly connected, so (ate through one-end pluggable components corresponding test plug a test device can be attached to the permanently installed components.

In this way, everything in the plant can become stuck

built-in electrical component without the need for additional measuring sockets in the manufacture of the system must be provided, via a plug-in connection with a measuring device in a metrologically safe and be connected in a highly electrically conductive manner. It is only used to conduct the exam to pull out a plug-in component and in its place one connected to the measuring device Insert test plug.

Although it is known in circuits equipped with tubes, operational tests of the tubes as a result to enable a test plug provided with sockets between the tube and the base is used; but this test plug only allows the tube contacts to be connected to separate running electrical circuits and to switch on any measuring instruments in them, which only allow a check of the easily removable tube during operation. Additional Test circuits via unconnected tube contacts are not available here.

According to a further embodiment of the invention, the various measurements that are used for Checking a single component, for example to measure the response and release times of a relay, are required to be carried out so that in the measuring device individual to the Connections leading to plug contacts of the test plug are connected to switching contacts of a rotary switch are, over the different measuring instruments according to its switch position connected to the component to be tested.

According to a further embodiment of the invention, a further advantage can be achieved by that the plug contacts, the test plug when plugged in also establish a connection between wired, Base connections of the pluggable components connected to the power source of the system and the measuring device. In this way it can be achieved that in the Measuring device for testing the power sources of the telecommunications system can also be used.

Details of the invention emerge from the following exemplary embodiments:

In the drawing shows

Fig. Ι a known embodiment of a plug-in Telegraph relay with a corresponding socket,

Fig. 2 is a base circuit diagram of this relay,

3 shows a transmission circuit ■ with measuring connections according to the invention,

4 shows a measuring device which is used for testing permanently installed components. this according to the invention is connected,

5 shows a known preselector circuit with measuring connections according to the invention.

The Fig.'I shows a perspective view of a pluggable executed telegraph relay, which consists of the Relaisschutzkapp.e 22, under which the coils and armature contacts are arranged, and the base plate 23, which for manufacturing reasons for all types of this type of relay uniformly with sixteen knife-like formed plug contacts 1 to 12, Z, A, T and 13 and two guide pins 25 is equipped. Some of the plug contacts ι to 12, Z, A, T and 13 are firmly connected to the coils and armature contacts arranged under the protective cap 22, so that the relay can be connected to a circuit by inserting it into a corresponding plug-in socket 26 . The guide pins 25 are used to define the insertion position. The plug-in base 26 has three bores 27 for mechanical fastening and, corresponding to the sixteen plug contacts of the relay, sixteen base connections 1 'to 12', Z ', Ä, T' and 13 ', preferably soldering lugs, for connection to the circuit.

In FIG. 2, a so-called base circuit diagram of this relay, ie a circuit diagram of the arrangement of the plug contacts in the base plate 23 of this relay, is shown. The plug contacts designated in Fig. 1 with 1 to 12, Z, A, T and 13 are, as the circuit diagram shows, arranged in four rows of four each. The plug contacts marked with the numbers 1 to 12 and 13 are intended for the connection of relay windings. The armature A, the normally open contact T and the closed contact Z of the relay are connected to the plug contacts designated Z, A, T. In this example, it is the base circuit diagram of a relay often used in telecommunications systems, which has two windings WT and

WIl is equipped. The winding Wl is connected to the plug contacts ι and 4, the winding WU to the plug contacts 5 and 8. As can be seen from this base circuit diagram, certain plug-in relay types used within a system have a certain number of non-connected plug-in contacts. Corresponding to these relay types, some of the base connections 1 'to 12', Z ', A, T' and 13 'are also not connected on the plug-in base 26 of the relay.

In Fig. 3 a known transmission circuit, the input of which is labeled Eg and the output of which is labeled Ag , is shown. The transfer

ij5 is equipped with a plug-in component, namely the telegraph relay B, and several control relays V, W, X and Y that are permanently installed in the circuit by means of soldered connections. On the right-hand side of FIG. 3, the telegraph relay is shown framed by dash-dotted lines. When the relay B is plugged in, its plug-in contacts labeled 1 to 12, Z, A, T and 13 are connected to the terminals of its plug-in base labeled with the same name on the left-hand side of FIG.

For the operation of the transmission circuit is the telegraph relay B with two windings, which are connected to the plug contacts 1, 4, 5 and 8 and connected in series by connecting the plug contacts 4 and S, and with an armature b with one idle and one Working contact Z and T equipped. The normally closed contact Z, the normally open contact T and the armature b are connected to the plug contacts Z, A, T. The telegraph relay thus has seven connected and nine unconnected plug contacts. Corresponding to the shading of the telegraph relay, only seven socket connections are of course used to connect the relay.

According to the invention, these unconnected base connections are now permanently connected to suitable switching points of these components for testing permanently installed components. A permanently installed component in the transmission circuit shown in Fig. 2 is, for example, the relay Y. Suitable switching points, for example for a response time measurement of this relay, are points 20, 21 and 22. The measuring connections of these switching points permanently installed according to the invention with the unconnected socket connections 2, 13, 6 of the telegraph relay B are shown in dashed lines in FIG. 4 shows a measuring device. It consists of a timing device Z, an ammeter /, a measuring initiation relay M, which is equipped with the two contacts mi and ni2 and in whose excitation circuit a test button Pt initiating the test process is arranged, and the rotary switch Ds provided with arms 1 and 2.

According to the invention, the measuring device is provided with a test plug designed according to the base of the telegraph relay, the plug contacts 1 " to 12", Z ", A", T "and 13" of which are shown on the left-hand side of FIG a plug contact are connected to the arm Ds 1 and another plug contact is connected to a switching contact of the rotary switch Ds . The individual plug contacts of the test plug could also only be connected to the switching contacts or only to the arms of the rotary switch.

In this way, the rotary switch can be used to connect different test objects to a Measuring instrument or used for a measurement object on various measuring instruments.

However, differently wired test plugs can also be used for different measurements will.

The mode of operation of the circuit shown in FIGS. 3 and 4 is described with reference to a response time measurement of the control relay Y shown in FIG. The switching processes run as follows:

The pluggable telegraph relay B shown in FIG. 3 is pulled out and the test plug inserted in its place, which belongs to the measuring device shown in FIG.

To measure the relay response time of relay Y , the rotary switch Ds shown in FIG. 3 is to be set to position 1. This completes the connection of the test object to the measuring device.

At the beginning of the measurement the test button Pt is pressed and the measuring relay M responds (■ + TB, plug contact T ", relay M, test button Pt, plug contact Z", - TB). The switch «1 closes the excitation circuit of the control relay to be tested Y (- TB, Y, measuring point 20, plug contact 2", switching arm ' Ds 1 in position 1, contact mi, Sahaltarm Ds2 in position i, plug contact 13 ", switching point 21, earth ).

Simultaneously with the start of the excitation of relay Y , contact m2 closes a measuring circuit for timing device Z * (switching point 21, plug contact 13, measuring device Z, «2, plug contact 6", switching point 22, contact 3/1, switching point 21) Z registers the start of the measurement and continues to count continuously in time units. As soon as the relay Y has responded, its contact y 1 opens the measuring circuit described above and thereby ends the measurement. The response time of the relay Y can be read in a known manner on the measuring instrument Measurement is finished. Now the test plug is pulled out and the telegraph relay is reinserted.

In Fig. 5, a known preselector circuit is shown. The mode of operation of the circuit is as follows: If the subscriber Tn wants a connection, he short-circuits winding I of the indicator relay Ss using the call button AT and thereby increases the current flowing through the subscriber loop to the response current strength of the relay R (- TB, contact rs, b in position Z, contact / 2, Ss II, AT, EM, SK, contact / 1, winding I of the relay R ,. + TB).

In this circuit, the relay R responds and opens the short circuit of the winding-II of the relay A with the contact? '2.

lai A trennsei tig energized and opens by means of its armature α the short circuit of the winding II of the relay R. Since during the operation of the relay R, the contact π winding I short-circuits of this relay, keeps the relay R further energized (-TB over its winding II , Winding II of relay R ₁ ■ armature α in separating layer T ₁ + TB) . When relay R responds, contact r3 closes a circuit for rotary magnet D of preselector ίο (earth, selector arm ei4 in position o, contact rß, rotary magnet D, relay reverser Ru, - WB). The selection starts to run and searches for a free group selector GW in a known manner.

As can be seen from this description of the circuit, a response time measurement of a relay Without a plugged-in telegraph relay, this cannot be carried out in a simple manner. This difficulty but can be eliminated according to a further embodiment of the invention in that the ao test plug of the measuring device is designed as an adapter plug for the telegraph relay. on In this way, it is possible, for example, to use a built-in measurement object in the manner described above Type to be connected to the unconnected socket connections of a pluggable telegraph relay and to connect these unconnected socket connections to a measuring device, at the same time but leave the telegraph relay in the circuit. Such a measurement is based on the Fig. 5 is described below:

Similar to FIG. 3, in FIG. 5 suitable measuring points 30, 31, 32 and 33 for a response time measurement of the relay R are connected to the unconnected socket connections 2, J, 6 and 13 of a telegraph relay socket. Before starting the measurement, first the telegraph relay B is pulled out, then the test plug of the measuring device (according to FIG. 4), which is designed as an adapter plug, is inserted in its place, and the telegraph relay B is plugged into this adapter plug. To measure the response time of the relay R , the rotary switch Ds (Fig. 4) must be set to position 5. The measuring device is thus connected to the test object and the measurement can begin. If the person measuring presses the test button Pt ₁ , the measuring relay M is activated, as already described, and its contact m 1 closes the excitation circuit for the relay R via winding I, namely + TB, winding I of relay R, switching point 30, Plug contact 2/2 ", switch arm Ds 1 in position 5, resistor RN, contact mi, switch arm Ds 2 in position 5, ammeter /, plug contact 3" / 3, switching point 31, armature b in position Z, contact r2, -TB.

Due to the adjustable replica resistor RN and the ammeter / in this circuit, it is possible to adjust the response current of the relay R in its strength to the current that otherwise causes a participant by pressing the call button AT before the actual response time measurement. Simultaneously with the closing of the prepared excitation current circuit by contact m 1, contact m 2 closes the measuring circuit for timing device Z (switching point 33, plug contact 13/13 ", timing device Z, contact« 2, plug contact 6'76, switching point 32, contact r3 , Selector arm d / \. In position o, switching point 33). The timing device starts up and registers the start of the measurement, as already described. As soon as the relay R responds, contact r3 opens this measuring circuit and thus interrupts the time measurement time between the start of the measurement and separation of the measuring circuit can be read in a known manner on the timepiece. in order to measure the response time of the relay R in a Vorwählerschaltung is also terminated.

The invention is not limited to that in the exemplary embodiments listed telex exchanges, but can be used in any Telecommunications system with pluggable components or assemblies and permanently installed components are equipped, provided that not all connections are made on the base of the plug-in components are connected.

Claims (6)

Patent claims: i. Test arrangement for testing permanently installed electrical components in telecommunications systems in which plug-in components are also provided and in which not all connections are connected to the bases of these plug-in components, characterized in that switching points (20, 21 and 22 in Fig. 3 ; 30, 31, 32 and 33 in Fig. 5), which enable the permanently installed electrical components (Y, R) to be checked, with the base connections (2, 3, 6, 13) of plug-in components (B) that are otherwise not connected are firmly connected, so that a test device (Fig. 4) can be connected to the permanently installed components through a test plug corresponding to the plug-in components (B). 2. Test arrangement according to claim 1, characterized in that in the measuring device individual connections leading to the plug contacts of the Pr.üfsteckers are connected to switching contacts of a rotary switch (Ds) , via which various measuring instruments are connected to the permanently installed component to be tested according to its switching position will. 3. Test arrangement according to claim 1, characterized in that in the measuring device the individual, leading to the plug contacts of the test plug 'connections are each connected to a switching contact of a rotary switch (Ds) , via which different objects to be measured are connected to the measuring device according to its switching position will. 4. Test arrangement according to claim 1, characterized in that different for testing of permanently installed electrical components, the plug contacts of the test plugs differ are connected. 5. Test arrangement according to one of the claims 1 to 4, characterized in that Plug contacts of the test plug when plugged in also establish a connection between the wired on the base connections of the pluggable components connected to the power sources of the system and the measuring device. 6. Test arrangement according to claim i, characterized characterized in that the test plugs are designed as an adapter plug between the Pluggable components and their bases are pluggable. ίο For this purpose ι sheet of drawings © 609 617/207 8.56 (609 809 2. 57)