DE1011785B - Procedure for testing and determining line faults in operationally switched loop lines operated in Morse code - Google Patents

Description

GERMAN

The detection of line faults in Morse code operated loop lines have so far always been carried out in such a way that the person responsible for checking the line himself one after the other from detector to detector and to the individual detectors by means of a telephone device with whom the central operator contacted. Care had to be taken that the connection always took place via the same loop branch. Only if it is between the control center and the detector Loop piece was in order, this speech connection could also be established. Contained that in question Line section but a fault, be it an earth fault or a wire break, it was about this Loop branch the speech connection with the control center is no longer possible, but only via the other Loop branch, and the control center had to contact the accordingly with its telephone system Switch on the other loop branch. The fact that the person in charge of testing the line at a Detector could still establish the voice connection via one loop branch on the other detector but only via the other loop branch, it was determined that the line fault was between them had to be located on both detectors.

The disadvantage of this type of line test is that two test groups are always necessary, from one of which goes off the line and the other is at the head office to handle the revision calls of the other group to receive and evaluate. Another disadvantage is that during the Submission of a revision discussion via a certain line branch a simultaneous submission of reports is impossible in many cases or at least at least is very badly disturbed.

Checking the line condition for earth faults or wire breaks does not, however, mean checking a loop line. It may be desirable here to also switch individual loop sections out of the loop so that such a loop section can be examined with regard to its insulation or its influence by external voltages independently of the power supply by the control center.

The invention therefore proposes a method for determining line faults in operationally switched, loop lines operated in Morse code, in which a test and a The disconnection of line sections located between two adjacent detectors takes place. This The method is distinguished from the known method above all by the fact that the Management of examiners without the aid of the operating device and operator of the central management Procedure for examination and determination

of line faults during operation

switched, in Morse code security

operated loop lines

Applicant:

Telefonbau und Normalzeit G.m.b.H., Frankfurt / M., Mainzer Landstr. 136/142

Werner Dardat, Frankfurt / M.-Rödelheim, has been named as the inventor

can determine and isolate management errors, with the further submission during this management test of messages is possible at any time. According to the invention is namely a one-sided grounded, with a Half-wave rectifier that can be switched in its forward direction is connected to a series of current flow indicators different points of the loop line are switched on one-pole one after the other until at a certain point the polarity of the indicator caused by the half-wave rectifier, the current flow indicator disappears and occurs again when the polarity of the indicator is reversed.

If this test procedure is carried out at the individual reporting points, the examiner recognizes the disappearance of the current flow display with a certain polarity of the instrument and the reappearance of the display after the polarity reversal of the instrument that the fault point between the two Detection points is located to which he last switched on the current flow indicator. So also then, if the reporting point is in the immediate vicinity of the current flow indicator, there is an even clearer one The rash of the current flow indicator results, it is also proposed that an instrument deflection in one resulting polarity of the device connected to the loop line an additional resistor between the connection point of the instrument in the loop line and the point of failure running line section is laid.

To determine insulation faults on cables, a method is already known in which the

703 586/82

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Direction of deflection of a galvanometer is used to determine the location of the fault. In this procedure With the help of a sensitive galvanometer, the voltage drop on the cable sheath is continuous measured. On a certain side of the fault, this voltage drop has a certain one Value that occurs again on the other side of the error, but as a result of it now in the opposite direction outflowing earth current is reversed.

As shown in FIG. 1, the tester contains a current flow indicator / with which, depending on the setting of the switches FSb or FSa, a rectifier Gl 3 or respectively. Gl 4 can be connected in series. If one of the switches FSb or FSa is thrown , the instrument / is also earthed at the same time. The plug St can be inserted into the telephone jacks of the individual detector points so that the loop line in the idle state via plug contacts

This method can therefore only be used with cables io takt α, the switch contacts USl, PTSbal, PTSabS, and assumes that the cable in question, the primary winding of the transformer U, the buttons from its supply device is switched off. By contrast, the contact valley, the switching contacts ΡΤ5 "ί> α 2, PT5a & 2, the above-identified arrangement according to the invention specifies a method that uses the 15 contacts PTSab 1 and US2 for loop lines with a single-core line to detect line faults in operational mode for the fr-coating of the plug If the polarity of the instrument is correct, the state of the loop speaks permitted without the need for special personnel.

For the implementation of the above-mentioned test association of the indicators SZ1 or SZ2, eil rectifier Eq 1 or Eq 2, the further details

the indicator SZ 2. If the polarity is incorrect, the indicator SZ1 can take effect, and the person operating the device can press the switch.

Driving is expediently a device that a Strom- 20 ter US change the polarity of the device so that

flow indicator, two half-wave rectifiers that can optionally be connected in series with this indicator, a grounding terminal and a two-wire terminating in a plug Contains connecting cord with which it is connected to the individual detector points of the loop line via the there arranged telephone jacks can be connected to the loop line. Also contains this Device switching and display elements, through which the polarity of the loop circuit is changed before the device is switched on

now the indicator SZ 2 comes into action again.

When connecting the measuring device to the loop line, the following points must now be observed:

1. Switch on the devices (Fig. 2 a)

All switches of the device must first be brought to the rest position and the plug St must be inserted into the telephone jack of the detector concerned.

line is determined and the polarity of the device corresponds. The telephone connection between the device and the grounding terminal of the person checking the line with the control center or with a second examiner who connects to another reporting point is made possible by the fact that in the device there is a switchable ¹ , 35 transmitter, local battery and Microphone existing telephone device is available, which, depending on the line status, allows speech communication with the control center either via the loop ring or via one of the loop branches and earth.

When testing loop lines, it often turns out to be necessary to disconnect individual line sections and check them separately, be it to determine the ohmic resistance or the insulation value of this line section, or to determine external voltages that are induced on this line section will measure. The device suitable for carrying out the method according to the invention can also be used expediently for this task, namely when it is necessary to break the connection. The device is correctly polarized according to the disconnection and testing of point 1, and then the faults between two adjacent detectors FSa (Fig. 1) or FSb are dealt with individually one after the other. In this case, everyone is depressed. The direction in which the fault signaling point that delimits this line section is located within the line loop can be switched on by two such devices, and if the instrument 7 deflects correctly in connection with the polarity of both devices, it can be displayed by pressing the depressed button . If, for example, the speaking switch-over element of the line key FSa to be tested is depressed and an instrument section occurs at both detector points from the loop deflection, this means that the fault line is separated and not for testing by the in Fig. 2c on the right from the device, but to the left of the b; e device for the loop test. The rash is too small to be provided with the facilities seen. To be able to recognize security is additionally the

striking detector manufactured and the handset MT via plug and jack with the device yer ^u prevented.

2. Check for detector quiescent current and correct detector polarity (Fig. 2 b)

If the indicator SZl (Fig. 1) is displayed, the polarity is reversed. It is then the switch US, as already described in standing before ^, they shall, after which the Schau- disappears ^one sign SZl and the indicator SZ 2 appears in its place.

3. Determination of the fault direction in the event of a ground fault (Fig. 2 c)

In this case, i.e. when an earth fault occurs, the fault location is determined in the control center which lead to the earth fault indication

The drawing shows the circuit arrangement of the test device and the implementation of the inventive Line test shown on the basis of some basic circuit diagrams. It shows

Fig. 1 shows the circuit arrangement of the loop tester and

Fig. 2a to 2i schematic circuit diagrams of the line loop and the test device when carrying out the various types of possible test processes. 70 when you press the FSa * button

Press the measuring range key MS , which increases the Επφ -> * sensitivity of the instrument by switching off the resistors WiI or Wi2. If the error is to the right of the starting point in Fig. 2 c:

of the instrument and if it is correctly polarized,

there is no longer an I deflection when the FSa key is pressed, but now when the FSb key is pressed, and if at the previously checked

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This means that the fault is to be found between these two reporting points.

4 Determination of the direction of the fault in the event of a wire break

(Fig.2d)

In this case, too, the error buttons FSa or FSb must be pressed one after the other. The direction of the error is again indicated by the instrument in connection with the pressed key, but this time the measuring range key does not have to be pressed. It is not necessary to observe the "polarity of the detector" when detecting a wire break.

5. Telephoning with the control center in the event of a wire break

(Fig.2e, 2f) _lg

In order to enable this speech communication between the individual reporting points and the control center, the telephone system of the control center must first be switched to the loop concerned and, in the case of series connection, to the loop branch that is passed first during the inspection, while with parallel connection the telephone system must be switched in such a way that the buzzer call can be heard above ground by pressing the SuS button (Fig. 1) on the inspection device. Then the key Ta is to be kept depressed for the duration of the telephone call, since the primary winding of the transformer Ü is connected to ground on one side via a capacitor via this key.

6. Disconnection of a line section (Fig. 2 g)

At two neighboring detector points, between which the line section to be disconnected runs, a test device is connected to the line. Here again there are all switches to put the two devices in the rest position and to polarize the device as such correctly as well as the speech connection with the headquarters.

7. Speech connection via the one to be switched out

Claims (7)

Claims: Line section (Fig. 2h) 40 In one device, the switch PTSab (Fig. 1) is toggled and on the other device the switch PTSba. This means that in one device the fr-branch is separated and the α-branch is connected to the test equipment of the device, while in the other device, conversely, the α-branch is separated and the δ-branch is connected to the corresponding test equipment of the device. In this state there is a voice connection between the two alarm points via the telephone devices of both measuring devices. 8. Measurement of external voltages (Fig. 2 i) In addition to the operating measures according to points 6 and 7, the switch FP (Fig. 1) must be turned over in one device so that contacts 1 and 2 are actuated, while the switch in the other device FP is to be reversed so that the contact FP 3 is closed. The connection shown in FIG. 2 i then arises, i. That is, an alternating current measuring instrument is placed in the relevant line section so that induced external voltages can be measured. It may be necessary here to also press the MS measuring range key. 1. Procedure for the detection of line faults in operationally switched, in Morse code security circuit operated loop lines, in which a test and a disconnection of between two neighboring detectors lying line sections takes place, characterized in that a one-sided grounded, with a half-wave rectifier that can be switched in its forward direction and is connected in series with a current flow indicator switched on one-pole one after the other at different points on the loop line is until with a certain polarity of the indicator caused by the half-wave rectifier the Current flow display disappears and reappears when the polarity of the display is reversed. 2. The method according to claim 1, characterized in that one instrument deflection resulting polarity of the device connected to the loop line an additional Resistance in the between the connection point of the instrument to the loop line and the Fault location running line section is laid. 3. Apparatus for performing the method according to claim 1 and 2, characterized in that it a current flow indicator, two half-wave rectifiers that can optionally be connected in series with this indicator, contains a grounding clamp and a two-core connecting cord ending in a plug, with which it is at the individual detector points of the loop line via the telephone jacks with the Loop line can be connected. 4. Apparatus according to claim 2 and 3, characterized in that there are switching and display elements contains, by which the polarity of the loop line is determined before the device is switched on and the polarity of the device can be adjusted accordingly. 5. Apparatus according to claim 2 to 4, characterized by a switchable in the manner, from transformer, Local battery and microphone existing telephone equipment, depending on the line condition a speech communication with the control center either via a loop ring or via one of the loop branches and earth is possible. 6. Apparatus according to claim 2 to 5, characterized in that it contains switching elements by whose actuation disconnects a loop branch after connecting the device to a loop line and the other loop branch can be laid to earth. 7. The method according to claim 1, with the aid of two devices according to claim 6, characterized characterized that with correct polarity of both devices by actuating the appropriate switching devices the line section to be tested is separated from the loop line at both detector points and for testing by those in the device intended for the loop test Facilities is provided. Considered publications: AEG help book for electrical lighting and power systems, 6th edition, Verlag Girardet, Essen, p. 322. 1 sheet of drawings © 70S 5 & 6 / S2 6.