DE19622532A1 - Testing method for checking and determining position of splices in telecommunications cable - Google Patents

Abstract

The method involves using a microprocessor program controlled process for testing splice points and junctions on telecommunications cables (1), particularly the core lines (2). The method uses a computerised transmitter (10) with a keyboard (12) to send core indicators in a defined sequence. The transmitter is connected to a receiver (15) and display (11) through the splice points by means of a multi-pin adaptor, preferably a cable-end connector (14). An external test cable (4') links the cable screening and the transmitter. When a double-pole link between transmitter and receiver is achieved, the signals are sent out. The presence of any fault is displayed and the type of fault is indicated as an electrical value, e.g. of resistance.

Description

The invention relates to a method and a device for checking and marking telecommunication cable splices according to the preamble of claim 1 or Claim 10.

Test methods and devices for use in Checking and marking when splice a sleeve Telecommunications cables are generally known. Splices are used, for example, to set and branch off Telecommunication cables used.

Up to now, the splicing has usually been checked by two people who are at the opposite ends of the cable, which may be several kilometers long. A person, who is referred to below as a tester, splices one end of the cable to one end of another cable and checks the splicing via a signal transmission through the cable. Communication between the tester and the person at the other end of the cable, who is referred to below as the helper, is via the wires of the cable. In Fig. 1, the usual way of testing and labeling of telecommunication cable splices is shown in principle. The cable 1 , which may be several kilometers long, consists of many wire pairs a / b 2. Both the tester and the assistant are equipped with a test headphone 6 and a test device 3 . Such a test device 3 normally contains a transmitter unit and a receiver unit. If the splice is OK, then both can communicate with one another via the speech line 5 and the test devices 3 .

However, it often happens that the required Communication cannot take place because, for example There are line faults in the form of an interruption of the Voice line or a swapped wire on the Splice.

In addition, it always happens that the helper and the tester are not ready for communication at the ends of the cable 1 at the same time. For example, while the examiner is waiting in vain for a connection, the helper is in a traffic jam. As a result, contact cannot be established between the two or the examiner gives up waiting before contacting the examining assistant. Such problems can generally be eliminated with radio devices, but it is disadvantageous that such radio devices are susceptible to interference and must always be carried along. In the case of a communication obstacle described above, a time-consuming search procedure is required until a speech connection is established via two wires of a line pair a / b 2. The speech connection is maintained over the speech line 5 during the test process. The wires of the cable are to be checked individually with the test cable 4 and existing errors are to be determined with the test device 3 .

A speech connection requires a twin wire a / b 2, which in the case of telephone cables consists of copper conductors. For the check, the helper goes to the start of the first cable and switches to the agreed pair. The tester switches to the associated twin wire at the end of the second cable. Checking a cable connection with the known test devices 3 always requires two people. When swaps occur, it always takes a long time to determine which wires are swapped. A splice can only be checked after it has been completed, unless the helper remains at one end of the cable during the splicing time and is not available for other activities during this time. If the test centers are several kilometers apart, there is a great loss of time due to the journey, especially if communication between the tester and the assistant fails. Several trips may be necessary to localize the cause so that further action can be agreed.

In addition, when cutting a cable, there is an uncertainty with regard to the wire to be selected, in particular because the view of the counting marks is usually extremely restricted. In this situation, the searched wire pair a / b 2 can only be found out by means of a mirror or by palpation by hand. After cutting the wrong wire, a repair is carried out. In most cases, this is done by inserting another piece of wire. Currently known and known cables 1 contain several basic bundles of ten color-coded double wires, each of which forms a pair of lines a / b 2. By manually scanning, counting the bundles and using a mirror, a specific pair of wires can be determined according to a splicing plan. The determined pair of wires must be cut and spliced with one or more cables.

The many possible sources of error are disadvantageous Determining the wire pair, for example by counting, wrong scanning, confused when looking at the Mirrors etc.

The invention is therefore based on the object Method and device for checking and labeling of telecommunication cable splices, especially of wires or pairs of wires to create an immediate and secure access to the selected wire in the cable through a Automatic counterpart enables that as an answer immediately sends the appropriate cable termination pin number and thus replacing the helper.

The solution for the method according to the invention is in Characteristic of claim 1 characterized. Further Refinements of the method are in the characteristics of the Claims 2 to 9 set out.

The device for solving the problem is in particular in characterized the characterizing part of claim 10 Further solutions to the task or configurations of the Invention are in the characterizing part of patent claims 11 characterized to 14.

The fact that according to the inventive method Test transmitter via a plug connection with the splice of the Telecommunication cable is connected and at the other end Test receiver is connected, so far necessary helpers are unnecessary. Furthermore, draws the procedure is characterized in that an automatic Search process for establishing a connection takes place and that afterwards an automatic assignment and thus identification of the Cores or double cores are made. This is mainly because of this achieved that the device for establishing a connection and Testing a transceiver and one automatic allocation unit for cables. In addition, the device for establishing a connection and testing also a measuring device that is capable is volume resistance, leakage resistance, Capacitance, wave resistance or damping measurements  to make. The fact that the device for Establishing connection and checking a display value offset module has the representation of the required Wire designation in the splice plan on a display of the Signal indicator enabled is a further improvement given both the device and the method.

There are several signal transmitters for higher-pair cables switchable, which is in the offset setting for the Distinguish cable core testing.

An advantageous embodiment consists in the permanent Readiness of the test sender, which makes it possible for one Cable cut to check the desired wires before they be cut, especially if that's for the Core counting necessary, specially marked core bundles is located on the underside of the cable core.

The invention is now based on one in the drawing illustrated embodiment described in more detail.

In the drawing:

Fig. 1 is a schematic diagram of the previously used method and the device used for checking and labeling telephone cables and

Fig. 2 shows a schematic diagram of the new and improved method and the devices created for this purpose.

In the drawing, in the description and in the Claims are listed below Reference numerals with the associated terms used:  

Reference list

1 cable
2 wire pair a / b
3 tester
4 , 4 ′ test cable
5 voice line with plug
6 test headphones
10 test transmitters
11 Display or
12 input keyboard
13 multi-connector
14 cable end closure
15 test recipients

In the following it will now be explained how branch wires a / b 2 of cable 1 are tested. A mechanic can have the twisted pair number shown in digital form on the display 11 and compares it with the number specified in the plan. This prevents "warping", that is, incorrect counting out of the branching twisted pair. The fitter at the splice place an electronic or optical test transmitter 10 with a suitable adapter or a multi-connector 13 in the cable end closure 14 of a cable distributor. With the cable terminations currently used, this is a 200-pin connector. The test transmitter 10 is thus connected to the wires 2 of one or more cables 1 by a single plug-in process. In order to enable the testing of a wire when cutting the cable, the cable sheath is included in the measuring process by a test cable 4 '. Other distributors can also be checked, such as main distributors, line distributors, etc.

The test transmitter 10 now continuously searches for the two data lines, for example 2a, 2b, as shown in FIG. 2, of the test receiver 15 using an automatic search method. If the two-pole connection to the test receiver 15 is closed, then the test transmitter 10 sends the designation of the pins or wires to the test receiver 15 , which are connected to it as a data line. For example, the test transmitter 10 sends the pin numbers 5 b, 18 a of the end closure in serial coding to the test receiver 15 when the data lines of the test receiver 15 are connected to it.

The limit value at which the measurements of one of the above-mentioned measuring methods indicate an error can be set by the tester in the test receiver 15 . In the case of a faultless double wire, for example: "Data connector 1 : 18 b Data connector 2 : 18 a OK" appears on a display or a display 11 of the test receiver 15 . In the event of a negative result of a test, the type of error and, if applicable, the size are displayed, for example "Leakage resistance: 58.4 kOhm". The numerical values of each measurement can also be displayed in a modification.

Example: The termination used has the double wire 151 on pins 1 a / b and the double wire 250 on pins 100 a / b. So that the device displays the correct end closure pin number when testing, the end closure pin number 151 a or 151 b is entered as an offset in the test transmitter 10 when checking the first pair of cable wires 1 a / b.

Both the test transmitter 10 and the test receiver 11 consist of an electronic signal transmitter and an electronic signal indicator, each with a transmitter and receiver device. The respective transmitter and receiver devices are designed for information transmission via an information channel. The signal transmitter of the test transmitter 10 uses a determination unit to determine the start signal from the test receiver 15 , which wires form the information channel, and determines the wire designation on the basis of a connector position. The multi-plug connection 13 is, for example, a counterpart with 200 poles that is suitable for the end closure, and preferably a cable shield connection. The test transmitter 10 of the cable termination 14 sends in a defined order the wire designations of the wires or wire pairs a / b which are connected to the test receiver 15 . The test receiver 15 has a transmitter unit for transmitting signals (for example DC voltage pulses with a period that is greater than a display process). The test receiver 15 is provided for receiving the wire designations sent. An alphanumeric display 11 is provided to visualize the wire designations received.

An advantageous embodiment is achieved in that an adjustable offset is provided, which enables the required wire designations to be shown in the splice plan on the display 11 of the test receiver 15 . For higher-pair cables (greater than 100 double wires), several signal transmitters can be activated, which differ in the offset setting for the cable wire test. It should also be mentioned that it is advantageous to measure and display, for example, the leakage resistance, the series resistance, the inductance, the capacitance and the cable loss of a connected wire pair a / b 2. This is made possible by the device according to the invention according to FIG. 2. In addition, single-pole testing is advantageous on cable glands for cable core testing, since no cable ends are available before the first core cut. The shield of the cable 1 , which is connected via a test cable 4 'to the test transmitter 10 , serves as return conductor here.

Claims (13)

1. A method for checking and marking telecommunication cable splice points by means of a cable core tester with a transmitter / receiver unit and display device, characterized in that
that a microprocessor-controlled test transmitter ( 10 ) is loaded with a search and test program for cable cores ( 2 ),
that the double wire number that appears on a display ( 11 ) is compared with the number specified in the wear plan,
that the test transmitter ( 10 ) is inserted directly or indirectly into the splice, preferably a cable end closure ( 14 ) and connected to the wires of one or more cables ( 1 ),
that the test transmitter ( 10 ), under the control of a search procedure, continuously searches for the data line pairs which a test receiver ( 15 ) indicates or communicates,
that if the search is successful, namely if there is a two-pole connection to the test receiver ( 15 ), the test transmitter ( 10 ) transmits the designation of the pins or wires to the test receiver ( 15 ) which are connected as a data line, and
that if there is a fault, the type of fault and / or a corresponding electrical variable (for example the resistance) is displayed. 2. The method according to claim 1, characterized in that the numerical values of each measurement are displayed. 3. The method according to claim 1, characterized in that the test transmitter ( 10 ) sends the pin numbers (for example 1 a, 1 b) of the cable end closure ( 14 ) in serial coding to the test receiver ( 15 ) when the data line or data lines of the Test recipient ( 15 ) are connected to this. 4. The method according to any one of claims 1 to 3, characterized in that the limit value for the fault in the test receiver ( 15 ) is adjustable. 5. The method according to any one of claims 1 to 4, characterized in that a program-controlled automatic search process for establishing a connection takes place, that the test transmitter ( 10 ) is in constant operational readiness for testing the cable wires ( 2 ) and that the search process is followed by a microprocessor-controlled measuring method. 6. The method according to claims 1 or 6, characterized in that for checking out a wire when cutting the cable sheath, the cable jacket is included as an aid in the measuring process and is connected via a test cable ( 4 ') with the test transmitter ( 10 ). 7. The method according to any one of claims 1 to 6, characterized, that in the measuring process a method of determination of at least one of the managerial characteristics of the Cores, for example the volume resistance, the Dissipation resistance, the capacitance, the Wave resistance or damping is integrated. 8. The method according to any one of claims 1 to 7, characterized, that by entering an offset the display area the wire identification can be changed. 9. The method according to the preamble of claim 1, characterized in
that an automatic search process for establishing a connection takes place,
that a test transmitter ( 10 ) for checking the wires ( 2 ) is in constant operational readiness and
that the automatic program-controlled search is followed by an adjustable, programmable measuring method. 10. Device for checking, marking and measuring telecommunication cable gates or splices, characterized in that
that a program-controlled and / or microprocessor-controlled test transmitter ( 10 ) with display ( 11 ) and keyboard ( 12 ) via a multi-plug connection or an adapter ( 13 ) with wires or wire pairs a / b ( 2 ) and via a test cable ( 4 ' ) is connected to the shielding of one or more cables ( 1 ) and
that at the other end of the cable or cables ( 1 ) the wires or line pairs a / b are connected by means of a test cable ( 4 ) of a test receiver ( 15 ) with display ( 11 ). 11. The device according to claim 10, characterized in that an automatic measuring device for measuring and displaying electrical quantities of the cable ( 1 ) is integrated. 12. Device according to one of the claims 10 or 11, characterized in that an adjustable offset module for displaying the required wire designation in the splice plan is integrated on the display ( 11 ) of the test receiver ( 15 ). 13. Device according to one of the claims 10 to 12, characterized in that a plurality of signal transmitters or test transmitters ( 10 ) for higher-pair cables are arranged switchable, which differ in their offset setting for cable core testing and / or identification. 14. Device according to one of the claims 10 to 13, characterized, that they carry out the procedure according to Claims 1 to 9 is used.