FR2847106A1 - Telecommunication network cable degradation preventing procedure, involves detecting electrically degraded cables that have highest points of concentration and electrical faults, and testing cables for issuing supportive document - Google Patents

Abstract

The procedure involves detecting electrically degraded cables that have highest points of concentration and highest number of electrical faults. The degraded cables are tested for issuing a supportive document for processing the cables. The cables are processed by printing a work order, doing an on site remedial/repair work, and updating a recorded data after work completion for upgrading the cable.

Description

METHOD FOR PREVENTIVE MAINTENANCE OF CABLES IN

NATURAL DEGRADATION IN A NETWORK OF

TELECOMMUNICATIONS

DESCRIPTION

TECHNICAL AREA
The present invention relates to a method for preventive maintenance of cables in natural degradation in a telecommunications network.

STATE OF THE PRIOR ART
In the field of cable maintenance in a telecommunications network, a decision support tool on the actions to be carried out in a preventive manner on the known art network is made available to network quality analysts to allow them to carry out their mission.
The objective is to:
Gather the information, contained in the databases of the applications, necessary for these analysts and historicize them, - Use the indications given, - Present summary tables, - Allow to optimize the impact of preventive maintenance actions of the local loop ( cost, gain, return on investment), - Log the various maintenance actions carried out on the network - Simulate maintenance programs according to clearly displayed criteria (cost, area priority, ...) In the implementation of this tool , the analyst is in possession of a very large network database regarding the volume of information stored. To manipulate this data certain rules must be followed. In particular, the analyst must, before launching a request, take into account the volume of data that will be returned to him.
In the event of excessive data volume or lack of compulsory data entry, alert messages are displayed on a screen.
In general, the approach followed is as follows: - The analyst chooses a request. - It then determines the desired level of research (Center / Zone / Head / Bait). - For a zone or a head, it can automatically perform a filtering with monitoring criteria. - The analyst chooses the "branch type" (Transport or Distribution) only if the data is retrieved at the network level (request "Network architecture", "Network status", "Network / Event synthesis", "Network / Signaling Summary"). - The analyst can then execute his request and work on a grid by applying sorts and filters.
The working method thus used is based on degradations observed on cables via signals. It acts by storage and processing of data. The known art tool therefore acts on a history of faults that have occurred in cables. It therefore analyzes the facts found. This working method does not represent any anticipatory nature. She works on cables already degraded.
The object of the process of the invention is to carry out preventive maintenance of cables in natural degradation, that is to say maintenance which has the object of reducing the probability of failure or degradation of these cables, by carrying out an analysis. objective and anticipation of events that could disrupt these cables.

STATEMENT OF THE INVENTION
The present invention relates to a method for preventive maintenance of cables in natural degradation in a telecommunications network, characterized in that it comprises the following steps: - early detection of electrically degraded cables, which have the greatest number of concentration points saturated, and the greatest number of electrical faults, - testing of the suspect cables thus detected in their entirety, - edition of a document to support the analysis. Advantageously, said method comprises a step of consulting the integral tests of the suspect cables detected and of the pairs known to be unusable.
Advantageously, said method comprises, after the editing step, a step of processing degraded cables with for each of these: - editing of a work order, - corrective work in the field, - updating, after work, recorded data.
Advantageously, the method of the invention further comprises: - storage of the data obtained:. by taking into account massive and random test results,. by taking into account the technical and economic characteristics of the cables, - a real-time consultation of the random tests carried out over the last six months on each cable, - a real-time consultation of the evolution of the transport cable heads, - an edition statistics on the real and estimated state of the network.

BRIEF DESCRIPTION OF THE DRAWINGS
Figure 1 illustrates the schematic representation of a telephone network. FIG. 2 illustrates the method of FIG. 3 illustrates, more precisely, a step of the method of the invention, namely the detection step. FIG. 4 illustrates possible complementary steps of the method of the invention.

DETAILED PRESENTATION OF PARTICULAR EMBODIMENTS
In Figure 1 is illustrated the schematic representation of a telephone network.
In this figure are thus represented: - a telephone distributor 10 with cable outlets 11, - an auto-switch 12, - a sub-distribution cabinet 13 containing a transport cable head 14, and a distribution cable head 15, - a zone sub-distribution cabinet 16, - an island sub-distribution cabinet 17, - residential houses 20 and 21, - residential buildings 22 and 23, - an industrial building 24, In this figure are also illustrated: - transport cables 25, 26 and 27, - distribution cables 28 to 34, - jumper wires 35, in the sub-distribution cabinet 13, - switching cables 36, - connection cables 37 to 40, The distribution cable 34 allows direct distribution between the telephone distributor 10 and the dwelling house 20.
The transport cables 26 and 27 respectively supply the power to the zone 16 distribution cabinet and the island 17 distribution cabinet.
Distribution cables 28 to 34 allow the supply of residential houses 20 and 21, residential buildings 22 and 23 and the industrial building 24.
The jumper wires 35 make it possible to connect the cable heads 14 and 15 to one another, ensuring metallic continuity.
In the description, a "local loop" corresponds to the wired part of the network between the telephone exchange 10 and the accommodation premises 20, 21, 22 and 23.
As illustrated in FIG. 2, the method for preventive maintenance of cables in natural degradation in a telecommunications network according to the invention comprises the following steps: - detection of cables showing symptoms related to degradation (step 50), - testing of suspect cables in their entirety (step 51), - possible consultation of the integral tests of the suspect cables detected and the pairs of cables known to be unusable (step 52), - publication of an analysis support document (step 53 ), - possible treatment of degraded cables with for each of these:. editing a work order (step 54),. corrective work in the field (step 55). update, after work, of the recorded data (step 56).
The cables, illustrated in FIG. 1, monitored by the method of the invention are the following: - transport cables 25, 26 and 27, - distribution cables 28, 29, 30, 31, 32, 33 and 34.
The jumper wires 35, the switching cables 36, and the connection cables 37, 38, 39 and 40 are not monitored by the method of the invention.
We will now describe step 50 of detecting cables showing symptoms related to degradation.
The detection of such cables according to the method of the known art, from electrical tests does not a priori make it possible to give a location (transport or distribution) of the fault, the test being carried out on an entire line.
The aim of this detection step is to remove such ambiguity and proposes to detect electrically degraded cables in advance, which have a large number of saturated concentration points, taking into account their economic weight.
This sought-after goal is to avoid customer signals on saturated distribution cables, which would cause significant service interruption times and urgent work.
.Identification of saturated concentration points By means of a local request, distribution cables which have saturated concentration points are listed on a regional network unit, knowing the number of total concentration points (step 60 in Figure 3).
From the synthesis / distribution network (step 61) obtained with the known art tool considered previously, we extract, for each cable head, the number of digitized lines (KN), the number of leased lines (LL ), the number of avoidable signals (SIGDI), the number of pairs occupied (POCC), the number of pairs of bad cables (NPHS).
These data are stored in an ACCESS file. Avoidable signals make it possible to confirm the approach in the final choice of cables to be treated.
Using a common FTTAM key, which is the registration number for each cable, a summary file is created which includes, for each head, the following fields: number of concentration points (NBRPC), number of concentration points saturated (NBRPCSAT), number of pairs of cables occupied (NBPAIOC), number of digitized lines (KN), number of leased lines (LL), number of rental successors (SL).
Electrical quality, local loop quality recovery (QBL) From the network quality analysis, the results of the local loop quality campaigns are periodically recorded periodically (for example every week) (tests not performed (PDE), lines good for trials (LBE)).
These results are stored in the ACCESS file over a period of 6 months throughout the regional network unit (step 62).
. Search for sub-distributions which are defective in transport We then select the sub-distributions which have a bad pair rate in transport, with high degradation and which has deteriorated in the last six months, and which have a number of defects significant local loop quality (QBL) (Number of faults> 9) (step 63). A QBL fault is an insulation fault with respect to the earth: there is a QBL fault if this insulation is less than 300 KQ.
From the transport network summary, the number of bad pairs (NBPHS) per transport head is extracted monthly.
These data are recorded in the ACCESS file over a period of 6 months. We average the number of the last 6 months, then subtract this average from month n (last value - average). A value is obtained which represents the value of the bad pairs in transport. We group by sub-distribution, only sub-distributions which have a value greater than a determined threshold are retained.
From the local loop quality history (QBL) we select the sub-distributions (SR) which have more than 9 QBL faults within six months. We then obtain a list of bad sub-distributions in QBL. We then create a list of sub-distributions.
We then apply the following rule. If a sub-distribution has an increasing rate of bad pairs in transport and a high number of QBL defects, it is deduced therefrom that QBL type defects are rather due to defective transport than to distribution (step 64). Since the method of the invention aims to a priori select defects in distribution, these defects are excluded and are treated separately (step 65).
. Detection of doubtful distributions By taking the history of QBL, we create a table taking into account the number of tests of suspected heads and the number of faults. A classification by head is carried out with identification of the zone (step 66). We cross the previous file in transport with this result and we only keep the heads whose areas are not defective in transport. A list of cables in associated distribution is assumed to be defective (step 67).
The analysis approach therefore consists in treating the cables which have the greatest number of saturated convergence points and the greatest number of electrical faults.
Step 51 for testing suspect cables may or may not be automated. When it is not automated there is output of a listing, and order to try a list of cables using industrial robots of the known art.
In step 53, the purpose of editing an analysis support document is to enable intervention actions to be launched in the field.
The step 56 of updating after work has the following advantages: - avoid incorrectly detecting the cables which have been maintained, - keep a record of the work carried out (for example marking of any defect treated by a star and erasing in the table used for the value of the field necessary for detection), - be able to follow the evolution of the health of a cable after treatment, - be able to compare the evolution of the health of a signaled cable.
To ensure timely detection, the method of the invention uses thresholds set when launching automated requests. These thresholds can therefore be configured according to the desired volume of work (number of teams available, configuration of the terrain (urban, rural, etc.), general condition of the network concerned, degree of anticipation chosen).
In any event, the method of the invention can operate on any local loop.
As illustrated in FIG. 4, advantageously, in parallel with the process described above, - storage of the data obtained (step 70):. by taking into account massive and random test results (step 71),. by taking into account the technical and economic characteristics of the cables (step 72), - a real-time consultation of the random tests carried out over the last six months on each cable (step 73), - a real-time consultation of the evolution of the heads of transport cables (step 74), - an edition of the statistics on the real and estimated state of the network (step 75).
Example of implementation of the process of the invention In an example of implementation of the process of the invention, an automated drop-down menu is used. The consultations of this one make it possible to observe the state of the local loop, its evolution (for transport). Above all, they make it possible to control the proper functioning of the process of the invention at any time and to take the necessary corrective measures.
Consultations can be carried out without prior knowledge of the local loop observed, because the drop-down menu is positioned automatically.
For example, the process successively gives: - the list of centers, - the list of zone sub-distributions, - then the list of heads of the chosen center-zone set.
By clicking on a "consult" button, you can view the QBL tests for the last six months.
The method of the invention is above all an automatic detection method which makes it possible to know in real time the quality drifts on all the cables of the local loop. The major function of this process is the editing of the analytical table.
This table can thus include ten columns which correspond respectively to: - name of the cable (FTTAM key), - number of concentration points supplied (NPC), - number of concentration points supplied and saturated (NPCSAT), - number of pairs of busy cables (POC), - number of bad cable pairs (PHS), - number of digitized lines (KN), - number of leased lines (LL), - number of rental successors (SL), - number of QBL faults on the last six months (NQBL), - number of actual faults (NREEL).
The analyst can therefore choose and prioritize maintenance actions. The method of the invention allows the latter to produce an official document intended for the services responsible for maintenance work. It also automatically edits the list of tests carried out and the list of bad pairs when they exist.
The purpose of the work then carried out is to eliminate faults which may give rise to signals. The method of calculating the statistics relating to the predictable local loop quality and the detection algorithm require an update of the treated cables.

Claims (3)

2. Method according to claim 1, which comprises a step (step 52) of consulting the integral tests of the cables detected and of the pairs known to be unusable. 3. Method according to claim 1, which comprises, after the editing step, a possible treatment of the degraded cables with for each of these: - edition of a work order (step 54), - corrective work in the field (stage 55), updating, after work, of the recorded data (step 56) 4. Method according to claim 1, in which there is a storage of the data (step 70) obtained: by taking into account massive and random test results (step 71),. by taking into account the technical and economic characteristics of the cables (step 72). 5. Method according to claim 4, in which there are the following steps: - real-time consultation of random tests carried out over the last six months on each cable (step 73), - consultation in real time of the evolution of the transport cable heads (step 74), - edition of statistics on the real and estimated state of the network (step 75).