On-line monitoring aided evaluation of power line cable shapes

•The dynamic line rating maximizes the capacity of electric transmission systems.•The optimal balance between cable model as well as experimental measurements.•Model parameters are modified to fit measurement data and their uncertainties.•Governing differential equations are adjusted to include all...

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Bibliographic Details
Published inEngineering structures Vol. 235; p. 111902
Main Authors Milewski, Sławomir, Cecot, Witold, Orkisz, Janusz
Format Journal Article
LanguageEnglish
Published Kidlington Elsevier Ltd 15.05.2021
Elsevier BV
Subjects
Computer applications
Configurations
Coupling
Data collection
Digital twin
Extensibility
FEM
Geodetic surveys
Meshless FDM
Overloading
Parameter modification
Physically based approximation
Power cables
Power line dynamic rating
Power lines
Predictions
Rigid structures
Surveying
Three dimensional models
Uncertainty
Physically based approximation
Digital twin
Meshless FDM
Power line dynamic rating
FEM
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Summary:•The dynamic line rating maximizes the capacity of electric transmission systems.•The optimal balance between cable model as well as experimental measurements.•Model parameters are modified to fit measurement data and their uncertainties.•Governing differential equations are adjusted to include all available information.•Simulated data and real existing power cable constructions are taken into account. The paper presents a novel method that by coupling of the measurement data with an advanced 3D, extensible cable model allows for the prediction of power line configuration. The method, which may be considered as an example of the predictive digital twin, is presented in two variants that were validated throughout a comparison of the predictions with an in situ geodetic surveying. It has resulted in an excellent agreement of the computed and the real power cable shapes and confirmed reliability of the proposed approaches. We use on-line measured temperature and inclinations at a certain point on a cable to enhance the non-linear mechanical model (not the simple catenary curve) of the cable sag. The proposed coupling of the real data and a computational model is done twofold, by modification of either selected parameters or equations used to model power cable configuration. In both approaches, our power cable model is combined with a rigid body model of insulator chains. The proposed predictions with quantified uncertainties may support the power line dynamic rating that in turn may significantly increase the capacity of electric transmission systems. The key component of such systems is the processing of the collected data in order to determine the maximum current that can be transmitted safely, without violating the required clearance space. Making use of the advanced 3D, extensible cable model, instead of the catenary curve, insignificantly increases computation time, however it enables taking into account out of plane loading (wind), data overload as well as effective using of measurement uncertainties.
ISSN:0141-0296
1873-7323
DOI:10.1016/j.engstruct.2021.111902