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A Broad-Based Decision-Making Procedure for Runway Friction Decay Analysis in Maintenance Operations

Author

Listed:
  • Salvatore Antonio Biancardo

    (Department of Civil, Construction and Environmental Engineering, Federico II University of Naples, 34102 Naples, Italy)

  • Francesco Abbondati

    (Department of Engineering, University of Naples Parthenope, 34102 Naples, Italy)

  • Francesca Russo

    (Department of Civil, Construction and Environmental Engineering, Federico II University of Naples, 34102 Naples, Italy)

  • Rosa Veropalumbo

    (Department of Civil, Construction and Environmental Engineering, Federico II University of Naples, 34102 Naples, Italy)

  • Gianluca Dell’Acqua

    (Department of Civil, Construction and Environmental Engineering, Federico II University of Naples, 34102 Naples, Italy)

Abstract

The evaluation of friction is a key factor in monitoring and controlling runway surface characteristics. For this reason, specific airport management and maintenance are required to continuously monitor the performance characteristics needed to guarantee an adequate level of safety and functionality. In this regard, the authors conducted years of experimental surveys at airports including Lamezia Terme International Airport. The surveys aimed to monitor air traffic, features of geometric infrastructure, the typological and physical/mechanical characteristics of pavement layers, and runway maintenance planning. The main objective of this study was to calibrate specific models to examine the evolution of friction decay on runways in relation to traffic loads. The reliability of the models was demonstrated in the light of the significance of the friction measurement patterns by learning algorithms and considering the traffic data by varying the geometric and performance characteristics of the aircraft. The calibrated models can be implemented into pavement management systems to predict runway friction degradation, based on aircraft loads during the lifetime of the surface layers of the pavement. It is thus possible to schedule the maintenance activities necessary to ensure the safety of landing and takeoff maneuvers.

Suggested Citation

  • Salvatore Antonio Biancardo & Francesco Abbondati & Francesca Russo & Rosa Veropalumbo & Gianluca Dell’Acqua, 2020. "A Broad-Based Decision-Making Procedure for Runway Friction Decay Analysis in Maintenance Operations," Sustainability, MDPI, vol. 12(9), pages 1-21, April.
    • Handle: RePEc:gam:jsusta:v:12:y:2020:i:9:p:3516-:d:350332
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    References listed on IDEAS

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