Abstract
As part of the first accelerated pavement tests completed in Costa Rica, laboratory permanent deformation tests were performed on asphalt mixture, granular base and soil samples from the test sections. The objective of this study was to calibrate prediction models using measured rutting data collected from instrumented flexible pavements. For the asphalt concrete the laboratory test was performed using unconfined cyclic loading at three different temperatures. Permanent deformation was found to be a function of the resilient strain, temperature and number of loading cycles. For the granular base and soil samples, the test was performed under repeated axial cyclic stress at different magnitudes and different confining stresses. Permanent deformation was found to be a function of the confining stress, deviator stress, moisture content, and number of loading cycles. Four instrumented flexible pavements were subjected to heavy vehicle simulator testing. Backcalculated moduli from multi depth deflectometers were introduced into an elastic multilayer system to obtain pavement responses. The number of equivalent standard axle load repetitions, the effective asphalt concrete mean temperature, and the in-place moisture content along with computed responses were used to calculate permanent deformation for the different layers. By comparing the measured rut depths with the predicted values from laboratory based models, the optimum combination of field calibration factors was determined so that the coefficient of variation was minimal by means of ordinary least squares.
This is a preview of subscription content, log in via an institution to check access.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
References
Aguiar-Moya, J. P., Corrales, J. P., Elizondo, F., & Loría-Salazar, L. (2012). PaveLab and heavy vehicle simulator implementation at the National Laboratory of Materials and Testing Models of the University of Costa Rica. Advances in pavement design through full-scale accelerated pavement testing, APT 2012.
Araya, Y. (2015). Desarrollo de modelos de deformación permanente para materiales granulares y suelos. San José: Universidad de Costa Rica.
Baker, H. B., Buth, M. R., & Van Deusen, D. A. (1994). Minnesota road research project: Load response instrumentation installation and testing procedures. Minnesota Department of Transportation.
EN 13286-7. (2004). Unbound and hydraulically bound mixtures—Part 7: Cyclic load triaxial test for unbound mixtures. European Committee for Standardization.
Guimaraes, A. C. (2009). Método mecanístico-empírico para la predicción de la deformación permanente en suelos tropicales para pavimentos. Río de Janeiro: Universidad Federal de Río de Janeiro.
Harvey, J., & Kanekanti, V. (2006). Calibration of mechanistic-empirical models using the California heavy vehicle simulators. Transportation Association of Canada. Quebec: International Society for Asphalt Pavements.
Heavy Vehicle Simulator. (2015). Monitoring of test sections and instrumentation. Documento consultado el 6 de abril del. http://www.gautrans-hvs.co.za/.
Leiva-Villacorta, F., Aguiar-Moya, J. P., & Loria-Salazar L. G. (2013). Ensayos acelerados de pavimento en Costa Rica. Infraestructura Vial Vol. 15 Núm. 26.
Leiva-Villacorta, F., Aguiar-Moya, J. P., & Loria-Salazar, L. G. (2015). Accelerated pavement testing first results at the Lanammeucr APT Facility. In Transportation Research Board 94th annual meeting. Washington, DC.
Lekarp, F. (1997). Permanent deformation behaviour of unbound granular materials. Licentiate Thesis. Kungliga Tekniska Högskolan.
NCHRP. (2004). Guide for mechanistic-empirical design of new and rehabilitated pavement structures. National Cooperative Highway Research Program, Report 1-37A, March 2004. http://www.trb.org/mepdg/guide.htm.
Powell, R. (2006). Predicting field performance on the NCAT pavement test track. Auburn: Auburn University.
Ullidtz, P., et al. (2006). Calibration of incremental-recursive flexible damage models in CalME using HVS experiments. Report prepared for the California Department of Transportation (Caltrans) Division of Research and Innovation. University of California Pavement Research Center, Davis and Berkeley.
Ullidtz, P. (1987). Pavement analysis. Development in civil engineering (Vol. 19). Amsterdam: Elsevier.
Von Quintus, H. L., Darter, M. I., & Mallela, J. (2007). Recommended practice for local calibration of the ME pavement design guide. Applied Research Associates, Inc.—Transportation Sector.
Werkmeister, S., Dawson, A., & Wellner, F. (2003). Permanent deformation behavior of granular materials and the shakedown concept. Journal of the Transportation Research Board, 1757, 75–81.
Werkmeister, S., Dawson, A., & Wellner, F. (2005). Permanent deformation behavior of granular materials. Road Materials and Pavement, 6, 31–51.
Author information
Authors and Affiliations
Corresponding author
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2016 Springer International Publishing Switzerland
About this paper
Cite this paper
Leiva-Villacorta, F., Vargas-Nordcbeck, A., Aguiar-Moya, J.P., Loría-Salazar, L. (2016). Development and Calibration of Permanent Deformation Models. In: Aguiar-Moya, J., Vargas-Nordcbeck, A., Leiva-Villacorta, F., Loría-Salazar, L. (eds) The Roles of Accelerated Pavement Testing in Pavement Sustainability. Springer, Cham. https://doi.org/10.1007/978-3-319-42797-3_37
Download citation
DOI: https://doi.org/10.1007/978-3-319-42797-3_37
Published:
Publisher Name: Springer, Cham
Print ISBN: 978-3-319-42796-6
Online ISBN: 978-3-319-42797-3
eBook Packages: Chemistry and Materials ScienceChemistry and Material Science (R0)