Share:


Load transfer-crack width relation of non-dowelled jointed plain concrete short slabs

    Mauricio PRADENA Affiliation
    ; Lambert HOUBEN Affiliation

Abstract

Non-dowelled short slabs are a cost-effective innovation of jointed plain concrete pavements. The development of this innovation has been concentrated in their structural performance. Still there is a lack of specific studies of the relation load transfer – crack width, being the crack width at joint the direct cause of the aggregate interlock. Considering that their provision of load transfer relies on aggregate interlock, the objective of the present article is to develop the relationship between the load transfer by aggregate interlock and its direct cause (the crack width) specifically for innovative non-dowelled short concrete slabs pavements. For that, the analysis includes a validated nonlinear aggregate interlock model incorporated in a 3D Finite Element program, laboratory results, and field measurements performed as part of the present investigation. The results show that due to the small crack widths, the short slabs are able to provide adequate load transfer (not less than 70%) even without dowels bars. Indeed, in this case, the load transfer relies on aggregate interlock and the results of the Faultimeter (residual value more than 0) have confirmed this interlocking for crack widths at joints not more than 1.2 mm, which are typical values in short slabs when the joints are activated. For that, the Early Entry saw cutting method needs to be modified or applied as a complementary method to perform the joints. Although in short concrete slabs pavements the provision of load transfer is already guaranteed by the small crack widths at joints, the application of high-quality coarse aggregates provides even higher load transfer.

Keyword : aggregate interlock, concrete pavements, crack width, joints, load transfer, short slabs

Published in Issue
Mar 27, 2018
Abstract Views
1182
PDF Downloads
981
Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

References

Achurra, S. (2009). Procedure to measure and control of the superficial friction in Chilean pavements (in Spanish): MSc Thesis. Catholic University of Chile, Santiago, Chile.

Brink, A., Horak, E., Perrie, B., Strauss, P., & Visser, A. (2004). Improvement of aggregate interlock equation used in cnc-Pave. Proceedings of the 23rd Southern African Transport Conference. Pretoria, South Africa.

Buch, N., Frabizzio, M. A., & Hiller, J. E. (2000). Impact of coarse aggregates on transverse crack performance in jointed concrete pavements. ACI Materials Journal, 97(3), 325-332.

Colley, B. E., & Humphrey, H. M. (1967). Aggregate interlock at joints in concrete pavements. Bulletin HRB National Research Council, 189, 1-18.

Covarrubias, J. P. (2011). Design of concrete slabs with optimized geometry. Proceedings of 2nd International Conference on Best Practices for Concrete Pavements. Florianopolis, Brazil.

Covarrubias, J. P. (2012). Design of concrete pavement with optimized slab geometry. Revista Ingeniería de Construcción 27(3), 181-197.

Davids, W. G., & Mahoney, J. P. (1999). Experimental verification of rigid pavement joint load transfer modeling with EverFE. Transportation Research Record, 1684, 81-89. https://doi.org/10.3141/1684-10

Hanekom, A. C., Horak, E.; Visser, A. T. (2001). Aggregate interlock load transfer efficiency at joints in concrete pavements during dynamic loading. Proceedings of the 7th International Conference on Concrete Pavements. Orlando FL, USA.

Hanekom, A. C., Horak, E.; Visser, A. T. (2003). Comparison of South African and American aggregate interlock efficiency at concrete pavement joints. Proceedings of the 16th ASCE Engineering Mechanics Conference. Seattle, USA.

Houben, L. J. M. (2010). Transversal cracking in jointed plain concrete pavements for Dutch climatic conditions. Proceedings of the 7th International DUT-Workshop on Design and Performance of Sustainable and Durable Concrete Pavement. Carmona, Spain.

Ioannides, A. M. (1984). Analysis of slabs-on-grade for a variety of loading and support conditions: PhD Thesis. University of Illinois, Urbana-Champaign, USA.

Ioannides, A. M., & Korovesis, G. (1990). Aggregate interlock: a pure-shear load transfer mechanism. Transportation Research Record, 1286, 14-24.

Jensen, E., & Hansen, W. (2001). Mechanism of load transfer-crack width relation in JPCP: influence of coarse aggregate properties. Proceedings of the 7th International Conference on Concrete Pavements. Orlando, USA.

Perez, S., & Van Geem, C. (2010). Evaluation by FWD and faultimeter of concrete slabs stability. 6th European FWD User Group Meeting Structural Condition Assessment. Sterrebeek, Belgium.

Perez, S., Beeldens, A., Maeck, J., Van Geem, C., Vanelstraete, A., Degrande, G., Lombaert, G., & De Winne, P. (2009). Evaluation of the use of FWD and Faultimeter in the stabilizations of concrete slabs (in French). Proceedings of the 21st Belgian Congress of Roads. Gent, Belgium.

Pradena, M., & Houben, L. J. M. (2014). Sustainable pavements: influence of the saw-cutting method on the performance of JPCPs. Proceedings of the 14th International Multidisciplinary Scientific GeoConference on Nano, Bio and Green Technology for a Sustainable Future. Albena, Bulgaria. https://doi.org/10.5593/SGEM2014/B62/S26.043

Pradena, M., & Houben, L. J. M. (2015). Analysis of the stress relaxation in plain concrete pavements. Baltic Journal of Road and Bridge Engineering, 10(1), 46-53. https://doi.org/10.3846/bjrbe.2015.06

Pradena, M., & Houben, L. J. M. (2016). Sustainable pavements: correction factor for the modelling of crack width at joints of short slabs. Proceedings of the 16th International Multidisciplinary Scientific GeoConference on Nano, Bio and Green Technology for a Sustainable Future. Albena, Bulgaria.

Pradena, M., & Houben, L. J. M. (2017). Influence of early-age concrete behaviour on concrete pavements performance. Journal Civil Engineer (Građevinar), 69(9), 875-883.

Roesler, J. R., Cervantes, V. G., & Amirkhanian, A. N. (2012). Accelerated performance testing of concrete pavement with short slabs. International Journal of Pavement Engineering, 13(6), 494-507. https://doi.org/10.1080/10298436.2011.575134

Ruiz, J. M., Rasmussen, R. O., Chang, G. K., Dick, J. C., & Nelson, P. K. (2005). Computer-based guidelines for concrete pavements, volume II: design and construction guidelines and HIPERPAV II user’s manual. Report FHWA–HRT–04–122, Federal Highway Administration. McLean, VA.

Salsilli, R., Wahr, C., Delgadillo, R., Huerta, J., & Sepúlveda, P. (2013). Design method for concrete pavements with short slabs based on Westergaard’s equations and Dimensional analysis. Proceedings of the 92nd Transportation Research Board Annual Meeting. Washington DC, USA.

Salsilli, R., Wahr, C., Delgadillo, R., Huerta, J., & Sepúlveda, P. (2015). Field performance of concrete pavements with short slabs and design procedure calibrated for Chilean conditions. International Journal of Pavement Engineering, 16(4), 363-379. https://doi.org/10.1080/10298436.2014.943129

Walraven, J. C. (1994). Rough cracks subjected to earthquake loading. Journal of Structural Engineering, 120(5), 1510-1524. https://doi.org/10.1061/(ASCE)0733-9445(1994)120:5(1510)