Load Testing of Highly Skewed Concrete Bridges

International Concrete Abstracts Portal

The International Concrete Abstracts Portal is an ACI led collaboration with leading technical organizations from within the international concrete industry and offers the most comprehensive collection of published concrete abstracts.

  


Title: Load Testing of Highly Skewed Concrete Bridges

Author(s): Mauricio Diaz Arancibia and Pinar Okumus

Publication: Symposium Paper

Volume: 323

Issue:

Appears on pages(s): 2.1-2.18

Keywords: bearing displacements, deck cracking, load distribution, load testing, shrinkage, skew, temperature

DOI: 10.14359/51702432

Date: 5/1/2018

Abstract:
Recurrent service problems and uncertainties in load distribution have been frequently reported by Departments of Transportation for skewed bridges. Service problems, such as deck cracking or excessive bridge racking can lead to bridge deterioration, and indicate the need of a better understanding of the structural response of high skew bridges to service loading. This paper presents the instrumentation and load testing of a three-span, medium span length, prestressed concrete bridge with 64° of skew to understand service, analysis and design problems associated with skew. The instrumentation plan for the bridge was developed based on service problems observed in concrete bridges with high skew such as deck cracking and displacements, as reported by the literature and by regular bridge inspections. Complete understanding of skew related responses required both short-term testing and long-term load monitoring. Structural responses of the key areas of the bridge to live and temperature loads and shrinkage were measured. The effects of certain bridge details on live load distribution were determined using finite element models validated through short-term load testing data. The evolution and magnitude of bearing movements and deck strains were captured for long periods of opposite thermal tendencies.

Related References:

1. Diaz Arancibia, M.; Okumus, P.; and Oliva, G. M., “Review of Skew Effects on Prestressed Concrete Girder Bridges: Problems and Current Practices,” Proceedings of the PCI Convention and National Bridge Conference, Cleveland, OH, February 28-March 4, 2017, 50, p. 18.

2. Diaz Arancibia, M., and Okumus, P., “Causes of Excessive Detensioning Stresses in Northeast Extreme Tee (NEXT) Beams,” PCI Journal, V. 62, No. 3, 2017, pp. 31-45.

3. Hag-elsafi, O., and Kunin, J., “Load Testing for Bridge Rating: Dean’s Mill Road over Hannacrois Creek,” Report No. 147, Transportation Research and Development Bureau, New York State Department of Transportation, Albany, NY, 2006, p. 60.

4. French, E. W. C.; Dymond, Z. B.; and Shield, K. C., “Investigation of Shear Distribution Factors in Prestressed Concrete Girder Bridges,” Report No. MN/RC 2016-32, Research Services and Library, Minnesota Department of Transportation, Minneapolis, MN, 2016, p. 595.

5. Fu, G.; Feng, J.; Dimaria, J.; and Zhuang, Y., “Bridge Deck Corner Cracking on Skewed Structures,” Report No. RC-1490, Construction and Technology Division, Michigan Department of Transportation, Lansing, MI, 2007, p. 153.

6. Huang, H.; Shenton, W. H.; and Chajes, J. M., “Load Distribution for a Highly Skewed Bridge: Testing and Analysis,” Journal of Bridge Engineering, V. 9, No. 6, 2004, pp. 558-562.

7. Wisconsin Department of Transportation, “Maintenance & Inspection — Highway Structures Information System (HSI),” 2017, http://wisconsindot.gov/Pages/doing-bus/eng-consultants/cnslt-rsrces/strct/hsi.aspx.

8. Wisconsin Department of Transportation, “Bridge Manual,” 2017, Madison, WI.

9. AASHTO, “LRFD Bridge Design Specifications,” Customary U.S. Units, 7th Edition, American Association of State Highway and Transportation Officials, Washington, DC, 2014, p. 1716.

10. ACI Committee 209, “Prediction of Creep, Shrinkage and Temperature Effects in Concrete Structures (ACI 209R-92, Reapproved 1997),” ACI Manual of Concrete Practice, American Concrete Institute, Farmington Hills, MI, 1992, p. 47.

11. Walpole, E. R.; Myers, H. R.; Myers, L. S.; and Ye, K., Probability and Statistics for Engineers and Scientists, 9th Edition, Prentice Hall, Boston, MA, 2012, p. 812.

12. Phares, M. B.; Greimann, L.; and Liu, Z., “Evaluation of the Need for Longitudinal Median Joints in Bridge Decks on Dual Structures,” Report No. TR-661, Iowa Highway Research Board, Iowa Department of Transportation, Ames, IA, 2015, p. 97.