Skip to main content
Intended for healthcare professionals
Restricted access
Research article
First published January 2004

Mobilization of Passive Earth Pressures Behind Abutments of Jointless Bridges

Sami ArsoyView all authors and affiliations
Volume 1868, Issue 1
https://doi.org/10.3141/1868-21

Abstract

Bridges without expansion joints are referred to as integral bridges. The abutment and the superstructure of integral bridges act as a single structural unit. As the temperature of an integral bridge changes, the length of the bridge increases and decreases. The changes push the abutment against the approach fill and pull it away and thus cause lateral deflections. The movement of the abutment into the approach fill develops passive earth pressure that is displacement dependent. Although earth pressures are detrimental for the substructure of a bridge, they are beneficial for the superstructure because they reduce the bending moments caused by the dead loads and the live loads in the bridge girders. Therefore, relying on the beneficial effects of the full passive earth pressures, regardless of the displacement, is not conservative. Charts are proposed to estimate the magnitude of the resultant force and the point of application of the resultant force as a function of the wall displacement. Medium-dense and dense granular backfill materials were considered in developing the charts. The need for estimating the maximum mobilized passive earth pressures for jointless bridges with cohesionless backfill may be fulfilled with the proposed charts.

Get full access to this article

View all access and purchase options for this article.

Get Access

References

1. Wolde-Tinsea A. M., and Klinger J. E. Integral Abutment Bridge Design and Construction, Final Report. FHWA/MD-87/04. Maryland Department of Transportation, Baltimore, Md., 1987.
Google Scholar
2. Arsoy S., Barker R. M., and Duncan J. M. Behavior of a Semi-Integral Bridge Abutment Under Static and Temperature-Induced Cyclic Loading. Journal of Bridge Engineering, Vol. 9, No. 2, 2004, pp. 193–199.
Crossref
Google Scholar
3. Yang P.-S., Wolde-Tinsae A. M., and Greimann L. F. Effects of Predrilling and Layered Soils on Piles. Journal of Geotechnical Engineering, Vol. 111, No. 1, 1985, pp. 18–31.
Crossref
Google Scholar
4. Greimann L. F., Abendroth R. E., Johnson D. E., and Ebner P. B. Pile Design and Tests for Integral Abutment Bridges. Iowa State University, Ames, 1987.
Google Scholar
5. Soltani A. A., and Kukreti A. R. Performance Evaluation of Integral Abutment Bridges. In Transportation Research Record 1371, TRB, National Research Council, Washington, D.C., 1992, pp. 17–25.
Google Scholar
6. Chen Y. Important Considerations, Guidelines, and Practical Details of Integral Bridges. Journal of Engineering Technology, Vol. 14, 1997, pp. 16–19.
Google Scholar
7. Hoppe E. J., and Gomez J. P. Field Study of an Integral Backwall Bridge. Virginia Transportation Research Council, VTRC 97-R7, 1996.
Google Scholar
8. Burke M. P. Jr. An Introduction to the Design and Construction of Integral Bridges. Presented at Workshop on Integral Abutment Bridges, Pittsburgh, Pa., 1996.
Google Scholar
9. GangaRao H., Thippeswamy H., Dickson B., and Franco J. Survey and Design of Integral Abutment Bridges. Presented at Workshop on Integral Abutment Bridges, Pittsburgh, Pa., 1996.
Google Scholar
10. Wassermann E. P., and Walker J. H. Integral Abutments for Continuous Steel Bridges. Presented at Workshop on Integral Abutment Bridges, Pittsburgh, Pa., 1996.
Google Scholar
11. Loveall C. Integral Abutment Bridges. Presented at Workshop on Integral Abutment Bridges, Pittsburgh, Pa., 1996.
Google Scholar
12. Soltani A. A., and Kukreti A. R. Performance Evaluation of Integral Abutment Bridges. Presented at Workshop on Integral Abutment Bridges, Pittsburgh, Pa., 1996.
Google Scholar
13. Thomson T. A. Jr., and Lutenegger A. J. Passive Earth Pressure Tests on Integral Bridge Abutment. Proc., 4th International Conference on Case Histories in Geotechnical Engineering, St. Louis, Mo., 1998, pp. 733–739.
Google Scholar
14. Fang Y.-S., Chen T.-J., and Wu B.-F. Passive Earth Pressures with Various Wall Movements. Journal of Geotechnical Engineering, Vol. 120, No. 8, 1994, pp. 1307–1323.
Crossref
Google Scholar
15. Sherif M. A., Ishibashi I., and Lee C. D. Earth Pressures Against Rigid Retaining Walls. Journal of Geotechnical Engineering, Vol. 110, No. 5, 1982, pp. 679–695.
Google Scholar
16. Rowe P. W. A Stress-Strain Theory for Cohesionless Soil with Applications to Earth Pressure at Rest and Moving Walls. Geotechnique, Vol. 4, No. 2, 1954, pp. 70–88.
Crossref
Google Scholar
17. Terzaghi K. A Fundamental Fallacy in Earth Pressure Calculations. Journal of Boston Society of Civil Engineers, Vol. 23, No. 2, 1936, pp. 71–88.
Google Scholar
18. Burke M. P. Jr. The Design of Integral Concrete Bridges. Concrete International, Vol. 15, 1993, pp. 37–42.
Google Scholar
19. Arsoy S., Barker R. M., and Duncan J. M. The Behavior of Integral Abutment Bridges, Final Contract Report. Virginia Transportation of Research Council, Charlottesville, Va., 1999.
Google Scholar
20. Clough G. W., and Duncan J. M. Earth Pressures. In Foundation Engineering Handbook, 2nd ed. (Hsai-Yang Fang, ed.), van Nostrand Reinhold, New York, N.Y., 1991, pp. 223–235.
Crossref
Google Scholar
21. Duncan J. M., and Mokwa R. L. Passive Earth Pressures: Theories and Tests. Journal of Geotechnical and Geoenvironmental Engineering, Vol. 127, No. 3., 2001, pp. 248–257.
Crossref
Google Scholar
22. Bang S. Active Earth Pressure Behind Retaining Walls. Technical Note in Journal of Geotechnical Engineering, Vol. 111, No. 3, 1985, pp. 407–412.
Crossref
Google Scholar
23. Chang M.-F. Lateral Earth Pressures Behind Rotating Walls. Canadian Geotechnical Journal, Vol. 34, 1997, pp. 498–509.
Crossref
Google Scholar
24. Zhang J.-M., Shamoto Y., and Tokimatsu K. Evaluation of Earth Pressure Under Any Lateral Deformation. Soils and Foundations, Vol. 38, No. 1, 1998, pp. 15–33.
Crossref
Google Scholar
25. Douglas D. J., and Davis E. H. The Movements of Buried Footings Due to Moment and Horizontal Load and the Movement of Anchor Plates. Geotechnique, Vol. 14, No. 2, 1964, pp. 115–132.
Crossref
Google Scholar
26. Mokwa R. L., Duncan J. M., and Arsoy S. Report of Research on Resistance of Pile Caps and Integral Abutments to Lateral Loading. Center for Geotechnical Practice and Research, Department of Civil Engineering, Virginia Polytechnic Institute and State University, Blacksburg, Va., 1998.
Google Scholar
27. Peterson M. S., Kulhawy F. H., Nucci L. R., and Wasil B. A. Stress-Deformation Behavior of Soil-Concrete Interface. Contract Report B-49 (1), Department of Civil Engineering, Syracuse University, N.Y., 1976.
Google Scholar
28. Duncan J. M., Bryne P., Wong K. S., and Mabry P. Strength, Stress-Strain and Bulk Modulus Parameters for Finite Element Analysis of Stresses and Movements Is Soil Masses. Report No. UCB/GT/80-01. University of California, Berkeley, 1980.
Google Scholar
29. Caquot A. I., and Kerisel J. Tables for Calculation of Passive Pressure, Active Pressure, and Bearing Capacity of Foundations. Gauthier-Villars, Imprimeur-Editeur, Paris, France, 1948.
Google Scholar

Cite article

Cite article

Cite article

OR

Download to reference manager

If you have citation software installed, you can download article citation data to the citation manager of your choice

Share options

Share

Share this article

Share with email
EMAIL ARTICLE LINK
Share on social media

Share access to this article

Sharing links are not relevant where the article is open access and not available if you do not have a subscription.

For more information view the Sage Journals article sharing page.

Information, rights and permissions

Information

Published In

Volume 1868, Issue 1
Pages: 199 - 204
Article first published: January 2004
Issue published: January 2004

Rights and permissions

© 2004 National Academy of Sciences.
Request permissions for this article.

Authors

Affiliations

Sami Arsoy
Kocaeli University, Muhendislik Fakultesi, Insaat Muh. Bol. Izmit 41040 Turkey
View all articles by this author

Metrics and citations

Metrics

Journals metrics

This article was published in Transportation Research Record: Journal of the Transportation Research Board.

VIEW ALL JOURNAL METRICS

Article usage*

Total views and downloads: 71

*Article usage tracking started in December 2016

Altmetric

See the impact this article is making through the number of times it’s been read, and the Altmetric Score.
Learn more about the Altmetric Scores


Articles citing this one

Receive email alerts when this article is cited

Web of Science: 0

Crossref: 7

  1. Field Monitoring and Analysis of Abutment Foundation Behavior for a Cu...
    Go to citation Crossref Google Scholar
  2. Influence of Construction Joint and Bridge Geometry on Integral Abutme...
    Go to citation Crossref Google Scholar
  3. Integral abutment bridges: Investigation of seismic soil‐structure int...
    Go to citation Crossref Google Scholar
  4. Nine-Year Field-Monitoring Data from an Integral-Abutment Bridge
    Go to citation Crossref Google Scholar
  5. Observed integral abutment bridge substructure response
    Go to citation Crossref Google Scholar
  6. Field monitoring of earth pressures on integral bridge abutments
    Go to citation Crossref Google Scholar
  7. Proposed Mathematical Model for Daily and Seasonal Thermal Bridge Disp...
    Go to citation Crossref Google Scholar

Figures and tables

Figures & Media

Tables

View Options

Get access

Access options

If you have access to journal content via a personal subscription, university, library, employer or society, select from the options below:

Alternatively, view purchase options below:

Purchase 24 hour online access to view and download content.

Subscribe to this journal

Access journal content via a DeepDyve subscription or find out more about this option.

Start 2 week free trial
Need help?

View options

PDF/ePub

View PDF/ePub
Download PDF

Also from Sage