Estimation of Steel Rebar Strength in Existing Concrete Bridges

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Title: Estimation of Steel Rebar Strength in Existing Concrete Bridges

Author(s): Alessandro P. Fantilli and Bernardino Chiaia

Publication: Symposium Paper

Volume: 342

Issue:

Appears on pages(s): 98-113

Keywords: reinforced concrete, existing bridges, tensile strength, yield strength, steel reinforcing bar, strength-forage curves, uniaxial tensile test

DOI: 10.14359/51725939

Date: 6/1/2020

Abstract:
To design a retrofit and/or maintenance protocol for existing reinforced concrete bridges, the assessment of rebar steel strength is generally required. The current methodology consists of uniaxial tensile tests performed on bar segments extracted from a structural element. Nevertheless, in several situations (e.g., the assessment of bridges in service), this traditional method cannot be used. Hence, a new simplified approach is introduced herein. It consists of the so-called “strength-for-age curves,” which relate the average strength of steel to the year of construction. Such curves are statistically computed from a database stored in the Department of Structural and Geotechnical Engineering of Politecnico di Torino (Italy). As a result, the yield and tensile strength values experimentally measured from rebar in two existing bridges in Northern Italy, built in 1930 and 1975, respectively, were correctly predicted using the proposed model.

Related References:

1. Glanz, J., Pianigiani, G., White, J., and Patanjali, K. (2018). “Genova Bridge Collapse: The Road to Tragedy”, The New York Times, September 6. Online: https://www.nytimes.com/interactive/2018/09/06/world/europe/genoa-italy-bridge.html

2. Proske, D. (2018). “Bridge Collapse Frequencies versus Failure Probabilities”, Springer, Berlin.

3. Wardhana, K., and Hadipriono, F.C. (2003). “Analysis of Recent Bridge Failures in the United States”, ASCE Journal of Performance of Constructed Facilities, 17(3), pp. 144-150.

4. Lee, G.C., Mohan, S.B., Huang, C., and Fard, B. N. (2013). “A Study of U.S. Bridge Failures (1980-2012)”, Technical Report MCEER – 13-0008, University at Buffalo. Online at: https://ubir.buffalo.edu/xmlui/handle/10477/29474

5. Peiris, A., Hudson, J., and Harik, I. (2018). “Load testing and rating of the KY 220 road bridge”, In Caspeele, Taerwe, and Frangopol (Eds), The Sixth International Symposium on Life-Cycle Civil Engineering (IALLCE), Ghent, Belgium, 28-31 October, pp.161-167.

6. American Association of State Highway and Transportation Officials (AASHTO). (2018). “The Manual for Bridge Evaluation”, AASHTO, Washington D.C., 3rd Edition.

7. Fantilli, A. P., Frigo, B., and Chiaia, B. (2018). “A simplified approach to the evaluation of the strength of old concrete”, ICE Construction Materials, 171(6), pp. 257–266.

8. Frigo, B., Fantilli, A.P., De Biagi. V., and Veylon, G. (2017). “A protocol to assess the seismic criticality of existing small concrete dams”, Journal of Structure and Infrastructure Engineering Maintenance, Management, Life-Cycle Design and Performance, 14(9), pp. 1197-1206.

9. Verderame, G.M., Stella, A., Cosenza, E. (2001). “Mechanical properties of the steel used to reinforce RC structures built during the sixties”. 10th Italian National Congress on Seismic Engineering, Potenza-Matera, Italy, 9-13 September. (in Italian).

10. Verderame, G. M., Ricci, P., Esposito, M., and Sansiviero, F.C. (2001). “Mechanical properties of the steel used to reinforce RC structures built from 1950 to 1980”. Proceeding of the AICAP days, Padova, Italy, 19-21 May, pp. 413 – 420. (in Italian).

11. Italian Royal Decree Law. (1927). “RDL September 4, 1927, n. 1981: Rules for the acceptance of hydraulic binders and the construction of concrete and reinforced concrete structures”. Italian Royal Decree Law, Rome, Italy. (in Italian).

12. Italian Royal Decree Law. (1939). “RDL November 16, 1939, n. 2229: Rules for the construction of concrete and reinforced concrete structures”. Italian Royal Decree Law, Rome, Italy. (in Italian).

13. Italian Ministry of Infrastructures. (1957). “CL May 23, 1957, n. 1472: the reinforcement of reinforced concrete structures”. Rome, Italy. (in Italian).

14. Italian Ministry Decree. (1972). “DM May 30, 1972: Technical rules for the constructions made with concrete, ordinary and prestressed, and steel”. Italian Ministry Decree, Rome, Italy. (in Italian).

15. Italian Ministry Decree. (1974). “DM July 29, 1972: Technical rules the ordinary reinforced concrete structures”. Italian Ministry Decree, Rome, Italy. (in Italian).

16. EN ISO 15630-1. (2010). “Steel for the reinforcement and prestressing of concrete – Test methods - Part 1: Reinforcing bars, wire rod and wire”, European Committee for Standardization, Brussels.

17. Johnson, A. P., Lawler, J. S., Enser, D., Konda, T., and Backer P. (2017). “The Franklin Avenue Bridge. Part 1: History, investigation, and rehabilitation. ACI Concrete International, 39(6), pp. 32-42.

18. Zaborac, J., Athanasiou, A., Salamone, S., Bayrak, O. and Hrynyk, T. (2019). “Toward crack-based assessment of reinforced concrete infrastructure”, Proceedings of the fib Symposium, Kraków, Poland, 27-29 May.