This research is focused on modeling the damage of concrete due to corrosion. The load used in this paper is only focused on the internal load due to rust expansion. In this study, corrosion was modeled uniformly and non-uniformly to investigate the difference between these two configurations to the damage in concrete. The simulation in this study was carried out using the 3DNLFEA program. The results show that numerical simulation provides predictions that are in line with experimental and numerical modeling results performed by the previous study in terms of pressure and corrosion cracking patterns. From the crack analysis, the pattern found that a non-uniform corrosion model can be used to express a realistic rust corrosion development around the reinforcement. Meanwhile, uniform corrosion requires a larger loss of steel area to reach the damage stage. Therefore, for non-uniform corrosion, the corrosion rate cause cracks and reaches a limiting crack width at earlier times in the service life of the corroded part.

P.B. Bamforth, “Enhancing reinforced concrete durability: guidance on selecting measures for minimizing the risk of corrosion of reinforcement in concrete”, Concrete Society Technical Report No. 61 ,2004.

Z.P. Bazant, “Physical model for steel corrosion in concrete sea structures theory”, Journal of the Structural Division ASCE, vol. 105, pp.1137–1153, 1979

C. L. Page and K. W. J. Treadaway, “Aspects of the electrochemistry of steel in concrete”, Nature, vol. 297, pp. 109-115, 1982.

G. K. Glass and N. R. Buenfeld, “The presentation of the chloride threshold level for corrosion of steel in concrete”, Corrosion Science, vol. 39, pp. 1001-1013, 1997

G. K. Glass and N. R. Buenfeld, “Chloride-induced corrosion of steel in concrete”, Progress in Structural Engineering and Materials, vol. 2, pp. 448-458, 2000

Sutrisno, W. “Numerical Modeling of Cracking in reinforced concrete structure induced by uniform reinforcement corrosion” Jurnal Teknologi, vol. 79, no. 3, pp. 1-6, 2017.

K. Suda, S. Misra and K. Motohashi, “Corrosion products of reinforcing bars embedded in concrete”, Corrosion Science, vol. 35, pp. 1543-1549, 1993.

Zhao, Y. A. R.. “Comparison of uniform and non-uniform corrosion induced damage in reinforced concrete based on a Gaussian description of the corrosion” Corrosion Science, vol. 53, no. 9, pp. 2803-2814, 2011.

M. Ohtsu and S. Yosimura, “Analysis of crack propagation and crack initiation due to corrosion of reinforcement”, Construction and Building Materials vol. 11 pp. 437–442, 1998.

S. J. Williamson and L. A. Clark, “Pressure required to cause cover cracking of concrete due to reinforcement corrosion”, Magazine of Concrete Research, vol. 52, pp. 455–467, 2000.

A. Bentur, S. Diamond and N.S. Berke, Steel corrosion in concrete, E&FN Spon, London, 1997.

Y. Zhao. J. Yu, B. Hu, W. Jin, “Crack shape and rust distribution incorrosion-induced cracking concrete” Corrosion Science, vol. 55, pp. 385-393, 2012.

SALOME - The Open source integration platform for numerical simulation. http://www.salome-platform.org/. (2019). [Online]. Available: http://www.salome-platform.org/

B. Piscesa, M. M. Attard, A. K. Samani, and S. Tangaramvong, “Plasticity constitutive model for stress-strain relationship of confined concrete”, ACI Materials Journal, vol. 114, no. 2, pp. 361–371. 2017.