Monotonic and quasi-static cyclic bond response of CFRP-to-steel joints after salt fog exposure

Citation:
Yang, Y., H. Biscaia, M. A. G. Silva, and C. Chastre. "Monotonic and quasi-static cyclic bond response of CFRP-to-steel joints after salt fog exposure." Composites Part B: Engineering. 168 (2019): 532-549. copy at https://docentes.fct.unl.pt/hb/publications/monotonic-and-quasi-static-cyclic-bond-response-cfrp-steel-joints-after-salt-fog-e-1

Abstract:

Deterioration of adhesively bonded CFRP/steel systems in salt fog environment, i.e., deicing salts and ocean environments, has to be taken into account in the design of steel strengthened structures. In the present work, monotonic and quasi-static cyclic loading were applied to CFRP-to-steel double strap joints for two kinds of CFRP laminates after being aged for a period of 5000 h to evaluate the bond behavior. The bonded joints exposed to salt fog had a different failure mode than that observed in the control specimens (0 h of exposure). The severe reduction of the maximum bond stress resulted from damage initiation that occurred in the corrosion region of the steel substrate, associated with final partial rupture on the corroded steel substrate around the edge of the bonded area: it was also correlated with reduced load carrying capacity. Results of pseudo-cyclic tests showed that the relationship between a local damage parameter (D) and normalized local dissipated energy (W d /G f ) and the normalized slip increment (ΔS/ΔS ult ) exhibited almost the same trend in the un-aged and aged bonded joints. The normalized slip increment can be seen as a direct indicator for the local and global damage for the un-aged and aged bonded joints. However, monotonic and quasi-static cyclic tests results revealed that the stress concentration due to local corrosion of steel substrate could lead to brittle rupture or accelerated cumulative damage once the aged bonded interface had become weaker. The bonded joints have exhibited also a smaller relative deformation capacity between CFRP and steel. © 2019 Elsevier Ltd

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