Crack detection using a frequency response function in offshore platforms

Zhao-de Zhang; Shuai Chen

doi:10.1007/s11804-007-7019-z

Journal of Marine Science and Application ›› 2007, Vol. 6 ›› Issue (3) : 1 -5. DOI: 10.1007/s11804-007-7019-z

Article

Crack detection using a frequency response function in offshore platforms

Zhao-de Zhang ¹
, Shuai Chen ²

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Abstract

Structural cracks can change the frequency response function (FRF) of an offshore platform. Thus, FRF shifts can be used to detect cracks. When a crack at a specific location and magnitude occurs in an offshore structure, changes in the FRF can be measured. In this way, shifts in FRF can be used to detect cracks. An experimental model was constructed to verify the FRF method. The relationship between FRF and cracks was found to be non-linear. The effect of multiple cracks on FRF was analyzed, and the shift due to multiple cracks was found to be much more than the summation of FRF shifts due to each of the cracks. Then the effects of noise and changes in the mass of the jacket on FRF were evaluated. The results show that significant damage to a beam can be detected by dramatic changes in the FRF, even when 10% random noise exists. FRF can also be used to approximately locate the breakage, but it can neither be efficiently used to predict the location of breakage nor the existence of small hairline cracks. The FRF shift caused by a 7% mass change is much less than the FRF shift caused by the breakage of any beam, but is larger than that caused by any early cracks.

Keywords

offshore platform / crack detection / numerical simulation / frequency response function

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Zhao-de Zhang, Shuai Chen. Crack detection using a frequency response function in offshore platforms. Journal of Marine Science and Application, 2007, 6(3): 1-5 DOI:10.1007/s11804-007-7019-z

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