Concrete cover characterisation using dynamic acousto-elastic testing and Rayleigh waves

•Dynamic acousto-elastic testing by using Rayleigh waves as probe wave and the first bending mode excitation as pump wave.•Nonlinear dynamic acousto-elastic behaviour of concrete.•High relative variation of nonlinear parameters for assessment of thermally damage concrete and carbonated concrete.•The...

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Bibliographic Details
Published inConstruction & building materials Vol. 114; pp. 87 - 97
Main Authors Vu, Quang Anh, Garnier, Vincent, Chaix, Jean François, Payan, Cédric, Lott, Martin, Eiras, Jesus N.
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.07.2016
Elsevier B.V
Elsevier
Subjects
Acoustic properties
Analysis
Carbonation
Concrete
Concrete cover
Conditioning
Dynamic acousto-elastic testing
Engineering Sciences
Mechanics
Non-destructive testing
Nondestructive evaluation
Rayleigh waves
Surface Rayleigh wave
Thermal damage
Thermal properties
Spain
Nondestructive evaluation
Surface Rayleigh wave
Dynamic acousto-elastic testing
Carbonation
Concrete cover
Conditioning
Thermal damage
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Summary:•Dynamic acousto-elastic testing by using Rayleigh waves as probe wave and the first bending mode excitation as pump wave.•Nonlinear dynamic acousto-elastic behaviour of concrete.•High relative variation of nonlinear parameters for assessment of thermally damage concrete and carbonated concrete.•The method opens up new possibilities for in situ measurement. This paper presents the application of surface Rayleigh waves in nonlinear dynamic acousto-elastic testing for the nondestructive evaluation of the concrete cover. Numerous physical phenomena, such as conditioning and slow dynamics, characterising the dynamic non-classical nonlinear elastic behaviour of many types of micro-heterogeneous solids, were observed in concrete. Rayleigh waves were used as probing waves to evaluate the effect of local property changes in a concrete cover. The proposed method was validated for two typical problems of concrete durability, in a case of thermal damage – distributed micro-damage – and in a case of carbonation – surface problem with determination of the carbonation depth. In both cases, the results showed that the relative variation as a function of material changes of the nonlinear parameters was much higher than that of the ultrasonic pulse velocity.
ISSN:0950-0618
1879-0526
DOI:10.1016/j.conbuildmat.2016.03.116