[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.12989/sss.2016.17.1.073

Investigation of influences of mixing parameters on acoustoelastic coefficient of concrete using coda wave interferometry

Shin, Sung Woo (Department of Safety Engineering, Pukyong National University)
Lee, Jiyong (Daewoo Engineering & Construction Company)
Kim, Jeong-Su (Hanwha Research Institute of Technology)
Shin, Joonwoo (Division of Navigation Science, Korea Maritime and Ocean University)

Publication Information

Smart Structures and Systems / v.17, no.1, 2016 , pp. 73-89 More about this Journal

Abstract

The stress dependence of ultrasonic wave velocity is known as the acoustoelastic effect. This effect is useful for stress monitoring if the acoustoelastic coefficient of a subject medium is known. The acoustoelastic coefficients of metallic materials such as steel have been studied widely. However, the acoustoelastic coefficient of concrete has not been well understood yet. Basic constituents of concrete are water, cement, and aggregates. The mix proportion of those constituents greatly affects many mechanical and physical properties of concrete and so does the acoustoelastic coefficient of concrete. In this study, influence of the water-cement ratio (w/c ratio) and the fine-coarse aggregates ratio (fa/ta ratio) on the acoustoelastic coefficient of concrete was investigated. The w/c and the fa/ta ratios are important parameters in mix design and affect wave behaviors in concrete. Load-controlled uni-axial compression tests were performed on concrete specimens. Ultrasonic wave measurements were also performed during the compression tests. The stretching coda wave interferometry method was used to obtain the relative velocity change of ultrasonic waves with respect to the stress level of the specimens. From the experimental results, it was found that the w/c ratio greatly affects the acoustoelastic coefficient while the fa/ta ratio does not. The acoustoelastic coefficient increased from $0.003073MPa^{-1}$ to $0.005553MPa^{-1}$ when the w/c ratio was increased from 0.4 to 0.5. On the other hand, the acoustoelastic coefficient changed in small from $0.003606MPa^{-1}$ to $0.003801MPa^{-1}$ when the fa/ta ratio was increased from 0.3 to 0.5. Finally, it was also found that the relative velocity change has a linear relationship with the stress level of concrete.

Keywords

acoustoelastic effect of concrete; acoustoelastic coefficient of concrete; coda wave interferometry; ultrasonic based stress monitoring;

Citations & Related Records

Times Cited By KSCI : 1 (Citation Analysis)

Reference
Cited By KSCI

1	Abo-Qudais, S.A. (2005), "Effect of concrete mixing parameters on propagation of ultrasonic waves", Constr. Build. Mater., 19(4), 257-263. DOI
2	Bray, D.E. and Stanley, R.K. (1997), Nondestructive evaluation: A tool in design, manufacturing, and service, CRC Press, NY, USA.
3	Cantrell, J.H. and Salama, K. (1991), "Acoustoelastic characterisation of materials", Int. Mater. Rev., 36(1), 125-145. DOI
4	Chaix, J.F., Garnier, V. and Corneloup, G. (2006), "Ultrasonic wave propagation in heterogeneous solid media: Theoretical analysis and experimental validation", Ultrasonics, 44(2), 200-210. DOI
5	Chaki, S. and Bourse, G. (2009), "Stress level measurement in prestressed steel strands using acoustoelastic effect", Exp. Mech., 49(5), 673-681. DOI
6	Dai, S., Wuttke, F. and Santamarina, J. (2013), "Coda wave analysis to monitor processes in soils", J. Geotech. Geoenviron., 139(9), 1504-1511. DOI
7	Egle, D.M. and Bray, D.E. (1976), "Measurement of acoustoelastic and third‐order elastic constants for rail steel", J. Acoust. Soc. Am., 60(3), 741-744. DOI
8	Hadziioannou, C., Larose, E., Coutant, O., Roux, P. and Campillo, M. (2009), "Stability of monitoring weak changes in multiply scattering media with ambient noise correlation: Laboratory experiments", J. Acoust. Soc. Am., 125(6), 3688-3695. DOI
9	Hughes, D.S. and Kelly, J.L. (1953), "Second-order elastic deformation of solids", Phys. Rev., 92(5), 1145-1149. DOI
10	Larose, E. and Hall, S. (2009), "Monitoring stress related velocity variation in concrete with a 2x10-5 relative resolution using diffuse ultrasound (L)", J. Acoust. Soc. Am., 125(4), 1853-1856. DOI
11	Lillamand, I., Chaix, J.F., Ploix, M.A. and Garnier, V. (2010), "Acoustoelastic effect in concrete material under uni-axial compressive loading", NDT & E Int., 43(8), 655-660. DOI
12	Liniers, A.D. (1987), "Microcracking of concrete under compression and its influence on tensile strength", Mater. Struct., 20(2), 111-116. DOI
13	Malhotra, V.M. and Carino, N.J. (2004), Handbook on nondestructive testing of concrete - 2nd Ed., CRC Press, PA, USA.
14	Mehta, P.K. and Monteiro, P.J.M. (2006), Concrete: Microstructure, Properties, and Materials, Prentice Hall, NJ, USA.
15	Mindess, S., Young, J.F. and Darwin, D. (2002), Concrete: 2nd Ed., Prentice Hall, NJ, USA.
16	Murnaghan, F.D. (1951), Finite deformation of an elastic solid, Dover Publications, NY, USA.
17	Pacheco, C. and Snieder, R. (2005), "Time-lapse travel time change of multiply scattered acoustic waves", J. Acoust. Soc. Am., 118(3), 1300-1310. DOI
18	Payan, C., Garnier, V., Moysan, J. and Johnson, P.A. (2009), "Determination of third order elastic constants in a complex solid applying coda wave interferometry", Appl. Phys. Lett., 94(1), 011904.
19	Philippidis, T.P. and Aggelis, D.G. (2005), "Experimental study of wave dispersion and attenuation in concrete", Ultrasonics, 43(7), 584-595. DOI
20	Planes, T. and Larose, E. (2013), "A review of ultrasonic coda wave interferometry in concrete", Cement Concrete Res., 53, 248-255. DOI
21	Rose, J.L. (1999), Ultrasonic waves in solid media, Cambridge University Press, Cambridge, UK
22	Popovics, J.S., Song, W., Achenbach, J., Lee, J. and Andre, R. (1998), "One-sided stress wave velocity measurement in concrete", J. Eng.Mech. - ASCE, 124(12), 1346-1353. DOI
23	Popovics, S. and Popovics, J.S. (1991), "Effect of stresses on the ultrasonic pulse velocity in concrete", Mater. Struct., 24(1), 15-23. DOI
24	Popovics, S. (1999), Strength and related properties of concrete: a quantitative approach, John Wiley & Sons, NY, USA.
25	Schurr, D.P., Kim, J., Sabra, K.G. and Jacobs, L.J. (2011), "Damage detection in concrete using coda wave interferometry", NDT & E Int., 44(8), 728-735. DOI
26	Shin, S.W. (2014), "Applicability of coda wave interferometry technique for measurement of acoustoelastic effect of concrete", J. Korean Soc. Nondestructive Testing, 34(6), 428-434. DOI
27	Shokouhi, P., Zoega, A. and Wiggenhauser, H. (2010), "Nondestructive investigation of stress-induced damage in concrete", Adv. Civil Eng., 2010, Article ID 740189.
28	Shokouhi, P., Zoega, A., Wiggenhauser, H. and Fischer, G. (2012), "Surface wave velocity-stress relationship in uniaxially loaded concrete", ACI Mater., 109(2), 141-148.
29	Snieder, R. (2006), "The theory of coda wave interferometry", Pure Appl. Geophys., 163(3), 455-473. DOI
30	Snieder, R., Gret, A., Douma, H. and Scales, J. (2002), "Coda wave interferometry for estimating nonlinear behavior in seismic velocity", Science, 295, 2253-2255. DOI
31	Zhang, Y., Abraham, O., Tourant, V., Duff, A., Lascoup, B., Loukili, A., Grondin, F. and Durand, O. (2012), "Validation of a thermal bias control technique for coda wave interferometry (CWI)", Ultrasonics, 53(3), 658-664. DOI
32	Stahler, S.C., Sens-Schonfelder, C. and Niederleithinger, E. (2011), "Monitoring stress changes in a concrete bridge with coda wave interferometry", J. Acoust. Soc. Am., 129(4), 1945-1952. DOI
33	Toupin, R.A. and Bernstein, B. (1961), "Sound waves in deformed perfectly elastic materials. Acoustoelastic effect", J. Acoust. Soc. Am., 33(2), 216-225. DOI
34	Washer, G.A., Green, R.E. and Pond, R.B. (2002), "Velocity constants for ultrasonic stress measurement in prestressing tendons", Res. Nondestruct. Eval., 14(2), 81-94. DOI